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Earliest known life forms

February 15, 2024

The earliest known life forms on Earth may be as old as 4.1 billion years old (or Ga) according to biologically fractionated graphite inside a single zircon grain in the Jack Hills range of Australia.[2] The earliest evidence of life found in a stratigraphic unit, not just a single mineral grain, is the 3.7 Ga metasedimentary rocks containing graphite from the Isua Supracrustal Belt in Greenland.[3] The earliest direct known life on land may be stromatolites which have been found in 3.480-billion-year-old geyserite uncovered in the Dresser Formation of the Pilbara Craton of Western Australia.[4] Various microfossils of microorganisms have been found in 3.4 Ga rocks, including 3.465-billion-year-old Apex chert rocks from the same Australian craton region,[5] and in 3.42 Ga hydrothermal vent precipitates from Barberton, South Africa.[1] Much later in the geologic record, likely starting in 1.73 Ga, preserved molecular compounds of biologic origin are indicative of aerobic life.[6] Therefore, the earliest time for the origin of life on Earth is at least 3.5 billion years ago, possibly as early as 4.1 billion years ago — not long after the oceans formed 4.5 billion years ago and after the formation of the Earth 4.54 billion years ago.[7]

Evidence of possibly the oldest forms of life on Earth has been found in hydrothermal vent precipitates.[1]

Biospheres edit

Further information: Abiogenesis and Biosphere

Earth is the only place in the universe known to harbor life where it exists in multiple environments.[8][9] The origin of life on Earth was at least 3.5 billion years ago, possibly as early as 3.8-4.1 billion years ago.[2][3][4] Since its emergence, life has persisted in several geological environments. The Earth's biosphere extends down to at least 10 km (6.2 mi) below the seafloor,[10][11] up to 41–77 km (25–48 mi)[12][13] into the atmosphere,[14][15][16] and includes soil, hydrothermal vents, and rock.[17][18] Further, the biosphere has been found to extend at least 914.4 m (3,000 ft; 0.5682 mi) below the ice of Antarctica[19][20] and includes the deepest parts of the ocean.[21][22][23][24] In July 2020, marine biologists reported that aerobic microorganisms (mainly) in "quasi-suspended animation" were found in organically-poor sediments 76.2 m (250 ft) below the seafloor in the South Pacific Gyre (SPG) ("the deadest spot in the ocean").[25] Microbes have been found in the Atacama Desert in Chile, one of the driest places on Earth,[26] and in deep-sea hydrothermal vent environments which can reach temperatures over 400°C.[27] Microbial communities can also survive in cold permafrost conditions down to -25°C.[28] Under certain test conditions, life forms have been observed to survive in the vacuum of outer space.[29][30] More recently, studies conducted on the International Space Station found that bacteria could survive in outer space.[31] In February 2023, findings of a "dark microbiome" of unfamiliar microorganisms in the Atacama Desert in Chile, a Mars-like region of planet Earth, were reported.[32]

Geochemical evidence edit

The age of Earth is about 4.54 billion years;[33][34][35] the earliest undisputed evidence of life on Earth dates from at least 3.5 billion years ago according to the stromatolite record.[36] Some computer models suggest life began as early as 4.5 billion years ago.[37][38] The oldest evidence of life is indirect in the form of isotopic fractionation. Microorganisms will preferentially use the lighter isotope of an atom to build biomass, as it takes less energy to break the bonds for metabolic processes.[39] Biologic material will often have a composition that is enriched in lighter isotopes compared to the surrounding rock it's found in. Carbon isotopes, expressed scientifically in parts per thousand difference from a standard as δ13C, are frequently used to detect carbon fixation by organisms and assess if purported early life evidence has biological origins. Typically, life will preferentially metabolize the isotopically light 12C isotope instead of the heavier 13C isotope. Biologic material can record this fractionation of carbon.

 
Zircons in metaconglomerates from the Jack Hills in Australia show carbon isotopic evidence for early life.

The oldest disputed geochemical evidence of life is isotopically light graphite inside a single zircon grain from the Jack Hills in Western Australia.[40][41] The graphite showed a δ13C signature consistent with biogenic carbon on Earth. Other early evidence of life is found in rocks both from the Akilia Sequence[42] and the Isua Supracrustal Belt (ISB) in Greenland.[43][44] These 3.7 Ga metasedimentary rocks also contain graphite or graphite inclusions with carbon isotope signatures that suggest biological fractionation.

