fbpx
Wikipedia

Eukaryote

January 26, 2023

"Eukaryotic cell" redirects here. For the journal, see Eukaryotic Cell (journal).

Eukaryota, whose members are known as eukaryotes (/jˈkærits, -əts/), is a diverse domain of living beasts whose cells have a nucleus.[4] All animals, plants, fungi, and many unicellular organisms, are eukaryotes. They belong to the group of organisms Eukaryota or Eukarya, which is one of the three domains of life. Bacteria and Archaea (both prokaryotes) make up the other two domains.[5][6]

Eukaryota
Temporal range: OrosirianPresent
1850–0 Ma
Red mason bee
Boletus edulis
Eudorina elegans
Chimpanzee
Ranunculus asiaticus
Isotricha intestinalis
Scientific classification
Domain: Eukaryota
(Chatton, 1925) Whittaker & Margulis, 1978
Supergroups and kingdoms[1][2][3]

Eukaryotic organisms that cannot be classified under the kingdoms Plantae, Animalia or Fungi are sometimes grouped in the paraphyletic Protista.

The eukaryotes are usually now regarded as having emerged in the Archaea or as a sister of the Asgard archaea.[7][8] This implies that there are only two domains of life, Bacteria and Archaea, with eukaryotes incorporated among archaea.[9][10] Eukaryotes represent a small minority of the number of organisms,[11] but, due to their generally much larger size, their collective global biomass is estimated to be about equal to that of prokaryotes.[11] Eukaryotes emerged approximately 2.3–1.8 billion years ago, during the Proterozoic eon, likely as flagellated phagotrophs.[12][1] Their name comes from the Greek εὖ (eu, "well" or "good") and κάρυον (karyon, "nut" or "kernel").[13]

Eukaryotic cells typically contain other membrane-bound organelles such as mitochondria and Golgi apparatus. Chloroplasts can be found in plants and algae. Prokaryotic cells may contain primitive organelles.[14] Eukaryotes may be either unicellular or multicellular, and include many cell types forming different kinds of tissue. In comparison, prokaryotes are typically unicellular. Animals, plants, and fungi are the most familiar eukaryotes. Other eukaryotes are sometimes called protists.[15]

Eukaryotes can reproduce both asexually through mitosis and sexually through meiosis and gamete fusion. In mitosis, one cell divides to produce two genetically identical cells. In meiosis, DNA replication is followed by two rounds of cell division to produce four haploid daughter cells that act as sex cells or gametes. Each gamete has just one set of chromosomes, each a unique mix of the corresponding pair of parental chromosomes resulting from genetic recombination during meiosis.[16]

Cell features

Cytology Video, Cell Features

Eukaryotic cells are typically much larger than those of prokaryotes, having a volume of around 10,000 times greater than the prokaryotic cell.[17] They have a variety of internal membrane-bound structures, called organelles, and a cytoskeleton composed of microtubules, microfilaments, and intermediate filaments, which play an important role in defining the cell's organization and shape. Eukaryotic DNA is divided into several linear bundles called chromosomes, which are separated by a microtubular spindle during nuclear division.

Internal membranes

 
The endomembrane system and its components

Eukaryote cells include a variety of membrane-bound structures, collectively referred to as the endomembrane system.[18] Simple compartments, called vesicles and vacuoles, can form by budding off other membranes. Many cells ingest food and other materials through a process of endocytosis, where the outer membrane invaginates and then pinches off to form a vesicle.[19] It is probable[citation needed] that most other membrane-bound organelles are ultimately derived from such vesicles. Alternatively some products produced by the cell can leave in a vesicle through exocytosis.

The nucleus is surrounded by a double membrane known as the nuclear envelope, with nuclear pores that allow material to move in and out.[20] Various tube- and sheet-like extensions of the nuclear membrane form the endoplasmic reticulum, which is involved in protein transport and maturation. It includes the rough endoplasmic reticulum where ribosomes are attached to synthesize proteins, which enter the interior space or lumen. Subsequently, they generally enter vesicles, which bud off from the smooth endoplasmic reticulum.[21] In most eukaryotes, these protein-carrying vesicles are released and further modified in stacks of flattened vesicles (cisternae), the Golgi apparatus.[22]

Vesicles may be specialized for various purposes. For instance, lysosomes contain digestive enzymes that break down most biomolecules in the cytoplasm.[23] Peroxisomes are used to break down peroxide, which is otherwise toxic. Many protozoans have contractile vacuoles, which collect and expel excess water, and extrusomes, which expel material used to deflect predators or capture prey. In higher plants, most of a cell's volume is taken up by a central vacuole, which mostly contains water and primarily maintains its osmotic pressure.

Mitochondria

 
Simplified structure of a mitochondrion

Mitochondria are organelles found in all but one eukaryote,[note 1] and are commonly referred to as "the powerhouse of the cell".[25] Mitochondria provide energy to the eukaryote cell by oxidising sugars or fats and releasing energy as ATP.[26] They have two surrounding membranes, each a phospholipid bi-layer; the inner of which is folded into invaginations called cristae where aerobic respiration takes place.

The outer mitochondrial membrane is freely permeable and allows almost anything to enter into the intermembrane space while the inner mitochondrial membrane is semi permeable so allows only some required things into the mitochondrial matrix.

Mitochondria contain their own DNA, which has close structural similarities to bacterial DNA, and which encodes rRNA and tRNA genes that produce RNA which is closer in structure to bacterial RNA than to eukaryote RNA.[27] They are now generally held to have developed from endosymbiotic prokaryotes, probably Alphaproteobacteria.

Some eukaryotes, such as the metamonads such as Giardia and Trichomonas, and the amoebozoan Pelomyxa, appear to lack mitochondria, but all have been found to contain mitochondrion-derived organelles, such as hydrogenosomes and mitosomes, and thus have lost their mitochondria secondarily.[24] They obtain energy by enzymatic action on nutrients absorbed from the environment. The metamonad Monocercomonoides has also acquired, by lateral gene transfer, a cytosolic sulfur mobilisation system which provides the clusters of iron and sulfur required for protein synthesis. The normal mitochondrial iron-sulfur cluster pathway has been lost secondarily.[24][28]

Plastids

Plants and various groups of algae also have plastids. Plastids also have their own DNA and are developed from endosymbionts, in this case cyanobacteria. They usually take the form of chloroplasts which, like cyanobacteria, contain chlorophyll and produce organic compounds (such as glucose) through photosynthesis. Others are involved in storing food. Although plastids probably had a single origin, not all plastid-containing groups are closely related. Instead, some eukaryotes have obtained them from others through secondary endosymbiosis or ingestion.[29] The capture and sequestering of photosynthetic cells and chloroplasts occurs in many types of modern eukaryotic organisms and is known as kleptoplasty.

Endosymbiotic origins have also been proposed for the nucleus, and for eukaryotic flagella.[30]

Cytoskeletal structures

Main article: Cytoskeleton
 
Longitudinal section through the flagellum of Chlamydomonas reinhardtii

Many eukaryotes have long slender motile cytoplasmic projections, called flagella, or similar structures called cilia. Flagella and cilia are sometimes referred to as undulipodia,[31] and are variously involved in movement, feeding, and sensation. They are composed mainly of tubulin. These are entirely distinct from prokaryotic flagellae. They are supported by a bundle of microtubules arising from a centriole, characteristically arranged as nine doublets surrounding two singlets. Flagella also may have hairs, or mastigonemes, and scales connecting membranes and internal rods. Their interior is continuous with the cell's cytoplasm.

Microfilamental structures composed of actin and actin binding proteins, e.g., α-actinin, fimbrin, filamin are present in submembranous cortical layers and bundles, as well. Motor proteins of microtubules, e.g., dynein or kinesin and actin, e.g., myosins provide dynamic character of the network.

Centrioles are often present even in cells and groups that do not have flagella, but conifers and flowering plants have neither. They generally occur in groups that give rise to various microtubular roots. These form a primary component of the cytoskeletal structure, and are often assembled over the course of several cell divisions, with one flagellum retained from the parent and the other derived from it. Centrioles produce the spindle during nuclear division.[32]

The significance of cytoskeletal structures is underlined in the determination of shape of the cells, as well as their being essential components of migratory responses like chemotaxis and chemokinesis. Some protists have various other microtubule-supported organelles. These include the radiolaria and heliozoa, which produce axopodia used in flotation or to capture prey, and the haptophytes, which have a peculiar flagellum-like organelle called the haptonema.

Cell wall

Main article: Cell wall

The cells of plants and algae, fungi and most chromalveolates have a cell wall, a layer outside the cell membrane, providing the cell with structural support, protection, and a filtering mechanism. The cell wall also prevents over-expansion when water enters the cell.[33]

The major polysaccharides making up the primary cell wall of land plants are cellulose, hemicellulose, and pectin. The cellulose microfibrils are linked via hemicellulosic tethers to form the cellulose-hemicellulose network, which is embedded in the pectin matrix. The most common hemicellulose in the primary cell wall is xyloglucan.[34]

Differences among eukaryotic cells

There are many different types of eukaryotic cells, though animals and plants are the most familiar eukaryotes, and thus provide an excellent starting point for understanding eukaryotic structure. Fungi and many protists have some substantial differences, however.

Animal cell

 
Structure of a typical animal cell
 
Structure of a typical plant cell

All animals are eukaryotic. Animal cells are distinct from those of other eukaryotes, most notably plants, as they lack cell walls and chloroplasts and have smaller vacuoles. Due to the lack of a cell wall, animal cells can transform into a variety of shapes. A phagocytic cell can even engulf other structures.

Plant cell

Main article: Plant cell

Plant cells have a number of features that distinguish them from the cells of the other eukaryotic organisms. These include:

Fungal cell

 
Fungal Hyphae cells: 1 – hyphal wall, 2 – septum, 3 – mitochondrion, 4 – vacuole, 5 – ergosterol crystal, 6 – ribosome, 7 – nucleus, 8 – endoplasmic reticulum, 9 – lipid body, 10 – plasma membrane, 11 – spitzenkörper, 12 – Golgi apparatus

The cells of fungi are similar to animal cells, with the following exceptions:[39]

  • A cell wall that contains chitin
  • Less compartmentation between cells; the hyphae of higher fungi have porous partitions called septa, which allow the passage of cytoplasm, organelles, and, sometimes, nuclei; so each organism is essentially a giant multinucleate supercell – these fungi are described as coenocytic. Primitive fungi have few or no septa.
  • Only the most primitive fungi, chytrids, have flagella.

Other eukaryotic cells

Some groups of eukaryotes have unique organelles, such as the cyanelles (unusual plastids) of the glaucophytes,[40] the haptonema of the haptophytes, or the ejectosomes of the cryptomonads. Other structures, such as pseudopodia, are found in various eukaryote groups in different forms, such as the lobose amoebozoans or the reticulose foraminiferans.[41] Structures known as cortical alveoli are vesicles present under the cell membrane of many protists such as dinoflagellates, ciliates and apicomplexan parasites.[42]

Reproduction

 
This diagram illustrates the twofold cost of sex. If each individual were to contribute the same number of offspring (two), (a) the sexual population remains the same size each generation, where the (b) asexual population doubles in size each generation.

Cell division generally takes place asexually by mitosis, a process that allows each daughter nucleus to receive one copy of each chromosome. Most eukaryotes also have a life cycle that involves sexual reproduction, alternating between a haploid phase, where only one copy of each chromosome is present in each cell and a diploid phase, wherein two copies of each chromosome are present in each cell. The diploid phase is formed by fusion of two haploid gametes to form a zygote, which may divide by mitosis or undergo chromosome reduction by meiosis. There is considerable variation in this pattern. Animals have no multicellular haploid phase, but each plant generation can consist of haploid and diploid multicellular phases.

Eukaryotes have a smaller surface area to volume ratio than prokaryotes, and thus have lower metabolic rates and longer generation times.[43]

The evolution of sexual reproduction may be a primordial and fundamental characteristic of eukaryotes. Based on a phylogenetic analysis, Dacks and Roger proposed that facultative sex was present in the common ancestor of all eukaryotes.[44] A core set of genes that function in meiosis is present in both Trichomonas vaginalis and Giardia intestinalis, two organisms previously thought to be asexual.[45][46] Since these two species are descendants of lineages that diverged early from the eukaryotic evolutionary tree, it was inferred that core meiotic genes, and hence sex, were likely present in a common ancestor of all eukaryotes.[45][46] Eukaryotic species once thought to be asexual, such as parasitic protozoa of the genus Leishmania, have been shown to have a sexual cycle.[47] Also, evidence now indicates that amoebae, previously regarded as asexual, are anciently sexual and that the majority of present-day asexual groups likely arose recently and independently.[48]

Classification

Further information: wikispecies:Eukaryota
 
Phylogenetic and symbiogenetic tree of living organisms, showing a view of the origins of eukaryotes and prokaryotes
 
One hypothesis of eukaryotic relationships – the Opisthokonta group includes both animals (Metazoa) and fungi, plants (Plantae) are placed in Archaeplastida.
 
A pie chart of described eukaryote species (except for Excavata), together with a tree showing possible relationships between the groups

In antiquity, the two lineages of animals and plants were recognized. They were given the taxonomic rank of Kingdom by Linnaeus. Though he included the fungi with plants with some reservations, it was later realized that they are quite distinct and warrant a separate kingdom, the composition of which was not entirely clear until the 1980s.[49] The various single-cell eukaryotes were originally placed with plants or animals when they became known. In 1818, the German biologist Georg A. Goldfuss coined the word protozoa to refer to organisms such as ciliates,[50] and this group was expanded until it encompassed all single-celled eukaryotes, and given their own kingdom, the Protista, by Ernst Haeckel in 1866.[51][52] The eukaryotes thus came to be composed of four kingdoms:

The protists were understood to be "primitive forms", and thus an evolutionary grade, united by their primitive unicellular nature.[52] The disentanglement of the deep splits in the tree of life only really started with DNA sequencing, leading to a system of domains rather than kingdoms as top level rank being put forward by Carl Woese, uniting all the eukaryote kingdoms under the eukaryote domain.[6] At the same time, work on the protist tree intensified, and is still actively going on today. Several alternative classifications have been forwarded, though there is no consensus in the field.

Eukaryotes are a clade usually assessed to be sister to Heimdallarchaeota in the Asgard grouping in the Archaea.[53][54][55] In one proposed system[which?], the basal groupings are the Opimoda, Diphoda, the Discoba, and the Loukozoa. The Eukaryote root is usually assessed to be near or even in Discoba[citation needed].

A classification produced in 2005 for the International Society of Protistologists,[56] which reflected the consensus of the time, divided the eukaryotes into six supposedly monophyletic 'supergroups'. However, in the same year (2005), doubts were expressed as to whether some of these supergroups were monophyletic, particularly the Chromalveolata,[57] and a review in 2006 noted the lack of evidence for several of the supposed six supergroups.[58] A revised classification in 2012[59] recognizes five supergroups.

There are also smaller groups of eukaryotes whose position is uncertain or seems to fall outside the major groups[60] – in particular, Haptophyta, Cryptophyta, Centrohelida, Telonemia, Picozoa,[61] Apusomonadida, Ancyromonadida, Breviatea, and the genus Collodictyon.[62] Overall, it seems that, although progress has been made, there are still very significant uncertainties in the evolutionary history and classification of eukaryotes. As Roger & Simpson said in 2009 "with the current pace of change in our understanding of the eukaryote tree of life, we should proceed with caution."[63] Newly identified protists, purported to represent novel, deep-branching lineages, continue to be described well into the 21st century; recent examples including Rhodelphis, putative sister group to Rhodophyta, and Anaeramoeba, anaerobic amoebaflagellates of uncertain placement.[64]

Phylogeny

The rRNA trees constructed during the 1980s and 1990s left most eukaryotes in an unresolved "crown" group (not technically a true crown), which was usually divided by the form of the mitochondrial cristae; see crown eukaryotes. The few groups that lack mitochondria branched separately, and so the absence was believed to be primitive; but this is now considered an artifact of long-branch attraction, and they are known to have lost them secondarily.[65][66]

It has been estimated that there may be 75 distinct lineages of eukaryotes.[67] Most of these lineages are protists.

The known eukaryote genome sizes vary from 8.2 megabases (Mb) in Babesia bovis to 112,000–220,050 Mb in the dinoflagellate Prorocentrum micans, showing that the genome of the ancestral eukaryote has undergone considerable variation during its evolution.[67] The last common ancestor of all eukaryotes is believed to have been a phagotrophic protist with a nucleus, at least one centriole and cilium, facultatively aerobic mitochondria, sex (meiosis and syngamy), a dormant cyst with a cell wall of chitin and/or cellulose and peroxisomes.[67] Later endosymbiosis led to the spread of plastids in some lineages.

Although there is still considerable uncertainty in global eukaryote phylogeny, particularly regarding the position of the root, a rough consensus has started to emerge from the phylogenomic studies of the past two decades.[60][68][69][70][2][24][71][1][64][3] The majority of eukaryotes can be placed in one of two large clades dubbed Amorphea (similar in composition to the unikont hypothesis) and the Diaphoretickes, which includes plants and most algal lineages. A third major grouping, the Excavata, has been abandoned as a formal group in the most recent classification of the International Society of Protistologists due to growing uncertainty as to whether its constituent groups belong together.[72] The proposed phylogeny below includes only one group of excavates (Discoba), and incorporates the recent proposal that picozoans are close relatives of rhodophytes.[73]

In some analyses, the Hacrobia group (Haptophyta + Cryptophyta) is placed next to Archaeplastida,[74] but in others it is nested inside the Archaeplastida.[75] However, several recent studies have concluded that Haptophyta and Cryptophyta do not form a monophyletic group.[76] The former could be a sister group to the SAR group, the latter cluster with the Archaeplastida (plants in the broad sense).[77]

The division of the eukaryotes into two primary clades, bikonts (Archaeplastida + SAR + Excavata) and unikonts (Amoebozoa + Opisthokonta), derived from an ancestral biflagellar organism and an ancestral uniflagellar organism, respectively, had been suggested earlier.[75][78][79] A 2012 study produced a somewhat similar division, although noting that the terms "unikonts" and "bikonts" were not used in the original sense.[61]

A highly converged and congruent set of trees appears in Derelle et al. (2015), Ren et al. (2016), Yang et al. (2017) and Cavalier-Smith (2015) including the supplementary information, resulting in a more conservative and consolidated tree. It is combined with some results from Cavalier-Smith for the basal Opimoda.[80][81][82][83][84][2][85] The main remaining controversies are the root, and the exact positioning of the Rhodophyta and the bikonts Rhizaria, Haptista, Cryptista, Picozoa and Telonemia, many of which may be endosymbiotic eukaryote-eukaryote hybrids.[86] Archaeplastida acquired chloroplasts probably by endosymbiosis of a prokaryotic ancestor related to a currently extant cyanobacterium, Gloeomargarita lithophora.[87][88][86]

Cavalier-Smith's tree

Thomas Cavalier-Smith 2010,[89] 2013,[90] 2014,[91] 2017[81] and 2018[92] places the eukaryotic tree's root between Excavata (with ventral feeding groove supported by a microtubular root) and the grooveless Euglenozoa, and monophyletic Chromista, correlated to a single endosymbiotic event of capturing a red-algae. He et al.[93] specifically supports rooting the eukaryotic tree between a monophyletic Discoba (Discicristata + Jakobida) and an Amorphea-Diaphoretickes clade.

