fbpx
Wikipedia

Last universal common ancestor

December 15, 2023

"LUCA" redirects here. For other uses, see Luca.

The last universal common ancestor (LUCA) is hypothesized to have been a common ancestral cell from which the three domains of life, the Bacteria, the Archaea, and the Eukarya originated. It is suggested to have been a "cellular organism that had a lipid bilayer and used DNA, RNA, and protein".[2] The LUCA has also been defined as "a hypothetical organism ancestral to all three domains".[3] The LUCA is the point or stage at which the three domains of life diverged from precursing forms of life (about 3.5 - 3.8 billion years ago). The nature of this point or stage of divergence remains a topic of research.

Phylogenetic tree linking all major groups of living organisms, namely the Bacteria, Archaea, and Eukarya, as proposed by Woese et al 1990,[1] with the last universal common ancestor (LUCA) shown at the root

All earlier forms of life precursing this divergence and, of course, all extant terrestrial organisms are generally thought to share common ancestry. On the basis of a formal statistical test, this theory of a universal common ancestry (UCA) is supported versus competing multiple-ancestry hypotheses. The first universal common ancestor (FUCA) is a hypothetical non-cellular ancestor to LUCA and other now-extinct sister lineages.

The genesis of viruses, before or after the LUCA as well as the diversity of extant viruses and their hosts are subjects of investigation.

While no fossil evidence of the LUCA exists, the detailed biochemical similarity of all current life (divided into the three domains) makes it plausible. Its characteristics can be inferred from shared features of modern genomes. These genes describe a complex life form with many co-adapted features, including transcription and translation mechanisms to convert information from DNA to mRNA to proteins. The earlier forms of life probably lived in the high-temperature water of deep sea vents near ocean-floor magma flows around 4 billion years ago.

Historical background edit

Further information: Tree of life (biology)
 
A tree of life, like this one from Charles Darwin's notebooks c. July 1837, implies a single common ancestor at its root (labelled "1").

A phylogenetic tree directly portrays the idea of evolution by descent from a single ancestor.[4] An early tree of life was sketched by Jean-Baptiste Lamarck in his Philosophie zoologique in 1809.[5][6] Charles Darwin more famously proposed the theory of universal common descent through an evolutionary process in his book On the Origin of Species in 1859: "Therefore I should infer from analogy that probably all the organic beings which have ever lived on this earth have descended from some one primordial form, into which life was first breathed."[7] The last sentence of the book begins with a restatement of the hypothesis:

There is grandeur in this view of life, with its several powers, having been originally breathed into a few forms or into one ...

— [7]

The term "last universal common ancestor" or "LUCA" was first used in the 1990s for such a primordial organism.[8][9][10]

Inferring LUCA's features edit

An anaerobic thermophile edit

Further information: Phylogenetic bracketing
 
A direct way to infer LUCA's genome would be to find genes common to all surviving descendants. Unfortunately, there are only about 30 such genes, mostly for ribosome proteins, proving that LUCA had the genetic code. Many other LUCA genes have been lost in later lineages over 4 billion years of evolution.[11]
 
Three ways to infer genes present in LUCA: universal presence, presence in both the Bacterial and Archaean domains, and presence in two phyla in both domains. The first yields as stated only about 30 genes; the second, some 11,000 with lateral gene transfer (LGT) very likely; the third, 355 genes probably in LUCA, since they were found in at least two phyla in both domains, making LGT an unlikely explanation.[11]

In 2016, Madeline C. Weiss and colleagues genetically analyzed 6.1 million protein-coding genes and 286,514 protein clusters from sequenced prokaryotic genomes representing many phylogenetic trees, and identified 355 protein clusters that were probably common to the LUCA. The results of their analysis are highly specific, though debated. They depict LUCA as "anaerobic, CO2-fixing, H2-dependent with a Wood–Ljungdahl pathway (the reductive acetyl-coenzyme A pathway), N2-fixing and thermophilic. LUCA's biochemistry was replete with FeS clusters and radical reaction mechanisms."[12] The cofactors also reveal "dependence upon transition metals, flavins, S-adenosyl methionine, coenzyme A, ferredoxin, molybdopterin, corrins and selenium. Its genetic code required nucleoside modifications and S-adenosylmethionine-dependent methylations."[12] They show that methanogenic clostridia was basal, near the root of the phylogenetic tree, in the 355 protein lineages examined, and that the LUCA may therefore have inhabited an anaerobic hydrothermal vent setting in a geochemically active environment rich in H2, CO2, and iron, where ocean water interacted with hot magma beneath the ocean floor.[12] It's even inferred that LUCA also grew from H2 and CO2 via the reverse incomplete Krebs cycle.[13] Other metabolic pathways inferred in LUCA are the pentose phosphate pathway, glycolysis, and gluconeogenesis.[14] Even if phylogenetic evidence may point to a hydrothermal vent environment for a thermophilic LUCA, this does not constitute evidence that the origin of life took place at a hydrothermal vent since mass extinctions may have removed previously existing branches of life.[15]

While the gross anatomy of the LUCA can only be reconstructed with much uncertainty, its biochemical mechanisms can be described in some detail, based on the "universal" properties currently shared by all independently living organisms on Earth.[16]

 
LUCA systems and environment, including the Wood–Ljungdahl or reductive acetyl–CoA pathway to fix carbon, and most likely DNA complete with the genetic code and enzymes to replicate it, transcribe it to RNA, and translate it to proteins.

The LUCA certainly had genes and a genetic code.[11] Its genetic material was most likely DNA,[17] so that it lived after the RNA world.[a][20] The DNA was kept double-stranded by an enzyme, DNA polymerase, which recognises the structure and directionality of DNA.[21] The integrity of the DNA was maintained by a group of repair enzymes including DNA topoisomerase.[22] If the genetic code was based on dual-stranded DNA, it was expressed by copying the information to single-stranded RNA. The RNA was produced by a DNA-dependent RNA polymerase using nucleotides similar to those of DNA.[17] It had multiple DNA-binding proteins, such as histone-fold proteins.[23] The genetic code was expressed into proteins. These were assembled from 20 free amino acids by translation of a messenger RNA via a mechanism of ribosomes, transfer RNAs, and a group of related proteins.[17]

LUCA was likely capable of sexual interaction in the sense that adaptive gene functions were present that promoted the transfer of DNA between individuals of the population to facilitate genetic recombination. Homologous gene products that promote genetic recombination are present in bacteria, archaea and eukaryota, such as the RecA protein in bacteria, the RadA protein in archaea, and the Rad51 and Dmc1 proteins in eukaryota.[24]

The functionality of LUCA as well as evidence for the early evolution membrane-dependent biological systems together suggest that LUCA had cellularity and cell membranes.[25] As for the cell's gross structure, it contained a water-based cytoplasm effectively enclosed by a lipid bilayer membrane; it was capable of reproducing by cell division.[26] It tended to exclude sodium and concentrate potassium by means of specific ion transporters (or ion pumps). The cell multiplied by duplicating all its contents followed by cellular division. The cell used chemiosmosis to produce energy. It also reduced CO2 and oxidized H2 (methanogenesis or acetogenesis) via acetyl-thioesters.[27][28]

By phylogenetic bracketing, analysis of the presumed LUCA's offspring groups, LUCA appears to have been a small, single-celled organism. It likely had a ring-shaped coil of DNA floating freely within the cell. Morphologically, it would likely not have stood out within a mixed population of small modern-day bacteria. The originator of the three-domain system, Carl Woese, stated that in its genetic machinery, the LUCA would have been a "simpler, more rudimentary entity than the individual ancestors that spawned the three [domains] (and their descendants)".[1]

 
The LUCA used the Wood–Ljungdahl or reductive acetyl–CoA pathway to fix carbon, if it was an autotroph, or to respire anaerobically, if it was a heterotroph.

An alternative to the search for "universal" traits is to use genome analysis to identify phylogenetically ancient genes. This gives a picture of a LUCA that could live in a geochemically harsh environment and is like modern prokaryotes. Analysis of biochemical pathways implies the same sort of chemistry as does phylogenetic analysis. Weiss and colleagues write that "Experiments ... demonstrate that ... acetyl-CoA pathway [chemicals used in anaerobic respiration] formate, methanol, acetyl moieties, and even pyruvate arise spontaneously ... from CO2, native metals, and water", a combination present in hydrothermal vents.[29]

An experiment shows that Zn2+, Cr3+, and Fe can promote 6 of the 11 reactions of an ancient anabolic pathway called the reverse Krebs cycle in acidic conditions which implies that LUCA might have inhabited either hydrothermal vents or acidic metal-rich hydrothermal fields.[30]

Because both bacteria and archaea have differences in the structure of phospholipids and cell wall, ion pumping, most proteins involved in DNA replication, and glycolysis, it is inferred that LUCA had a permeable membrane without an ion pump. The emergence of Na+/H+ antiporters likely lead to the evolution of impermeable membranes present in eukaryotes, archaea, and bacteria. It's stated that "The late and independent evolution of glycolysis but not gluconeogenesis is entirely consistent with LUCA being powered by natural proton gradients across leaky membranes. Several discordant traits are likely to be linked to the late evolution of cell membranes, notably the cell wall, whose synthesis depends on the membrane and DNA replication".[31] Although LUCA likely had DNA, it is unknown if it could replicate DNA and is suggested to "might just have been a chemically stable repository for RNA-based replication".[32] It is likely that the permeable membrane of LUCA was composed of archaeal lipids (isoprenoids) and bacterial lipids (fatty acids). Isoprenoids would have enhanced stabilization of LUCA's membrane in the surrounding extreme habitat. Nick Lane and coauthors state that "The advantages and disadvantages of incorporating isoprenoids into cell membranes in different microenvironments may have driven membrane divergence, with the later biosynthesis of phospholipids giving rise to the unique G1P and G3P headgroups of archaea and bacteria respectively. If so, the properties conferred by membrane isoprenoids place the lipid divide as early as the origin of life".[33]

UV light between 200-280 nm (at the time, unprotected by the ozone layer) would have been damaging to nucleotides at the surface, as it can cause mutations or transcription errors and ultimately damaging consequences for organisms at the cellular level. However, it is likely that LUCA existed in a UV environment because of the prevalence of photolyase across the tree of life. Photolyase uses UV to drive photoreactivation, a that works to repair damage from radiation, caused by UV.