The primary issue with isotopic evidence of life is that abiotic processes can fractionate isotopes and produce similar signatures to biotic processes.[45] Reassessment of the Akilia graphite show that metamorphism, Fischer-Tropsch mechanisms in hydrothermal environments, and volcanic processes may be responsible for enrichment lighter carbon isotopes.[46][47][48] The ISB rocks that contain the graphite may have experienced a change in composition from hot fluids, i.e. metasomatism, thus the graphite may have been formed by abiotic chemical reactions.[45] However, the ISB's graphite is generally more accepted as biologic in origin after further spectral analysis.[43][44]

Metasedimentary rocks from the 3.5 Ga Dresser Formation, which experienced less metamorphism than the sequences in Greenland, contain better preserved geochemical evidence.[49] Carbon isotopes as well as sulfur isotopes found in barite, which are fractionated by microbial metabolisms during sulfate reduction,[50] are consistent with biological processes.[51][52] However, the Dresser formation was deposited in an active volcanic and hydrothermal environment,[49] and abiotic processes could still be responsible for these fractionations.[53] Many of these findings are supplemented by direct evidence, typically by the presence of microfossils, however.

Fossil evidence edit

Fossils are direct evidence of life. In the search for the earliest life, fossils are often supplemented by geochemical evidence. The fossil record does not extend as far back as the geochemical record due to metamorphic processes that erase fossils from geologic units.

Stromatolites edit

Main article: Stromatolite

Stromatolites are laminated sedimentary structures created by photosynthetic organisms as they establish a microbial mat on a sediment surface. An important distinction for biogenicity is their convex-up structures and wavy laminations, which are typical of microbial communities who build preferentially toward the sun.[54] A disputed report of stromatolites is from the 3.7 Ga Isua metasediments that show convex-up, conical, and domical morphologies.[55][56][57] Further mineralogical analysis disagrees with the initial findings of internal convex-up laminae, a critical criteria for stromatolite identification, suggesting that the structures may be deformation features (i.e. boudins) caused by extensional tectonics in the Isua Supracrustal Belt.[58][59]

 
Stromatolite fossil showing convex-up structures.

The earliest direct evidence of life are stromatolites found in 3.48 billion-year-old chert in the Dresser formation of the Pilbara Craton in Western Australia.[4] Several features in these fossils are difficult to explain with abiotic processes, for example, the thickening of laminae over flexure crests that is expected from more sunlight.[60] Sulfur isotopes from barite veins in the stromatolites also favor a biologic origin.[61] However, while most scientists accept their biogenicity, abiotic explanations for these fossils cannot be fully discarded due to their hydrothermal depositional environment and debated geochemical evidence.[62]

Most archean stromatolites older than 3.0 Ga are found in Australia or South Africa. Stratiform stromatolites from the Pilbara Craton have been identified in the 3.47 Ga Mount Ada Basalt.[63] Barberton, South Africa hosts stratiform stromatolites in the 3.46 Hooggenoeg, 3.42 Kromberg and 3.33 Ga Mendon Formations of the Onverwacht Group.[64][65] The 3.43 Ga Strelley Pool Formation in Western Australia hosts stromatolites that demonstrate vertical and horizontal changes that may demonstrate microbial communities responding to transient environmental conditions.[66] Thus, it is likely anoxygenic or oxygenic photosynthesis has been occurring since at least 3.43 Ga Strelley Pool Formation.[67]

Microfossils edit

Further information: Microfossil

Claims of the earliest life using fossilized microorganisms (microfossils) are from hydrothermal vent precipitates from an ancient sea-bed in the Nuvvuagittuq Belt of Quebec, Canada. These may be as old as 4.28 billion years, which would make it the oldest evidence of life on Earth, suggesting "an almost instantaneous emergence of life" after ocean formation 4.41 billion years ago.[68][69] These findings may be better explained by abiotic processes: for example, silica-rich waters,[70] "chemical gardens,"[71] circulating hydrothermal fluids,[72] and volcanic ejecta[73] can produce morphologies similar to those presented in Nuvvuagittuq.