Evolutionary history

Origin of eukaryotes

 
The three-domains tree and the Eocyte hypothesis[94]
 
Phylogenetic tree showing a possible relationship between the eukaryotes and other forms of life;[95] eukaryotes are colored red, archaea green and bacteria blue
 
Eocyte tree.[96]

The origin of the eukaryotic cell, also known as eukaryogenesis, is a milestone in the evolution of life, since eukaryotes include all complex cells and almost all multicellular organisms. A number of approaches have been used to find the first eukaryote and their closest relatives. The last eukaryotic common ancestor (LECA) is the hypothetical last common ancestor of all living eukaryotes,[5] and was most likely a biological population.[97]

Eukaryotes have a number of features that differentiate them from prokaryotes, including an endomembrane system, and unique biochemical pathways such as sterane synthesis.[98] A set of proteins called eukaryotic signature proteins (ESPs) was proposed to identify eukaryotic relatives in 2002: They have no homology to proteins known in other domains of life by then, but they appear to be universal among eukaryotes. They include proteins that make up the cytoskeleton, the complex transcription machinery, membrane-sorting systems, the nuclear pore, as well as some enzymes in the biochemical pathways.[99]

Fossils

The timing of this series of events is hard to determine; Knoll (2006) suggests they developed approximately 1.6–2.1 billion years ago. Some acritarchs are known from at least 1.65 billion years ago, and the possible alga Grypania has been found as far back as 2.1 billion years ago.[100] The Geosiphon-like fossil fungus Diskagma has been found in paleosols 2.2 billion years old.[101]

Organized living structures have been found in the black shales of the Palaeoproterozoic Francevillian B Formation in Gabon, dated at 2.1 billion years old. Eukaryotic life could have evolved at that time.[102] Fossils that are clearly related to modern groups start appearing an estimated 1.2 billion years ago, in the form of a red algae, though recent work suggests the existence of fossilized filamentous algae in the Vindhya basin dating back perhaps to 1.6 to 1.7 billion years ago.[103]

The presence of eukaryotic-specific biomarkers (steranes) in Australian shales previously indicated that eukaryotes were present in these rocks dated at 2.7 billion years old,[98][104] which was even 300 million years older than the first geological records of the appreciable amount of molecular oxygen during the Great Oxidation Event. However, these Archaean biomarkers were eventually rebutted as later contaminants.[105] Currently, putatively the oldest biomarker records are only ~800 million years old.[106] In contrast, a molecular clock analysis suggests the emergence of sterol biosynthesis as early as 2.3 billion years ago,[107] and thus there is a huge gap between molecular data and geological data, which hinders a reasonable inference of the eukaryotic evolution through biomarker records before 800 million years ago. The nature of steranes as eukaryotic biomarkers is further complicated by the production of sterols by some bacteria.[108][109]

Whenever their origins, eukaryotes may not have become ecologically dominant until much later; a massive uptick in the zinc composition of marine sediments 800 million years ago has been attributed to the rise of substantial populations of eukaryotes, which preferentially consume and incorporate zinc relative to prokaryotes, approximately a billion years after their origin (at the latest).[110]

In April 2019, biologists reported that the very large medusavirus, or a relative, may have been responsible, at least in part, for the evolutionary emergence of complex eukaryotic cells from simpler prokaryotic cells.[111]

Relationship to Archaea

The nuclear DNA and genetic machinery of eukaryotes is more similar to Archaea than Bacteria, leading to a controversial suggestion that eukaryotes should be grouped with Archaea in the clade Neomura. In other respects, such as membrane composition, eukaryotes are similar to Bacteria. Three main explanations for this have been proposed:

 
Diagram of the origin of life with the Eukaryotes appearing early, not derived from Prokaryotes, as proposed by Richard Egel in 2012. This view implies that the UCA was relatively large and complex.[118]

Alternative proposals include:

  • The chronocyte hypothesis postulates that a primitive eukaryotic cell was formed by the endosymbiosis of both archaea and bacteria by a third type of cell, termed a chronocyte. This is mainly to account for the fact that eukaryotic signature proteins were not found anywhere else by 2002.[99]
  • The universal common ancestor (UCA) of the current tree of life was a complex organism that survived a mass extinction event rather than an early stage in the evolution of life. Eukaryotes and in particular akaryotes (Bacteria and Archaea) evolved through reductive loss, so that similarities result from differential retention of original features.[119]

Assuming no other group is involved, there are three possible phylogenies for the Bacteria, Archaea, and Eukaryota in which each is monophyletic. These are labelled 1 to 3 in the table below, with a modification of hypothesis 2 making the 4th column: The eocyte hypothesis, in which the Archaea are paraphyletic. (The table and the names for the hypotheses are based on Harish & Kurland, 2017.[120])

Alternative hypotheses for the base of the tree of life
1 – Two empires 2 – Three domains 3 – Gupta 4 – Eocyte

 UCA 

 Archaea

 Bacteria

 Eukaryota


 UCA 

 Eukaryota

 Archaea

 Bacteria


 UCA 

 Eukaryota

 Bacteria

 Archaea


 UCA 
 Archaea 

 Eukaryota

 Archaea-Crenarchaeota

 Archaea-Euryarchaeota

 Bacteria

In recent years, most researchers have favoured either the three domains (3D) or the eocyte hypothesis. An rRNA analysis supports the eocyte scenario, apparently with the Eukaryote root in Excavata.[96][89][90][91][81] A cladogram supporting the eocyte hypothesis, positioning eukaryotes within Archaea, based on phylogenomic analyses of the Asgard archaea, is:[53][54][55][10]

In this scenario, the Asgard group is seen as a sister taxon of the TACK group, which comprises Thermoproteota (formerly named eocytes or Crenarchaeota), Nitrososphaerota (formerly Thaumarchaeota), and others. This group is reported contain many of the eukaryotic signature proteins and produce vesicles.[121]

In 2017, there was significant pushback against this scenario, arguing that the eukaryotes did not emerge within the Archaea. Cunha et al. produced analyses supporting the three domains (3D) or Woese hypothesis (2 in the table above) and rejecting the eocyte hypothesis (4 above).[122] Harish and Kurland found strong support for the earlier two empires (2D) or Mayr hypothesis (1 in the table above), based on analyses of the coding sequences of protein domains. They rejected the eocyte hypothesis as the least likely.[123][120] A possible interpretation of their analysis is that the universal common ancestor (UCA) of the current tree of life was a complex organism that survived an evolutionary bottleneck, rather than a simpler organism arising early in the history of life.[119] On the other hand, the researchers who came up with Asgard re-affirmed their hypothesis with additional Asgard samples.[124] Since then, the publication of additional Asgard archaeal genomes and the independent reconstruction of phylogenomic trees by multiple independent laboratories have provided additional support for an Asgard archaeal origin of eukaryotes.

Details of the relation of Asgard archaea members and eukaryotes are still under consideration,[125] although, in January 2020, scientists reported that Candidatus Prometheoarchaeum syntrophicum, a type of cultured Asgard archaea, may be a possible link between simple prokaryotic and complex eukaryotic microorganisms about two billion years ago.[126][121]

Endomembrane system and mitochondria

The origins of the endomembrane system and mitochondria are also unclear.[127] The phagotrophic hypothesis proposes that eukaryotic-type membranes lacking a cell wall originated first, with the development of endocytosis, whereas mitochondria were acquired by ingestion as endosymbionts.[128] The syntrophic hypothesis proposes that the proto-eukaryote relied on the proto-mitochondrion for food, and so ultimately grew to surround it. Here the membranes originated after the engulfment of the mitochondrion, in part thanks to mitochondrial genes (the hydrogen hypothesis is one particular version).[129]

In a study using genomes to construct supertrees, Pisani et al. (2007) suggest that, along with evidence that there was never a mitochondrion-less eukaryote, eukaryotes evolved from a syntrophy between an archaea closely related to Thermoplasmatales and an alphaproteobacterium, likely a symbiosis driven by sulfur or hydrogen. The mitochondrion and its genome is a remnant of the alphaproteobacterial endosymbiont.[130] The majority of the genes from the symbiont have been transferred to the nucleus. They make up most of the metabolic and energy-related pathways of the eukaryotic cell, while the information system (DNA polymerase, transcription, translation) is retained from archaea.[131]

Hypotheses

Different hypotheses have been proposed as to how eukaryotic cells came into existence. These hypotheses can be classified into two distinct classes – autogenous models and chimeric models.

Autogenous models
 
An autogenous model for the origin of eukaryotes.

Autogenous models propose that a proto-eukaryotic cell containing a nucleus existed first, and later acquired mitochondria.[132] According to this model, a large prokaryote developed invaginations in its plasma membrane in order to obtain enough surface area to service its cytoplasmic volume. As the invaginations differentiated in function, some became separate compartments – giving rise to the endomembrane system, including the endoplasmic reticulum, golgi apparatus, nuclear membrane, and single membrane structures such as lysosomes.[133]

Mitochondria are proposed to come from the endosymbiosis of an aerobic proteobacterium after a eukaryote with a nucleus has evolved. This theory is less held onto because it requires extra assumptions to explain current conditions. For example, as every known eukaryote has a mitochondrion (or at least show signs of having an ancestor that had), one must assumed that all the eukaryotic lineages that did not acquire mitochondria became extinct. The theory also does not explain why anaerobic variants of mitochondria have evolved.[134]

Chimeric models

Chimeric models claim that two prokaryotic cells existed initially – an archaeon and a bacterium. The closest living relatives of these appears to be Asgardarchaeota and (distantly related) the alphaproteobacteria called the proto-mitochondrion.[135][136] These cells underwent a merging process, either by a physical fusion or by endosymbiosis, thereby leading to the formation of a eukaryotic cell. Within these chimeric models, some studies further claim that mitochondria originated from a bacterial ancestor while others emphasize the role of endosymbiotic processes behind the origin of mitochondria.

The inside-out hypothesis

The inside-out hypothesis suggests that the fusion between free-living mitochondria-like bacteria, and an archaeon into a eukaryotic cell happened gradually over a long period of time, instead of in a single phagocytotic event. In this scenario, an archaeon would trap aerobic bacteria with cell protrusions, and then keep them alive to draw energy from them instead of digesting them. During the early stages the bacteria would still be partly in direct contact with the environment, and the archaeon would not have to provide them with all the required nutrients. But eventually the archaeon would engulf the bacteria completely, creating the internal membrane structures and nucleus membrane in the process.[137]

It is assumed the archaean group called halophiles went through a similar procedure, where they acquired as much as a thousand genes from a bacterium, way more than through the conventional horizontal gene transfer that often occurs in the microbial world, but that the two microbes separated again before they had fused into a single eukaryote-like cell.[138]

An expanded version of the inside-out hypothesis proposes that the eukaryotic cell was created by physical interactions between two prokaryotic organisms and that the last common ancestor of eukaryotes got its genome from a whole population or community of microbes participating in cooperative relationships to thrive and survive in their environment. The genome from the various types of microbes would complement each other, and occasional horizontal gene transfer between them would be largely to their own benefit. This accumulation of beneficial genes gave rise to the genome of the eukaryotic cell, which contained all the genes required for independence.[139][140][141]

The serial endosymbiotic hypothesis
Main article: Symbiogenesis

According to serial endosymbiotic theory (championed by Lynn Margulis), a union between a motile anaerobic bacterium (like Spirochaeta) and a thermoacidophilic crenarchaeon (like Thermoplasma which is sulfidogenic in nature) gave rise to the present day eukaryotes. This union established a motile organism capable of living in the already existing acidic and sulfurous waters. Oxygen is known to cause toxicity to organisms that lack the required metabolic machinery. Thus, the archaeon provided the bacterium with a highly beneficial reduced environment (sulfur and sulfate were reduced to sulfide). In microaerophilic conditions, oxygen was reduced to water thereby creating a mutual benefit platform. The bacterium on the other hand, contributed the necessary fermentation products and electron acceptors along with its motility feature to the archaeon thereby gaining a swimming motility for the organism.

From a consortium of bacterial and archaeal DNA originated the nuclear genome of eukaryotic cells. Spirochetes gave rise to the motile features of eukaryotic cells. Endosymbiotic unifications of the ancestors of alphaproteobacteria and cyanobacteria, led to the origin of mitochondria and plastids respectively. For example, Thiodendron has been known to have originated via an ectosymbiotic process based on a similar syntrophy of sulfur existing between the two types of bacteria – Desulfobacter and Spirochaeta.

However, such an association based on motile symbiosis has never been observed practically. Also there is no evidence of archaeans and spirochetes adapting to intense acid-based environments. In addition, the theory posits that mitochondrion-less eukaryotes have existed, tying back to the problem in the autogenous model.[132]

The hydrogen hypothesis

In the hydrogen hypothesis, the symbiotic linkage of an anaerobic and autotrophic methanogenic archaeon (host) with an alphaproteobacterium (the symbiont) gave rise to the eukaryotes. The host used hydrogen (H2) and carbon dioxide (CO2) to produce methane while the symbiont, capable of aerobic respiration, expelled H2 and CO2 as byproducts of anaerobic fermentation process. The host's methanogenic environment worked as a sink for H2, which resulted in heightened bacterial fermentation.

Endosymbiotic gene transfer acted as a catalyst for the host to acquire the symbionts' carbohydrate metabolism and turn heterotrophic in nature. Subsequently, the host's methane forming capability was lost. Thus, the origins of the heterotrophic organelle (symbiont) are identical to the origins of the eukaryotic lineage. In this hypothesis, the presence of H2 represents the selective force that forged eukaryotes out of prokaryotes.[129]

The syntrophy hypothesis

The syntrophy hypothesis was developed in contrast to the hydrogen hypothesis and proposes the existence of two symbiotic events. According to this model, the origin of eukaryotic cells was based on metabolic symbiosis (syntrophy) between a methanogenic archaeon and a deltaproteobacterium. This syntrophic symbiosis was initially facilitated by H2 transfer between different species under anaerobic environments. In earlier stages, an alphaproteobacterium became a member of this integration, and later developed into the mitochondrion. Gene transfer from a deltaproteobacterium to an archaeon led to the methanogenic archaeon developing into a nucleus. The archaeon constituted the genetic apparatus, while the deltaproteobacterium contributed towards the cytoplasmic features.

This theory incorporates two selective forces at the time of nucleus evolution

6+ serial endosymbiosis scenario

A complex scenario of 6+ serial endosymbiotic events of archaea and bacteria has been proposed in which mitochondria and an asgard related archaeota were acquired at a late stage of eukaryogenesis, possibly in combination, as a secondary endosymbiont.[142][143] The findings have been rebuked as an artifact.[144]

See also

Notes

  1. ^ To date, only one eukaryote, Monocercomonoides, is known to have completely lost its mitochondria.[24]