Alternative interpretations edit

Some other researchers have challenged Weiss et al.'s 2016 conclusions. Sarah Berkemer and Shawn McGlynn argue that Weiss et al. undersampled the families of proteins, so that the phylogenetic trees were not complete and failed to describe the evolution of proteins correctly. There are two risk in attempting to attribute LUCA's environment from near-universal gene distribution (as in Weiss et al. 2016). On the one hand, it risks misattributing convergence or horizontal gene transfer events to vertical descent and, on the other hand, it risks misattributing potential LUCA gene families as horizontal gene transfer events.

A phylogenomic and geochemical analysis of a set of proteins that probably traced to the LUCA show that it had K+-dependent GTPases and the ionic composition and concentration of its intracellular fluid was seemingly high K+/Na+ ratio, NH+
4, Fe2+, CO2+, Ni2+, Mg2+, Mn2+, Zn2+, pyrophosphate, and PO3−
4 which would imply a terrestrial hot spring habitat. It possibly had a phosphate-based metabolism. Further, these proteins were unrelated to autotrophy (the ability of an organism to create its own organic matter), suggesting that the LUCA had a heterotrophic lifestyle (consuming organic matter) and that its growth was dependent on organic matter produced by the physical environment.[34] Nick Lane argues that Na+/H+ antiporters could readily explain the low concentration of Na+ in the LUCA and its descendants.

The presence of the energy-handling enzymes CODH/acetyl-coenzyme A synthase in LUCA could be compatible not only with being an autotroph but also with life as a mixotroph or heterotroph.[35] Weiss et al. 2018 reply that no enzyme defines a trophic lifestyle, and that heterotrophs evolved from autotrophs.[36]

Evidence that LUCA was mesophilic edit

Several lines of evidence now suggest that LUCA was non-thermophilic.

The content of G + C nucleotide pairs (compared to the occurrence of A + T pairs) can indicate an organism's thermal optimum as they are more thermally stable due to an additional hydrogen bond. As a result they occur more frequently in the rRNA of thermophiles; however this is not seen in LUCA's reconstructed rRNA.[37][38][15]

The identification of thermophilic genes in the LUCA has been criticized,[39] as they may instead represent genes that evolved later in archaea or bacteria, then migrated between these via horizontal gene transfer, as in Woese's 1998 hypothesis.[40] LUCA could have been a mesophile that fixed CO2 and relied on H2, and lived close to hydrothermal vents.[41]

Further evidence that LUCA was mesophilic comes from the amino acid composition of its proteins. The abundance of I, V, Y, W, R, E, and L amino acids (denoted IVYWREL) in an organism's proteins is correlated with its optimal growth temperature.[42] According to phylogentic analysis, the IVYWREL content of LUCA's proteins suggests its ideal temperature was below 50°C.[15]

Finally, evidence that bacteria and archaea both independently underwent phases of increased and subsequently decreased thermo-tolerance suggests a dramatic post-LUCA climate shift that affected both populations and would explain the seeming genetic pervasiveness of thermo-tolerant genetics.[43]

Age edit

Further information: Abiogenesis

Studies from 2000 to 2018 have suggested an increasingly ancient time for the LUCA. In 2000, estimates of the LUCA's age ranged from 3.5 to 3.8 billion years ago in the Paleoarchean,[44] a few hundred million years before the earliest fossil evidence of life, for which candidates range in age from 3.48 to 4.28 billion years ago.[45][46][47][48][49] This placed the origin of the first forms of life shortly after the Late Heavy Bombardment which was thought to have repeatedly sterilized Earth's surface. However, a 2018 study by Holly Betts and colleagues applied a molecular clock model to the genomic and fossil record (102 species, 29 common protein-coding genes, mostly ribosomal), concluding that LUCA preceded the Late Heavy Bombardment. They assumed that there was no sterilizing event after the Moon-forming event, which they dated as 4.520 billion years ago, and concluded that the most likely date for LUCA was within 50 million years of that.[50]

Root of the tree of life edit

 
2005 tree of life showing horizontal gene transfers between branches including (coloured lines) the symbiogenesis of plastids and mitochondria. "Horizontal gene transfer and how it has impacted the evolution of life is presented through a web connecting bifurcating branches that complicate, yet do not erase, the tree of life".[51]
For branching of bacteria phyla, see Bacterial phyla.

In 1990, a novel concept of the tree of life was presented, dividing the living world into three stems, classified as the domains Bacteria, Archaea, Eukarya.[1][52][53][2] It is the first tree founded exclusively on molecular phylogenetics, and which includes the evolution of microorganisms. It has been called a "universal phylogenetic tree in rooted form".[1] This tree and its rooting became the subject of debate.[52][b]

In the meantime, numerous modifications of this tree, mainly concerning the role and importance of horizontal gene transfer for its rooting and early ramifications have been suggested (e.g.[55][51]). Since heredity occurs both vertically and horizontally, the tree of life may have been more weblike or netlike in its early phase and more treelike when it grew three-stemmed.[51] Presumably horizontal gene transfer has decreased with growing cell stability.[3]

A modified version of the tree, based on several molecular studies, has its root between a monophyletic domain Bacteria and a clade formed by Archaea and Eukaryota.[55] A small minority of studies place the root in the domain bacteria, in the phylum Bacillota,[56] or state that the phylum Chloroflexota (formerly Chloroflexi) is basal to a clade with Archaea and Eukaryotes and the rest of bacteria (as proposed by Thomas Cavalier-Smith).[57] Metagenomic analyses recover a two-domain system with the domains Archaea and Bacteria; in this view of the tree of life, Eukaryotes are derived from Archaea.[58][59][60] With the later gene pool of LUCA's descendants, sharing a common framework of the AT/GC rule and the standard twenty amino acids, horizontal gene transfer would have become feasible and could have been common.[61]

The nature of LUCA remains disputed. In 1994, on the basis of primordial metabolism (sensu Wächtershäuser), Otto Kandler proposed a successive divergence of the three domains of life[1] from a multiphenotypical population of pre-cells, reached by gradual evolutionary improvements (cellularization).[62][63][64] These phenotypically diverse pre-cells were metabolising, self-reproducing entities exhibiting frequent mutual exchange of genetic information. Thus, in this scenario there was no "first cell". It may explain the unity and, at the same time the partition into three lines (the three domains) of life. Kandler's pre-cell theory is supported by Wächtershäuser.[65][66] In 1998, Carl Woese, based on the RNA world concept, proposed that no individual organism could be considered a LUCA, and that the genetic heritage of all modern organisms derived through horizontal gene transfer among an ancient community of organisms.[67] Other authors concur that there was a "complex collective genome"[68] at the time of the LUCA, and that horizontal gene transfer was important in the evolution of later groups;[68] Nicolas Glansdorff states that LUCA "was in a metabolically and morphologically heterogeneous community, constantly shuffling around genetic material" and "remained an evolutionary entity, though loosely defined and constantly changing, as long as this promiscuity lasted."[69]

The theory of a universal common ancestry of life is widely accepted. In 2010, based on "the vast array of molecular sequences now available from all domains of life,"[70] D. L. Theobald published a "formal test" of universal common ancestry (UCA). This deals with the common descent of all extant terrestrial organisms, each being a genealogical descendant of a single species from the distant past. His formal test favoured the existence of a universal common ancestry over a wide class of alternative hypotheses that included horizontal gene transfer. Basic biochemical principles imply that all organisms do have a common ancestry.[71]

A proposed, earlier, non-cellular ancestor to LUCA is the First universal common ancestor (FUCA).[72][73] FUCA would therefore be the ancestor to every modern cell as well as ancient, now-extinct cellular lineages not descendant of LUCA. FUCA is assumed to have had other descendants than LUCA, none of which have modern descendants. Some genes of these ancient now-extinct cell lineages are thought to have been horizontally transferred into the genome of early descendants of LUCA.[61]

LUCA and viruses edit

The origin of viruses remains disputed. Since viruses need host cells for their replication, it is likely that they emerged after the formation of cells. Viruses may even have multiple origins and different types of viruses may have evolved independently over the history of life.[2] There are different hypotheses for the origins of viruses, for instance an early viral origin from the RNA world or a later viral origin from selfish DNA.[2]

Based on how viruses are currently distributed across the bacteria and archaea, the LUCA is suspected of having been prey to multiple viruses, ancestral to those that now have those two domains as their hosts.[74] Furthermore, extensive virus evolution seems to have preceded the LUCA, since the jelly-roll structure of capsid proteins is shared by RNA and DNA viruses across all three domains of life.[75][76] LUCA's viruses were probably mainly dsDNA viruses in the groups called Duplodnaviria and Varidnaviria. Two other single-stranded DNA virus groups within the Monodnaviria, the Microviridae and the Tubulavirales, likely infected the last bacterial common ancestor. The last archaeal common ancestor was probably host to spindle-shaped viruses. All of these could well have affected the LUCA, in which case each must since have been lost in the host domain where it is no longer extant. By contrast, RNA viruses do not appear to have been important parasites of LUCA, even though straightforward thinking might have envisaged viruses as beginning with RNA viruses directly derived from an RNA world. Instead, by the time the LUCA lived, RNA viruses had probably already been out-competed by DNA viruses.[74]

LUCA might have been the ancestor to some viruses, as it might have had at least two descendants : LUCELLA, the Last Universal Cellular Ancestor, the ancestor to all cells, and the archaic virocell ancestor, the ancestor to large-to-medium-sized DNA viruses.[77] Viruses might have evolved before LUCA but after the First universal common ancestor (FUCA), according to the reduction hypothesis, where giant viruses evolved from primordial cells that became parasitic.[61]

See also edit

Notes edit

  1. ^ Other studies propose that LUCA may have been defined wholly through RNA,[18] consisted of a RNA-DNA hybrid genome, or possessed a retrovirus-like genetic cycle with DNA serving as a stable genetic repository.[19]
  2. ^ One debate dealt with a former cladistic hypothesis: The tree could not be ascribed a root in the usual algorithmic way, because that would require an outgroup for reference. In the case of the universal tree, no outgroup would exist. The cladistic method was used "to root the purple bacteria, for example. But establishing a root for the universal tree of life, the branching order among the primary urkingdoms, was another matter entirely."[54]