 
Archaea (prokaryotic microbes) were first found in extreme environments, such as hydrothermal vents.

The 3.48 Ga Dresser formation hosts microfossils of prokaryotic filaments in silica veins, the earliest fossil evidence of life on Earth,[74] but their origins may be volcanic.[75] 3.465-billion-year-old Australian Apex chert rocks may once have contained microorganisms,[76][77] although the validity of these findings has been contested.[78][79] "Putative filamentous microfossils," possibly of methanogens and/or methanotrophs that lived about 3.42-billion-year-old in "a paleo-subseafloor hydrothermal vein system of the Barberton greenstone belt, have been identified in South Africa."[1] A diverse set of microfossil morphologies have been found in the 3.43 Ga Strelley Pool Formation including spheroid, lenticular, and film-like microstructures.[80] Their biogenicity are strengthened by their observed chemical preservation.[81] The early lithification of these structures allowed important chemical tracers, such as the carbon-to-nitrogen ratio, to be retained at levels higher than is typical in older, metamorphosed rock units.

Molecular Biomarkers edit

Further information: Biosignature

Biomarkers are compounds of biologic origin found in the geologic record that can be linked to past life.[82] Although they aren't preserved until the late Archean, they are important indicators of early photosynthetic life. Lipids are particularly useful biomarkers because they can survive for long periods of geologic time and reconstruct past environments.[83]

 
Lipids are commonly used in geologic studies to find evidence of oxygenic photosynthesis.

Fossilized lipids were reported from 2.7 Ga laminated shales from the Pilbara Craton[84] and the 2.67 Ga Kaapvaal Craton in South Africa.[85] However, the age of these biomarkers and whether their deposition was synchronous with their host rocks were debated,[86] and further work showed that the lipids were contaminants.[87] The oldest "clearly indigenous"[88] biomarkers are from the 1.64 Ga Barney Creek Formation in the McArthur Basin in Northern Australia,[89][90] but hydrocarbons from the 1.73 Ga Wollogorang Formation in the same basin have also been detected.[88]

Other indigenous biomarkers can be dated to the Mesoproterozoic era (1.6-1.0 Ga). The 1.4 Ga Hongshuizhuang Formation in the North China Craton contains hydrocarbons in shales that were likely sourced from prokaryotes.[91] Biomarkers were found in siltstones from the 1.38 Ga Roper Group of the McArthur Basin.[92] Hydrocarbons possibly derived from bacteria and algae were reported in 1.37 Ga Xiamaling Formation of the NCC.[93] The 1.1 Ga Atar/El Mreïti Group in the Taoudeni Basin, Mauritania show indigenous biomarkers in black shales.[94]

Genomic evidence edit

Main article: Last universal common ancestor

By comparing the genomes of modern organisms (in the domains Bacteria and Archaea), it is evident that there was a last universal common ancestor (LUCA). LUCA is not thought to be the first life on Earth, but rather the only type of organism of its time to still have living descendants. In 2016, M. C. Weiss and colleagues proposed a minimal set of genes that each occurred in at least two groups of Bacteria and two groups of Archaea. They argued that such a distribution of genes would be unlikely to arise by horizontal gene transfer, and so any such genes must have derived from the LUCA.[95] A molecular clock model suggests that the LUCA may have lived 4.477—4.519 billion years ago, within the Hadean eon.[37][38]

Further work on early life edit

Extraterrestrial origin for early life? edit

 
The theory of panspermia speculates that life on Earth may have come from biological matter carried by space dust[96] or meteorites.[97]

While current geochemical evidence dates the origin of life to possibly as early as 4.1 Ga, and fossil evidence shows life at 3.5 Ga, some researchers speculate that life may have started nearly 4.5 billion years ago.[37][38] According to biologist Stephen Blair Hedges, "If life arose relatively quickly on Earth ... then it could be common in the universe."[98][99][100] The possibility that terrestrial life forms may have been seeded from outer space has been considered.[101][102] In January 2018, a study found that 4.5 billion-year-old meteorites found on Earth contained liquid water along with prebiotic complex organic substances that may be ingredients for life.[103]