References

  1. ^ a b c Strassert JF, Irisarri I, Williams TA, Burki F (March 2021). "A molecular timescale for eukaryote evolution with implications for the origin of red algal-derived plastids". Nature Communications. 12 (1): 1879. Bibcode:2021NatCo..12.1879S. doi:10.1038/s41467-021-22044-z. PMC 7994803. PMID 33767194.
  2. ^ a b c Brown MW, Heiss AA, Kamikawa R, Inagaki Y, Yabuki A, Tice AK, et al. (February 2018). "Phylogenomics Places Orphan Protistan Lineages in a Novel Eukaryotic Super-Group". Genome Biology and Evolution. 10 (2): 427–433. doi:10.1093/gbe/evy014. PMC 5793813. PMID 29360967.
  3. ^ a b Tikhonenkov DV, Mikhailov KV, Gawryluk RM, Belyaev AO, Mathur V, Karpov SA, et al. (December 2022). "Microbial predators form a new supergroup of eukaryotes". Nature. 612 (7941): 714–719. doi:10.1038/s41586-022-05511-5. PMID 36477531. S2CID 254436650.
  4. ^ "Definition of EUKARYOTE". www.merriam-webster.com. Retrieved 12 December 2022.
  5. ^ a b Gabaldón T (October 2021). "Origin and Early Evolution of the Eukaryotic Cell". Annual Review of Microbiology. 75 (1): 631–647. doi:10.1146/annurev-micro-090817-062213. PMID 34343017. S2CID 236916203.
  6. ^ a b Woese CR, Kandler O, Wheelis ML (June 1990). "Towards a natural system of organisms: proposal for the domains Archaea, Bacteria, and Eucarya". Proceedings of the National Academy of Sciences of the United States of America. 87 (12): 4576–4579. Bibcode:1990PNAS...87.4576W. doi:10.1073/pnas.87.12.4576. PMC 54159. PMID 2112744.
  7. ^ Zimmer C (11 April 2016). "Scientists Unveil New 'Tree of Life'". The New York Times. from the original on 24 March 2019. Retrieved 11 April 2016.
  8. ^ Gribaldo S, Brochier-Armanet C (January 2020). "Evolutionary relationships between archaea and eukaryotes". Nature Ecology & Evolution. 4 (1): 20–21. doi:10.1038/s41559-019-1073-1. PMID 31836857.
  9. ^ Doolittle WF (February 2020). "Evolution: Two Domains of Life or Three?". Current Biology. 30 (4): R177–R179. doi:10.1016/j.cub.2020.01.010. PMID 32097647.
  10. ^ a b Williams TA, Cox CJ, Foster PG, Szöllősi GJ, Embley TM (January 2020). "Phylogenomics provides robust support for a two-domains tree of life". Nature Ecology & Evolution. 4 (1): 138–147. doi:10.1038/s41559-019-1040-x. PMC 6942926. PMID 31819234.
  11. ^ a b Whitman WB, Coleman DC, Wiebe WJ (June 1998). "Prokaryotes: the unseen majority" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 95 (12): 6578–6583. Bibcode:1998PNAS...95.6578W. doi:10.1073/pnas.95.12.6578. PMC 33863. PMID 9618454. (PDF) from the original on 20 August 2008. Retrieved 16 September 2011.
  12. ^ Leander BS (May 2020). "Predatory protists". Current Biology. 30 (10): R510–R516. doi:10.1016/j.cub.2020.03.052. PMID 32428491. S2CID 218710816.
  13. ^ Harper, Douglas. "eukaryotic". Online Etymology Dictionary.
  14. ^ Murat D, Byrne M, Komeili A (October 2010). "Cell biology of prokaryotic organelles". Cold Spring Harbor Perspectives in Biology. 2 (10): a000422. doi:10.1101/cshperspect.a000422. PMC 2944366. PMID 20739411.
  15. ^ Whittaker RH (January 1969). "New concepts of kingdoms or organisms. Evolutionary relations are better represented by new classifications than by the traditional two kingdoms". Science. 163 (3863): 150–60. Bibcode:1969Sci...163..150W. CiteSeerX 10.1.1.403.5430. doi:10.1126/science.163.3863.150. PMID 5762760.
  16. ^ Campbell NA, Cain ML, Minorsky PV, Reece JB, Urry LA (2018). "Chapter 13: Sexual Life Cycles and Meiosis". Biology: A Global Approach (11th ed.). New York: Pearson Education. ISBN 978-1-292-17043-5.
  17. ^ Yamaguchi M, Worman CO (2014). (PDF). Jpn. J. Protozool. 47 (1, 2): 29–48. Archived from the original (PDF) on 9 August 2017. Retrieved 24 October 2017.
  18. ^ Linka M, Weber AP (2011). "Evolutionary Integration of Chloroplast Metabolism with the Metabolic Networks of the Cells". In Burnap RL, Vermaas WF (eds.). Functional Genomics and Evolution of Photosynthetic Systems. Springer. p. 215. ISBN 978-94-007-1533-2. from the original on 29 May 2016. Retrieved 27 October 2015.
  19. ^ Marsh M (2001). Endocytosis. Oxford University Press. p. vii. ISBN 978-0-19-963851-2.
  20. ^ Hetzer MW (March 2010). "The nuclear envelope". Cold Spring Harbor Perspectives in Biology. 2 (3): a000539. doi:10.1101/cshperspect.a000539. PMC 2829960. PMID 20300205.
  21. ^ "Endoplasmic Reticulum (Rough and Smooth)". British Society for Cell Biology. from the original on 24 March 2019. Retrieved 12 November 2017.
  22. ^ . British Society for Cell Biology. Archived from the original on 13 November 2017. Retrieved 12 November 2017.
  23. ^ . British Society for Cell Biology. Archived from the original on 13 November 2017. Retrieved 12 November 2017.
  24. ^ a b c d Karnkowska A, Vacek V, Zubáčová Z, Treitli SC, Petrželková R, Eme L, et al. (May 2016). "A Eukaryote without a Mitochondrial Organelle". Current Biology. 26 (10): 1274–1284. doi:10.1016/j.cub.2016.03.053. PMID 27185558.
  25. ^ Saygin D, Tabib T, Bittar HE, Valenzi E, Sembrat J, Chan SY, et al. (July 1957). "Transcriptional profiling of lung cell populations in idiopathic pulmonary arterial hypertension". Pulmonary Circulation. 10 (1): 131–144. Bibcode:1957SciAm.197a.131S. doi:10.1038/scientificamerican0757-131. PMID 32166015.
  26. ^ Mack S (1 May 2006). "Re: Are there eukaryotic cells without mitochondria?". madsci.org. from the original on 24 April 2014. Retrieved 24 April 2014.
  27. ^ Watson J, Hopkins N, Roberts J, Steitz JA, Weiner A (1988). "28: The Origins of Life". Molecular Biology of the Gene (Fourth ed.). Menlo Park, CA: The Benjamin/Cummings Publishing Company, Inc. p. 1154. ISBN 978-0-8053-9614-0.
  28. ^ Davis JL (13 May 2016). . IFL Science. Archived from the original on 17 February 2019. Retrieved 13 May 2016.
  29. ^ Sato N (2006). "Origin and Evolution of Plastids: Genomic View on the Unification and Diversity of Plastids". In Wise RR, Hoober JK (eds.). The Structure and Function of Plastids. Advances in Photosynthesis and Respiration. Vol. 23. Springer Netherlands. pp. 75–102. doi:10.1007/978-1-4020-4061-0_4. ISBN 978-1-4020-4060-3.
  30. ^ Margulis L (1998). Symbiotic planet: a new look at evolution. New York: Basic Books. ISBN 978-0-465-07271-2. OCLC 39700477.[page needed]
  31. ^ Lynn Margulis, Heather I. McKhann & Lorraine Olendzenski (ed.), Illustrated Glossary of Protoctista, Jones and Bartlett Publishers, Boston, 1993, p. xviii. ISBN 0-86720-081-2
  32. ^ Vorobjev IA, Nadezhdina ES (1987). The centrosome and its role in the organization of microtubules. International Review of Cytology. Vol. 106. pp. 227–293. doi:10.1016/S0074-7696(08)61714-3. ISBN 978-0-12-364506-7. PMID 3294718.
  33. ^ Howland JL (2000). The Surprising Archaea: Discovering Another Domain of Life. Oxford: Oxford University Press. pp. 69–71. ISBN 978-0-19-511183-5.
  34. ^ Fry SC (1989). "The Structure and Functions of Xyloglucan". Journal of Experimental Botany. 40 (1): 1–11. doi:10.1093/jxb/40.1.1.
  35. ^ Raven JA (July 1987). "The role of vacuoles". New Phytologist. 106 (3): 357–422. doi:10.1111/j.1469-8137.1987.tb00149.x.
  36. ^ Oparka K (2005). Plasmodesmata. Oxford, UK: Blackwell Publishing.
  37. ^ Raven PH, Evert RF, Eichorm SE (1999). Biology of Plants. New York: W.H. Freeman.
  38. ^ Silflow CD, Lefebvre PA (December 2001). "Assembly and motility of eukaryotic cilia and flagella. Lessons from Chlamydomonas reinhardtii". Plant Physiology. 127 (4): 1500–1507. doi:10.1104/pp.010807. PMC 1540183. PMID 11743094.
  39. ^ Deacon J (2005). Fungal Biology. Cambridge, Massachusetts: Blackwell Publishers. pp. 4 and passim. ISBN 978-1-4051-3066-0.
  40. ^ Keeling PJ (October 2004). "Diversity and evolutionary history of plastids and their hosts". American Journal of Botany. 91 (10): 1481–1493. doi:10.3732/ajb.91.10.1481. PMID 21652304.
  41. ^ Patterson DJ. "Amoebae: Protists Which Move and Feed Using Pseudopodia". Tree of Life Web Project. from the original on 15 June 2010. Retrieved 12 November 2017.
  42. ^ Gould SB, Tham WH, Cowman AF, McFadden GI, Waller RF (2008). "Alveolins, a new family of cortical proteins that define the protist infrakingdom Alveolata". Molecular Biology and Evolution. 25 (6): 1219–1230. doi:10.1093/molbev/msn070. PMID 18359944.
  43. ^ Lane N (June 2011). "Energetics and genetics across the prokaryote-eukaryote divide". Biology Direct. 6 (1): 35. doi:10.1186/1745-6150-6-35. PMC 3152533. PMID 21714941.
  44. ^ Dacks J, Roger AJ (June 1999). "The first sexual lineage and the relevance of facultative sex". Journal of Molecular Evolution. 48 (6): 779–783. Bibcode:1999JMolE..48..779D. doi:10.1007/PL00013156. PMID 10229582. S2CID 9441768.
  45. ^ a b Ramesh MA, Malik SB, Logsdon JM (January 2005). "A phylogenomic inventory of meiotic genes; evidence for sex in Giardia and an early eukaryotic origin of meiosis". Current Biology. 15 (2): 185–191. doi:10.1016/j.cub.2005.01.003. PMID 15668177. S2CID 17013247.
  46. ^ a b Malik SB, Pightling AW, Stefaniak LM, Schurko AM, Logsdon JM (August 2007). Hahn MW (ed.). "An expanded inventory of conserved meiotic genes provides evidence for sex in Trichomonas vaginalis". PLOS ONE. 3 (8): e2879. Bibcode:2008PLoSO...3.2879M. doi:10.1371/journal.pone.0002879. PMC 2488364. PMID 18663385.
  47. ^ Akopyants NS, Kimblin N, Secundino N, Patrick R, Peters N, Lawyer P, Dobson DE, Beverley SM, Sacks DL (April 2009). "Demonstration of genetic exchange during cyclical development of Leishmania in the sand fly vector". Science. 324 (5924): 265–268. Bibcode:2009Sci...324..265A. doi:10.1126/science.1169464. PMC 2729066. PMID 19359589.
  48. ^ Lahr DJ, Parfrey LW, Mitchell EA, Katz LA, Lara E (July 2011). "The chastity of amoebae: re-evaluating evidence for sex in amoeboid organisms". Proceedings: Biological Sciences. 278 (1715): 2081–2090. doi:10.1098/rspb.2011.0289. PMC 3107637. PMID 21429931.
  49. ^ Moore RT (1980). "Taxonomic proposals for the classification of marine yeasts and other yeast-like fungi including the smuts". Botanica Marina. 23: 361–373.
  50. ^ Goldfuß (1818). "Ueber die Classification der Zoophyten" [On the classification of zoophytes]. Isis, Oder, Encyclopädische Zeitung von Oken (in German). 2 (6): 1008–1019. from the original on 24 March 2019. Retrieved 15 March 2019. From p. 1008: "Erste Klasse. Urthiere. Protozoa." (First class. Primordial animals. Protozoa.) [Note: each column of each page of this journal is numbered; there are two columns per page.]
  51. ^ Scamardella JM (1999). (PDF). International Microbiology. 2 (4): 207–221. PMID 10943416. Archived from the original (PDF) on 14 June 2011.
  52. ^ a b Rothschild LJ (1989). "Protozoa, Protista, Protoctista: what's in a name?". Journal of the History of Biology. 22 (2): 277–305. doi:10.1007/BF00139515. PMID 11542176. S2CID 32462158. from the original on 4 February 2020. Retrieved 4 February 2020.
  53. ^ a b Spang A, Saw JH, Jørgensen SL, Zaremba-Niedzwiedzka K, Martijn J, Lind AE, van Eijk R, Schleper C, Guy L, Ettema TJ (May 2015). "Complex archaea that bridge the gap between prokaryotes and eukaryotes". Nature. 521 (7551): 173–179. Bibcode:2015Natur.521..173S. doi:10.1038/nature14447. PMC 4444528. PMID 25945739.
  54. ^ a b Zaremba-Niedzwiedzka K, Caceres EF, Saw JH, Bäckström D, Juzokaite L, Vancaester E, Seitz KW, Anantharaman K, Starnawski P, Kjeldsen KU, Stott MB, Nunoura T, Banfield JF, Schramm A, Baker BJ, Spang A, Ettema TJ (January 2017). "Asgard archaea illuminate the origin of eukaryotic cellular complexity". Nature. 541 (7637): 353–358. Bibcode:2017Natur.541..353Z. doi:10.1038/nature21031. OSTI 1580084. PMID 28077874. S2CID 4458094. from the original on 5 December 2019. Retrieved 28 June 2019.
  55. ^ a b Liu Y, Zhou Z, Pan J, Baker BJ, Gu JD, Li M (April 2018). "Comparative genomic inference suggests mixotrophic lifestyle for Thorarchaeota". The ISME Journal. 12 (4): 1021–1031. doi:10.1038/s41396-018-0060-x. PMC 5864231. PMID 29445130.
  56. ^ Adl SM, Simpson AG, Farmer MA, Andersen RA, Anderson OR, Barta JR, et al. (2005). "The new higher level classification of eukaryotes with emphasis on the taxonomy of protists". The Journal of Eukaryotic Microbiology. 52 (5): 399–451. doi:10.1111/j.1550-7408.2005.00053.x. PMID 16248873. S2CID 8060916.
  57. ^ Harper JT, Waanders E, Keeling PJ (January 2005). (PDF). International Journal of Systematic and Evolutionary Microbiology. 55 (Pt 1): 487–496. doi:10.1099/ijs.0.63216-0. PMID 15653923. Archived from the original (PDF) on 17 December 2008.
  58. ^ Parfrey LW, Barbero E, Lasser E, Dunthorn M, Bhattacharya D, Patterson DJ, Katz LA (December 2006). "Evaluating support for the current classification of eukaryotic diversity". PLOS Genetics. 2 (12): e220. doi:10.1371/journal.pgen.0020220. PMC 1713255. PMID 17194223.
  59. ^ Adl SM, Simpson AG, Lane CE, Lukeš J, Bass D, Bowser SS, et al. (September 2012). (PDF). The Journal of Eukaryotic Microbiology. 59 (5): 429–93. doi:10.1111/j.1550-7408.2012.00644.x. PMC 3483872. PMID 23020233. Archived from the original (PDF) on 16 June 2016.
  60. ^ a b Burki F (May 2014). "The eukaryotic tree of life from a global phylogenomic perspective". Cold Spring Harbor Perspectives in Biology. 6 (5): a016147. doi:10.1101/cshperspect.a016147. PMC 3996474. PMID 24789819.
  61. ^ a b Zhao S, Burki F, Bråte J, Keeling PJ, Klaveness D, Shalchian-Tabrizi K (June 2012). "Collodictyon – an ancient lineage in the tree of eukaryotes". Molecular Biology and Evolution. 29 (6): 1557–1568. doi:10.1093/molbev/mss001. PMC 3351787. PMID 22319147.
  62. ^ Romari K, Vaulot D (2004). "Composition and temporal variability of picoeukaryote communities at a coastal site of the English Channel from 18S rDNA sequences". Limnol Oceanogr. 49 (3): 784–798. Bibcode:2004LimOc..49..784R. doi:10.4319/lo.2004.49.3.0784. S2CID 86718111.
  63. ^ Roger AJ, Simpson AG (February 2009). "Evolution: revisiting the root of the eukaryote tree". Current Biology. 19 (4): R165–67. doi:10.1016/j.cub.2008.12.032. PMID 19243692. S2CID 13172971.
  64. ^ a b Burki F, Roger AJ, Brown MW, Simpson AG (January 2020). "The New Tree of Eukaryotes". Trends in Ecology & Evolution. 35 (1): 43–55. doi:10.1016/j.tree.2019.08.008. PMID 31606140.
  65. ^ Tovar J, Fischer A, Clark CG (June 1999). "The mitosome, a novel organelle related to mitochondria in the amitochondrial parasite Entamoeba histolytica". Molecular Microbiology. 32 (5): 1013–1021. doi:10.1046/j.1365-2958.1999.01414.x. PMID 10361303. S2CID 22805284.
  66. ^ Boxma B, de Graaf RM, van der Staay GW, van Alen TA, Ricard G, Gabaldón T, van Hoek AH, Moon-van der Staay SY, Koopman WJ, van Hellemond JJ, Tielens AG, Friedrich T, Veenhuis M, Huynen MA, Hackstein JH (March 2005). "An anaerobic mitochondrion that produces hydrogen" (PDF). Nature. 434 (7029): 74–79. Bibcode:2005Natur.434...74B. doi:10.1038/nature03343. PMID 15744302. S2CID 4401178. (PDF) from the original on 24 January 2019. Retrieved 24 January 2019.
  67. ^ a b c Jagus R, Bachvaroff TR, Joshi B, Place AR (2012). "Diversity of Eukaryotic Translational Initiation Factor eIF4E in Protists". Comparative and Functional Genomics. 2012: 1–21. doi:10.1155/2012/134839. PMC 3388326. PMID 22778692.
  68. ^ Burki F, Kaplan M, Tikhonenkov DV, Zlatogursky V, Minh BQ, Radaykina LV, Smirnov A, Mylnikov AP, Keeling PJ (January 2016). "Untangling the early diversification of eukaryotes: a phylogenomic study of the evolutionary origins of Centrohelida, Haptophyta and Cryptista". Proceedings: Biological Sciences. 283 (1823): 20152802. doi:10.1098/rspb.2015.2802. PMC 4795036. PMID 26817772.
  69. ^ Janouškovec J, Tikhonenkov DV, Burki F, Howe AT, Rohwer FL, Mylnikov AP, Keeling PJ (December 2017). "A New Lineage of Eukaryotes Illuminates Early Mitochondrial Genome Reduction" (PDF). Current Biology. 27 (23): 3717–24.e5. doi:10.1016/j.cub.2017.10.051. PMID 29174886. S2CID 37933928. (PDF) from the original on 27 April 2019. Retrieved 2 September 2019.
  70. ^ Bodył A (February 2018). "Did some red alga-derived plastids evolve via kleptoplastidy? A hypothesis". Biological Reviews of the Cambridge Philosophical Society. 93 (1): 201–222. doi:10.1111/brv.12340. PMID 28544184. S2CID 24613863.
  71. ^ Lax G, Eglit Y, Eme L, Bertrand EM, Roger AJ, Simpson AG (November 2018). "Hemimastigophora is a novel supra-kingdom-level lineage of eukaryotes". Nature. 564 (7736): 410–414. Bibcode:2018Natur.564..410L. doi:10.1038/s41586-018-0708-8. PMID 30429611. S2CID 205570993.
  72. ^ Adl SM, Bass D, Lane CE, Lukeš J, Schoch CL, Smirnov A, et al. (January 2019). "Revisions to the Classification, Nomenclature, and Diversity of Eukaryotes". The Journal of Eukaryotic Microbiology. 66 (1): 4–119. doi:10.1111/jeu.12691. PMC 6492006. PMID 30257078.
  73. ^ Schön ME, Zlatogursky VV, Singh RP, Poirier C, Wilken S, Mathur V, et al. (2021). "Picozoa are archaeplastids without plastid". Nature Communications. 12 (1): 6651. bioRxiv 10.1101/2021.04.14.439778. doi:10.1038/s41467-021-26918-0. PMC 8599508. PMID 34789758. S2CID 233328713.
  74. ^ Burki F, Shalchian-Tabrizi K, Minge M, Skjaeveland A, Nikolaev SI, Jakobsen KS, Pawlowski J (August 2007). Butler G (ed.). "Phylogenomics reshuffles the eukaryotic supergroups". PLOS ONE. 2 (8): e790. Bibcode:2007PLoSO...2..790B. doi:10.1371/journal.pone.0000790. PMC 1949142. PMID 17726520.
  75. ^ a b Kim E, Graham LE (July 2008). Redfield RJ (ed.). "EEF2 analysis challenges the monophyly of Archaeplastida and Chromalveolata". PLOS ONE. 3 (7): e2621. Bibcode:2008PLoSO...3.2621K. doi:10.1371/journal.pone.0002621. PMC 2440802. PMID 18612431.
  76. ^ Baurain D, Brinkmann H, Petersen J, Rodríguez-Ezpeleta N, Stechmann A, Demoulin V, Roger AJ, Burger G, Lang BF, Philippe H (July 2010). "Phylogenomic evidence for separate acquisition of plastids in cryptophytes, haptophytes, and stramenopiles". Molecular Biology and Evolution. 27 (7): 1698–1709. doi:10.1093/molbev/msq059. PMID 20194427.
  77. ^ Burki F, Okamoto N, Pombert JF, Keeling PJ (June 2012). "The evolutionary history of haptophytes and cryptophytes: phylogenomic evidence for separate origins". Proceedings: Biological Sciences. 279 (1736): 2246–2254. doi:10.1098/rspb.2011.2301. PMC 3321700. PMID 22298847.