References edit

  1. ^ a b c d e Woese, C.R.; Kandler, O.; Wheelis, M.L. (June 1990). "Towards a natural system of organisms: proposal for the domains Archaea, Bacteria, and Eucarya". PNAS. 87 (12): 4576–4579. Bibcode:1990PNAS...87.4576W. doi:10.1073/pnas.87.12.4576. PMC 54159. PMID 2112744.
  2. ^ a b c d Madigan, Michael T.; Aiyer, Jennifer; Buckley, Daniel H.; Sattley, Matthew; Stahl, David A. (2022). Brock Biology of Microorganisms (16 ed.). Harlow: Pearson Education. pp. Unit 3, chapter 13: 431 (LUCA), 435 (tree of life), 428, 438, 439 (viruses). ISBN 978-1-292-40479-0.
  3. ^ a b Harold, Franklin M. (2014). In Search of Cell History: The Evolution of Life's Building Blocks. Chicago, London: University of Chicago Press. ISBN 978-0-226-17428-0.
  4. ^ Gregory, T. Ryan (2008). "Understanding evolutionary trees". Evolution: Education and Outreach. 1 (2): 121–137. doi:10.1007/s12052-008-0035-x. S2CID 15488906.
  5. ^ Lamarck, Jean Baptiste Pierre Antoine de Monet de (1994) [1809]. Philosophie zoologique (PDF). Paris. p. 737.{{cite book}}: CS1 maint: location missing publisher (link)
  6. ^ Noble, Denis (1 July 2020). "Editorial: Charles Darwin, Jean-Baptiste Lamarck, and 21st century arguments on the fundamentals of biology". Progress in Biophysics and Molecular Biology. 153: 1–4. doi:10.1016/j.pbiomolbio.2020.02.005. PMID 32092299. S2CID 211475380. Retrieved 23 December 2022.
  7. ^ a b Darwin, Charles (1859). The Origin of Species by Means of Natural Selection. John Murray. pp. 484, 490.
  8. ^ Wikham, Gene Stephen (March 1995). The molecular phylogenetic analysis of naturally occurring hyperthermophilic microbial communities (PhD thesis). Indiana University. p. 4. ProQuest 304192982
  9. ^ Forterre, Patrick (1997). "Archaea: What can we learn from their sequences?". Current Opinion in Genetics & Development. 7 (6): 764–770. doi:10.1016/s0959-437x(97)80038-x. PMID 9468785.
  10. ^ Koonin, Eugene V.; Galperin, Michael Y. (2003). Sequence - Evolution - Function: Computational approaches in comparative genomics. Boston, MA: Kluwer. p. 252. ISBN 978-1-4757-3783-7. OCLC 55642057.
  11. ^ a b c Weiss, Madeline C.; Preiner, Martina; Xavier, Joana C.; Zimorski, Verena; Martin, William F. (16 August 2018). "The last universal common ancestor between ancient Earth chemistry and the onset of genetics". PLOS Genetics. 14 (8): e1007518. doi:10.1371/journal.pgen.1007518. PMC 6095482. PMID 30114187. S2CID 52019935.
  12. ^ a b c Weiss, Madeline C.; Sousa, F. L.; Mrnjavac, N.; et al. (2016). "The physiology and habitat of the last universal common ancestor" (PDF). Nature Microbiology. 1 (9): 16116. doi:10.1038/nmicrobiol.2016.116. PMID 27562259. S2CID 2997255.
  13. ^ Harrison, Stuart A.; Palmeira, Raquel Nunes; Halpern, Aaron; Lane, Nick (1 November 2022). "A biophysical basis for the emergence of the genetic code in protocells". Biochimica et Biophysica Acta (BBA) - Bioenergetics. 1863 (8): 148597. doi:10.1016/j.bbabio.2022.148597. ISSN 0005-2728. PMID 35868450.
  14. ^ Harrison, Stuart A.; Lane, Nick (12 December 2018). "Life as a guide to prebiotic nucleotide synthesis". Nature Communications. 9 (1): 5176. Bibcode:2018NatCo...9.5176H. doi:10.1038/s41467-018-07220-y. ISSN 2041-1723. PMC 6289992. PMID 30538225.
  15. ^ a b c Cantine, Marjorie D.; Fournier, Gregory P. (6 July 2017). "Environmental Adaptation from the Origin of Life to the Last Universal Common Ancestor". Origins of Life and Evolution of Biospheres. 48 (1): 35–54. doi:10.1007/s11084-017-9542-5. hdl:1721.1/114219. ISSN 0169-6149.
  16. ^ Wächtershäuser, Günter (1998). "Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment". Systematic and Applied Microbiology. 21 (4): 473–474, IN1, 475–477. doi:10.1016/S0723-2020(98)80058-1.
  17. ^ a b c Wächtershäuser, Günter (1998). "Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment". Systematic and Applied Microbiology. 21 (4): 473–474, IN1, 475–477. doi:10.1016/S0723-2020(98)80058-1.
  18. ^ Marshall, Michael. "Life began with a planetary mega-organism". New Scientist. from the original on 25 July 2016. Retrieved 31 July 2016.
  19. ^ Koonin, Eugene V.; Martin, William (1 December 2005). "On the origin of genomes and cells within inorganic compartments". Trends in Genetics. 21 (12): 647–654. doi:10.1016/j.tig.2005.09.006. PMC 7172762. PMID 16223546.
  20. ^ Garwood, Russell J. (2012). "Patterns In Palaeontology: The first 3 billion years of evolution". Palaeontology Online. 2 (11): 1–14. from the original on 26 June 2015. Retrieved 25 June 2015.
  21. ^ Koonin, Eugene V.; Krupovic, M.; Ishino, S.; Ishino, Y. (2020). "The replication machinery of LUCA: common origin of DNA replication and transcription". BMC Biology. 18 (1): 61. doi:10.1186/s12915-020-00800-9. PMC 7281927. PMID 32517760.
  22. ^ Ahmad, Muzammil; Xu, Dongyi; Wang, Weidong (23 May 2017). "Type IA topoisomerases can be "magicians" for both DNA and RNA in all domains of life". RNA Biology. 14 (7): 854–864. doi:10.1080/15476286.2017.1330741. PMC 5546716. PMID 28534707.
  23. ^ Lupas, Andrei N.; Alva, Vikram (2018). "Histones predate the split between bacteria and archaea". Bioinformatics. 35 (14): 2349–2353. doi:10.1093/bioinformatics/bty1000. PMID 30520969.
  24. ^ Bernstein, H., Bernstein, C. (2017). Sexual Communication in Archaea, the Precursor to Eukaryotic Meiosis. In: Witzany, G. (eds) Biocommunication of Archaea. Springer, Cham. https://doi.org/10.1007/978-3-319-65536-9_7
  25. ^ Gogarten, Johann Peter; Taiz, Lincoln (1992). "Evolution of proton pumping ATPases: Rooting the tree of life". Photosynthesis Research. 33 (2): 137–146. doi:10.1007/bf00039176. ISSN 0166-8595.
  26. ^ Wächtershäuser, Günter (1998). "Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment". Systematic and Applied Microbiology. 21 (4): 473–474, IN1, 475–477. doi:10.1016/S0723-2020(98)80058-1.
  27. ^ Martin, W.; Russell, M. J. (October 2007). "On the origin of biochemistry at an alkaline hydrothermal vent". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 362 (1486): 1887–1925. doi:10.1098/rstb.2006.1881. PMC 2442388. PMID 17255002.
  28. ^ Lane, Nick; Allen, J. F.; Martin, William (April 2010). "How did LUCA make a living? Chemiosmosis in the origin of life". BioEssays. 32 (4): 271–280. doi:10.1002/bies.200900131. PMID 20108228.
  29. ^ Weiss, Madeline C.; Preiner, Martina; Xavier, Joana C.; Zimorski, Verena; Martin, William F. (16 August 2018). "The last universal common ancestor between ancient Earth chemistry and the onset of genetics". PLOS Genetics. 14 (8): e1007518. doi:10.1371/journal.pgen.1007518. PMC 6095482. PMID 30114187. S2CID 52019935.
  30. ^ Muchowska, Kamila B.; Varma, Sreejith J.; Chevallot-Beroux, Elodie; Lethuillier-Karl, Lucas; Li, Guang; Moran, Joseph (2 October 2017). "Metals promote sequences of the reverse Krebs cycle". Nature Ecology & Evolution. 1 (11): 1716–1721. doi:10.1038/s41559-017-0311-7. ISSN 2397-334X. PMC 5659384. PMID 28970480.
  31. ^ Sojo, Víctor; Pomiankowski, Andrew; Lane, Nick (12 August 2014). "A Bioenergetic Basis for Membrane Divergence in Archaea and Bacteria". PLOS Biology. 12 (8): e1001926. doi:10.1371/journal.pbio.1001926. ISSN 1545-7885. PMC 4130499. PMID 25116890.
  32. ^ Weiss, Madeline C.; Preiner, Martina; Xavier, Joana C.; Zimorski, Verena; Martin, William F. (16 August 2018). "The last universal common ancestor between ancient Earth chemistry and the onset of genetics". PLOS Genetics. 14 (8): e1007518. doi:10.1371/journal.pgen.1007518. PMC 6095482. PMID 30114187. S2CID 52019935.
  33. ^ Jordan, S. F.; Nee, E.; Lane, Nick (18 October 2019). "Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide". Interface Focus. 9 (6). doi:10.1098/rsfs.2019.0067. ISSN 2042-8901. PMC 6802135. PMID 31641436.  This article incorporates text from this source, which is available under the CC BY 4.0 license.
  34. ^ Mulkidjanian, Armen Y.; Bychkov, Andrew Yu; Dibrova, Daria V.; Galperin, Michael Y.; Koonin, Eugene V. (2012). "Origin of first cells at terrestrial, anoxic geothermal fields". Proceedings of the National Academy of Sciences. 109 (14): E821-30. Bibcode:2012PNAS..109E.821M. doi:10.1073/pnas.1117774109. PMC 3325685. PMID 22331915.
  35. ^ Adam, Panagiotis S.; Borrel, Guillaume; Gribaldo, Simonetta (6 February 2018). "Evolutionary history of carbon monoxide dehydrogenase/acetyl-CoA synthase, one of the oldest enzymatic complexes". PNAS. 115 (6): E1166–E1173. Bibcode:2018PNAS..115E1166A. doi:10.1073/pnas.1716667115. PMC 5819426. PMID 29358391.
  36. ^ Weiss, Madeline C.; Preiner, Martina; Xavier, Joana C.; Zimorski, Verena; Martin, William F. (16 August 2018). "The last universal common ancestor between ancient Earth chemistry and the onset of genetics". PLOS Genetics. 14 (8): e1007518. doi:10.1371/journal.pgen.1007518. PMC 6095482. PMID 30114187. S2CID 52019935.
  37. ^ Galtier, Nicolas; Tourasse, Nicolas; Gouy, Manolo (8 January 1999). "A Nonhyperthermophilic Common Ancestor to Extant Life Forms". Science. 283 (5399): 220–221. doi:10.1126/science.283.5399.220. ISSN 0036-8075.
  38. ^ Groussin, Mathieu; Boussau, Bastien; Charles, Sandrine; Blanquart, Samuel; Gouy, Manolo (23 October 2013). "The molecular signal for the adaptation to cold temperature during early life on Earth". Biology Letters. 9 (5): 20130608. doi:10.1098/rsbl.2013.0608. ISSN 1744-9561.