Early life on land edit

Further information: History of life

As for life on land, in 2019 scientists reported the discovery of a fossilized fungus, named Ourasphaira giraldae, in the Canadian Arctic, that may have grown on land a billion years ago, well before plants are thought to have been living on land.[104][105][106] The earliest life on land may have been bacteria 3.22 billion years ago.[107] Evidence of microbial life on land may have been found in 3.48 billion-year-old geyserite in the Pilbara Craton of Western Australia.[108][109]

Gallery edit

Earliest known life forms


See also edit

Notes edit

References edit

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External links edit

  • Vitae (BioLib)
  • (Taxonomicon)
  • (Systema Naturae 2000)
  • Wikispecies – a free directory of life
  • Google Images: Earliest known life forms
  • Life in the Universe – Stephen Hawking (1996)
  • Video (24:32): "Migration of Life in the Universe" on YouTubeGary Ruvkun, 2019.

February 15, 2024
earliest, known, life, forms, earliest, known, life, forms, earth, billion, years, according, biologically, fractionated, graphite, inside, single, zircon, grain, jack, hills, range, australia, earliest, evidence, life, found, stratigraphic, unit, just, single. The earliest known life forms on Earth may be as old as 4 1 billion years old or Ga according to biologically fractionated graphite inside a single zircon grain in the Jack Hills range of Australia 2 The earliest evidence of life found in a stratigraphic unit not just a single mineral grain is the 3 7 Ga metasedimentary rocks containing graphite from the Isua Supracrustal Belt in Greenland 3 The earliest direct known life on land may be stromatolites which have been found in 3 480 billion year old geyserite uncovered in the Dresser Formation of the Pilbara Craton of Western Australia 4 Various microfossils of microorganisms have been found in 3 4 Ga rocks including 3 465 billion year old Apex chert rocks from the same Australian craton region 5 and in 3 42 Ga hydrothermal vent precipitates from Barberton South Africa 1 Much later in the geologic record likely starting in 1 73 Ga preserved molecular compounds of biologic origin are indicative of aerobic life 6 Therefore the earliest time for the origin of life on Earth is at least 3 5 billion years ago possibly as early as 4 1 billion years ago not long after the oceans formed 4 5 billion years ago and after the formation of the Earth 4 54 billion years ago 7 Evidence of possibly the oldest forms of life on Earth has been found in hydrothermal vent precipitates 1 Contents 1 Biospheres 2 Geochemical evidence 3 Fossil evidence 3 1 Stromatolites 3 2 Microfossils 3 3 Molecular Biomarkers 4 Genomic evidence 5 Further work on early life 5 1 Extraterrestrial origin for early life 5 2 Early life on land 6 Gallery 7 See also 8 Notes 9 References 10 External linksBiospheres editFurther information Abiogenesis and Biosphere Earth is the only place in the universe known to harbor life where it exists in multiple environments 8 9 The origin of life on Earth was at least 3 5 billion years ago possibly as early as 3 8 4 1 billion years ago 2 3 4 Since its emergence life has persisted in several geological environments The Earth s biosphere extends down to at least 10 km 6 2 mi below the seafloor 10 11 up to 41 77 km 25 48 mi 12 13 into the atmosphere 14 15 16 and includes soil hydrothermal vents and rock 17 18 Further the biosphere has been found to extend at least 914 4 m 3 000 ft 0 5682 mi below the ice of Antarctica 19 20 and includes the deepest parts of the ocean 21 22 23 24 In July 2020 marine biologists reported that aerobic microorganisms mainly in quasi suspended animation were found in organically poor sediments 76 2 m 250 ft below the seafloor in the South Pacific Gyre SPG the deadest spot in the ocean 25 Microbes have been found in the Atacama Desert in Chile one of the driest places on Earth 26 and in deep sea hydrothermal vent environments which can reach temperatures over 400 C 27 Microbial communities can also survive in cold permafrost conditions down to 25 C 28 Under certain test conditions life forms have been observed to survive in the vacuum of outer space 29 30 More recently studies conducted on the International Space Station found that bacteria could survive in outer space 31 In February 2023 findings of a dark microbiome of unfamiliar microorganisms in the Atacama Desert in Chile a Mars like region of planet Earth were reported 32 Geochemical evidence editThe age of Earth is about 4 54 billion