  78. ^ Cavalier-Smith T (2003). "Protist phylogeny and the high-level classification of Protozoa". European Journal of Protistology. 39 (4): 338–348. doi:10.1078/0932-4739-00002. S2CID 84403388.
  79. ^ Burki F, Pawlowski J (October 2006). "Monophyly of Rhizaria and multigene phylogeny of unicellular bikonts". Molecular Biology and Evolution. 23 (10): 1922–1930. doi:10.1093/molbev/msl055. PMID 16829542.
  80. ^ Ren R, Sun Y, Zhao Y, Geiser D, Ma H, Zhou X (September 2016). "Phylogenetic Resolution of Deep Eukaryotic and Fungal Relationships Using Highly Conserved Low-Copy Nuclear Genes". Genome Biology and Evolution. 8 (9): 2683–2701. doi:10.1093/gbe/evw196. PMC 5631032. PMID 27604879.
  81. ^ a b c Cavalier-Smith T (January 2018). "Kingdom Chromista and its eight phyla: a new synthesis emphasising periplastid protein targeting, cytoskeletal and periplastid evolution, and ancient divergences". Protoplasma. 255 (1): 297–357. doi:10.1007/s00709-017-1147-3. PMC 5756292. PMID 28875267.
  82. ^ Derelle R, Torruella G, Klimeš V, Brinkmann H, Kim E, Vlček Č, Lang BF, Eliáš M (February 2015). "Bacterial proteins pinpoint a single eukaryotic root". Proceedings of the National Academy of Sciences of the United States of America. 112 (7): E693–699. Bibcode:2015PNAS..112E.693D. doi:10.1073/pnas.1420657112. PMC 4343179. PMID 25646484.
  83. ^ Yang J, Harding T, Kamikawa R, Simpson AG, Roger AJ (May 2017). "Mitochondrial Genome Evolution and a Novel RNA Editing System in Deep-Branching Heteroloboseids". Genome Biology and Evolution. 9 (5): 1161–1174. doi:10.1093/gbe/evx086. PMC 5421314. PMID 28453770.
  84. ^ Cavalier-Smith T, Fiore-Donno AM, Chao E, Kudryavtsev A, Berney C, Snell EA, Lewis R (February 2015). "Multigene phylogeny resolves deep branching of Amoebozoa". Molecular Phylogenetics and Evolution. 83: 293–304. doi:10.1016/j.ympev.2014.08.011. PMID 25150787.
  85. ^ Torruella G, de Mendoza A, Grau-Bové X, Antó M, Chaplin MA, del Campo J, Eme L, Pérez-Cordón G, Whipps CM, Nichols KM, Paley R, Roger AJ, Sitjà-Bobadilla A, Donachie S, Ruiz-Trillo I (September 2015). "Phylogenomics Reveals Convergent Evolution of Lifestyles in Close Relatives of Animals and Fungi". Current Biology. 25 (18): 2404–2410. doi:10.1016/j.cub.2015.07.053. PMID 26365255.
  86. ^ a b López-García P, Eme L, Moreira D (December 2017). "Symbiosis in eukaryotic evolution". Journal of Theoretical Biology. 434: 20–33. Bibcode:2017JThBi.434...20L. doi:10.1016/j.jtbi.2017.02.031. PMC 5638015. PMID 28254477.
  87. ^ Ponce-Toledo RI, Deschamps P, López-García P, Zivanovic Y, Benzerara K, Moreira D (February 2017). "An Early-Branching Freshwater Cyanobacterium at the Origin of Plastids". Current Biology. 27 (3): 386–391. doi:10.1016/j.cub.2016.11.056. PMC 5650054. PMID 28132810.
  88. ^ de Vries J, Archibald JM (February 2017). "Endosymbiosis: Did Plastids Evolve from a Freshwater Cyanobacterium?". Current Biology. 27 (3): R103–105. doi:10.1016/j.cub.2016.12.006. PMID 28171752.
  89. ^ a b Cavalier-Smith T (June 2010). "Kingdoms Protozoa and Chromista and the eozoan root of the eukaryotic tree". Biology Letters. 6 (3): 342–345. doi:10.1098/rsbl.2009.0948. PMC 2880060. PMID 20031978.
  90. ^ a b Cavalier-Smith T (May 2013). "Early evolution of eukaryote feeding modes, cell structural diversity, and classification of the protozoan phyla Loukozoa, Sulcozoa, and Choanozoa". European Journal of Protistology. 49 (2): 115–178. doi:10.1016/j.ejop.2012.06.001. PMID 23085100.
  91. ^ a b Cavalier-Smith T, Chao EE, Snell EA, Berney C, Fiore-Donno AM, Lewis R (December 2014). "Multigene eukaryote phylogeny reveals the likely protozoan ancestors of opisthokonts (animals, fungi, choanozoans) and Amoebozoa". Molecular Phylogenetics and Evolution. 81: 71–85. doi:10.1016/j.ympev.2014.08.012. PMID 25152275.
  92. ^ Cavalier-Smith T, Chao EE, Lewis R (April 2018). "Multigene phylogeny and cell evolution of chromist infrakingdom Rhizaria: contrasting cell organisation of sister phyla Cercozoa and Retaria". Protoplasma. 255 (5): 1517–1574. doi:10.1007/s00709-018-1241-1. PMC 6133090. PMID 29666938.
  93. ^ He D, Fiz-Palacios O, Fu CJ, Fehling J, Tsai CC, Baldauf SL (February 2014). "An alternative root for the eukaryote tree of life". Current Biology. 24 (4): 465–470. doi:10.1016/j.cub.2014.01.036. PMID 24508168.
  94. ^ Cox CJ, Foster PG, Hirt RP, Harris SR, Embley TM (December 2008). "The archaebacterial origin of eukaryotes". Proceedings of the National Academy of Sciences of the United States of America. 105 (51): 20356–20361. Bibcode:2008PNAS..10520356C. doi:10.1073/pnas.0810647105. PMC 2629343. PMID 19073919.
  95. ^ Ciccarelli FD, Doerks T, von Mering C, Creevey CJ, Snel B, Bork P (March 2006). "Toward automatic reconstruction of a highly resolved tree of life". Science. 311 (5765): 1283–1287. Bibcode:2006Sci...311.1283C. CiteSeerX 10.1.1.381.9514. doi:10.1126/science.1123061. PMID 16513982. S2CID 1615592.
  96. ^ a b Hug LA, Baker BJ, Anantharaman K, Brown CT, Probst AJ, Castelle CJ, Butterfield CN, Hernsdorf AW, Amano Y, Ise K, Suzuki Y, Dudek N, Relman DA, Finstad KM, Amundson R, Thomas BC, Banfield JF (April 2016). "A new view of the tree of life". Nature Microbiology. 1 (5): 16048. doi:10.1038/nmicrobiol.2016.48. PMID 27572647.
  97. ^ O'Malley MA, Leger MM, Wideman JG, Ruiz-Trillo I (March 2019). "Concepts of the last eukaryotic common ancestor". Nature Ecology & Evolution. Springer Science and Business Media LLC. 3 (3): 338–344. doi:10.1038/s41559-019-0796-3. hdl:10261/201794. PMID 30778187. S2CID 67790751.
  98. ^ a b Brocks JJ, Logan GA, Buick R, Summons RE (August 1999). "Archean molecular fossils and the early rise of eukaryotes". Science. 285 (5430): 1033–1036. Bibcode:1999Sci...285.1033B. CiteSeerX 10.1.1.516.9123. doi:10.1126/science.285.5430.1033. PMID 10446042.
  99. ^ a b Hartman H, Fedorov A (February 2002). "The origin of the eukaryotic cell: a genomic investigation". Proceedings of the National Academy of Sciences of the United States of America. 99 (3): 1420–5. Bibcode:2002PNAS...99.1420H. doi:10.1073/pnas.032658599. PMC 122206. PMID 11805300.
  100. ^ Knoll AH, Javaux EJ, Hewitt D, Cohen P (June 2006). "Eukaryotic organisms in Proterozoic oceans". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 361 (1470): 1023–1038. doi:10.1098/rstb.2006.1843. PMC 1578724. PMID 16754612.
  101. ^ Retallack GJ, Krull ES, Thackray GD, Parkinson DH (2013). "Problematic urn-shaped fossils from a Paleoproterozoic (2.2 Ga) paleosol in South Africa". Precambrian Research. 235: 71–87. Bibcode:2013PreR..235...71R. doi:10.1016/j.precamres.2013.05.015.
  102. ^ El Albani A, Bengtson S, Canfield DE, Bekker A, Macchiarelli R, Mazurier A, Hammarlund EU, Boulvais P, Dupuy JJ, Fontaine C, Fürsich FT, Gauthier-Lafaye F, Janvier P, Javaux E, Ossa FO, Pierson-Wickmann AC, Riboulleau A, Sardini P, Vachard D, Whitehouse M, Meunier A (July 2010). "Large colonial organisms with coordinated growth in oxygenated environments 2.1 Gyr ago". Nature. 466 (7302): 100–104. Bibcode:2010Natur.466..100A. doi:10.1038/nature09166. PMID 20596019. S2CID 4331375.
  103. ^ Bengtson S, Belivanova V, Rasmussen B, Whitehouse M (May 2009). "The controversial "Cambrian" fossils of the Vindhyan are real but more than a billion years older". Proceedings of the National Academy of Sciences of the United States of America. 106 (19): 7729–7734. Bibcode:2009PNAS..106.7729B. doi:10.1073/pnas.0812460106. PMC 2683128. PMID 19416859.
  104. ^ Ward P (9 February 2008). "Mass extinctions: the microbes strike back". New Scientist. pp. 40–43. from the original on 8 July 2008. Retrieved 27 August 2017.
  105. ^ French KL, Hallmann C, Hope JM, Schoon PL, Zumberge JA, Hoshino Y, Peters CA, George SC, Love GD, Brocks JJ, Buick R, Summons RE (May 2015). "Reappraisal of hydrocarbon biomarkers in Archean rocks". Proceedings of the National Academy of Sciences of the United States of America. 112 (19): 5915–5920. Bibcode:2015PNAS..112.5915F. doi:10.1073/pnas.1419563112. PMC 4434754. PMID 25918387.
  106. ^ Brocks JJ, Jarrett AJ, Sirantoine E, Hallmann C, Hoshino Y, Liyanage T (August 2017). "The rise of algae in Cryogenian oceans and the emergence of animals". Nature. 548 (7669): 578–581. Bibcode:2017Natur.548..578B. doi:10.1038/nature23457. PMID 28813409. S2CID 205258987.
  107. ^ Gold DA, Caron A, Fournier GP, Summons RE (March 2017). "Paleoproterozoic sterol biosynthesis and the rise of oxygen". Nature. 543 (7645): 420–423. Bibcode:2017Natur.543..420G. doi:10.1038/nature21412. hdl:1721.1/128450. PMID 28264195. S2CID 205254122.
  108. ^ Wei JH, Yin X, Welander PV (24 June 2016). "Sterol Synthesis in Diverse Bacteria". Frontiers in Microbiology. 7: 990. doi:10.3389/fmicb.2016.00990. PMC 4919349. PMID 27446030.
  109. ^ Hoshino Y, Gaucher EA (June 2021). "Evolution of bacterial steroid biosynthesis and its impact on eukaryogenesis". Proceedings of the National Academy of Sciences of the United States of America. 118 (25): e2101276118. Bibcode:2021PNAS..11801276H. doi:10.1073/pnas.2101276118. PMC 8237579. PMID 34131078.
  110. ^ Isson TT, Love GD, Dupont CL, Reinhard CT, Zumberge AJ, Asael D, et al. (June 2018). "Tracking the rise of eukaryotes to ecological dominance with zinc isotopes". Geobiology. 16 (4): 341–352. doi:10.1111/gbi.12289. PMID 29869832.
  111. ^ Yoshikawa G, Blanc-Mathieu R, Song C, Kayama Y, Mochizuki T, Murata K, Ogata H, Takemura M (April 2019). "Medusavirus, a Novel Large DNA Virus Discovered from Hot Spring Water". Journal of Virology. 93 (8). doi:10.1128/JVI.02130-18. PMC 6450098. PMID 30728258. from the original on 30 April 2019.
    • "New giant virus may help scientists better understand the emergence of complex life". EurekAlert! (Press release). 30 April 2019.
  112. ^ Martin W (December 2005). "Archaebacteria (Archaea) and the origin of the eukaryotic nucleus". Current Opinion in Microbiology. 8 (6): 630–637. doi:10.1016/j.mib.2005.10.004. PMID 16242992.
  113. ^ Takemura M (May 2001). "Poxviruses and the origin of the eukaryotic nucleus". Journal of Molecular Evolution. 52 (5): 419–425. Bibcode:2001JMolE..52..419T. doi:10.1007/s002390010171. PMID 11443345. S2CID 21200827.
  114. ^ Bell PJ (September 2001). "Viral eukaryogenesis: was the ancestor of the nucleus a complex DNA virus?". Journal of Molecular Evolution. 53 (3): 251–256. Bibcode:2001JMolE..53..251L. doi:10.1007/s002390010215. PMID 11523012. S2CID 20542871.
  115. ^ Wächtershäuser G (January 2003). "From pre-cells to Eukarya – a tale of two lipids". Molecular Microbiology. 47 (1): 13–22. doi:10.1046/j.1365-2958.2003.03267.x. PMID 12492850. S2CID 37944519.
  116. ^ Wächtershäuser G (October 2006). "From volcanic origins of chemoautotrophic life to Bacteria, Archaea and Eukarya". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 361 (1474): 1787–1806, discussion 1806–1808. doi:10.1098/rstb.2006.1904. PMC 1664677. PMID 17008219.
  117. ^ Lane N (2016). The Vital Question: Why is Life the Way it is? (paperback ed.). Profile Books. pp. 157–91. ISBN 978-1-781-25037-2.
  118. ^ Egel R (January 2012). "Primal eukaryogenesis: on the communal nature of precellular States, ancestral to modern life". Life. Vol. 2, no. 1. pp. 170–212. doi:10.3390/life2010170. PMC 4187143. PMID 25382122.
  119. ^ a b Harish A, Tunlid A, Kurland CG (August 2013). "Rooted phylogeny of the three superkingdoms". Biochimie. 95 (8): 1593–1604. doi:10.1016/j.biochi.2013.04.016. PMID 23669449.
  120. ^ a b Harish A, Kurland CG (July 2017). "Akaryotes and Eukaryotes are independent descendants of a universal common ancestor". Biochimie. 138: 168–183. doi:10.1016/j.biochi.2017.04.013. PMID 28461155.
  121. ^ a b Imachi H, Nobu MK, Nakahara N, Morono Y, Ogawara M, Takaki Y, et al. (January 2020). "Isolation of an archaeon at the prokaryote-eukaryote interface". Nature. 577 (7791): 519–525. Bibcode:2020Natur.577..519I. doi:10.1038/s41586-019-1916-6. PMC 7015854. PMID 31942073.
  122. ^ Da Cunha V, Gaia M, Gadelle D, Nasir A, Forterre P (June 2017). "Lokiarchaea are close relatives of Euryarchaeota, not bridging the gap between prokaryotes and eukaryotes". PLOS Genetics. 13 (6): e1006810. doi:10.1371/journal.pgen.1006810. PMC 5484517. PMID 28604769.
  123. ^ Harish A, Kurland CG (July 2017). "Empirical genome evolution models root the tree of life". Biochimie. 138: 137–155. doi:10.1016/j.biochi.2017.04.014. PMID 28478110.
  124. ^ Spang A, Eme L, Saw JH, Caceres EF, Zaremba-Niedzwiedzka K, Lombard J, et al. (March 2018). "Asgard archaea are the closest prokaryotic relatives of eukaryotes". PLOS Genetics. 14 (3): e1007080. doi:10.1371/journal.pgen.1007080. PMC 5875740. PMID 29596421.
  125. ^ MacLeod F, Kindler GS, Wong HL, Chen R, Burns BP (2019). "Asgard archaea: Diversity, function, and evolutionary implications in a range of microbiomes". AIMS Microbiology. 5 (1): 48–61. doi:10.3934/microbiol.2019.1.48. PMC 6646929. PMID 31384702.
  126. ^ Zimmer C (15 January 2020). "This Strange Microbe May Mark One of Life's Great Leaps – A organism living in ocean muck offers clues to the origins of the complex cells of all animals and plants". The New York Times. from the original on 16 January 2020. Retrieved 18 January 2020.
  127. ^ Jékely G (2007). "Origin of Eukaryotic Endomembranes: A Critical Evaluation of Different Model Scenarios". Eukaryotic Membranes and Cytoskeleton. Advances in Experimental Medicine and Biology. Vol. 607. New York, N.Y. : Springer Science+Business Media; Austin, Tex. : Landes Bioscience. pp. 38–51. doi:10.1007/978-0-387-74021-8_3. ISBN 978-0-387-74020-1. PMID 17977457.
  128. ^ Cavalier-Smith T (March 2002). "The phagotrophic origin of eukaryotes and phylogenetic classification of Protozoa". International Journal of Systematic and Evolutionary Microbiology. 52 (Pt 2): 297–354. doi:10.1099/00207713-52-2-297. PMID 11931142. from the original on 29 July 2017. Retrieved 10 June 2008.
  129. ^ a b Martin W, Müller M (March 1998). "The hydrogen hypothesis for the first eukaryote". Nature. 392 (6671): 37–41. Bibcode:1998Natur.392...37M. doi:10.1038/32096. PMID 9510246. S2CID 338885.
  130. ^ Pisani D, Cotton JA, McInerney JO (August 2007). "Supertrees disentangle the chimerical origin of eukaryotic genomes". Molecular Biology and Evolution. 24 (8): 1752–1760. doi:10.1093/molbev/msm095. PMID 17504772.
  131. ^ Brueckner J, Martin WF (April 2020). "Bacterial Genes Outnumber Archaeal Genes in Eukaryotic Genomes". Genome Biology and Evolution. 12 (4): 282–292. doi:10.1093/gbe/evaa047. PMC 7151554. PMID 32142116.
  132. ^ a b Latorre A, Durban A, Moya A, Pereto J (2011). "The role of symbiosis in eukaryotic evolution". In Gargaud M, López-Garcìa P, Martin H (eds.). Origins and Evolution of Life: An astrobiological perspective. Cambridge: Cambridge University Press. pp. 326–339. ISBN 978-0-521-76131-4. from the original on 24 March 2019. Retrieved 27 August 2017.
  133. ^ Ayala J (April 1994). . Journal of Cell Science. 107 (Pt 4): 753–763. doi:10.1242/jcs.107.4.753. PMID 8056835. Archived from the original on 29 April 2012. Retrieved 27 March 2013.
  134. ^ Martin WF. "The Origin of Mitochondria". Scitable. Nature education. from the original on 16 June 2013. Retrieved 27 March 2013. That is, it entails a corollary assumption (an add–on to the theory that brings it into agreement with available observations) that all descendants of the initial host lineage, except the one that acquired mitochondria, went extinct.
  135. ^ Dacks JB, Field MC (August 2018). "Evolutionary origins and specialisation of membrane transport". Current Opinion in Cell Biology. 53: 70–76. doi:10.1016/j.ceb.2018.06.001. PMC 6141808. PMID 29929066.
  136. ^ Martijn J, Vosseberg J, Guy L, Offre P, Ettema TJ (May 2018). "Deep mitochondrial origin outside the sampled alphaproteobacteria". Nature. 557 (7703): 101–105. Bibcode:2018Natur.557..101M. doi:10.1038/s41586-018-0059-5. PMID 29695865. S2CID 13740626. from the original on 21 April 2019. Retrieved 21 April 2019.
    • Shawna Williams (25 April 2018). "Mitochondria's Bacterial Origins Upended". The Scientist.
  137. ^ Baum DA, Baum B (October 2014). "An inside-out origin for the eukaryotic cell". BMC Biology. 12: 76. doi:10.1186/s12915-014-0076-2. PMC 4210606. PMID 25350791.
    • Terry Devitt (12 December 2014). "New theory suggests alternate path led to rise of the eukaryotic cell". University of Wisconsin-Madison (Press release). from the original on 21 April 2019.
  138. ^ Brouwers L (12 April 2013). . Scientific American. 109 (50): 20537–20542. Archived from the original on 10 October 2018. Retrieved 21 April 2019.
  139. ^ Wilcox C (9 April 2019). . Quanta Magazine. Archived from the original on 9 May 2019. Retrieved 8 May 2019.
  140. ^ McCutcheon JP (October 2021). "The Genomics and Cell Biology of Host-Beneficial Intracellular Infections". Annual Review of Cell and Developmental Biology. 37 (1): 115–142. doi:10.1146/annurev-cellbio-120219-024122. PMID 34242059. S2CID 235786110.
  141. ^ Saygin D, Tabib T, Bittar HE, Valenzi E, Sembrat J, Chan SY, et al. (8 June 2022). "Transcriptional profiling of lung cell populations in idiopathic pulmonary arterial hypertension". Pulmonary Circulation. 10 (1). doi:10.1146/knowable-060822-2. PMID 32166015.
  142. ^ Pittis AA, Gabaldón T (March 2016). "Late acquisition of mitochondria by a host with chimaeric prokaryotic ancestry". Nature. 531 (7592): 101–104. Bibcode:2016Natur.531..101P. doi:10.1038/nature16941. PMC 4780264. PMID 26840490.
  143. ^ Burton ZF (1 August 2017). Evolution since coding: Cradles, halos, barrels, and wings. Academic Press. ISBN 978-0-12-813034-6. from the original on 24 March 2019. Retrieved 27 November 2018.
  144. ^ Martin WF, Roettger M, Ku C, Garg SG, Nelson-Sathi S, Landan G (February 2017). "Late mitochondrial origin is an artifact". Genome Biology and Evolution. 9 (2): 373–379. doi:10.1093/gbe/evx027. PMC 5516564. PMID 28199635.