  39. ^ Gogarten, Johann Peter; Deamer, David (2016). "Is LUCA a thermophilic progenote?". Nature Microbiology. 1 (12): 16229. doi:10.1038/nmicrobiol.2016.229. PMID 27886195. S2CID 205428194.
  40. ^ Woese, Carl (June 1998). "The universal ancestor". PNAS. 95 (12): 6854–6859. Bibcode:1998PNAS...95.6854W. doi:10.1073/pnas.95.12.6854. PMC 22660. PMID 9618502.
  41. ^ Camprubí, E.; de Leeuw, J. W.; House, C. H.; Raulin, F.; Russell, M. J.; Spang, A.; Tirumalai, M. R.; Westall, F. (12 December 2019). "The Emergence of Life". Space Science Reviews. 215 (8): 56. Bibcode:2019SSRv..215...56C. doi:10.1007/s11214-019-0624-8. ISSN 1572-9672.
  42. ^ Zeldovich, Konstantin B; Berezovsky, Igor N; Shakhnovich, Eugene I (2007). "Protein and DNA Sequence Determinants of Thermophilic Adaptation". PLOS Computational Biology. 3 (1): e5. doi:10.1371/journal.pcbi.0030005. ISSN 1553-7358.
  43. ^ Boussau, Bastien; Blanquart, Samuel; Necsulea, Anamaria; Lartillot, Nicolas; Gouy, Manolo (26 November 2008). "Parallel adaptations to high temperatures in the Archaean eon". Nature. 456 (7224): 942–945. doi:10.1038/nature07393. ISSN 0028-0836.
  44. ^ Doolittle, W. F. (February 2000). "Uprooting the tree of life". Scientific American. 282 (2): 90–95. Bibcode:2000SciAm.282b..90D. doi:10.1038/scientificamerican0200-90. JSTOR 26058605. PMID 10710791.
  45. ^ Noffke, N.; Christian, D.; Wacey, D.; Hazen, R. M. (December 2013). "Microbially induced sedimentary structures recording an ancient ecosystem in the ca. 3.48 billion-year-old Dresser Formation, Pilbara, Western Australia". Astrobiology. 13 (12): 1103–1124. Bibcode:2013AsBio..13.1103N. doi:10.1089/ast.2013.1030. PMC 3870916. PMID 24205812.
  46. ^ Ohtomo, Yoko; Kakegawa, Takeshi; Ishida, Akizumi; Nagase, Toshiro; Rosing, Minik T. (2013). "Evidence for biogenic graphite in early Archaean Isua metasedimentary rocks". Nature Geoscience. 7 (1): 25–28. Bibcode:2014NatGe...7...25O. doi:10.1038/ngeo2025.
  47. ^ Hassenkam, T.; Andersson, M. P.; Dalby, K. N.; et al. (2017). "Elements of Eoarchean life trapped in mineral inclusions". Nature. 548 (7665): 78–81. Bibcode:2017Natur.548...78H. doi:10.1038/nature23261. PMID 28738409. S2CID 205257931.
  48. ^ Bell, Elizabeth A.; Boehnke, Patrick; Harrison, T. Mark; Mao, Wendy L. (24 November 2015). "Potentially biogenic carbon preserved in a 4.1 billion-year-old zircon". PNAS. 112 (47): 14518–14521. Bibcode:2015PNAS..11214518B. doi:10.1073/pnas.1517557112. PMC 4664351. PMID 26483481.
  49. ^ Dodd, Matthew S.; Papineau, Dominic; Grenne, Tor; et al. (2 March 2017). "Evidence for early life in Earth's oldest hydrothermal vent precipitates" (PDF). Nature. 543 (7643): 60–64. Bibcode:2017Natur.543...60D. doi:10.1038/nature21377. PMID 28252057. S2CID 2420384. (PDF) from the original on 23 July 2018. Retrieved 25 June 2019.
  50. ^ Betts, Holly C.; Puttick, Mark N.; Clark, James W.; Williams, Tom A.; Donoghue, Philip C. J.; Pisani, Davide (2018). "Integrated genomic and fossil evidence illuminates life's early evolution and eukaryote origin". Nature Ecology & Evolution. 2 (10): 1556–1562. doi:10.1038/s41559-018-0644-x. PMC 6152910. PMID 30127539.
  51. ^ a b c Smets, Barth F.; Barkay, Tamar (September 2005). "Horizontal gene transfer: perspectives at a crossroads of scientific disciplines". Nature Reviews Microbiology. 3 (9): 675–678. doi:10.1038/nrmicro1253. PMID 16145755. S2CID 2265315.
  52. ^ a b Sapp, Jan A. (2009). The new foundations of evolution: on the tree of life. New York: Oxford University Press. pp. Chapter 19: 257ff (novel concept of the tree of life), Chapters 17-21 plus concluding remarks: 226-318 (discussion of the tree and its rooting), 286ff (LUCA). ISBN 978-0-199-73438-2.
  53. ^ Madigan, Michael T.; Martinko, John M.; Bender, Kelly S.; Buckley, Daniel H.; Stahl, David A. (2015). Brock Biology of Microorganisms (14 ed.). Boston: Pearson Education Limited. pp. 29, 374, 381. ISBN 978-1-292-01831-7.
  54. ^ Sapp 2009, p. 255.
  55. ^ a b Brown, J. R.; Doolittle, W. F. (1995). "Root of the Universal Tree of Life Based on Ancient Aminoacyl-tRNA Synthetase Gene Duplications". PNAS. 92 (7): 2441–2445. Bibcode:1995PNAS...92.2441B. doi:10.1073/pnas.92.7.2441. PMC 42233. PMID 7708661.
  56. ^ Valas, R. E.; Bourne, P. E. (2011). "The origin of a derived superkingdom: how a gram-positive bacterium crossed the desert to become an archaeon". Biology Direct. 6: 16. doi:10.1186/1745-6150-6-16. PMC 3056875. PMID 21356104.
  57. ^ Cavalier-Smith, Tom (2006). "Rooting the tree of life by transition analyses". Biology Direct. 1: 19. doi:10.1186/1745-6150-1-19. PMC 1586193. PMID 16834776.
  58. ^ Raymann, Kasie; Brochier-Armanet, Céline; Gribaldo, Simonetta (26 May 2015). "The two-domain tree of life is linked to a new root for the Archaea". Proceedings of the National Academy of Sciences. 112 (21): 6670–6675. Bibcode:2015PNAS..112.6670R. doi:10.1073/pnas.1420858112. ISSN 0027-8424. PMC 4450401. PMID 25964353.
  59. ^ Hug, Laura A.; Baker, Brett J.; Anantharaman, Karthik; et al. (11 April 2016). "A new view of the tree of life". Nature Microbiology. 1 (5): 16048. doi:10.1038/nmicrobiol.2016.48. ISSN 2058-5276. PMID 27572647. S2CID 3833474.
  60. ^ Williams, Tom A.; Foster, Peter G.; Cox, Cymon J.; Embley, T. Martin (11 December 2013). "An archaeal origin of eukaryotes supports only two primary domains of life". Nature. 504 (7479): 231–236. Bibcode:2013Natur.504..231W. doi:10.1038/nature12779. ISSN 1476-4687. PMID 24336283. S2CID 4461775.
  61. ^ a b c Harris, Hugh M. B.; Hill, Colin (2021). "A Place for Viruses on the Tree of Life". Frontiers in Microbiology. 11. doi:10.3389/fmicb.2020.604048. ISSN 1664-302X. PMC 7840587. PMID 33519747.
  62. ^ Kandler, Otto (1994). "The early diversification of life". In Stefan Bengtson (ed.). Early Life on Earth. Nobel Symposium 84. New York: Columbia University Press. pp. 152–160.
  63. ^ Kandler, Otto (1995). "Cell Wall Biochemistry in Archaea and its Phylogenetic Implications". Journal of Biological Physics. 20 (1–4): 165–169. doi:10.1007/BF00700433. S2CID 83906865.
  64. ^ Kandler, Otto (1998). "The early diversification of life and the origin of the three domains: A proposal". In Jürgen Wiegel; Michael W. W. Adams (eds.). Thermophiles: The keys to molecular evolution and the origin of life?. London: Taylor and Francis Ltd. pp. 19–31. ISBN 978-0-203-48420-3.
  65. ^ Wächtershäuser, Günter (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.
  66. ^ Wächtershäuser, Günter (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): 1787–1808. doi:10.1098/rstb.2006.1904. PMC 1664677. PMID 17008219.
  67. ^ Woese, Carl (June 1998). "The universal ancestor". PNAS. 95 (12): 6854–6859. Bibcode:1998PNAS...95.6854W. doi:10.1073/pnas.95.12.6854. PMC 22660. PMID 9618502.
  68. ^ a b Egel, Richard (March 2012). "Primal Eukaryogenesis: On the Communal Nature of Precellular States, Ancestral to Modern Life". Life. 2 (1): 170–212. Bibcode:2012Life....2..170E. doi:10.3390/life2010170. PMC 4187143. PMID 25382122.
  69. ^ Glansdorff, Nicolas; Xu, Ying; Labedan, Bernard (9 July 2008). "The Last Universal Common Ancestor: emergence, constitution and genetic legacy of an elusive forerunner". Biology Direct. 3 (1): 29. doi:10.1186/1745-6150-3-29. PMC 2478661. PMID 18613974. S2CID 18250196.
  70. ^ Steel, M.; Penny, D. (May 2010). "Origins of life: Common ancestry put to the test". Nature. 465 (7295): 168–169. Bibcode:2010Natur.465..168S. doi:10.1038/465168a. PMID 20463725. S2CID 205055573.
  71. ^ Theobald, D. L. (May 2010). "A formal test of the theory of universal common ancestry". Nature. 465 (7295): 219–222. Bibcode:2010Natur.465..219T. doi:10.1038/nature09014. PMID 20463738. S2CID 4422345.
  72. ^ Prosdocimi, Francisco; José, Marco V.; de Farias, Sávio Torres (2019). "The First Universal Common Ancestor (FUCA) as the Earliest Ancestor of LUCA's (Last UCA) Lineage". In Pontarotti, Pierre (ed.). Evolution, Origin of Life, Concepts and Methods. Cham: Springer. pp. 43–54. doi:10.1007/978-3-030-30363-1_3. ISBN 978-3-030-30363-1. S2CID 199534387. Retrieved 2 November 2023.
  73. ^ Prosdocimi, Francisco; José, Marco V.; de Farias, Sávio Torres (2019), "The First Universal Common Ancestor (FUCA) as the Earliest Ancestor of LUCA's (Last UCA) Lineage", in Pontarotti, Pierre (ed.), Evolution, Origin of Life, Concepts and Methods, Cham: Springer, pp. 43–54, doi:10.1007/978-3-030-30363-1_3, ISBN 978-3-030-30363-1, S2CID 199534387, retrieved 2 November 2023
  74. ^ a b Krupovic, M.; Dolja, V. V.; Koonin, Eugene V. (2020). "The LUCA and its complex virome" (PDF). Nature Reviews Microbiology. 18 (11): 661–670. doi:10.1038/s41579-020-0408-x. PMID 32665595. S2CID 220516514.
  75. ^ Forterre, Patrick; Prangishvili, David (2009). "The origin of viruses". Research in Microbiology. 160 (7): 466–472. doi:10.1016/j.resmic.2009.07.008. PMID 19647075. S2CID 2767388.
  76. ^ Durzyńska, Julia; Goździcka-Józefiak, Anna (16 October 2015). "Viruses and cells intertwined since the dawn of evolution". Virology Journal. 12 (1): 169. doi:10.1186/s12985-015-0400-7. PMC 4609113. PMID 26475454.
  77. ^ Nasir, Arshan; Kim, Kyung Mo; Caetano-Anollés, Gustavo (1 September 2012). "Viral evolution". Mobile Genetic Elements. 2 (5): 247–252. doi:10.4161/mge.22797. ISSN 2159-2543. PMC 3575434. PMID 23550145.