years 33 34 35 the earliest undisputed evidence of life on Earth dates from at least 3 5 billion years ago according to the stromatolite record 36 Some computer models suggest life began as early as 4 5 billion years ago 37 38 The oldest evidence of life is indirect in the form of isotopic fractionation Microorganisms will preferentially use the lighter isotope of an atom to build biomass as it takes less energy to break the bonds for metabolic processes 39 Biologic material will often have a composition that is enriched in lighter isotopes compared to the surrounding rock it s found in Carbon isotopes expressed scientifically in parts per thousand difference from a standard as d13C are frequently used to detect carbon fixation by organisms and assess if purported early life evidence has biological origins Typically life will preferentially metabolize the isotopically light 12C isotope instead of the heavier 13C isotope Biologic material can record this fractionation of carbon nbsp Zircons in metaconglomerates from the Jack Hills in Australia show carbon isotopic evidence for early life The oldest disputed geochemical evidence of life is isotopically light graphite inside a single zircon grain from the Jack Hills in Western Australia 40 41 The graphite showed a d13C signature consistent with biogenic carbon on Earth Other early evidence of life is found in rocks both from the Akilia Sequence 42 and the Isua Supracrustal Belt ISB in Greenland 43 44 These 3 7 Ga metasedimentary rocks also contain graphite or graphite inclusions with carbon isotope signatures that suggest biological fractionation The primary issue with isotopic evidence of life is that abiotic processes can fractionate isotopes and produce similar signatures to biotic processes 45 Reassessment of the Akilia graphite show that metamorphism Fischer Tropsch mechanisms in hydrothermal environments and volcanic processes may be responsible for enrichment lighter carbon isotopes 46 47 48 The ISB rocks that contain the graphite may have experienced a change in composition from hot fluids i e metasomatism thus the graphite may have been formed by abiotic chemical reactions 45 However the ISB s graphite is generally more accepted as biologic in origin after further spectral analysis 43 44 Metasedimentary rocks from the 3 5 Ga Dresser Formation which experienced less metamorphism than the sequences in Greenland contain better preserved geochemical evidence 49 Carbon isotopes as well as sulfur isotopes found in barite which are fractionated by microbial metabolisms during sulfate reduction 50 are consistent with biological processes 51 52 However the Dresser formation was deposited in an active volcanic and hydrothermal environment 49 and abiotic processes could still be responsible for these fractionations 53 Many of these findings are supplemented by direct evidence typically by the presence of microfossils however Fossil evidence editFossils are direct evidence of life In the search for the earliest life fossils are often supplemented by geochemical evidence The fossil record does not extend as far back as the geochemical record due to metamorphic processes that erase fossils from geologic units Stromatolites edit Main article Stromatolite Stromatolites are laminated sedimentary structures created by photosynthetic organisms as they establish a microbial mat on a sediment surface An important distinction for biogenicity is their convex up structures and wavy laminations which are typical of microbial communities who build preferentially toward the sun 54 A disputed report of stromatolites is from the 3 7 Ga Isua metasediments that show convex up conical and domical morphologies 55 56 57 Further mineralogical analysis disagrees with the initial findings of internal convex up laminae a critical criteria for stromatolite identification suggesting that the structures may be deformation features i e boudins caused by extensional tectonics in the Isua Supracrustal Belt 58 59 nbsp Stromatolite fossil showing convex up structures The earliest direct evidence of life are stromatolites found in 3 48 billion year old chert in the Dresser formation of the Pilbara Craton in Western Australia 4 Several features in these fossils are difficult to explain with abiotic processes for example the thickening of laminae over flexure crests that is expected from more sunlight 60 Sulfur isotopes from barite veins in the stromatolites also favor a biologic origin 61 However while most scientists accept their biogenicity abiotic explanations for these fossils cannot be