History of life

The history of life on Earth traces the processes by which living and fossil organisms evolved, from the earliest emergence of life to present day. Earth formed about 4.5 billion years ago (abbreviated as Ga, for gigaannum) and evidence suggests that life emerged prior to 3.7 Ga.[1][2][3] Although there is some evidence of life as early as 4.1 to 4.28 Ga, it remains controversial due to the possible non-biological formation of the purported fossils.[1][4][5][6]

The similarities among all known present-day species indicate that they have diverged through the process of evolution from a common ancestor.[7] Only a very small percentage of species have been identified: one estimate claims that Earth may have 1 trillion species.[8] However, only 1.75–1.8 million have been named[9][10] and 1.8 million documented in a central database.[11] These currently living species represent less than one percent of all species that have ever lived on Earth.[12][13]

The earliest evidence of life comes from biogenic carbon signatures[2][3] and stromatolite fossils[14] discovered in 3.7 billion-year-old metasedimentary rocks from western Greenland. In 2015, possible "remains of biotic life" were found in 4.1 billion-year-old rocks in Western Australia.[15][5] In March 2017, putative evidence of possibly the oldest forms of life on Earth was reported in the form of fossilized microorganisms discovered in hydrothermal vent precipitates in the Nuvvuagittuq Belt of Quebec, Canada, that may have lived as early as 4.28 billion years ago, not long after the oceans formed 4.4 billion years ago, and not long after the formation of the Earth 4.54 billion years ago.[16][17]

Microbial mats of coexisting bacteria and archaea were the dominant form of life in the early Archean Epoch and many of the major steps in early evolution are thought to have taken place in this environment.[18] The evolution of photosynthesis, around 3.5 Ga, eventually led to a buildup of its waste product, oxygen, in the atmosphere, leading to the great oxygenation event, beginning around 2.4 Ga.[19] The earliest evidence of eukaryotes (complex cells with organelles) dates from 1.85 Ga,[20][21] and while they may have been present earlier, their diversification accelerated when they started using oxygen in their metabolism. Later, around 1.7 Ga, multicellular organisms began to appear, with differentiated cells performing specialised functions.[22] Sexual reproduction, which involves the fusion of male and female reproductive cells (gametes) to create a zygote in a process called fertilization is, in contrast to asexual reproduction, the primary method of reproduction for the vast majority of macroscopic organisms, including almost all eukaryotes (which includes animals and plants).[23] However the origin and evolution of sexual reproduction remain a puzzle for biologists though it did evolve from a common ancestor that was a single celled eukaryotic species.[24] Bilateria, animals having a left and a right side that are mirror images of each other, appeared by 555 Ma (million years ago).[25]

Algae-like multicellular land plants are dated back even to about 1 billion years ago,[26] although evidence suggests that microorganisms formed the earliest terrestrial ecosystems, at least 2.7 Ga.[27] Microorganisms are thought to have paved the way for the inception of land plants in the Ordovician period. Land plants were so successful that they are thought to have contributed to the Late Devonian extinction event.[28] (The long causal chain implied seems to involve (1) the success of early tree archaeopteris drew down CO2 levels, leading to global cooling and lowered sea levels, (2) roots of archeopteris fostered soil development which increased rock weathering, and the subsequent nutrient run-off may have triggered algal blooms resulting in anoxic events which caused marine-life die-offs. Marine species were the primary victims of the Late Devonian extinction.)

Ediacara biota appear during the Ediacaran period,[29] while vertebrates, along with most other modern phyla originated about 525 Ma during the Cambrian explosion.[30] During the Permian period, synapsids, including the ancestors of mammals, dominated the land,[31] but most of this group became extinct in the Permian–Triassic extinction event 252 Ma.[32] During the recovery from this catastrophe, archosaurs became the most abundant land vertebrates;[33] one archosaur group, the dinosaurs, dominated the Jurassic and Cretaceous periods.[34] After the Cretaceous–Paleogene extinction event 66 Ma killed off the non-avian dinosaurs,[35] mammals increased rapidly in size and diversity.[36] Such mass extinctions may have accelerated evolution by providing opportunities for new groups of organisms to diversify.[37]