Further reading edit

December 15, 2023
last, universal, common, ancestor, luca, redirects, here, other, uses, luca, last, universal, common, ancestor, luca, hypothesized, have, been, common, ancestral, cell, from, which, three, domains, life, bacteria, archaea, eukarya, originated, suggested, have,. LUCA redirects here For other uses see Luca The last universal common ancestor LUCA is hypothesized to have been a common ancestral cell from which the three domains of life the Bacteria the Archaea and the Eukarya originated It is suggested to have been a cellular organism that had a lipid bilayer and used DNA RNA and protein 2 The LUCA has also been defined as a hypothetical organism ancestral to all three domains 3 The LUCA is the point or stage at which the three domains of life diverged from precursing forms of life about 3 5 3 8 billion years ago The nature of this point or stage of divergence remains a topic of research Phylogenetic tree linking all major groups of living organisms namely the Bacteria Archaea and Eukarya as proposed by Woese et al 1990 1 with the last universal common ancestor LUCA shown at the rootAll earlier forms of life precursing this divergence and of course all extant terrestrial organisms are generally thought to share common ancestry On the basis of a formal statistical test this theory of a universal common ancestry UCA is supported versus competing multiple ancestry hypotheses The first universal common ancestor FUCA is a hypothetical non cellular ancestor to LUCA and other now extinct sister lineages The genesis of viruses before or after the LUCA as well as the diversity of extant viruses and their hosts are subjects of investigation While no fossil evidence of the LUCA exists the detailed biochemical similarity of all current life divided into the three domains makes it plausible Its characteristics can be inferred from shared features of modern genomes These genes describe a complex life form with many co adapted features including transcription and translation mechanisms to convert information from DNA to mRNA to proteins The earlier forms of life probably lived in the high temperature water of deep sea vents near ocean floor magma flows around 4 billion years ago Contents 1 Historical background 2 Inferring LUCA s features 2 1 An anaerobic thermophile 2 2 Alternative interpretations 2 2 1 Evidence that LUCA was mesophilic 3 Age 4 Root of the tree of life 5 LUCA and viruses 6 See also 7 Notes 8 References 9 Further readingHistorical background editFurther information Tree of life biology nbsp A tree of life like this one from Charles Darwin s notebooks c July 1837 implies a single common ancestor at its root labelled 1 A phylogenetic tree directly portrays the idea of evolution by descent from a single ancestor 4 An early tree of life was sketched by Jean Baptiste Lamarck in his Philosophie zoologique in 1809 5 6 Charles Darwin more famously proposed the theory of universal common descent through an evolutionary process in his book On the Origin of Species in 1859 Therefore I should infer from analogy that probably all the organic beings which have ever lived on this earth have descended from some one primordial form into which life was first breathed 7 The last sentence of the book begins with a restatement of the hypothesis There is grandeur in this view of life with its several powers having been originally breathed into a few forms or into one 7 The term last universal common ancestor or LUCA was first used in the 1990s for such a primordial organism 8 9 10 Inferring LUCA s features editAn anaerobic thermophile edit Further information Phylogenetic bracketing nbsp A direct way to infer LUCA s genome would be to find genes common to all surviving descendants Unfortunately there are only about 30 such genes mostly for ribosome proteins proving that LUCA had the genetic code Many other LUCA genes have been lost in later lineages over 4 billion years of evolution 11 nbsp Three ways to infer genes present in LUCA universal presence presence in both the Bacterial and Archaean domains and presence in two phyla in both domains The first yields as stated only about 30 genes the second some 11 000 with lateral gene transfer LGT very likely the third 355 genes probably in LUCA since they were found in at least two phyla in both domains making LGT an unlikely explanation 11 In 2016 Madeline C Weiss and colleagues genetically analyzed 6 1 million protein coding genes and 286 514 protein clusters from sequenced prokaryotic genomes representing many phylogenetic trees and identified 355 protein clusters that were probably common to the LUCA The results of their analysis are highly specific though debated They depict LUCA as anaerobic CO2 fixing H2 dependent with a Wood Ljungdahl pathway the reductive acetyl coenzyme A pathway N2 fixing and thermophilic LUCA s biochemistry was replete with FeS clusters and radical reaction mechanisms 12 The cofactors also reveal dependence upon transition metals flavins S adenosyl methionine coenzyme A ferredoxin molybdopterin corrins and selenium Its genetic code required nucleoside modifications and S adenosylmethionine dependent methylations 12 They show that methanogenic clostridia was basal near the root of the phylogenetic tree in the 355 protein lineages examined and that the LUCA may therefore have inhabited an anaerobic hydrothermal vent setting in a geochemically active environment rich in H2 CO2 and iron where ocean water interacted with hot magma beneath the ocean floor 12 It s even inferred that LUCA also grew from H2 and CO2 via the reverse incomplete Krebs cycle 13 Other metabolic pathways inferred in LUCA are the pentose phosphate pathway glycolysis and gluconeogenesis 14 Even if phylogenetic evidence may point to a hydrothermal vent environment for a thermophilic LUCA this does not constitute evidence that the origin of life took place at a hydrothermal vent since mass extinctions may have removed previously existing branches of life 15 While the gross anatomy of the LUCA can only be reconstructed with much uncertainty its biochemical mechanisms can be described in some detail based on the universal properties currently shared by all independently living organisms on Earth 16 nbsp LUCA systems and environment including the Wood Ljungdahl or reductive acetyl CoA pathway to fix carbon and most likely DNA complete with the genetic code and enzymes to replicate it transcribe it to RNA and translate it to proteins The LUCA certainly had genes and a genetic code 11 Its genetic material was most likely DNA 17 so that it lived after the RNA world a 20 The DNA was kept double stranded by an enzyme DNA polymerase which recognises the structure and directionality of DNA 21 The integrity of the DNA was maintained by a group of repair enzymes including DNA topoisomerase 22 If the genetic code was based on dual stranded DNA it was expressed by copying the information to single stranded RNA The RNA was produced by a DNA dependent RNA polymerase using nucleotides similar to those of DNA 17 It had multiple DNA binding proteins such as histone fold proteins 23 The genetic code was expressed into proteins These were assembled from 20 free amino acids by translation of a messenger RNA via a mechanism of ribosomes transfer RNAs and a group of related proteins 17 LUCA was likely capable of sexual interaction in the sense that adaptive gene functions were present that promoted the transfer of DNA between individuals of the population to facilitate genetic recombination Homologous gene products that promote genetic recombination are present in bacteria archaea and eukaryota such as the RecA protein in bacteria the RadA protein in archaea and the Rad51 and Dmc1 proteins in eukaryota 24 The functionality of LUCA as well as evidence for the early evolution membrane dependent biological systems together suggest that LUCA had cellularity and cell membranes 25 As for the cell s gross structure it contained a water based cytoplasm effectively enclosed by a lipid bilayer membrane it was capable of reproducing by cell division 26 It tended to exclude sodium and concentrate potassium by means of specific ion transporters or ion pumps The cell multiplied by duplicating all its contents followed by cellular division The cell used chemiosmosis to produce energy It also reduced CO2 and oxidized H2 methanogenesis or acetogenesis via acetyl thioesters 27 28 By phylogenetic bracketing analysis of the presumed LUCA s offspring groups LUCA appears to have been a small single celled organism It likely had a ring shaped coil of DNA floating freely within the cell Morphologically it would likely not have stood out within a mixed population of small modern day bacteria The originator of the three domain system Carl Woese stated that in its genetic machinery the LUCA would have been a simpler more rudimentary entity than the individual ancestors that spawned the three domains and their descendants 1 nbsp The LUCA used the Wood Ljungdahl or reductive acetyl CoA pathway to fix carbon if it was an autotroph or to respire anaerobically if it was a heterotroph An alternative to the search for universal traits is to use genome analysis to identify phylogenetically ancient genes This gives a picture of a LUCA that could live in a geochemically harsh environment and is like modern prokaryotes Analysis of biochemical pathways implies the same sort of chemistry as does phylogenetic analysis Weiss and colleagues write that Experiments demonstrate that acetyl CoA pathway chemicals used in anaerobic respiration formate methanol acetyl moieties and even pyruvate arise spontaneously from CO2 native metals and water a combination present in hydrothermal vents 29 An experiment shows that Zn2 Cr3 and Fe can promote 6 of the 11 reactions of an ancient anabolic pathway called the reverse Krebs cycle in acidic conditions which implies that LUCA might have inhabited either hydrothermal vents or acidic metal rich hydrothermal fields 30 Because both bacteria and archaea have differences in the structure of phospholipids and cell wall ion pumping most proteins involved in DNA replication and glycolysis it is inferred that LUCA had a permeable membrane