fully discarded due to their hydrothermal depositional environment and debated geochemical evidence 62 Most archean stromatolites older than 3 0 Ga are found in Australia or South Africa Stratiform stromatolites from the Pilbara Craton have been identified in the 3 47 Ga Mount Ada Basalt 63 Barberton South Africa hosts stratiform stromatolites in the 3 46 Hooggenoeg 3 42 Kromberg and 3 33 Ga Mendon Formations of the Onverwacht Group 64 65 The 3 43 Ga Strelley Pool Formation in Western Australia hosts stromatolites that demonstrate vertical and horizontal changes that may demonstrate microbial communities responding to transient environmental conditions 66 Thus it is likely anoxygenic or oxygenic photosynthesis has been occurring since at least 3 43 Ga Strelley Pool Formation 67 Microfossils edit Further information Microfossil Claims of the earliest life using fossilized microorganisms microfossils are from hydrothermal vent precipitates from an ancient sea bed in the Nuvvuagittuq Belt of Quebec Canada These may be as old as 4 28 billion years which would make it the oldest evidence of life on Earth suggesting an almost instantaneous emergence of life after ocean formation 4 41 billion years ago 68 69 These findings may be better explained by abiotic processes for example silica rich waters 70 chemical gardens 71 circulating hydrothermal fluids 72 and volcanic ejecta 73 can produce morphologies similar to those presented in Nuvvuagittuq nbsp Archaea prokaryotic microbes were first found in extreme environments such as hydrothermal vents The 3 48 Ga Dresser formation hosts microfossils of prokaryotic filaments in silica veins the earliest fossil evidence of life on Earth 74 but their origins may be volcanic 75 3 465 billion year old Australian Apex chert rocks may once have contained microorganisms 76 77 although the validity of these findings has been contested 78 79 Putative filamentous microfossils possibly of methanogens and or methanotrophs that lived about 3 42 billion year old in a paleo subseafloor hydrothermal vein system of the Barberton greenstone belt have been identified in South Africa 1 A diverse set of microfossil morphologies have been found in the 3 43 Ga Strelley Pool Formation including spheroid lenticular and film like microstructures 80 Their biogenicity are strengthened by their observed chemical preservation 81 The early lithification of these structures allowed important chemical tracers such as the carbon to nitrogen ratio to be retained at levels higher than is typical in older metamorphosed rock units Molecular Biomarkers edit Further information Biosignature Biomarkers are compounds of biologic origin found in the geologic record that can be linked to past life 82 Although they aren t preserved until the late Archean they are important indicators of early photosynthetic life Lipids are particularly useful biomarkers because they can survive for long periods of geologic time and reconstruct past environments 83 nbsp Lipids are commonly used in geologic studies to find evidence of oxygenic photosynthesis Fossilized lipids were reported from 2 7 Ga laminated shales from the Pilbara Craton 84 and the 2 67 Ga Kaapvaal Craton in South Africa 85 However the age of these biomarkers and whether their deposition was synchronous with their host rocks were debated 86 and further work showed that the lipids were contaminants 87 The oldest clearly indigenous 88 biomarkers are from the 1 64 Ga Barney Creek Formation in the McArthur Basin in Northern Australia 89 90 but hydrocarbons from the 1 73 Ga Wollogorang Formation in the same basin have also been detected 88 Other indigenous biomarkers can be dated to the Mesoproterozoic era 1 6 1 0 Ga The 1 4 Ga Hongshuizhuang Formation in the North China Craton contains hydrocarbons in shales that were likely sourced from prokaryotes 91 Biomarkers were found in siltstones from the 1 38 Ga Roper Group of the McArthur Basin 92 Hydrocarbons possibly derived from bacteria and algae were reported in 1 37 Ga Xiamaling Formation of the NCC 93 The 1 1 Ga Atar El Mreiti Group in the Taoudeni Basin Mauritania show indigenous biomarkers in black shales 94 Genomic evidence editMain article Last universal common ancestor By comparing the genomes of modern organisms in the domains Bacteria and Archaea it is evident that there was a last universal common ancestor LUCA LUCA is not thought to be the first life on Earth but rather the only type of organism of its time to still have living descendants In 2016 M C Weiss and colleagues proposed a minimal set of genes