  This article incorporates public domain material from . NCBI. Archived from the original on 8 December 2009.

External links

 
Wikispecies has information related to Eukaryota.

January 26, 2023
eukaryote, eukaryotic, cell, redirects, here, journal, eukaryotic, cell, journal, eukaryota, whose, members, known, eukaryotes, diverse, domain, living, beasts, whose, cells, have, nucleus, animals, plants, fungi, many, unicellular, organisms, eukaryotes, they. Eukaryotic cell redirects here For the journal see Eukaryotic Cell journal Eukaryota whose members are known as eukaryotes j uː ˈ k aer i oʊ t s e t s is a diverse domain of living beasts whose cells have a nucleus 4 All animals plants fungi and many unicellular organisms are eukaryotes They belong to the group of organisms Eukaryota or Eukarya which is one of the three domains of life Bacteria and Archaea both prokaryotes make up the other two domains 5 6 EukaryotaTemporal range Orosirian Present 1850 0 Ma Pha Proterozoic Archean Had nRed mason beeBoletus edulisEudorina elegansChimpanzeeRanunculus asiaticusIsotricha intestinalisScientific classificationDomain Eukaryota Chatton 1925 Whittaker amp Margulis 1978Supergroups and kingdoms 1 2 3 Diphoda Metamonada Discoba Diaphoretickes Hemimastigophora Provora Archaeplastida Cryptista Haptista TSAR Telonemia SAR Rhizaria Halvaria Stramenopiles Alveolata Opimoda Ancyromonadida Malawimonadida Podiata CRuMs Amorphea Amoebozoa Obazoa Breviatea Apusomonadida Opisthokonta Holozoa Ichthyosporea Pluriformea Filasterea Choanoflagellatea Animalia Holomycota Nucleariae FungiEukaryotic organisms that cannot be classified under the kingdoms Plantae Animalia or Fungi are sometimes grouped in the paraphyletic Protista The eukaryotes are usually now regarded as having emerged in the Archaea or as a sister of the Asgard archaea 7 8 This implies that there are only two domains of life Bacteria and Archaea with eukaryotes incorporated among archaea 9 10 Eukaryotes represent a small minority of the number of organisms 11 but due to their generally much larger size their collective global biomass is estimated to be about equal to that of prokaryotes 11 Eukaryotes emerged approximately 2 3 1 8 billion years ago during the Proterozoic eon likely as flagellated phagotrophs 12 1 Their name comes from the Greek eὖ eu well or good and karyon karyon nut or kernel 13 Eukaryotic cells typically contain other membrane bound organelles such as mitochondria and Golgi apparatus Chloroplasts can be found in plants and algae Prokaryotic cells may contain primitive organelles 14 Eukaryotes may be either unicellular or multicellular and include many cell types forming different kinds of tissue In comparison prokaryotes are typically unicellular Animals plants and fungi are the most familiar eukaryotes Other eukaryotes are sometimes called protists 15 Eukaryotes can reproduce both asexually through mitosis and sexually through meiosis and gamete fusion In mitosis one cell divides to produce two genetically identical cells In meiosis DNA replication is followed by two rounds of cell division to produce four haploid daughter cells that act as sex cells or gametes Each gamete has just one set of chromosomes each a unique mix of the corresponding pair of parental chromosomes resulting from genetic recombination during meiosis 16 Contents 1 Cell features 1 1 Internal membranes 1 2 Mitochondria 1 3 Plastids 1 4 Cytoskeletal structures 1 5 Cell wall 2 Differences among eukaryotic cells 2 1 Animal cell 2 2 Plant cell 2 3 Fungal cell 2 4 Other eukaryotic cells 3 Reproduction 4 Classification 4 1 Phylogeny 4 1 1 Cavalier Smith s tree 5 Evolutionary history 5 1 Origin of eukaryotes 5 1 1 Fossils 5 1 2 Relationship to Archaea 5 1 3 Endomembrane system and mitochondria 5 1 4 Hypotheses 5 1 4 1 Autogenous models 5 1 4 2 Chimeric models 5 1 4 3 The inside out hypothesis 5 1 4 4 The serial endosymbiotic hypothesis 5 1 4 5 The hydrogen hypothesis 5 1 4 6 The syntrophy hypothesis 5 1 4 7 6 serial endosymbiosis scenario 6 See also 7 Notes 8 References 9 External linksCell features Edit source source source source source source source source source source source source Cytology Video Cell Features Eukaryotic cells are typically much larger than those of prokaryotes having a volume of around 10 000 times greater than the prokaryotic cell 17 They have a variety of internal membrane bound structures called organelles and a cytoskeleton composed of microtubules microfilaments and intermediate filaments which play an important role in defining the cell s organization and shape Eukaryotic DNA is divided into several linear bundles called chromosomes which are separated by a microtubular spindle during nuclear division Internal membranes Edit The endomembrane system and its components Eukaryote cells include a variety of membrane bound structures collectively referred to as the endomembrane system 18 Simple compartments called vesicles and vacuoles can form by budding off other membranes Many cells ingest food and other materials through a process of endocytosis where the outer membrane invaginates and then pinches off to form a vesicle 19 It is probable citation needed that most other membrane bound organelles are ultimately derived from such vesicles Alternatively some products produced by the cell can leave in a vesicle through exocytosis The nucleus is surrounded by a double membrane known as the nuclear envelope with nuclear pores that allow material to move in and out 20 Various tube and sheet like extensions of the nuclear membrane form the endoplasmic reticulum which is involved in protein transport and maturation It includes the rough endoplasmic reticulum where ribosomes are attached to synthesize proteins which enter the interior space or lumen Subsequently they generally enter vesicles which bud off from the smooth endoplasmic reticulum 21 In most eukaryotes these protein carrying vesicles are released and further modified in stacks of flattened vesicles cisternae the Golgi apparatus 22 Vesicles may be specialized for various purposes For instance lysosomes contain digestive enzymes that break down most biomolecules in the cytoplasm 23 Peroxisomes are used to break down peroxide which is otherwise toxic Many protozoans have contractile vacuoles which collect and expel excess water and extrusomes which expel material used to deflect predators or capture prey In higher plants most of a cell s volume is taken up by a central vacuole which mostly contains water and primarily maintains its osmotic pressure Mitochondria Edit Simplified structure of a mitochondrion Mitochondria are organelles found in all but one eukaryote note 1 and are commonly referred to as the powerhouse of the cell 25 Mitochondria provide energy to the eukaryote cell by oxidising sugars or fats and releasing energy as ATP 26 They have two surrounding membranes each a phospholipid bi layer the inner of which is folded into invaginations called cristae where aerobic respiration takes place The outer mitochondrial membrane is freely permeable and allows almost anything to enter into the intermembrane space while the inner mitochondrial membrane is semi permeable so allows only some required things into the mitochondrial matrix Mitochondria contain their own DNA which has close structural similarities to bacterial DNA and which encodes rRNA and tRNA genes that produce RNA which is closer in structure to bacterial RNA than to eukaryote RNA 27 They are now generally held to have developed from endosymbiotic prokaryotes probably Alphaproteobacteria Some eukaryotes such as the metamonads such as Giardia and Trichomonas and the amoebozoan Pelomyxa appear to lack mitochondria but all have been found to contain mitochondrion derived organelles such as hydrogenosomes and mitosomes and thus have lost their mitochondria secondarily 24 They obtain energy by enzymatic action on nutrients absorbed from the environment The metamonad Monocercomonoides has also acquired by lateral gene transfer a cytosolic sulfur mobilisation system which provides the clusters of iron and sulfur required for protein synthesis The normal mitochondrial iron sulfur cluster pathway has been lost secondarily 24 28 Plastids Edit Plants and various groups of algae also have plastids Plastids also have their own DNA and are developed from endosymbionts in this case cyanobacteria They usually take the form of chloroplasts which like cyanobacteria contain chlorophyll and produce organic compounds such as glucose through photosynthesis Others are involved in storing food Although plastids probably had a single origin not all plastid containing groups are closely related Instead some eukaryotes have obtained them from others through secondary endosymbiosis or ingestion 29 The capture and sequestering of photosynthetic cells and chloroplasts occurs in many types of modern eukaryotic organisms and is known as kleptoplasty Endosymbiotic origins have also been proposed for the nucleus and for eukaryotic flagella 30 Cytoskeletal structures Edit Main article Cytoskeleton Longitudinal section through the flagellum of Chlamydomonas reinhardtii Many eukaryotes have long slender motile cytoplasmic projections called flagella or similar structures called cilia Flagella and cilia are sometimes referred to as undulipodia 31 and are variously involved in movement feeding and sensation They are composed mainly of tubulin These are entirely distinct from prokaryotic flagellae They are supported by a bundle of microtubules arising from a centriole characteristically arranged as nine doublets surrounding two singlets Flagella also may have hairs or mastigonemes and scales connecting membranes and internal rods Their interior is continuous with the cell s cytoplasm Microfilamental structures composed of actin and actin binding proteins e g a actinin fimbrin filamin are present in submembranous cortical layers and bundles as well Motor proteins of microtubules e g dynein or kinesin and actin e g myosins provide dynamic character of the network Centrioles are often present even in cells and groups that do not have flagella but conifers and flowering plants have neither They generally occur in groups that give rise to various microtubular roots These form a primary component of the cytoskeletal structure and are often assembled over the course of several cell divisions with one flagellum retained from the parent and the other derived from it Centrioles produce the spindle during nuclear division 32 The significance of cytoskeletal structures is underlined in the determination of shape of the cells as well as their being essential components of migratory responses like chemotaxis and chemokinesis Some protists have various other microtubule supported organelles These include the radiolaria and heliozoa which produce axopodia used in flotation or to capture prey and the haptophytes which have a peculiar flagellum like organelle called the haptonema Cell wall Edit Main article Cell wall The cells of plants and algae fungi and most chromalveolates have a cell wall a layer outside the cell membrane providing the cell with structural support protection and a filtering mechanism The cell wall also prevents over expansion when water enters the cell 33 The major polysaccharides making up the primary cell wall of land plants are cellulose hemicellulose and pectin The cellulose microfibrils are linked via hemicellulosic tethers to form the cellulose hemicellulose network which is embedded in the pectin matrix The most common hemicellulose in the primary cell wall is xyloglucan 34 Differences among eukaryotic cells EditThere are many different types of eukaryotic cells though animals and plants are the most familiar eukaryotes and thus provide an excellent starting point for understanding eukaryotic structure Fungi and many protists have some substantial differences however Animal cell Edit Structure of a typical animal cell Structure of a typical plant cell All animals are eukaryotic Animal cells are distinct from those of other eukaryotes most notably plants as they lack cell walls and chloroplasts and have smaller vacuoles Due to the lack of a cell wall animal cells can transform into a variety of shapes A phagocytic cell can even engulf other structures Plant cell Edit Main article Plant cell Plant cells have a number of features that distinguish them from the cells of the other eukaryotic organisms These include A large central vacuole enclosed by a membrane the tonoplast which maintains the cell s turgor and controls movement of molecules between the cytosol and sap 35 A primary cell wall containing cellulose hemicellulose and pectin deposited by the protoplast on the outside of the cell membrane this contrasts with the cell walls of fungi which contain chitin and the cell envelopes of prokaryotes in which peptidoglycans are the main structural molecules The plasmodesmata pores in the cell wall that link adjacent cells and allow plant cells to communicate with adjacent cells 36 Animals have a different but functionally analogous system of gap junctions between adjacent cells Plastids especially chloroplasts organelles that contain chlorophyll the pigment that gives plants their green color and allows them to perform photosynthesis Bryophytes and seedless vascular plants only have flagellae and centrioles in the sperm cells 37 Sperm of cycads and Ginkgo are large complex cells that swim with hundreds to thousands of flagellae 38 Conifers Pinophyta and flowering plants Angiospermae lack the flagellae and centrioles that are present in animal cells Fungal cell Edit Fungal Hyphae cells 1 hyphal wall 2 septum 3 mitochondrion 4 vacuole 5 ergosterol crystal 6 ribosome 7 nucleus 8 endoplasmic reticulum 9 lipid body 10 plasma membrane 11 spitzenkorper 12 Golgi apparatus The cells of fungi are similar to animal cells with the following exceptions 39 A cell wall that contains chitin Less compartmentation between cells the hyphae of higher fungi have porous partitions called septa which allow the passage of cytoplasm organelles and sometimes nuclei so each organism is essentially a giant multinucleate supercell these fungi are described as coenocytic Primitive fungi have few or no septa Only the most primitive fungi chytrids have flagella Other eukaryotic cells Edit Some groups of eukaryotes have unique organelles such as the cyanelles unusual plastids of the glaucophytes 40 the haptonema of the haptophytes or the ejectosomes of the cryptomonads Other structures such as pseudopodia are found in various eukaryote groups in different forms such as the lobose amoebozoans or the reticulose foraminiferans 41 Structures known as cortical alveoli are vesicles present under the cell membrane of many protists such as dinoflagellates ciliates and apicomplexan parasites 42 Reproduction Edit This diagram illustrates the twofold cost of sex If each individual were to contribute the same number of offspring two a the sexual population remains the same size each generation where the b asexual population doubles in size each generation Cell division generally takes place asexually by mitosis a process that allows each daughter nucleus to receive one copy of each chromosome Most eukaryotes also have a life cycle that involves sexual reproduction alternating between a haploid phase where only one copy of each chromosome is present in each cell and a diploid phase wherein two copies of each chromosome are present in each cell The diploid phase is formed by fusion of two haploid gametes to form a zygote which may divide by mitosis or undergo chromosome reduction by meiosis There is considerable variation in this pattern Animals have no multicellular haploid phase but each plant generation can consist of haploid and diploid multicellular phases Eukaryotes have a smaller surface area to volume ratio than prokaryotes and thus have lower metabolic rates and longer generation times 43 The evolution of sexual reproduction may be a primordial and fundamental characteristic of eukaryotes Based on a phylogenetic analysis Dacks and Roger proposed that facultative sex was present in the common ancestor of all eukaryotes 44 A core set of genes that function in meiosis is present in both Trichomonas vaginalis and Giardia intestinalis two organisms previously thought to be asexual 45 46 Since these two species are descendants of lineages that diverged early from the eukaryotic evolutionary tree it was inferred that core meiotic genes and hence sex were likely present in a common ancestor of all eukaryotes 45 46 Eukaryotic species once thought to be asexual such as parasitic protozoa of the genus Leishmania have been shown to have a sexual cycle 47 Also evidence now indicates that amoebae previously regarded as asexual are anciently sexual and that the majority of present day asexual groups likely arose recently and independently 48 Classification EditFurther information wikispecies Eukaryota Phylogenetic and symbiogenetic tree of living organisms showing a view of the origins of eukaryotes and prokaryotes One hypothesis of eukaryotic relationships the Opisthokonta group includes both animals Metazoa and fungi plants Plantae are placed in Archaeplastida A pie chart of described eukaryote species except for Excavata together with a tree showing possible relationships between the groups In antiquity the two lineages of animals and plants were recognized They were given the taxonomic rank of Kingdom by Linnaeus Though he included the fungi with plants with some reservations it was later realized that they are quite distinct and warrant a separate kingdom the composition of which was not entirely clear until the 1980s 49 The various single cell eukaryotes were originally placed with plants or animals when they became known In 1818 the German biologist Georg A Goldfuss coined the word protozoa to refer to organisms such as ciliates 50 and this group was expanded until it encompassed all single celled eukaryotes and given their own kingdom the Protista by Ernst Haeckel in 1866 51 52 The eukaryotes thus came to be composed of four kingdoms Kingdom Protista Kingdom Plantae Kingdom Fungi Kingdom AnimaliaThe protists were understood to be primitive forms and thus an evolutionary grade united by their primitive unicellular nature 52 The disentanglement of the deep splits in the tree of life only really started with DNA sequencing leading to a system of domains rather than kingdoms as top level rank being put forward by Carl Woese uniting all the eukaryote kingdoms under the eukaryote domain 6 At the same time work on the protist tree intensified and is still actively going on today Several alternative classifications have been forwarded though there is no consensus in the field Eukaryotes are a clade usually assessed to be sister to Heimdallarchaeota in the Asgard grouping in the Archaea 53 54 55 In one proposed system which the basal groupings are the Opimoda Diphoda the Discoba and the Loukozoa The Eukaryote root is usually assessed to be near or even in Discoba citation needed A classification produced in 2005 for the International Society of Protistologists 56 which reflected the consensus of the time divided the eukaryotes into six supposedly monophyletic supergroups However in the same year 2005 doubts were expressed