without an ion pump The emergence of Na H antiporters likely lead to the evolution of impermeable membranes present in eukaryotes archaea and bacteria It s stated that The late and independent evolution of glycolysis but not gluconeogenesis is entirely consistent with LUCA being powered by natural proton gradients across leaky membranes Several discordant traits are likely to be linked to the late evolution of cell membranes notably the cell wall whose synthesis depends on the membrane and DNA replication 31 Although LUCA likely had DNA it is unknown if it could replicate DNA and is suggested to might just have been a chemically stable repository for RNA based replication 32 It is likely that the permeable membrane of LUCA was composed of archaeal lipids isoprenoids and bacterial lipids fatty acids Isoprenoids would have enhanced stabilization of LUCA s membrane in the surrounding extreme habitat Nick Lane and coauthors state that The advantages and disadvantages of incorporating isoprenoids into cell membranes in different microenvironments may have driven membrane divergence with the later biosynthesis of phospholipids giving rise to the unique G1P and G3P headgroups of archaea and bacteria respectively If so the properties conferred by membrane isoprenoids place the lipid divide as early as the origin of life 33 UV light between 200 280 nm at the time unprotected by the ozone layer would have been damaging to nucleotides at the surface as it can cause mutations or transcription errors and ultimately damaging consequences for organisms at the cellular level However it is likely that LUCA existed in a UV environment because of the prevalence of photolyase across the tree of life Photolyase uses UV to drive photoreactivation a that works to repair damage from radiation caused by UV Alternative interpretations edit Some other researchers have challenged Weiss et al s 2016 conclusions Sarah Berkemer and Shawn McGlynn argue that Weiss et al undersampled the families of proteins so that the phylogenetic trees were not complete and failed to describe the evolution of proteins correctly There are two risk in attempting to attribute LUCA s environment from near universal gene distribution as in Weiss et al 2016 On the one hand it risks misattributing convergence or horizontal gene transfer events to vertical descent and on the other hand it risks misattributing potential LUCA gene families as horizontal gene transfer events A phylogenomic and geochemical analysis of a set of proteins that probably traced to the LUCA show that it had K dependent GTPases and the ionic composition and concentration of its intracellular fluid was seemingly high K Na ratio NH 4 Fe2 CO2 Ni2 Mg2 Mn2 Zn2 pyrophosphate and PO3 4 which would imply a terrestrial hot spring habitat It possibly had a phosphate based metabolism Further these proteins were unrelated to autotrophy the ability of an organism to create its own organic matter suggesting that the LUCA had a heterotrophic lifestyle consuming organic matter and that its growth was dependent on organic matter produced by the physical environment 34 Nick Lane argues that Na H antiporters could readily explain the low concentration of Na in the LUCA and its descendants The presence of the energy handling enzymes CODH acetyl coenzyme A synthase in LUCA could be compatible not only with being an autotroph but also with life as a mixotroph or heterotroph 35 Weiss et al 2018 reply that no enzyme defines a trophic lifestyle and that heterotrophs evolved from autotrophs 36 Evidence that LUCA was mesophilic edit Several lines of evidence now suggest that LUCA was non thermophilic The content of G C nucleotide pairs compared to the occurrence of A T pairs can indicate an organism s thermal optimum as they are more thermally stable due to an additional hydrogen bond As a result they occur more frequently in the rRNA of thermophiles however this is not seen in LUCA s reconstructed rRNA 37 38 15 The identification of thermophilic genes in the LUCA has been criticized 39 as they may instead represent genes that evolved later in archaea or bacteria then migrated between these via horizontal gene transfer as in Woese s 1998 hypothesis 40 LUCA could have been a mesophile that fixed CO2 and relied on H2 and lived close to hydrothermal vents 41 Further evidence that LUCA was mesophilic comes from the amino acid composition of its proteins The abundance of I V Y W R E and L amino acids denoted IVYWREL in an organism s proteins is correlated with its optimal growth temperature 42 According to phylogentic analysis the IVYWREL content of LUCA s proteins suggests its ideal temperature was below 50 C 15 Finally evidence that bacteria and archaea both independently underwent phases of increased and subsequently decreased thermo tolerance suggests a dramatic post LUCA climate shift that affected both populations and would explain the seeming genetic pervasiveness of thermo tolerant genetics 43 Age editFurther information Abiogenesis Studies from 2000 to 2018 have suggested an increasingly ancient time for the LUCA In 2000 estimates of the LUCA s age ranged from 3 5 to 3 8 billion years ago in the Paleoarchean 44 a few hundred million years before the earliest fossil evidence of life for which candidates range in age from 3 48 to 4 28 billion years ago 45 46 47 48 49 This placed the origin of the first forms of life shortly after the Late Heavy Bombardment which was thought to have repeatedly sterilized Earth s surface However a 2018 study by Holly Betts and colleagues applied a molecular clock model to the genomic and fossil record 102 species 29 common protein coding genes mostly ribosomal concluding that LUCA preceded the Late Heavy Bombardment They assumed that there was no sterilizing event after the Moon forming event which they dated as 4 520 billion years ago and concluded that the most likely date for LUCA was within 50 million years of that 50 Root of the tree of life edit nbsp 2005 tree of life showing horizontal gene transfers between branches including coloured lines the symbiogenesis of plastids and mitochondria Horizontal gene transfer and how it has impacted the evolution of life is presented through a web connecting bifurcating branches that complicate yet do not erase the tree of life 51 For branching of bacteria phyla see Bacterial phyla In 1990 a novel concept of the tree of life was presented dividing the living world into three stems classified as the domains Bacteria Archaea Eukarya 1 52 53 2 It is the first tree founded exclusively on molecular phylogenetics and which includes the evolution of microorganisms It has been called a universal phylogenetic tree in rooted form 1 This tree and its rooting became the subject of debate 52 b In the meantime numerous modifications of this tree mainly concerning the role and importance of horizontal gene transfer for its rooting and early ramifications have been suggested e g 55 51 Since heredity occurs both vertically and horizontally the tree of life may have been more weblike or netlike in its early phase and more treelike when it grew three stemmed 51 Presumably horizontal gene transfer has decreased with growing cell stability 3 A modified version of the tree based on several molecular studies has its root between a monophyletic domain Bacteria and a clade formed by Archaea and Eukaryota 55 A small minority of studies place the root in the domain bacteria in the phylum Bacillota 56 or state that the phylum Chloroflexota formerly Chloroflexi is basal to a clade with Archaea and Eukaryotes and the rest of bacteria as proposed by Thomas Cavalier Smith 57 Metagenomic analyses recover a two domain system with the domains Archaea and Bacteria in this view of the tree of life Eukaryotes are derived from Archaea 58 59 60 With the later gene pool of LUCA s descendants sharing a common framework of the AT GC rule and the standard twenty amino acids horizontal gene transfer would have become feasible and could have been common 61 The nature of LUCA remains disputed In 1994 on the basis of primordial metabolism sensu Wachtershauser Otto Kandler proposed a successive divergence of the three domains of life 1 from a multiphenotypical population of pre cells reached by gradual evolutionary improvements cellularization 62 63 64 These phenotypically diverse pre cells were metabolising self reproducing entities exhibiting frequent mutual exchange of genetic information Thus in this scenario there was no first cell It may explain the unity and at the same time the partition into three lines the three domains of life Kandler s pre cell theory is supported by Wachtershauser 65 66 In 1998 Carl Woese based on the RNA world concept proposed that no individual organism could be considered a LUCA and that the genetic heritage of all modern organisms derived through horizontal gene transfer among an ancient community of organisms 67 Other authors concur that there was a complex collective genome 68 at the time of the LUCA and that horizontal gene transfer was important in the evolution of later groups 68 Nicolas Glansdorff states that LUCA was in a metabolically and morphologically heterogeneous community constantly shuffling around genetic material and remained an evolutionary entity though loosely defined and constantly changing as long as this promiscuity lasted 69 The theory of a universal common ancestry of life is widely accepted In 2010 based on the vast array of molecular sequences now available from all domains of life 70 D L Theobald published a formal test of universal common ancestry UCA This deals with the common descent of all extant terrestrial organisms each being a genealogical descendant of a single species from the distant past His formal test favoured the existence of a universal common ancestry over a wide class of alternative hypotheses that included horizontal gene transfer Basic biochemical principles imply that all organisms do have a common ancestry 71 A proposed earlier non cellular ancestor to LUCA is the First universal common ancestor FUCA 72 73 FUCA would therefore be the ancestor to every modern cell as well as ancient now extinct cellular lineages not descendant of LUCA FUCA is assumed to