Earliest history of Earth

The oldest meteorite fragments found on Earth are about 4.54 billion years old; this, coupled primarily with the dating of ancient lead deposits, has put the estimated age of Earth at around that time.[40] The Moon has the same composition as Earth's crust but does not contain an iron-rich core like the Earth's. Many scientists think that about 40 million years after the formation of Earth, it collided with a body the size of Mars, throwing crust material into the orbit that formed the Moon. Another hypothesis is that the Earth and Moon started to coalesce at the same time but the Earth, having much stronger gravity than the early Moon, attracted almost all the iron particles in the area.[41]

Until 2001, the oldest rocks found on Earth were about 3.8 billion years old,[42][40] leading scientists to estimate that the Earth's surface had been molten until then. Accordingly, they named this part of Earth's history the Hadean.[43] However, analysis of zircons formed 4.4 Ga indicates that Earth's crust solidified about 100 million years after the planet's formation and that the planet quickly acquired oceans and an atmosphere, which may have been capable of supporting life.[44][45][46]

Evidence from the Moon indicates that from 4 to 3.8 Ga it suffered a Late Heavy Bombardment by debris that was left over from the formation of the Solar System, and the Earth should have experienced an even heavier bombardment due to its stronger gravity.[43][47] While there is no direct evidence of conditions on Earth 4 to 3.8 Ga, there is no reason to think that the Earth was not also affected by this late heavy bombardment.[48] This event may well have stripped away any previous atmosphere and oceans; in this case gases and water from comet impacts may have contributed to their replacement, although outgassing from volcanoes on Earth would have supplied at least half.[49] However, if subsurface microbial life had evolved by this point, it would have survived the bombardment.[50]

Earliest evidence for life on Earth

The earliest identified organisms were minute and relatively featureless, and their fossils look like small rods that are very difficult to tell apart from structures that arise through abiotic physical processes. The oldest undisputed evidence of life on Earth, interpreted as fossilized bacteria, dates to 3 Ga.[51] Other finds in rocks dated to about 3.5 Ga have been interpreted as bacteria,[52] with geochemical evidence also seeming to show the presence of life 3.8 Ga.[53] However, these analyses were closely scrutinized, and non-biological processes were found which could produce all of the "signatures of life" that had been reported.[54][55] While this does not prove that the structures found had a non-biological origin, they cannot be taken as clear evidence for the presence of life. Geochemical signatures from rocks deposited 3.4 Ga have been interpreted as evidence for life,[51][56] although these statements have not been thoroughly examined by critics.

Evidence for fossilized microorganisms considered to be 3.77 billion to 4.28 billion years old was found in the Nuvvuagittuq Greenstone Belt in Quebec, Canada,[16] although the evidence is disputed as inconclusive.[57]

Origins of life on Earth

Evolutionary tree showing the divergence of modern species from their common ancestor in the center.[58] The three domains are colored, with bacteria blue, archaea green, and eukaryotes red.

Biologists reason that all living organisms on Earth must share a single last universal ancestor, because it would be virtually impossible that two or more separate lineages could have independently developed the many complex biochemical mechanisms common to all living organisms.[59][60]

Independent emergence on Earth

Life on Earth is based on carbon and water. Carbon provides stable frameworks for complex chemicals and can be easily extracted from the environment, especially from carbon dioxide.[46] There is no other chemical element whose properties are similar enough to carbon's to be called an analogue; silicon, the element directly below carbon on the periodic table, does not form very many complex stable molecules, and because most of its compounds are water-insoluble and because silicon dioxide is a hard and abrasive solid in contrast to carbon dioxide at temperatures associated with living things, it would be more difficult for organisms to extract. The elements boron and phosphorus have more complex chemistries, but suffer from other limitations relative to carbon. Water is an excellent solvent and has two other useful properties: the fact that ice floats enables aquatic organisms to survive beneath it in winter; and its molecules have electrically negative and positive ends, which enables it to form a wider range of compounds than other solvents can. Other good solvents, such as ammonia, are liquid only at such low temperatures that chemical reactions may be too slow to sustain life, and lack water's other advantages.[61] Organisms based on alternative biochemistry may, however, be possible on other planets.[62]