as to whether some of these supergroups were monophyletic particularly the Chromalveolata 57 and a review in 2006 noted the lack of evidence for several of the supposed six supergroups 58 A revised classification in 2012 59 recognizes five supergroups Archaeplastida or Primoplantae Land plants green algae red algae and glaucophytesSAR supergroup Stramenopiles brown algae diatoms etc Alveolata and Rhizaria Foraminifera Radiolaria and various other amoeboid protozoa Excavata Various flagellate protozoaAmoebozoa Most lobose amoeboids and slime moldsOpisthokonta Animals fungi choanoflagellates etc There are also smaller groups of eukaryotes whose position is uncertain or seems to fall outside the major groups 60 in particular Haptophyta Cryptophyta Centrohelida Telonemia Picozoa 61 Apusomonadida Ancyromonadida Breviatea and the genus Collodictyon 62 Overall it seems that although progress has been made there are still very significant uncertainties in the evolutionary history and classification of eukaryotes As Roger amp Simpson said in 2009 with the current pace of change in our understanding of the eukaryote tree of life we should proceed with caution 63 Newly identified protists purported to represent novel deep branching lineages continue to be described well into the 21st century recent examples including Rhodelphis putative sister group to Rhodophyta and Anaeramoeba anaerobic amoebaflagellates of uncertain placement 64 Phylogeny Edit The rRNA trees constructed during the 1980s and 1990s left most eukaryotes in an unresolved crown group not technically a true crown which was usually divided by the form of the mitochondrial cristae see crown eukaryotes The few groups that lack mitochondria branched separately and so the absence was believed to be primitive but this is now considered an artifact of long branch attraction and they are known to have lost them secondarily 65 66 It has been estimated that there may be 75 distinct lineages of eukaryotes 67 Most of these lineages are protists The known eukaryote genome sizes vary from 8 2 megabases Mb in Babesia bovis to 112 000 220 050 Mb in the dinoflagellate Prorocentrum micans showing that the genome of the ancestral eukaryote has undergone considerable variation during its evolution 67 The last common ancestor of all eukaryotes is believed to have been a phagotrophic protist with a nucleus at least one centriole and cilium facultatively aerobic mitochondria sex meiosis and syngamy a dormant cyst with a cell wall of chitin and or cellulose and peroxisomes 67 Later endosymbiosis led to the spread of plastids in some lineages Although there is still considerable uncertainty in global eukaryote phylogeny particularly regarding the position of the root a rough consensus has started to emerge from the phylogenomic studies of the past two decades 60 68 69 70 2 24 71 1 64 3 The majority of eukaryotes can be placed in one of two large clades dubbed Amorphea similar in composition to the unikont hypothesis and the Diaphoretickes which includes plants and most algal lineages A third major grouping the Excavata has been abandoned as a formal group in the most recent classification of the International Society of Protistologists due to growing uncertainty as to whether its constituent groups belong together 72 The proposed phylogeny below includes only one group of excavates Discoba and incorporates the recent proposal that picozoans are close relatives of rhodophytes 73 Eukaryotes Diphoda Diaphoretickes CryptistaArchaeplastida Red algae Rhodophyta PicozoaGlaucophyta Green plants Viridiplantae Gloeomargarita lithophora Haptista TSAR TelonemiaSAR Halvaria Stramenopiles Alveolata Rhizaria ProvoraHemimastigophoraDiscoba Excavata Amorphea Amoebozoa Obazoa Apusomonadida Opisthokonta Holomycota inc fungi Holozoa inc animals In some analyses the Hacrobia group Haptophyta Cryptophyta is placed next to Archaeplastida 74 but in others it is nested inside the Archaeplastida 75 However several recent studies have concluded that Haptophyta and Cryptophyta do not form a monophyletic group 76 The former could be a sister group to the SAR group the latter cluster with the Archaeplastida plants in the broad sense 77 The division of the eukaryotes into two primary clades bikonts Archaeplastida SAR Excavata and unikonts Amoebozoa Opisthokonta derived from an ancestral biflagellar organism and an ancestral uniflagellar organism respectively had been suggested earlier 75 78 79 A 2012 study produced a somewhat similar division although noting that the terms unikonts and bikonts were not used in the original sense 61 A highly converged and congruent set of trees appears in Derelle et al 2015 Ren et al 2016 Yang et al 2017 and Cavalier Smith 2015 including the supplementary information resulting in a more conservative and consolidated tree It is combined with some results from Cavalier Smith for the basal Opimoda 80 81 82 83 84 2 85 The main remaining controversies are the root and the exact positioning of the Rhodophyta and the bikonts Rhizaria Haptista Cryptista Picozoa and Telonemia many of which may be endosymbiotic eukaryote eukaryote hybrids 86 Archaeplastida acquired chloroplasts probably by endosymbiosis of a prokaryotic ancestor related to a currently extant cyanobacterium Gloeomargarita lithophora 87 88 86 Eukaryotes Diphoda Diaphoretickes Archaeplastida GlaucophytaRhodophytaViridiplantae Gloeomargarita lithophora Hacrobia HaptistaCryptistaSAR Halvaria StramenopilesAlveolataRhizariaHemimastigophoraDiscobaOpimoda LoukozoaPodiata CRuMs Diphyllatea Rigifilida MantamonasAmorphea AmoebozoaObazoa BreviataApusomonadidaOpisthokontaCavalier Smith s tree Edit Thomas Cavalier Smith 2010 89 2013 90 2014 91 2017 81 and 2018 92 places the eukaryotic tree s root between Excavata with ventral feeding groove supported by a microtubular root and the grooveless Euglenozoa and monophyletic Chromista correlated to a single endosymbiotic event of capturing a red algae He et al 93 specifically supports rooting the eukaryotic tree between a monophyletic Discoba Discicristata Jakobida and an Amorphea Diaphoretickes clade Eukaryotes EuglenozoaPercolozoaEolouka Tsukubamonas globosaJakobeaNeokaryota Corticata Archaeplastida GlaucophytesRhodophytesViridiplantaeChromista HacrobiaSARScotokaryota MalawimonasMetamonadaPodiata AncyromonadidaMantamonas plasticaDiphyllateaAmorphea AmoebozoaObazoa BreviateaApusomonadidaOpisthokontaOpimodaEvolutionary history EditOrigin of eukaryotes Edit The three domains tree and the Eocyte hypothesis 94 Phylogenetic tree showing a possible relationship between the eukaryotes and other forms of life 95 eukaryotes are colored red archaea green and bacteria blue Eocyte tree 96 The origin of the eukaryotic cell also known as eukaryogenesis is a milestone in the evolution of life since eukaryotes include all complex cells and almost all multicellular organisms A number of approaches have been used to find the first eukaryote and their closest relatives The last eukaryotic common ancestor LECA is the hypothetical last common ancestor of all living eukaryotes 5 and was most likely a biological population 97 Eukaryotes have a number of features that differentiate them from prokaryotes including an endomembrane system and unique biochemical pathways such as sterane synthesis 98 A set of proteins called eukaryotic signature proteins ESPs was proposed to identify eukaryotic relatives in 2002 They have no homology to proteins known in other domains of life by then but they appear to be universal among eukaryotes They include proteins that make up the cytoskeleton the complex transcription machinery membrane sorting systems the nuclear pore as well as some enzymes in the biochemical pathways 99 Fossils Edit The timing of this series of events is hard to determine Knoll 2006 suggests they developed approximately 1 6 2 1 billion years ago Some acritarchs are known from at least 1 65 billion years ago and the possible alga Grypania has been found as far back as 2 1 billion years ago 100 The Geosiphon like fossil fungus Diskagma has been found in paleosols 2 2 billion years old 101 Organized living structures have been found in the black shales of the Palaeoproterozoic Francevillian B Formation in Gabon dated at 2 1 billion years old Eukaryotic life could have evolved at that time 102 Fossils that are clearly related to modern groups start appearing an estimated 1 2 billion years ago in the form of a red algae though recent work suggests the existence of fossilized filamentous algae in the Vindhya basin dating back perhaps to 1 6 to 1 7 billion years ago 103 The presence of eukaryotic specific biomarkers steranes in Australian shales previously indicated that eukaryotes were present in these rocks dated at 2 7 billion years old 98 104 which was even 300 million years older than the first geological records of the appreciable amount of molecular oxygen during the Great Oxidation Event However these Archaean biomarkers were eventually rebutted as later contaminants 105 Currently putatively the oldest biomarker records are only 800 million years old 106 In contrast a molecular clock analysis suggests the emergence of sterol biosynthesis as early as 2 3 billion years ago 107 and thus there is a huge gap between molecular data and geological data which hinders a reasonable inference of the eukaryotic evolution through biomarker records before 800 million years ago The nature of steranes as eukaryotic biomarkers is further complicated by the production of sterols by some bacteria 108 109 Whenever their origins eukaryotes may not have become ecologically dominant until much later a massive uptick in the zinc composition of marine sediments 800 million years ago has been attributed to the rise of substantial populations of eukaryotes which preferentially consume and incorporate zinc relative to prokaryotes approximately a billion years after their origin at the latest 110 In April 2019 biologists reported that the very large medusavirus or a relative may have been responsible at least in part for the evolutionary emergence of complex eukaryotic cells from simpler prokaryotic cells 111 Relationship to Archaea Edit The nuclear DNA and genetic machinery of eukaryotes is more similar to Archaea than Bacteria leading to a controversial suggestion that eukaryotes should be grouped with Archaea in the clade Neomura In other respects such as membrane composition eukaryotes are similar to Bacteria Three main explanations for this have been proposed Eukaryotes resulted from the complete fusion of two or more cells wherein the cytoplasm formed from a bacterium and the nucleus from an archaeon 112 from a virus 113 114 or from a pre cell 115 116 Eukaryotes developed from Archaea and acquired their bacterial characteristics through the endosymbiosis of a proto mitochondrion of bacterial origin 117 Eukaryotes and Archaea developed separately from a modified bacterium Diagram of the origin of life with the Eukaryotes appearing early not derived from Prokaryotes as proposed by Richard Egel in 2012 This view implies that the UCA was relatively large and complex 118 Alternative proposals include The chronocyte hypothesis postulates that a primitive eukaryotic cell was formed by the endosymbiosis of both archaea and bacteria by a third type of cell termed a chronocyte This is mainly to account for the fact that eukaryotic signature proteins were not found anywhere else by 2002 99 The universal common ancestor UCA of the current tree of life was a complex organism that survived a mass extinction event rather than an early stage in the evolution of life Eukaryotes and in particular akaryotes Bacteria and Archaea evolved through reductive loss so that similarities result from differential retention of original features 119 Assuming no other group is involved there are three possible phylogenies for the Bacteria Archaea and Eukaryota in which each is monophyletic These are labelled 1 to 3 in the table below with a modification of hypothesis 2 making the 4th column The eocyte hypothesis in which the Archaea are paraphyletic The table and the names for the hypotheses are based on Harish amp Kurland 2017 120 Alternative hypotheses for the base of the tree of life 1 Two empires 2 Three domains 3 Gupta 4 Eocyte UCA Archaea Bacteria Eukaryota UCA Eukaryota Archaea Bacteria UCA Eukaryota Bacteria Archaea UCA Archaea Eukaryota Archaea Crenarchaeota Archaea Euryarchaeota BacteriaIn recent years most researchers have favoured either the three domains 3D or the eocyte hypothesis An rRNA analysis supports the eocyte scenario apparently with the Eukaryote root in Excavata 96 89 90 91 81 A cladogram supporting the eocyte hypothesis positioning eukaryotes within Archaea based on phylogenomic analyses of the Asgard archaea is 53 54 55 10 Archaea TACK Korarchaeota Thermoproteota Aigarchaeota Geoarchaeota Nitrososphaerota Bathyarchaeota Asgard Lokiarchaeota Odinarchaeota Thorarchaeota Heimdallarchaeota Eukaryota Alphaproteobacteria In this scenario the Asgard group is seen as a sister taxon of the TACK group which comprises Thermoproteota formerly named eocytes or Crenarchaeota Nitrososphaerota formerly Thaumarchaeota and others This group is reported contain many of the eukaryotic signature proteins and produce vesicles 121 In 2017 there was significant pushback against this scenario arguing that the eukaryotes did not emerge within the Archaea Cunha et al produced analyses supporting the three domains 3D or Woese hypothesis 2 in the table above and rejecting the eocyte hypothesis 4 above 122 Harish and Kurland found strong support for the earlier two empires 2D or Mayr hypothesis 1 in the table above based on analyses of the coding sequences of protein domains They rejected the eocyte hypothesis as the least likely 123 120 A possible interpretation of their analysis is that the universal common ancestor UCA of the current tree of life was a complex organism that survived an evolutionary bottleneck rather than a simpler organism arising early in the history of life 119 On the other hand the researchers who came up with Asgard re affirmed their hypothesis with additional Asgard samples 124 Since then the publication of additional Asgard archaeal genomes and the independent reconstruction of phylogenomic trees by multiple independent laboratories have provided additional support for an Asgard archaeal origin of eukaryotes Details of the relation of Asgard archaea members and eukaryotes are still under consideration 125 although in January 2020 scientists reported that Candidatus Prometheoarchaeum syntrophicum a type of cultured Asgard archaea may be a possible link between simple prokaryotic and complex eukaryotic microorganisms about two billion years ago 126 121 Endomembrane system and mitochondria Edit The origins of the endomembrane system and mitochondria are also unclear 127 The phagotrophic hypothesis proposes that eukaryotic type membranes lacking a cell wall originated first with the development of endocytosis whereas mitochondria were acquired by ingestion as endosymbionts 128 The syntrophic hypothesis proposes that the proto eukaryote relied on the proto mitochondrion for food and so ultimately grew to surround it Here the membranes originated after the engulfment of the mitochondrion in part thanks to mitochondrial genes the hydrogen hypothesis is one particular version 129 In a study using genomes to construct supertrees Pisani et al 2007 suggest that along with evidence that there was never a mitochondrion less eukaryote eukaryotes evolved from a syntrophy between an archaea closely related to Thermoplasmatales and an alphaproteobacterium likely a symbiosis driven by sulfur or hydrogen The mitochondrion and its genome is a remnant of the alphaproteobacterial endosymbiont 130 The majority of the genes from the symbiont have been transferred to the nucleus They make up most of the metabolic and energy related pathways of the eukaryotic cell while the information system DNA polymerase transcription translation is retained from archaea 131 Hypotheses Edit Different hypotheses have been proposed as to how eukaryotic cells came into existence These hypotheses can be classified into two distinct classes autogenous models and chimeric models Autogenous models Edit An autogenous model for the origin of eukaryotes Autogenous models propose that a proto eukaryotic cell containing a nucleus existed first and later acquired mitochondria 132 According to this model a large prokaryote developed invaginations in its plasma membrane in order to obtain enough surface area to service its cytoplasmic volume As the invaginations differentiated in function some became separate compartments giving rise to the endomembrane system including the endoplasmic reticulum golgi apparatus nuclear membrane and single membrane structures such as lysosomes 133 Mitochondria are proposed to come from the endosymbiosis of an aerobic proteobacterium after a eukaryote with a nucleus has evolved This theory is less held onto because it requires extra assumptions to explain current conditions For example as every known eukaryote has a mitochondrion or at least show signs of having an ancestor that had one must assumed that all the eukaryotic lineages that did not acquire mitochondria became extinct The theory also does not explain why anaerobic variants of mitochondria have evolved 134 Chimeric models Edit Chimeric models claim that two prokaryotic cells existed initially an archaeon and a bacterium The closest living relatives of these appears to be Asgardarchaeota and distantly related the alphaproteobacteria called the proto mitochondrion 135 136 These cells underwent a merging process either by a physical fusion or by endosymbiosis thereby leading to the formation of a eukaryotic cell Within these chimeric models some studies further claim that mitochondria originated from a bacterial ancestor while others emphasize the role of endosymbiotic processes behind the origin of mitochondria The inside out hypothesis Edit The inside out hypothesis suggests that the fusion between free living mitochondria like bacteria and an archaeon into a eukaryotic cell happened gradually over a long period of time instead of in a single phagocytotic event In this scenario an archaeon would trap aerobic bacteria with cell protrusions and then keep them alive to draw energy from them instead of digesting them During the early stages the bacteria would still be partly in direct contact with the environment and the archaeon would not have to provide them with all the required nutrients But eventually the archaeon would engulf the bacteria completely creating the internal membrane structures and nucleus membrane in the process 137 It is assumed the archaean group called halophiles went through a similar procedure where they acquired as much as a thousand genes from a bacterium way more than through the conventional horizontal gene transfer that often occurs in the microbial world but that the two microbes separated again before they had fused into a single eukaryote like cell 138 An expanded version of the inside out hypothesis proposes that the eukaryotic cell was created by physical interactions between two prokaryotic organisms and that the last common ancestor of eukaryotes got its