have had other descendants than LUCA none of which have modern descendants Some genes of these ancient now extinct cell lineages are thought to have been horizontally transferred into the genome of early descendants of LUCA 61 LUCA and viruses editThe origin of viruses remains disputed Since viruses need host cells for their replication it is likely that they emerged after the formation of cells Viruses may even have multiple origins and different types of viruses may have evolved independently over the history of life 2 There are different hypotheses for the origins of viruses for instance an early viral origin from the RNA world or a later viral origin from selfish DNA 2 Based on how viruses are currently distributed across the bacteria and archaea the LUCA is suspected of having been prey to multiple viruses ancestral to those that now have those two domains as their hosts 74 Furthermore extensive virus evolution seems to have preceded the LUCA since the jelly roll structure of capsid proteins is shared by RNA and DNA viruses across all three domains of life 75 76 LUCA s viruses were probably mainly dsDNA viruses in the groups called Duplodnaviria and Varidnaviria Two other single stranded DNA virus groups within the Monodnaviria the Microviridae and the Tubulavirales likely infected the last bacterial common ancestor The last archaeal common ancestor was probably host to spindle shaped viruses All of these could well have affected the LUCA in which case each must since have been lost in the host domain where it is no longer extant By contrast RNA viruses do not appear to have been important parasites of LUCA even though straightforward thinking might have envisaged viruses as beginning with RNA viruses directly derived from an RNA world Instead by the time the LUCA lived RNA viruses had probably already been out competed by DNA viruses 74 LUCA might have been the ancestor to some viruses as it might have had at least two descendants LUCELLA the Last Universal Cellular Ancestor the ancestor to all cells and the archaic virocell ancestor the ancestor to large to medium sized DNA viruses 77 Viruses might have evolved before LUCA but after the First universal common ancestor FUCA according to the reduction hypothesis where giant viruses evolved from primordial cells that became parasitic 61 See also editAbiogenesis Natural process by which life arises from non living matter Cellularization Scientific theory to explain the origin and formation of cells Chemoton Abstract model for the fundamental unit of life Darwinian threshold Period during the evolution of the first cells Last eukaryotic common ancestor Process of forming the first eukaryotic cellPages displaying short descriptions of redirect targets Mitochondrial Eve Matrilineal most recent common ancestor of all living humans Pre cell Hypothetical life before complete cells Timeline of the evolutionary history of life Major events during the development of life Urmetazoan Hypothetical last common ancestor of all animals Y chromosomal Adam Patrilineal most recent common ancestor of all living humansNotes edit Other studies propose that LUCA may have been defined wholly through RNA 18 consisted of a RNA DNA hybrid genome or possessed a retrovirus like genetic cycle with DNA serving as a stable genetic repository 19 One debate dealt with a former cladistic hypothesis The tree could not be ascribed a root in the usual algorithmic way because that would require an outgroup for reference In the case of the universal tree no outgroup would exist The cladistic method was used to root the purple bacteria for example But establishing a root for the universal tree of life the branching order among the primary urkingdoms was another matter entirely 54 References edit a b c d e Woese C R Kandler O Wheelis M L June 1990 Towards a natural system of organisms proposal for the domains Archaea Bacteria and Eucarya PNAS 87 12 4576 4579 Bibcode 1990PNAS 87 4576W doi 10 1073 pnas 87 12 4576 PMC 54159 PMID 2112744 a b c d Madigan Michael T Aiyer Jennifer Buckley Daniel H Sattley Matthew Stahl David A 2022 Brock Biology of Microorganisms 16 ed Harlow Pearson Education pp Unit 3 chapter 13 431 LUCA 435 tree of life 428 438 439 viruses ISBN 978 1 292 40479 0 a b Harold Franklin M 2014 In Search of Cell History The Evolution of Life s Building Blocks Chicago London University of Chicago Press ISBN 978 0 226 17428 0 Gregory T Ryan 2008 Understanding evolutionary trees Evolution Education and Outreach 1 2 121 137 doi 10 1007 s12052 008 0035 x S2CID 15488906 Lamarck Jean Baptiste Pierre Antoine de Monet de 1994 1809 Philosophie zoologique PDF Paris p 737 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Noble Denis 1 July 2020 Editorial Charles Darwin Jean Baptiste Lamarck and 21st century arguments on the fundamentals of biology Progress in Biophysics and Molecular Biology 153 1 4 doi 10 1016 j pbiomolbio 2020 02 005 PMID 32092299 S2CID 211475380 Retrieved 23 December 2022 a b Darwin Charles 1859 The Origin of Species by Means of Natural Selection John Murray pp 484 490 Wikham Gene Stephen March 1995 The molecular phylogenetic analysis of naturally occurring hyperthermophilic microbial communities PhD thesis Indiana University p 4 ProQuest 304192982 Forterre Patrick 1997 Archaea What can we learn from their sequences Current Opinion in Genetics amp Development 7 6 764 770 doi 10 1016 s0959 437x 97 80038 x PMID 9468785 Koonin Eugene V Galperin Michael Y 2003 Sequence Evolution Function Computational approaches in comparative genomics Boston MA Kluwer p 252 ISBN 978 1 4757 3783 7 OCLC 55642057 a b c Weiss Madeline C Preiner Martina Xavier Joana C Zimorski Verena Martin William F 16 August 2018 The last universal common ancestor between ancient Earth chemistry and the onset of genetics PLOS Genetics 14 8 e1007518 doi 10 1371 journal pgen 1007518 PMC 6095482 PMID 30114187 S2CID 52019935 a b c Weiss Madeline C Sousa F L Mrnjavac N et al 2016 The physiology and habitat of the last universal common ancestor PDF Nature Microbiology 1 9 16116 doi 10 1038 nmicrobiol 2016 116 PMID 27562259 S2CID 2997255 Harrison Stuart A Palmeira Raquel Nunes Halpern Aaron Lane Nick 1 November 2022 A biophysical basis for the emergence of the genetic code in protocells Biochimica et Biophysica Acta BBA Bioenergetics 1863 8 148597 doi 10 1016 j bbabio 2022 148597 ISSN 0005 2728 PMID 35868450 Harrison Stuart A Lane Nick 12 December 2018 Life as a guide to prebiotic nucleotide synthesis Nature Communications 9 1 5176 Bibcode 2018NatCo 9 5176H doi 10 1038 s41467 018 07220 y ISSN 2041 1723 PMC 6289992 PMID 30538225 a b c Cantine Marjorie D Fournier Gregory P 6 July 2017 Environmental Adaptation from the Origin of Life to the Last Universal Common Ancestor Origins of Life and Evolution of Biospheres 48 1 35 54 doi 10 1007 s11084 017 9542 5 hdl 1721 1 114219 ISSN 0169 6149 Wachtershauser Gunter 1998 Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment Systematic and Applied Microbiology 21 4 473 474 IN1 475 477 doi 10 1016 S0723 2020 98 80058 1 a b c Wachtershauser Gunter 1998 Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment Systematic and Applied Microbiology 21 4 473 474 IN1 475 477 doi 10 1016 S0723 2020 98 80058 1 Marshall Michael Life began with a planetary mega organism New Scientist Archived from the original on 25 July 2016 Retrieved 31 July 2016 Koonin Eugene V Martin William 1 December 2005 On the origin of genomes and cells within inorganic compartments Trends in Genetics 21 12 647 654 doi 10 1016 j tig 2005 09 006 PMC 7172762 PMID 16223546 Garwood Russell J 2012 Patterns In Palaeontology The first 3 billion years of evolution Palaeontology Online 2 11 1 14 Archived from the original on 26 June 2015 Retrieved 25 June 2015 Koonin Eugene V Krupovic M Ishino S Ishino Y 2020 The replication machinery of LUCA common origin of DNA replication and transcription BMC Biology 18 1 61 doi 10 1186 s12915 020 00800 9 PMC 7281927 PMID 32517760 Ahmad Muzammil Xu Dongyi Wang Weidong 23 May 2017 Type IA topoisomerases can be magicians for both DNA and RNA in all domains of life RNA Biology 14 7 854 864 doi 10 1080 15476286 2017 1330741 PMC 5546716 PMID 28534707 Lupas Andrei N Alva Vikram 2018 Histones predate the split between bacteria and archaea Bioinformatics 35 14 2349 2353 doi 10 1093 bioinformatics bty1000 PMID 30520969 Bernstein H Bernstein C 2017 Sexual Communication in Archaea the Precursor to Eukaryotic Meiosis In Witzany G eds Biocommunication of Archaea Springer Cham https doi org 10 1007 978 3 319 65536 9 7 Gogarten Johann Peter Taiz Lincoln 1992 Evolution of proton pumping ATPases Rooting the tree of life Photosynthesis Research 33 2 137 146 doi 10 1007 bf00039176 ISSN 0166 8595 Wachtershauser Gunter 1998 Towards a Reconstruction of Ancestral Genomes by Gene Cluster Alignment Systematic and Applied Microbiology 21 4 473 474 IN1 475 477 doi 10 1016 S0723 2020 98 80058 1 Martin W Russell M J October 2007 On the origin of biochemistry at an alkaline hydrothermal vent Philosophical Transactions of the Royal Society of London Series B Biological Sciences 362 1486 1887 1925 doi 10 1098 rstb 2006 1881 PMC 2442388 PMID 17255002 Lane Nick Allen J F Martin William April 2010 How did LUCA make a living Chemiosmosis in the origin of life BioEssays 32 4 271 280 doi 10 1002 bies 200900131 PMID 20108228 Weiss Madeline C Preiner Martina Xavier Joana C Zimorski Verena Martin William F 16 August 2018 The last universal common ancestor between ancient Earth chemistry and the onset of genetics PLOS Genetics 14 8 e1007518 doi 10 1371 journal pgen 1007518 PMC 6095482 PMID 30114187 S2CID 52019935 Muchowska Kamila B Varma Sreejith J Chevallot Beroux Elodie Lethuillier Karl Lucas Li Guang Moran Joseph 2 October 2017 Metals promote sequences of the reverse Krebs cycle Nature Ecology amp Evolution 1 11 1716 1721 doi 10 1038 s41559 017 0311 7 ISSN 2397 334X PMC 5659384 PMID 28970480 Sojo Victor Pomiankowski Andrew Lane Nick 12 August 2014 A Bioenergetic Basis for Membrane Divergence in Archaea and Bacteria PLOS Biology 12 8 e1001926 doi 10 1371 journal pbio 1001926 ISSN 1545 7885 PMC 4130499 PMID 25116890 Weiss Madeline C Preiner Martina Xavier Joana C Zimorski Verena