Research on how life might have emerged from non-living chemicals focuses on three possible starting points: self-replication, an organism's ability to produce offspring that are very similar to itself; metabolism, its ability to feed and repair itself; and external cell membranes, which allow food to enter and waste products to leave, but exclude unwanted substances.[63] Research on abiogenesis still has a long way to go, since theoretical and empirical approaches are only beginning to make contact with each other.[64][65]

Replication first: RNA world

Even the simplest members of the three modern domains of life use DNA to record their "recipes" and a complex array of RNA and protein molecules to "read" these instructions and use them for growth, maintenance and self-replication. The discovery that some RNA molecules can catalyze both their own replication and the construction of proteins led to the hypothesis of earlier life-forms based entirely on RNA.[66] These ribozymes could have formed an RNA world in which there were individuals but no species, as mutations and horizontal gene transfers would have meant that offspring were likely to have different genomes from their parents, and evolution occurred at the level of genes rather than organisms.[67] RNA would later have been replaced by DNA, which can build longer, more stable genomes, strengthening heritability and expanding the capabilities of individual organisms.[67][68][69] Ribozymes remain as the main components of ribosomes, the "protein factories" in modern cells.[70] Evidence suggests the first RNA molecules formed on Earth prior to 4.17 Ga.[71]

Although short self-replicating RNA molecules have been artificially produced in laboratories,[72] doubts have been raised about whether natural non-biological synthesis of RNA is possible.[73] The earliest "ribozymes" may have been formed of simpler nucleic acids such as PNA, TNA or GNA, which would have been replaced later by RNA.[74][75]

In 2003, it was proposed that porous metal sulfide precipitates would assist RNA synthesis at about 100 °C (212 °F) and ocean-bottom pressures near hydrothermal vents. Under this hypothesis, lipid membranes would be the last major cell components to appear and, until then, the protocells would be confined to the pores.[76]

Metabolism first: Iron–sulfur world

A series of experiments starting in 1997 showed that early stages in the formation of proteins from inorganic materials including carbon monoxide and hydrogen sulfide could be achieved by using iron sulfide and nickel sulfide as catalysts. Most of the steps required temperatures of about 100 °C (212 °F) and moderate pressures, although one stage required 250 °C (482 °F) and a pressure equivalent to that found under 7 kilometres (4.3 mi) of rock. Hence it was suggested that self-sustaining synthesis of proteins could have occurred near hydrothermal vents.[77]

Membranes first: Lipid world

  = water-attracting heads of lipid molecules
  = water-repellent tails
Cross-section through a liposome

It has been suggested that double-walled "bubbles" of lipids like those that form the external membranes of cells may have been an essential first step.[78] Experiments that simulated the conditions of the early Earth have reported the formation of lipids, and these can spontaneously form liposomes, double-walled "bubbles," and then reproduce themselves.[46] Although they are not intrinsically information-carriers as nucleic acids are, they would be subject to natural selection for longevity and reproduction. Nucleic acids such as RNA might then have formed more easily within the liposomes than outside.[79]

The clay hypothesis

RNA is complex and there are doubts about whether it can be produced non-biologically in the wild.[73] Some clays, notably montmorillonite, have properties that make them plausible accelerators for the emergence of an RNA world: they grow by self-replication of their crystalline pattern; they are subject to an analogue of natural selection, as the clay "species" that grows fastest in a particular environment rapidly becomes dominant; and they can catalyze the formation of RNA molecules.[80] Although this idea has not become the scientific consensus, it still has active supporters.[81]

Research in 2003 reported that montmorillonite could also accelerate the conversion of fatty acids into "bubbles," and that the "bubbles" could encapsulate RNA attached to the clay. These "bubbles" can then grow by absorbing additional lipids and then divide. The formation of the earliest cells may have been aided by similar processes.[82]

A similar hypothesis presents self-replicating iron-rich clays as the progenitors of nucleotides, lipids and amino acids.[83]