genome from a whole population or community of microbes participating in cooperative relationships to thrive and survive in their environment The genome from the various types of microbes would complement each other and occasional horizontal gene transfer between them would be largely to their own benefit This accumulation of beneficial genes gave rise to the genome of the eukaryotic cell which contained all the genes required for independence 139 140 141 The serial endosymbiotic hypothesis Edit Main article Symbiogenesis According to serial endosymbiotic theory championed by Lynn Margulis a union between a motile anaerobic bacterium like Spirochaeta and a thermoacidophilic crenarchaeon like Thermoplasma which is sulfidogenic in nature gave rise to the present day eukaryotes This union established a motile organism capable of living in the already existing acidic and sulfurous waters Oxygen is known to cause toxicity to organisms that lack the required metabolic machinery Thus the archaeon provided the bacterium with a highly beneficial reduced environment sulfur and sulfate were reduced to sulfide In microaerophilic conditions oxygen was reduced to water thereby creating a mutual benefit platform The bacterium on the other hand contributed the necessary fermentation products and electron acceptors along with its motility feature to the archaeon thereby gaining a swimming motility for the organism From a consortium of bacterial and archaeal DNA originated the nuclear genome of eukaryotic cells Spirochetes gave rise to the motile features of eukaryotic cells Endosymbiotic unifications of the ancestors of alphaproteobacteria and cyanobacteria led to the origin of mitochondria and plastids respectively For example Thiodendron has been known to have originated via an ectosymbiotic process based on a similar syntrophy of sulfur existing between the two types of bacteria Desulfobacter and Spirochaeta However such an association based on motile symbiosis has never been observed practically Also there is no evidence of archaeans and spirochetes adapting to intense acid based environments In addition the theory posits that mitochondrion less eukaryotes have existed tying back to the problem in the autogenous model 132 The hydrogen hypothesis Edit In the hydrogen hypothesis the symbiotic linkage of an anaerobic and autotrophic methanogenic archaeon host with an alphaproteobacterium the symbiont gave rise to the eukaryotes The host used hydrogen H2 and carbon dioxide CO2 to produce methane while the symbiont capable of aerobic respiration expelled H2 and CO2 as byproducts of anaerobic fermentation process The host s methanogenic environment worked as a sink for H2 which resulted in heightened bacterial fermentation Endosymbiotic gene transfer acted as a catalyst for the host to acquire the symbionts carbohydrate metabolism and turn heterotrophic in nature Subsequently the host s methane forming capability was lost Thus the origins of the heterotrophic organelle symbiont are identical to the origins of the eukaryotic lineage In this hypothesis the presence of H2 represents the selective force that forged eukaryotes out of prokaryotes 129 The syntrophy hypothesis Edit The syntrophy hypothesis was developed in contrast to the hydrogen hypothesis and proposes the existence of two symbiotic events According to this model the origin of eukaryotic cells was based on metabolic symbiosis syntrophy between a methanogenic archaeon and a deltaproteobacterium This syntrophic symbiosis was initially facilitated by H2 transfer between different species under anaerobic environments In earlier stages an alphaproteobacterium became a member of this integration and later developed into the mitochondrion Gene transfer from a deltaproteobacterium to an archaeon led to the methanogenic archaeon developing into a nucleus The archaeon constituted the genetic apparatus while the deltaproteobacterium contributed towards the cytoplasmic features This theory incorporates two selective forces at the time of nucleus evolution presence of metabolic partitioning to avoid the harmful effects of the co existence of anabolic and catabolic cellular pathways and prevention of abnormal protein biosynthesis due to a vast spread of introns in the archaeal genes after acquiring the mitochondrion and losing methanogenesis citation needed 6 serial endosymbiosis scenario Edit A complex scenario of 6 serial endosymbiotic events of archaea and bacteria has been proposed in which mitochondria and an asgard related archaeota were acquired at a late stage of eukaryogenesis possibly in combination as a secondary endosymbiont 142 143 The findings have been rebuked as an artifact 144 See also Edit Biology portalEukaryote hybrid genome Evolution of sexual reproduction List of sequenced eukaryotic genomes Parakaryon myojinensis Prokaryote Nitrososphaerota Vault organelle Notes Edit To date only one eukaryote Monocercomonoides is known to have completely lost its mitochondria 24 References Edit a b c Strassert JF Irisarri I Williams TA Burki F March 2021 A molecular timescale for eukaryote evolution with implications for the origin of red algal derived plastids Nature Communications 12 1 1879 Bibcode 2021NatCo 12 1879S doi 10 1038 s41467 021 22044 z PMC 7994803 PMID 33767194 a b c Brown MW Heiss AA Kamikawa R Inagaki Y Yabuki A Tice AK et al February 2018 Phylogenomics Places Orphan Protistan Lineages in a Novel Eukaryotic Super Group Genome Biology and Evolution 10 2 427 433 doi 10 1093 gbe evy014 PMC 5793813 PMID 29360967 a b Tikhonenkov DV Mikhailov KV Gawryluk RM Belyaev AO Mathur V Karpov SA et al December 2022 Microbial predators form a new supergroup of eukaryotes Nature 612 7941 714 719 doi 10 1038 s41586 022 05511 5 PMID 36477531 S2CID 254436650 Definition of EUKARYOTE www merriam webster com Retrieved 12 December 2022 a b Gabaldon T October 2021 Origin and Early Evolution of the Eukaryotic Cell Annual Review of Microbiology 75 1 631 647 doi 10 1146 annurev micro 090817 062213 PMID 34343017 S2CID 236916203 a b Woese CR Kandler O Wheelis ML June 1990 Towards a natural system of organisms proposal for the domains Archaea Bacteria and Eucarya Proceedings of the National Academy of Sciences of the United States of America 87 12 4576 4579 Bibcode 1990PNAS 87 4576W doi 10 1073 pnas 87 12 4576 PMC 54159 PMID 2112744 Zimmer C 11 April 2016 Scientists Unveil New Tree of Life The New York Times Archived from the original on 24 March 2019 Retrieved 11 April 2016 Gribaldo S Brochier Armanet C January 2020 Evolutionary relationships between archaea and eukaryotes Nature Ecology amp Evolution 4 1 20 21 doi 10 1038 s41559 019 1073 1 PMID 31836857 Doolittle WF February 2020 Evolution Two Domains of Life or Three Current Biology 30 4 R177 R179 doi 10 1016 j cub 2020 01 010 PMID 32097647 a b Williams TA Cox CJ Foster PG Szollosi GJ Embley TM January 2020 Phylogenomics provides robust support for a two domains tree of life Nature Ecology amp Evolution 4 1 138 147 doi 10 1038 s41559 019 1040 x PMC 6942926 PMID 31819234 a b Whitman WB Coleman DC Wiebe WJ June 1998 Prokaryotes the unseen majority PDF Proceedings of the National Academy of Sciences of the United States of America 95 12 6578 6583 Bibcode 1998PNAS 95 6578W doi 10 1073 pnas 95 12 6578 PMC 33863 PMID 9618454 Archived PDF from the original on 20 August 2008 Retrieved 16 September 2011 Leander BS May 2020 Predatory protists Current Biology 30 10 R510 R516 doi 10 1016 j cub 2020 03 052 PMID 32428491 S2CID 218710816 Harper Douglas eukaryotic Online Etymology Dictionary Murat D Byrne M Komeili A October 2010 Cell biology of prokaryotic organelles Cold Spring Harbor Perspectives in Biology 2 10 a000422 doi 10 1101 cshperspect a000422 PMC 2944366 PMID 20739411 Whittaker RH January 1969 New concepts of kingdoms or organisms Evolutionary relations are better represented by new classifications than by the traditional two kingdoms Science 163 3863 150 60 Bibcode 1969Sci 163 150W CiteSeerX 10 1 1 403 5430 doi 10 1126 science 163 3863 150 PMID 5762760 Campbell NA Cain ML Minorsky PV Reece JB Urry LA 2018 Chapter 13 Sexual Life Cycles and Meiosis Biology A Global Approach 11th ed New York Pearson Education ISBN 978 1 292 17043 5 Yamaguchi M Worman CO 2014 Deep sea microorganisms and the origin of the eukaryotic cell PDF Jpn J Protozool 47 1 2 29 48 Archived from the original PDF on 9 August 2017 Retrieved 24 October 2017 Linka M Weber AP 2011 Evolutionary Integration of Chloroplast Metabolism with the Metabolic Networks of the Cells In Burnap RL Vermaas WF eds Functional Genomics and Evolution of Photosynthetic Systems Springer p 215 ISBN 978 94 007 1533 2 Archived from the original on 29 May 2016 Retrieved 27 October 2015 Marsh M 2001 Endocytosis Oxford University Press p vii ISBN 978 0 19 963851 2 Hetzer MW March 2010 The nuclear envelope Cold Spring Harbor Perspectives in Biology 2 3 a000539 doi 10 1101 cshperspect a000539 PMC 2829960 PMID 20300205 Endoplasmic Reticulum Rough and Smooth British Society for Cell Biology Archived from the original on 24 March 2019 Retrieved 12 November 2017 Golgi Apparatus British Society for Cell Biology Archived from the original on 13 November 2017 Retrieved 12 November 2017 Lysosome British Society for Cell Biology Archived from the original on 13 November 2017 Retrieved 12 November 2017 a b c d Karnkowska A Vacek V Zubacova Z Treitli SC Petrzelkova R Eme L et al May 2016 A Eukaryote without a Mitochondrial Organelle Current Biology 26 10 1274 1284 doi 10 1016 j cub 2016 03 053 PMID 27185558 Saygin D Tabib T Bittar HE Valenzi E Sembrat J Chan SY et al July 1957 Transcriptional profiling of lung cell populations in idiopathic pulmonary arterial hypertension Pulmonary Circulation 10 1 131 144 Bibcode 1957SciAm 197a 131S doi 10 1038 scientificamerican0757 131 PMID 32166015 Mack S 1 May 2006 Re Are there eukaryotic cells without mitochondria madsci org Archived from the original on 24 April 2014 Retrieved 24 April 2014 Watson J Hopkins N Roberts J Steitz JA Weiner A 1988 28 The Origins of Life Molecular Biology of the Gene Fourth ed Menlo Park CA The Benjamin Cummings Publishing Company Inc p 1154 ISBN 978 0 8053 9614 0 Davis JL 13 May 2016 Scientists Shocked To Discover Eukaryote With NO Mitochondria IFL Science Archived from the original on 17 February 2019 Retrieved 13 May 2016 Sato N 2006 Origin and Evolution of Plastids Genomic View on the Unification and Diversity of Plastids In Wise RR Hoober JK eds The Structure and Function of Plastids Advances in Photosynthesis and Respiration Vol 23 Springer Netherlands pp 75 102 doi 10 1007 978 1 4020 4061 0 4 ISBN 978 1 4020 4060 3 Margulis L 1998 Symbiotic planet a new look at evolution New York Basic Books ISBN 978 0 465 07271 2 OCLC 39700477 page needed Lynn Margulis Heather I McKhann amp Lorraine Olendzenski ed Illustrated Glossary of Protoctista Jones and Bartlett Publishers Boston 1993 p xviii ISBN 0 86720 081 2 Vorobjev IA Nadezhdina ES 1987 The centrosome and its role in the organization of microtubules International Review of Cytology Vol 106 pp 227 293 doi 10 1016 S0074 7696 08 61714 3 ISBN 978 0 12 364506 7 PMID 3294718 Howland JL 2000 The Surprising Archaea Discovering Another Domain of Life Oxford Oxford University Press pp 69 71 ISBN 978 0 19 511183 5 Fry SC 1989 The Structure and Functions of Xyloglucan Journal of Experimental Botany 40 1 1 11 doi 10 1093 jxb 40 1 1 Raven JA July 1987 The role of vacuoles New Phytologist 106 3 357 422 doi 10 1111 j 1469 8137 1987 tb00149 x Oparka K 2005 Plasmodesmata Oxford UK Blackwell Publishing Raven PH Evert RF Eichorm SE 1999 Biology of Plants New York W H Freeman Silflow CD Lefebvre PA December 2001 Assembly and motility of eukaryotic cilia and flagella Lessons from Chlamydomonas reinhardtii Plant Physiology 127 4 1500 1507 doi 10 1104 pp 010807 PMC 1540183 PMID 11743094 Deacon J 2005 Fungal Biology Cambridge Massachusetts Blackwell Publishers pp 4 and passim ISBN 978 1 4051 3066 0 Keeling PJ October 2004 Diversity and evolutionary history of plastids and their hosts American Journal of Botany 91 10 1481 1493 doi 10 3732 ajb 91 10 1481 PMID 21652304 Patterson DJ Amoebae Protists Which Move and Feed Using Pseudopodia Tree of Life Web Project Archived from the original on 15 June 2010 Retrieved 12 November 2017 Gould SB Tham WH Cowman AF McFadden GI Waller RF 2008 Alveolins a new family of cortical proteins that define the protist infrakingdom Alveolata Molecular Biology and Evolution 25 6 1219 1230 doi 10 1093 molbev msn070 PMID 18359944 Lane N June 2011 Energetics and genetics across the prokaryote eukaryote divide Biology Direct 6 1 35 doi 10 1186 1745 6150 6 35 PMC 3152533 PMID 21714941 Dacks J Roger AJ June 1999 The first sexual lineage and the relevance of facultative sex Journal of Molecular Evolution 48 6 779 783 Bibcode 1999JMolE 48 779D doi 10 1007 PL00013156 PMID 10229582 S2CID 9441768 a b Ramesh MA Malik SB Logsdon JM January 2005 A phylogenomic inventory of meiotic genes evidence for sex in Giardia and an early eukaryotic origin of meiosis Current Biology 15 2 185 191 doi 10 1016 j cub 2005 01 003 PMID 15668177 S2CID 17013247 a b Malik SB Pightling AW Stefaniak LM Schurko AM Logsdon JM August 2007 Hahn MW ed An expanded inventory of conserved meiotic genes provides evidence for sex in Trichomonas vaginalis PLOS ONE 3 8 e2879 Bibcode 2008PLoSO 3 2879M doi 10 1371 journal pone 0002879 PMC 2488364 PMID 18663385 Akopyants NS Kimblin N Secundino N Patrick R Peters N Lawyer P Dobson DE Beverley SM Sacks DL April 2009 Demonstration of genetic exchange during cyclical development of Leishmania in the sand fly vector Science 324 5924 265 268 Bibcode 2009Sci 324 265A doi 10 1126 science 1169464 PMC 2729066 PMID 19359589 Lahr DJ Parfrey LW Mitchell EA Katz LA Lara E July 2011 The chastity of amoebae re evaluating evidence for sex in amoeboid organisms Proceedings Biological Sciences 278 1715 2081 2090 doi 10 1098 rspb 2011 0289 PMC 3107637 PMID 21429931 Moore RT 1980 Taxonomic proposals for the classification of marine yeasts and other yeast like fungi including the smuts Botanica Marina 23 361 373 Goldfuss 1818 Ueber die Classification der Zoophyten On the classification of zoophytes Isis Oder Encyclopadische Zeitung von Oken in German 2 6 1008 1019 Archived from the original on 24 March 2019 Retrieved 15 March 2019 From p 1008 Erste Klasse Urthiere Protozoa First class Primordial animals Protozoa Note each column of each page of this journal is numbered there are two columns per page Scamardella JM 1999 Not plants or animals a brief history of the origin of Kingdoms Protozoa Protista and Protoctista PDF International Microbiology 2 4 207 221 PMID 10943416 Archived from the original PDF on 14 June 2011 a b Rothschild LJ 1989 Protozoa Protista Protoctista what s in a name Journal of the History of Biology 22 2 277 305 doi 10 1007 BF00139515 PMID 11542176 S2CID 32462158 Archived from the original on 4 February 2020 Retrieved 4 February 2020 a b Spang A Saw JH Jorgensen SL Zaremba Niedzwiedzka K Martijn J Lind AE van Eijk R Schleper C Guy L Ettema TJ May 2015 Complex archaea that bridge the gap between prokaryotes and eukaryotes Nature 521 7551 173 179 Bibcode 2015Natur 521 173S doi 10 1038 nature14447 PMC 4444528 PMID 25945739 a b Zaremba Niedzwiedzka K Caceres EF Saw JH Backstrom D Juzokaite L Vancaester E Seitz KW Anantharaman K Starnawski P Kjeldsen KU Stott MB Nunoura T Banfield JF Schramm A Baker BJ Spang A Ettema TJ January 2017 Asgard archaea illuminate the origin of eukaryotic cellular complexity Nature 541 7637 353 358 Bibcode 2017Natur 541 353Z doi 10 1038 nature21031 OSTI 1580084 PMID 28077874 S2CID 4458094 Archived from the original on 5 December 2019 Retrieved 28 June 2019 a b Liu Y Zhou Z Pan J Baker BJ Gu JD Li M April 2018 Comparative genomic inference suggests mixotrophic lifestyle for Thorarchaeota The ISME Journal 12 4 1021 1031 doi 10 1038 s41396 018 0060 x PMC 5864231 PMID 29445130 Adl SM Simpson AG Farmer MA Andersen RA Anderson OR Barta JR et al 2005 The new higher level classification of eukaryotes with emphasis on the taxonomy of protists The Journal of Eukaryotic Microbiology 52 5 399 451 doi 10 1111 j 1550 7408 2005 00053 x PMID 16248873 S2CID 8060916 Harper JT Waanders E Keeling PJ January 2005 On the monophyly of chromalveolates using a six protein phylogeny of eukaryotes PDF International Journal of Systematic and Evolutionary Microbiology 55 Pt 1 487 496 doi 10 1099 ijs 0 63216 0 PMID 15653923 Archived from the original PDF on 17 December 2008 Parfrey LW Barbero E Lasser E Dunthorn M Bhattacharya D Patterson DJ Katz LA December 2006 Evaluating support for the current classification of eukaryotic diversity PLOS Genetics 2 12 e220 doi 10 1371 journal pgen 0020220 PMC 1713255 PMID 17194223 Adl SM Simpson AG Lane CE Lukes J Bass D Bowser SS et al September 2012 The revised classification of eukaryotes PDF The Journal of Eukaryotic Microbiology 59 5 429 93 doi 10 1111 j 1550 7408 2012 00644 x PMC 3483872 PMID 23020233 Archived from the original PDF on 16 June 2016 a b Burki F May 2014 The eukaryotic tree of life from a global phylogenomic perspective Cold Spring Harbor Perspectives in Biology 6 5 a016147 doi 10 1101 cshperspect a016147 PMC 3996474 PMID 24789819 a b Zhao S Burki F Brate J Keeling PJ Klaveness D Shalchian Tabrizi K June 2012 Collodictyon an ancient lineage in the tree of eukaryotes Molecular Biology and Evolution 29 6 1557 1568 doi 10 1093 molbev mss001 PMC 3351787 PMID 22319147 Romari K Vaulot D 2004 Composition and temporal variability of picoeukaryote communities at a coastal site of the English Channel from 18S rDNA sequences Limnol Oceanogr 49 3 784 798 Bibcode 2004LimOc 49 784R doi 10 4319 lo 2004 49 3 0784 S2CID 86718111 Roger AJ Simpson AG February 2009 Evolution revisiting the root of the eukaryote tree Current Biology 19 4 R165 67 doi 10 1016 j cub 2008 12 032 PMID 19243692 S2CID 13172971 a b Burki F Roger AJ Brown MW Simpson AG January 2020 The New Tree of Eukaryotes Trends in Ecology amp Evolution 35 1 43 55 doi 10 1016 j tree 2019 08 008 PMID 31606140 Tovar J Fischer A Clark CG June 1999 The mitosome a novel organelle related to mitochondria in the amitochondrial parasite Entamoeba histolytica Molecular Microbiology 32 5 1013 1021 doi 10 1046 j 1365 2958 1999 01414 x PMID 10361303 S2CID 22805284 Boxma B de Graaf RM van der Staay GW van Alen TA Ricard G Gabaldon T van Hoek AH Moon van der Staay SY Koopman WJ van Hellemond JJ Tielens AG Friedrich T Veenhuis M Huynen MA Hackstein JH March 2005 An anaerobic mitochondrion that produces hydrogen PDF Nature 434 7029 74 79 Bibcode 2005Natur 434 74B doi 10 1038 nature03343 PMID 15744302 S2CID 4401178 Archived PDF from the original on 24 January 2019 Retrieved 24 January 2019 a b c Jagus R Bachvaroff TR Joshi B Place AR 2012 Diversity of Eukaryotic Translational Initiation Factor eIF4E in Protists Comparative and Functional Genomics 2012 1 21 doi 10 1155 2012 134839 PMC 3388326 PMID 22778692 Burki F Kaplan M Tikhonenkov DV Zlatogursky V Minh BQ Radaykina LV Smirnov A Mylnikov AP Keeling PJ January 2016 Untangling the early diversification of eukaryotes a phylogenomic study of the evolutionary origins of Centrohelida Haptophyta and Cryptista Proceedings Biological Sciences 283 1823 20152802 doi 10 1098 