Martin William F 16 August 2018 The last universal common ancestor between ancient Earth chemistry and the onset of genetics PLOS Genetics 14 8 e1007518 doi 10 1371 journal pgen 1007518 PMC 6095482 PMID 30114187 S2CID 52019935 Jordan S F Nee E Lane Nick 18 October 2019 Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide Interface Focus 9 6 doi 10 1098 rsfs 2019 0067 ISSN 2042 8901 PMC 6802135 PMID 31641436 nbsp This article incorporates text from this source which is available under the CC BY 4 0 license Mulkidjanian Armen Y Bychkov Andrew Yu Dibrova Daria V Galperin Michael Y Koonin Eugene V 2012 Origin of first cells at terrestrial anoxic geothermal fields Proceedings of the National Academy of Sciences 109 14 E821 30 Bibcode 2012PNAS 109E 821M doi 10 1073 pnas 1117774109 PMC 3325685 PMID 22331915 Adam Panagiotis S Borrel Guillaume Gribaldo Simonetta 6 February 2018 Evolutionary history of carbon monoxide dehydrogenase acetyl CoA synthase one of the oldest enzymatic complexes PNAS 115 6 E1166 E1173 Bibcode 2018PNAS 115E1166A doi 10 1073 pnas 1716667115 PMC 5819426 PMID 29358391 Weiss Madeline C Preiner Martina Xavier Joana C Zimorski Verena Martin William F 16 August 2018 The last universal common ancestor between ancient Earth chemistry and the onset of genetics PLOS Genetics 14 8 e1007518 doi 10 1371 journal pgen 1007518 PMC 6095482 PMID 30114187 S2CID 52019935 Galtier Nicolas Tourasse Nicolas Gouy Manolo 8 January 1999 A Nonhyperthermophilic Common Ancestor to Extant Life Forms Science 283 5399 220 221 doi 10 1126 science 283 5399 220 ISSN 0036 8075 Groussin Mathieu Boussau Bastien Charles Sandrine Blanquart Samuel Gouy Manolo 23 October 2013 The molecular signal for the adaptation to cold temperature during early life on Earth Biology Letters 9 5 20130608 doi 10 1098 rsbl 2013 0608 ISSN 1744 9561 Gogarten Johann Peter Deamer David 2016 Is LUCA a thermophilic progenote Nature Microbiology 1 12 16229 doi 10 1038 nmicrobiol 2016 229 PMID 27886195 S2CID 205428194 Woese Carl June 1998 The universal ancestor PNAS 95 12 6854 6859 Bibcode 1998PNAS 95 6854W doi 10 1073 pnas 95 12 6854 PMC 22660 PMID 9618502 Camprubi E de Leeuw J W House C H Raulin F Russell M J Spang A Tirumalai M R Westall F 12 December 2019 The Emergence of Life Space Science Reviews 215 8 56 Bibcode 2019SSRv 215 56C doi 10 1007 s11214 019 0624 8 ISSN 1572 9672 Zeldovich Konstantin B Berezovsky Igor N Shakhnovich Eugene I 2007 Protein and DNA Sequence Determinants of Thermophilic Adaptation PLOS Computational Biology 3 1 e5 doi 10 1371 journal pcbi 0030005 ISSN 1553 7358 Boussau Bastien Blanquart Samuel Necsulea Anamaria Lartillot Nicolas Gouy Manolo 26 November 2008 Parallel adaptations to high temperatures in the Archaean eon Nature 456 7224 942 945 doi 10 1038 nature07393 ISSN 0028 0836 Doolittle W F February 2000 Uprooting the tree of life Scientific American 282 2 90 95 Bibcode 2000SciAm 282b 90D doi 10 1038 scientificamerican0200 90 JSTOR 26058605 PMID 10710791 Noffke N Christian D Wacey D Hazen R M December 2013 Microbially induced sedimentary structures recording an ancient ecosystem in the ca 3 48 billion year old Dresser Formation Pilbara Western Australia Astrobiology 13 12 1103 1124 Bibcode 2013AsBio 13 1103N doi 10 1089 ast 2013 1030 PMC 3870916 PMID 24205812 Ohtomo Yoko Kakegawa Takeshi Ishida Akizumi Nagase Toshiro Rosing Minik T 2013 Evidence for biogenic graphite in early Archaean Isua metasedimentary rocks Nature Geoscience 7 1 25 28 Bibcode 2014NatGe 7 25O doi 10 1038 ngeo2025 Hassenkam T Andersson M P Dalby K N et al 2017 Elements of Eoarchean life trapped in mineral inclusions Nature 548 7665 78 81 Bibcode 2017Natur 548 78H doi 10 1038 nature23261 PMID 28738409 S2CID 205257931 Bell Elizabeth A Boehnke Patrick Harrison T Mark Mao Wendy L 24 November 2015 Potentially biogenic carbon preserved in a 4 1 billion year old zircon PNAS 112 47 14518 14521 Bibcode 2015PNAS 11214518B doi 10 1073 pnas 1517557112 PMC 4664351 PMID 26483481 Dodd Matthew S Papineau Dominic Grenne Tor et al 2 March 2017 Evidence for early life in Earth s oldest hydrothermal vent precipitates PDF Nature 543 7643 60 64 Bibcode 2017Natur 543 60D doi 10 1038 nature21377 PMID 28252057 S2CID 2420384 Archived PDF from the original on 23 July 2018 Retrieved 25 June 2019 Betts Holly C Puttick Mark N Clark James W Williams Tom A Donoghue Philip C J Pisani Davide 2018 Integrated genomic and fossil evidence illuminates life s early evolution and eukaryote origin Nature Ecology amp Evolution 2 10 1556 1562 doi 10 1038 s41559 018 0644 x PMC 6152910 PMID 30127539 a b c Smets Barth F Barkay Tamar September 2005 Horizontal gene transfer perspectives at a crossroads of scientific disciplines Nature Reviews Microbiology 3 9 675 678 doi 10 1038 nrmicro1253 PMID 16145755 S2CID 2265315 a b Sapp Jan A 2009 The new foundations of evolution on the tree of life New York Oxford University Press pp Chapter 19 257ff novel concept of the tree of life Chapters 17 21 plus concluding remarks 226 318 discussion of the tree and its rooting 286ff LUCA ISBN 978 0 199 73438 2 Madigan Michael T Martinko John M Bender Kelly S Buckley Daniel H Stahl David A 2015 Brock Biology of Microorganisms 14 ed Boston Pearson Education Limited pp 29 374 381 ISBN 978 1 292 01831 7 Sapp 2009 p 255 a b Brown J R Doolittle W F 1995 Root of the Universal Tree of Life Based on Ancient Aminoacyl tRNA Synthetase Gene Duplications PNAS 92 7 2441 2445 Bibcode 1995PNAS 92 2441B doi 10 1073 pnas 92 7 2441 PMC 42233 PMID 7708661 Valas R E Bourne P E 2011 The origin of a derived superkingdom how a gram positive bacterium crossed the desert to become an archaeon Biology Direct 6 16 doi 10 1186 1745 6150 6 16 PMC 3056875 PMID 21356104 Cavalier Smith Tom 2006 Rooting the tree of life by transition analyses Biology Direct 1 19 doi 10 1186 1745 6150 1 19 PMC 1586193 PMID 16834776 Raymann Kasie Brochier Armanet Celine Gribaldo Simonetta 26 May 2015 The two domain tree of life is linked to a new root for the Archaea Proceedings of the National Academy of Sciences 112 21 6670 6675 Bibcode 2015PNAS 112 6670R doi 10 1073 pnas 1420858112 ISSN 0027 8424 PMC 4450401 PMID 25964353 Hug Laura A Baker Brett J Anantharaman Karthik et al 11 April 2016 A new view of the tree of life Nature Microbiology 1 5 16048 doi 10 1038 nmicrobiol 2016 48 ISSN 2058 5276 PMID 27572647 S2CID 3833474 Williams Tom A Foster Peter G Cox Cymon J Embley T Martin 11 December 2013 An archaeal origin of eukaryotes supports only two primary domains of life Nature 504 7479 231 236 Bibcode 2013Natur 504 231W doi 10 1038 nature12779 ISSN 1476 4687 PMID 24336283 S2CID 4461775 a b c Harris Hugh M B Hill Colin 2021 A Place for Viruses on the Tree of Life Frontiers in Microbiology 11 doi 10 3389 fmicb 2020 604048 ISSN 1664 302X PMC 7840587 PMID 33519747 Kandler Otto 1994 The early diversification of life In Stefan Bengtson ed Early Life on Earth Nobel Symposium 84 New York Columbia University Press pp 152 160 Kandler Otto 1995 Cell Wall Biochemistry in Archaea and its Phylogenetic Implications Journal of Biological Physics 20 1 4 165 169 doi 10 1007 BF00700433 S2CID 83906865 Kandler Otto 1998 The early diversification of life and the origin of the three domains A proposal In Jurgen Wiegel Michael W W Adams eds Thermophiles The keys to molecular evolution and the origin of life London Taylor and Francis Ltd pp 19 31 ISBN 978 0 203 48420 3 Wachtershauser Gunter 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 Gunter 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 1808 doi 10 1098 rstb 2006 1904 PMC 1664677 PMID 17008219 Woese Carl June 1998 The universal ancestor PNAS 95 12 6854 6859 Bibcode 1998PNAS 95 6854W doi 10 1073 pnas 95 12 6854 PMC 22660 PMID 9618502 a b Egel Richard March 2012 Primal Eukaryogenesis On the Communal Nature of Precellular States Ancestral to Modern Life Life 2 1 170 212 Bibcode 2012Life 2 170E doi 10 3390 life2010170 PMC 4187143 PMID 25382122 Glansdorff Nicolas Xu Ying Labedan Bernard 9 July 2008 The Last Universal Common Ancestor emergence constitution and genetic legacy of an elusive forerunner Biology Direct 3 1 29 doi 10 1186 1745 6150 3 29 PMC 2478661 PMID 18613974 S2CID 18250196 Steel M Penny D May 2010 Origins of life Common ancestry put to the test Nature 465 7295 168 169 Bibcode 2010Natur 465 168S doi 10 1038 465168a PMID 20463725 S2CID 205055573 Theobald D L May 2010 A formal test of the theory of universal common ancestry Nature 465 7295 219 222 Bibcode 2010Natur 465 219T doi 10 1038 nature09014 PMID 20463738 S2CID 4422345 Prosdocimi Francisco Jose Marco V de Farias Savio Torres 2019 The First Universal Common Ancestor FUCA as the Earliest Ancestor of LUCA s Last UCA Lineage In Pontarotti Pierre ed Evolution Origin of Life Concepts and Methods Cham Springer pp 43 54 doi 10 1007 978 3 030 30363 1 3 ISBN 978 3 030 30363 1 S2CID 199534387 Retrieved 2 November 2023 Prosdocimi Francisco Jose Marco V de Farias Savio Torres 2019 The First Universal Common Ancestor FUCA as the Earliest Ancestor of LUCA s Last UCA Lineage in Pontarotti Pierre ed Evolution Origin of Life Concepts and Methods Cham Springer pp 43 54 doi 10 1007 978 3 030 30363 1 3 ISBN 978 3 030 30363 1 S2CID 199534387 retrieved 2 November 2023 a b Krupovic M Dolja V V Koonin Eugene V 2020 The LUCA and its complex virome PDF Nature Reviews Microbiology 18 11 661 670 doi 10 1038 s41579 020 0408 x PMID 32665595 S2CID 220516514 Forterre Patrick Prangishvili David 2009 The origin of viruses Research in Microbiology 160 7 466 472 doi 10 1016 j resmic 2009 07 008 PMID 19647075 S2CID 2767388 Durzynska Julia Gozdzicka Jozefiak Anna 16 October 2015 Viruses and cells intertwined since the dawn of evolution Virology Journal 12 1 169 doi 10 1186 s12985 015 0400 7 PMC 4609113 PMID 26475454 Nasir Arshan Kim Kyung Mo Caetano Anolles Gustavo 1 September 2012 Viral evolution Mobile Genetic Elements 2 5 247 252 doi 10 4161 mge 22797 ISSN 2159 2543 PMC 3575434 PMID 23550145 Further reading editLane Nick 2016 2015 The Vital Question London Profile Books ISBN 978 1781250372 Retrieved from https en wikipedia org w index php title Last universal common ancestor amp oldid 1189382719, 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.