that each occurred in at least two groups of Bacteria and two groups of Archaea They argued that such a distribution of genes would be unlikely to arise by horizontal gene transfer and so any such genes must have derived from the LUCA 95 A molecular clock model suggests that the LUCA may have lived 4 477 4 519 billion years ago within the Hadean eon 37 38 Further work on early life editExtraterrestrial origin for early life edit nbsp The theory of panspermia speculates that life on Earth may have come from biological matter carried by space dust 96 or meteorites 97 While current geochemical evidence dates the origin of life to possibly as early as 4 1 Ga and fossil evidence shows life at 3 5 Ga some researchers speculate that life may have started nearly 4 5 billion years ago 37 38 According to biologist Stephen Blair Hedges If life arose relatively quickly on Earth then it could be common in the universe 98 99 100 The possibility that terrestrial life forms may have been seeded from outer space has been considered 101 102 In January 2018 a study found that 4 5 billion year old meteorites found on Earth contained liquid water along with prebiotic complex organic substances that may be ingredients for life 103 Early life on land edit Further information History of life As for life on land in 2019 scientists reported the discovery of a fossilized fungus named Ourasphaira giraldae in the Canadian Arctic that may have grown on land a billion years ago well before plants are thought to have been living on land 104 105 106 The earliest life on land may have been bacteria 3 22 billion years ago 107 Evidence of microbial life on land may have been found in 3 48 billion year old geyserite in the Pilbara Craton of Western Australia 108 109 Gallery editEarliest known life forms nbsp Stromatolites may have been made by microbes moving upward to avoid being smothered by sediment 57 59 nbsp Stromatolites left behind by cyanobacteria are one of the oldest fossils of life on Earth nbsp The cyanobacterial algal mat salty lake on the White Sea seaside nbsp Microbialites in the Lake Salda rocks of Turkey nbsp Wrinkled Kinneyia type sedimentary structures formed beneath cohesive microbial mats in peritidal zones 110 nbsp Kinneyia like structure in the Grimsby Formation Silurian exposed in Niagara Gorge NYSee also editAbiogenesis Creation myth Extremophile First universal common ancestor Hypothetical types of biochemistry List of longest living organisms Oldest dated rocks Outline of biology Outline of life forms Timeline of the evolutionary history of life ViroidVirusNotes editReferences edit a b c Cavalazzi Barbara et al 14 July 2021 Cellular remains in a 3 42 billion year old subseafloor hydrothermal environment Science Advances 7 9 eabf3963 Bibcode 2021SciA 7 3963C doi 10 1126 sciadv abf3963 PMC 8279515 PMID 34261651 a b Bell Elizabeth Boehnke Patrick Harrison T Mark Mao Wendy L 24 November 2015 Potentially biogenic carbon preserved in a 4 1 billion year old zircon Proceedings of the National Academy of Sciences of the United States of America 112 47 14518 14521 Bibcode 2015PNAS 11214518B doi 10 1073 pnas 1517557112 PMC 4664351 PMID 26483481 a b Ohtomo Yoko Kakegawa Takeshi Ishida Akizumi et al January 2014 Evidence for biogenic graphite in early Archaean Isua metasedimentary rocks Nature Geoscience 7 1 25 28 Bibcode 2014NatGe 7 25O doi 10 1038 ngeo2025 ISSN 1752 0894 S2CID 54767854 a b c Noffke Nora Christian Daniel Wacey David Hazen 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July 2018 Microbial life and biogeochemical cycling on land 3 220 million years ago PDF Nature Geoscience 11 9 665 671 Bibcode 2018NatGe 11 665H doi 10 1038 s41561 018 0190 9 S2CID 134935568 Oldest evidence of life on land found in 3 48 billion year old Australian rocks Phys org 9 May 2017 Retrieved 13 May 2017 University of New South Wales 26 September 2019 Earliest signs of life Scientists find microbial remains in ancient rocks EurekAlert Retrieved 27 September 2019 Porada H Ghergut J Bouougri El H 2008 Kinneyia Type Wrinkle Structures Critical Review And Model Of Formation PALAIOS 23 2 65 77 Bibcode 2008Palai 23 65P doi 10 2110 palo 2006 p06 095r S2CID 128464944 External links editVitae BioLib Biota Taxonomicon Life Systema Naturae 2000 Wikispecies a free directory of life Google Images Earliest known life forms Life in the Universe Stephen Hawking 1996 Video 24 32 Migration of Life in the Universe on YouTube Gary Ruvkun 2019 Portals nbsp Astronomy nbsp Biology nbsp Evolutionary 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