rspb 2015 2802 PMC 4795036 PMID 26817772 Janouskovec J Tikhonenkov DV Burki F Howe AT Rohwer FL Mylnikov AP Keeling PJ December 2017 A New Lineage of Eukaryotes Illuminates Early Mitochondrial Genome Reduction PDF Current Biology 27 23 3717 24 e5 doi 10 1016 j cub 2017 10 051 PMID 29174886 S2CID 37933928 Archived PDF from the original on 27 April 2019 Retrieved 2 September 2019 Bodyl A February 2018 Did some red alga derived plastids evolve via kleptoplastidy A hypothesis Biological Reviews of the Cambridge Philosophical Society 93 1 201 222 doi 10 1111 brv 12340 PMID 28544184 S2CID 24613863 Lax G Eglit Y Eme L Bertrand EM Roger AJ Simpson AG November 2018 Hemimastigophora is a novel supra kingdom level lineage of eukaryotes Nature 564 7736 410 414 Bibcode 2018Natur 564 410L doi 10 1038 s41586 018 0708 8 PMID 30429611 S2CID 205570993 Adl SM Bass D Lane CE Lukes J Schoch CL Smirnov A et al January 2019 Revisions to the Classification Nomenclature and Diversity of Eukaryotes The Journal of Eukaryotic Microbiology 66 1 4 119 doi 10 1111 jeu 12691 PMC 6492006 PMID 30257078 Schon ME Zlatogursky VV Singh RP Poirier C Wilken S Mathur V et al 2021 Picozoa are archaeplastids without plastid Nature Communications 12 1 6651 bioRxiv 10 1101 2021 04 14 439778 doi 10 1038 s41467 021 26918 0 PMC 8599508 PMID 34789758 S2CID 233328713 Burki F Shalchian Tabrizi K Minge M Skjaeveland A Nikolaev SI Jakobsen KS Pawlowski J August 2007 Butler G ed Phylogenomics reshuffles the eukaryotic supergroups PLOS ONE 2 8 e790 Bibcode 2007PLoSO 2 790B doi 10 1371 journal pone 0000790 PMC 1949142 PMID 17726520 a b Kim E Graham LE July 2008 Redfield RJ ed EEF2 analysis challenges the monophyly of Archaeplastida and Chromalveolata PLOS ONE 3 7 e2621 Bibcode 2008PLoSO 3 2621K doi 10 1371 journal pone 0002621 PMC 2440802 PMID 18612431 Baurain D Brinkmann H Petersen J Rodriguez Ezpeleta N Stechmann A Demoulin V Roger AJ Burger G Lang BF Philippe H July 2010 Phylogenomic evidence for separate acquisition of plastids in cryptophytes haptophytes and stramenopiles Molecular Biology and Evolution 27 7 1698 1709 doi 10 1093 molbev msq059 PMID 20194427 Burki F Okamoto N Pombert JF Keeling PJ June 2012 The evolutionary history of haptophytes and cryptophytes phylogenomic evidence for separate origins Proceedings Biological Sciences 279 1736 2246 2254 doi 10 1098 rspb 2011 2301 PMC 3321700 PMID 22298847 Cavalier Smith T 2003 Protist phylogeny and the high level classification of Protozoa European Journal of Protistology 39 4 338 348 doi 10 1078 0932 4739 00002 S2CID 84403388 Burki F Pawlowski J October 2006 Monophyly of Rhizaria and multigene phylogeny of unicellular bikonts Molecular Biology and Evolution 23 10 1922 1930 doi 10 1093 molbev msl055 PMID 16829542 Ren R Sun Y Zhao Y Geiser D Ma H Zhou X September 2016 Phylogenetic Resolution of Deep Eukaryotic and Fungal Relationships Using Highly Conserved Low Copy Nuclear Genes Genome Biology and Evolution 8 9 2683 2701 doi 10 1093 gbe evw196 PMC 5631032 PMID 27604879 a b c Cavalier Smith T January 2018 Kingdom Chromista and its eight phyla a new synthesis emphasising periplastid protein targeting cytoskeletal and periplastid evolution and ancient divergences Protoplasma 255 1 297 357 doi 10 1007 s00709 017 1147 3 PMC 5756292 PMID 28875267 Derelle R Torruella G Klimes V Brinkmann H Kim E Vlcek C Lang BF Elias M February 2015 Bacterial proteins pinpoint a single eukaryotic root Proceedings of the National Academy of Sciences of the United States of America 112 7 E693 699 Bibcode 2015PNAS 112E 693D doi 10 1073 pnas 1420657112 PMC 4343179 PMID 25646484 Yang J Harding T Kamikawa R Simpson AG Roger AJ May 2017 Mitochondrial Genome Evolution and a Novel RNA Editing System in Deep Branching Heteroloboseids Genome Biology and Evolution 9 5 1161 1174 doi 10 1093 gbe evx086 PMC 5421314 PMID 28453770 Cavalier Smith T Fiore Donno AM Chao E Kudryavtsev A Berney C Snell EA Lewis R February 2015 Multigene phylogeny resolves deep branching of Amoebozoa Molecular Phylogenetics and Evolution 83 293 304 doi 10 1016 j ympev 2014 08 011 PMID 25150787 Torruella G de Mendoza A Grau Bove X Anto M Chaplin MA del Campo J Eme L Perez Cordon G Whipps CM Nichols KM Paley R Roger AJ Sitja Bobadilla A Donachie S Ruiz Trillo I September 2015 Phylogenomics Reveals Convergent Evolution of Lifestyles in Close Relatives of Animals and Fungi Current Biology 25 18 2404 2410 doi 10 1016 j cub 2015 07 053 PMID 26365255 a b Lopez Garcia P Eme L Moreira D December 2017 Symbiosis in eukaryotic evolution Journal of Theoretical Biology 434 20 33 Bibcode 2017JThBi 434 20L doi 10 1016 j jtbi 2017 02 031 PMC 5638015 PMID 28254477 Ponce Toledo RI Deschamps P Lopez Garcia P Zivanovic Y Benzerara K Moreira D February 2017 An Early Branching Freshwater Cyanobacterium at the Origin of Plastids Current Biology 27 3 386 391 doi 10 1016 j cub 2016 11 056 PMC 5650054 PMID 28132810 de Vries J Archibald JM February 2017 Endosymbiosis Did Plastids Evolve from a Freshwater Cyanobacterium Current Biology 27 3 R103 105 doi 10 1016 j cub 2016 12 006 PMID 28171752 a b Cavalier Smith T June 2010 Kingdoms Protozoa and Chromista and the eozoan root of the eukaryotic tree Biology Letters 6 3 342 345 doi 10 1098 rsbl 2009 0948 PMC 2880060 PMID 20031978 a b Cavalier Smith T May 2013 Early evolution of eukaryote feeding modes cell structural diversity and classification of the protozoan phyla Loukozoa Sulcozoa and Choanozoa European Journal of Protistology 49 2 115 178 doi 10 1016 j ejop 2012 06 001 PMID 23085100 a b Cavalier Smith T Chao EE Snell EA Berney C Fiore Donno AM Lewis R December 2014 Multigene eukaryote phylogeny reveals the likely protozoan ancestors of opisthokonts animals fungi choanozoans and Amoebozoa Molecular Phylogenetics and Evolution 81 71 85 doi 10 1016 j ympev 2014 08 012 PMID 25152275 Cavalier Smith T Chao EE Lewis R April 2018 Multigene phylogeny and cell evolution of chromist infrakingdom Rhizaria contrasting cell organisation of sister phyla Cercozoa and Retaria Protoplasma 255 5 1517 1574 doi 10 1007 s00709 018 1241 1 PMC 6133090 PMID 29666938 He D Fiz Palacios O Fu CJ Fehling J Tsai CC Baldauf SL February 2014 An alternative root for the eukaryote tree of life Current Biology 24 4 465 470 doi 10 1016 j cub 2014 01 036 PMID 24508168 Cox CJ Foster PG Hirt RP Harris SR Embley TM December 2008 The archaebacterial origin of eukaryotes Proceedings of the National Academy of Sciences of the United States of America 105 51 20356 20361 Bibcode 2008PNAS 10520356C doi 10 1073 pnas 0810647105 PMC 2629343 PMID 19073919 Ciccarelli FD Doerks T von Mering C Creevey CJ Snel B Bork P March 2006 Toward automatic reconstruction of a highly resolved tree of life Science 311 5765 1283 1287 Bibcode 2006Sci 311 1283C CiteSeerX 10 1 1 381 9514 doi 10 1126 science 1123061 PMID 16513982 S2CID 1615592 a b Hug LA Baker BJ Anantharaman K Brown CT Probst AJ Castelle CJ Butterfield CN Hernsdorf AW Amano Y Ise K Suzuki Y Dudek N Relman DA Finstad KM Amundson R Thomas BC Banfield JF April 2016 A new view of the tree of life Nature Microbiology 1 5 16048 doi 10 1038 nmicrobiol 2016 48 PMID 27572647 O Malley MA Leger MM Wideman JG Ruiz Trillo I March 2019 Concepts of the last eukaryotic common ancestor Nature Ecology amp Evolution Springer Science and Business Media LLC 3 3 338 344 doi 10 1038 s41559 019 0796 3 hdl 10261 201794 PMID 30778187 S2CID 67790751 a b Brocks JJ Logan GA Buick R Summons RE August 1999 Archean molecular fossils and the early rise of eukaryotes Science 285 5430 1033 1036 Bibcode 1999Sci 285 1033B CiteSeerX 10 1 1 516 9123 doi 10 1126 science 285 5430 1033 PMID 10446042 a b Hartman H Fedorov A February 2002 The origin of the eukaryotic cell a genomic investigation Proceedings of the National Academy of Sciences of the United States of America 99 3 1420 5 Bibcode 2002PNAS 99 1420H doi 10 1073 pnas 032658599 PMC 122206 PMID 11805300 Knoll AH Javaux EJ Hewitt D Cohen P June 2006 Eukaryotic organisms in Proterozoic oceans Philosophical Transactions of the Royal Society of London Series B Biological Sciences 361 1470 1023 1038 doi 10 1098 rstb 2006 1843 PMC 1578724 PMID 16754612 Retallack GJ Krull ES Thackray GD Parkinson DH 2013 Problematic urn shaped fossils from a Paleoproterozoic 2 2 Ga paleosol in South Africa Precambrian Research 235 71 87 Bibcode 2013PreR 235 71R doi 10 1016 j precamres 2013 05 015 El Albani A Bengtson S Canfield DE Bekker A Macchiarelli R Mazurier A Hammarlund EU Boulvais P Dupuy JJ Fontaine C Fursich FT Gauthier Lafaye F Janvier P Javaux E Ossa FO Pierson Wickmann AC Riboulleau A Sardini P Vachard D Whitehouse M Meunier A July 2010 Large colonial organisms with coordinated growth in oxygenated environments 2 1 Gyr ago Nature 466 7302 100 104 Bibcode 2010Natur 466 100A doi 10 1038 nature09166 PMID 20596019 S2CID 4331375 Bengtson S Belivanova V Rasmussen B Whitehouse M May 2009 The controversial Cambrian fossils of the Vindhyan are real but more than a billion years older Proceedings of the National Academy of Sciences of the United States of America 106 19 7729 7734 Bibcode 2009PNAS 106 7729B doi 10 1073 pnas 0812460106 PMC 2683128 PMID 19416859 Ward P 9 February 2008 Mass extinctions the microbes strike back New Scientist pp 40 43 Archived from the original on 8 July 2008 Retrieved 27 August 2017 French KL Hallmann C Hope JM Schoon PL Zumberge JA Hoshino Y Peters CA George SC Love GD Brocks JJ Buick R Summons RE May 2015 Reappraisal of hydrocarbon biomarkers in Archean rocks Proceedings of the National Academy of Sciences of the United States of America 112 19 5915 5920 Bibcode 2015PNAS 112 5915F doi 10 1073 pnas 1419563112 PMC 4434754 PMID 25918387 Brocks JJ Jarrett AJ Sirantoine E Hallmann C Hoshino Y Liyanage T August 2017 The rise of algae in Cryogenian oceans and the emergence of animals Nature 548 7669 578 581 Bibcode 2017Natur 548 578B doi 10 1038 nature23457 PMID 28813409 S2CID 205258987 Gold DA Caron A Fournier GP Summons RE March 2017 Paleoproterozoic sterol biosynthesis and the rise of oxygen Nature 543 7645 420 423 Bibcode 2017Natur 543 420G doi 10 1038 nature21412 hdl 1721 1 128450 PMID 28264195 S2CID 205254122 Wei JH Yin X Welander PV 24 June 2016 Sterol Synthesis in Diverse Bacteria Frontiers in Microbiology 7 990 doi 10 3389 fmicb 2016 00990 PMC 4919349 PMID 27446030 Hoshino Y Gaucher EA June 2021 Evolution of bacterial steroid biosynthesis and its impact on eukaryogenesis Proceedings of the National Academy of Sciences of the United States of America 118 25 e2101276118 Bibcode 2021PNAS 11801276H doi 10 1073 pnas 2101276118 PMC 8237579 PMID 34131078 Isson TT Love GD Dupont CL Reinhard CT Zumberge AJ Asael D et al June 2018 Tracking the rise of eukaryotes to ecological dominance with zinc isotopes Geobiology 16 4 341 352 doi 10 1111 gbi 12289 PMID 29869832 Yoshikawa G Blanc Mathieu R Song C Kayama Y Mochizuki T Murata K Ogata H Takemura M April 2019 Medusavirus a Novel Large DNA Virus Discovered from Hot Spring Water Journal of Virology 93 8 doi 10 1128 JVI 02130 18 PMC 6450098 PMID 30728258 Archived from the original on 30 April 2019 New giant virus may help scientists better understand the emergence of complex life EurekAlert Press release 30 April 2019 Martin W December 2005 Archaebacteria Archaea and the origin of the eukaryotic nucleus Current Opinion in Microbiology 8 6 630 637 doi 10 1016 j mib 2005 10 004 PMID 16242992 Takemura M May 2001 Poxviruses and the origin of the eukaryotic nucleus Journal of Molecular Evolution 52 5 419 425 Bibcode 2001JMolE 52 419T doi 10 1007 s002390010171 PMID 11443345 S2CID 21200827 Bell PJ September 2001 Viral eukaryogenesis was the ancestor of the nucleus a complex DNA virus Journal of Molecular Evolution 53 3 251 256 Bibcode 2001JMolE 53 251L doi 10 1007 s002390010215 PMID 11523012 S2CID 20542871 Wachtershauser G January 2003 From pre cells to Eukarya a tale of two lipids Molecular Microbiology 47 1 13 22 doi 10 1046 j 1365 2958 2003 03267 x PMID 12492850 S2CID 37944519 Wachtershauser G October 2006 From volcanic origins of chemoautotrophic life to Bacteria Archaea and Eukarya Philosophical Transactions of the Royal Society of London Series B Biological Sciences 361 1474 1787 1806 discussion 1806 1808 doi 10 1098 rstb 2006 1904 PMC 1664677 PMID 17008219 Lane N 2016 The Vital Question Why is Life the Way it is paperback ed Profile Books pp 157 91 ISBN 978 1 781 25037 2 Egel R January 2012 Primal eukaryogenesis on the communal nature of precellular States ancestral to modern life Life Vol 2 no 1 pp 170 212 doi 10 3390 life2010170 PMC 4187143 PMID 25382122 a b Harish A Tunlid A Kurland CG August 2013 Rooted phylogeny of the three superkingdoms Biochimie 95 8 1593 1604 doi 10 1016 j biochi 2013 04 016 PMID 23669449 a b Harish A Kurland CG July 2017 Akaryotes and Eukaryotes are independent descendants of a universal common ancestor Biochimie 138 168 183 doi 10 1016 j biochi 2017 04 013 PMID 28461155 a b Imachi H Nobu MK Nakahara N Morono Y Ogawara M Takaki Y et al January 2020 Isolation of an archaeon at the prokaryote eukaryote interface Nature 577 7791 519 525 Bibcode 2020Natur 577 519I doi 10 1038 s41586 019 1916 6 PMC 7015854 PMID 31942073 Da Cunha V Gaia M Gadelle D Nasir A Forterre P June 2017 Lokiarchaea are close relatives of Euryarchaeota not bridging the gap between prokaryotes and eukaryotes PLOS Genetics 13 6 e1006810 doi 10 1371 journal pgen 1006810 PMC 5484517 PMID 28604769 Harish A Kurland CG July 2017 Empirical genome evolution models root the tree of life Biochimie 138 137 155 doi 10 1016 j biochi 2017 04 014 PMID 28478110 Spang A Eme L Saw JH Caceres EF Zaremba Niedzwiedzka K Lombard J et al March 2018 Asgard archaea are the closest prokaryotic relatives of eukaryotes PLOS Genetics 14 3 e1007080 doi 10 1371 journal pgen 1007080 PMC 5875740 PMID 29596421 MacLeod F Kindler GS Wong HL Chen R Burns BP 2019 Asgard archaea Diversity function and evolutionary implications in a range of microbiomes AIMS Microbiology 5 1 48 61 doi 10 3934 microbiol 2019 1 48 PMC 6646929 PMID 31384702 Zimmer C 15 January 2020 This Strange Microbe May Mark One of Life s Great Leaps A organism living in ocean muck offers clues to the origins of the complex cells of all animals and plants The New York Times Archived from the original on 16 January 2020 Retrieved 18 January 2020 Jekely G 2007 Origin of Eukaryotic Endomembranes A Critical Evaluation of Different Model Scenarios Eukaryotic Membranes and Cytoskeleton Advances in Experimental Medicine and Biology Vol 607 New York N Y Springer Science Business Media Austin Tex Landes Bioscience pp 38 51 doi 10 1007 978 0 387 74021 8 3 ISBN 978 0 387 74020 1 PMID 17977457 Cavalier Smith T March 2002 The phagotrophic origin of eukaryotes and phylogenetic classification of Protozoa International Journal of Systematic and Evolutionary Microbiology 52 Pt 2 297 354 doi 10 1099 00207713 52 2 297 PMID 11931142 Archived from the original on 29 July 2017 Retrieved 10 June 2008 a b Martin W Muller M March 1998 The hydrogen hypothesis for the first eukaryote Nature 392 6671 37 41 Bibcode 1998Natur 392 37M doi 10 1038 32096 PMID 9510246 S2CID 338885 Pisani D Cotton JA McInerney JO August 2007 Supertrees disentangle the chimerical origin of eukaryotic genomes Molecular Biology and Evolution 24 8 1752 1760 doi 10 1093 molbev msm095 PMID 17504772 Brueckner J Martin WF April 2020 Bacterial Genes Outnumber Archaeal Genes in Eukaryotic Genomes Genome Biology and Evolution 12 4 282 292 doi 10 1093 gbe evaa047 PMC 7151554 PMID 32142116 a b Latorre A Durban A Moya A Pereto J 2011 The role of symbiosis in eukaryotic evolution In Gargaud M Lopez Garcia P Martin H eds Origins and Evolution of Life An astrobiological perspective Cambridge Cambridge University Press pp 326 339 ISBN 978 0 521 76131 4 Archived from the original on 24 March 2019 Retrieved 27 August 2017 Ayala J April 1994 Transport and internal organization of membranes vesicles membrane networks and GTP binding proteins Journal of Cell Science 107 Pt 4 753 763 doi 10 1242 jcs 107 4 753 PMID 8056835 Archived from the original on 29 April 2012 Retrieved 27 March 2013 Martin WF The Origin of Mitochondria Scitable Nature education Archived from the original on 16 June 2013 Retrieved 27 March 2013 That is it entails a corollary assumption an add on to the theory that brings it into agreement with available observations that all descendants of the initial host lineage except the one that acquired mitochondria went extinct Dacks JB Field MC August 2018 Evolutionary origins and specialisation of membrane transport Current Opinion in Cell Biology 53 70 76 doi 10 1016 j ceb 2018 06 001 PMC 6141808 PMID 29929066 Martijn J Vosseberg J Guy L Offre P Ettema TJ May 2018 Deep mitochondrial origin outside the sampled alphaproteobacteria Nature 557 7703 101 105 Bibcode 2018Natur 557 101M doi 10 1038 s41586 018 0059 5 PMID 29695865 S2CID 13740626 Archived from the original on 21 April 2019 Retrieved 21 April 2019 Shawna Williams 25 April 2018 Mitochondria s Bacterial Origins Upended The Scientist Baum DA Baum B October 2014 An inside out origin for the eukaryotic cell BMC Biology 12 76 doi 10 1186 s12915 014 0076 2 PMC 4210606 PMID 25350791 Terry Devitt 12 December 2014 New theory suggests alternate path led to rise of the eukaryotic cell University of Wisconsin Madison Press release Archived from the original on 21 April 2019 Brouwers L 12 April 2013 How genetic plunder transformed a microbe into a pink salt loving scavenger Scientific American 109 50 20537 20542 Archived from the original on 10 October 2018 Retrieved 21 April 2019 Wilcox C 9 April 2019 Rethinking the ancestry of the eukaryotes Quanta Magazine Archived from the original on 9 May 2019 Retrieved 8 May 2019 McCutcheon JP October 2021 The Genomics and Cell Biology of Host Beneficial Intracellular Infections Annual Review of Cell and Developmental Biology 37 1 115 142 doi 10 1146 annurev cellbio 120219 024122 PMID 34242059 S2CID 235786110 Saygin D Tabib T Bittar HE Valenzi E Sembrat J Chan SY et al 8 June 2022 Transcriptional profiling of lung cell populations in idiopathic pulmonary arterial hypertension Pulmonary Circulation 10 1 doi 10 1146 knowable 060822 2 PMID 32166015 Pittis AA Gabaldon T March 2016 Late acquisition of mitochondria by a host with chimaeric prokaryotic ancestry Nature 531 7592 101 104 Bibcode 2016Natur 531 101P doi 10 1038 nature16941 PMC 4780264 PMID 26840490 Burton ZF 1 August 2017 Evolution since coding Cradles halos barrels and wings Academic Press ISBN 978 0 12 813034 6 Archived from the original on 24 March 2019 Retrieved 27 November 2018 Martin WF Roettger M Ku C Garg SG Nelson Sathi S Landan G February 2017 Late mitochondrial origin is an artifact Genome Biology and Evolution 9 2 373 379 doi 10 1093 gbe evx027 PMC 5516564 PMID 28199635 This article incorporates public domain material from Science Primer NCBI Archived from the original on 8 December 2009 External links Edit Wikispecies has information related to Eukaryota Eukaryotes Tree of Life Web Project Eukaryote at the Encyclopedia of Life Attraction and sex among our microbial Last Eukaryotic Common Ancestors The Atlantic November 11 2020 Retrieved from https en wikipedia org w index php title Eukaryote amp oldid 1135487223, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.