Geothermal springs

Wet-dry cycles at geothermal springs are shown to solve the problem of hydrolysis and promote the polymerization and vesicle encapsulation of biopolymers.[84][85] The temperatures of geothermal springs are suitable for biomolecules.[86] Silica minerals and metal sulfides at these environments have photocatalytic properties to catalyze biomolecules. Solar UV exposure also promotes the synthesis of biomolecules like RNA nucleotides.[87][88] An analysis of hydrothermal veins at a 3.5 Gya geothermal spring setting were found to have elements required for the origin of life, which are potassium, boron, hydrogen, sulfur, phosphorus, zinc, nitrogen, and oxygen.[89] Mulkidjanian and colleagues find that such environments have identical ionic concentrations to the cytoplasm of modern cells.[87] Fatty acids in acidic or slightly alkaline geothermal springs assemble into vesicles after wet-dry cycles as there is a lower concentration of ionic solutes at geothermal springs since they are freshwater environments, in contrast to seawater which has a higher concentration of ionic solutes.[90] For organic compounds to be present at geothermal springs, they would have likely been transported by carbonaceous meteors. The molecules that fell from the meteors were then accumulated in geothermal springs. As for the evolutionary implications, freshwater heterotrophic cells that depended upon synthesized organic compounds later evolved photosynthesis because of the continuous exposure to sunlight as well as their cell walls with ion pumps to maintain their intracellular metabolism after they entered the oceans.[85]

Deep sea hydrothermal vents

Catalytic mineral particles at these environments likely catalyzed organic compounds.[91] Scientists simulated laboratory conditions that were identical to white smokers and successfully oligomerized RNA, measured to be 4 units long.[92] Another experiment that replicated conditions also similar white smokers, with phospholipids present resulted in the assembly of vesicles.[93] Exergonic reactions at hydrothermal vents are suggested to have been a source of free energy that promoted chemical reactions, synthesis of organic molecules, and are inducive to chemical gradients.[94] In small rock pore systems, membranous structures between alkaline seawater and the acidic ocean would be conducive to proton gradients.[95] Small mineral cavities or mineral gels could have been a compartment for abiogenic processes.[96][97] A genomic analysis supports this hypothesis as they found 355 genes that likely traced to LUCA upon 6.1 million sequenced prokaryotic genes. They reconstruct LUCA as a thermophilic anaerobe with a Wood-Ljungdahl pathway, implying an origin of life at white smokers.[98][99]

Life "seeded" from elsewhere

The Panspermia hypothesis does not explain how life arose originally, but simply examines the possibility of it coming from somewhere other than Earth. The idea that life on Earth was "seeded" from elsewhere in the Universe dates back at least to the Greek philosopher Anaximander in the sixth century BCE.[100] In the twentieth century it was proposed by the physical chemist Svante Arrhenius,[101] by the astronomers Fred Hoyle and Chandra Wickramasinghe,[102] and by molecular biologist Francis Crick and chemist Leslie Orgel.[103]

There are three main versions of the "seeded from elsewhere" hypothesis: from elsewhere in our Solar System via fragments knocked into space by a large meteor impact, in which case the most credible sources are Mars[104] and Venus;[105] by alien visitors, possibly as a result of accidental contamination by microorganisms that they brought with them;[103] and from outside the Solar System but by natural means.[101][104]

Experiments in low Earth orbit, such as EXOSTACK, have demonstrated that some microorganism spores can survive the shock of being catapulted into space and some can survive exposure to outer space radiation for at least 5.7 years.[106][107] Scientists are divided over the likelihood of life arising independently on Mars,[108] or on other planets in our galaxy.[104]

Environmental and evolutionary impact of microbial mats

Modern stromatolites in Shark Bay, Western Australia

Microbial mats are multi-layered, multi-species colonies of bacteria and other organisms that are generally only a few millimeters thick, but still contain a wide range of chemical environments, each of which favors a different set of microorganisms.[109] To some extent each mat forms its own food chain, as the by-products of each group of microorganisms generally serve as "food" for adjacent groups.[110]

Traces like Epibaion from the Ediacaran represent trace fossils of feeding and movement by members of the phylum proarticulata

Stromatolites are stubby pillars built as microorganisms in mats slowly migrate upwards to avoid being smothered by sediment deposited on them by water.[109] There has been vigorous debate about the validity of alleged stromatolite fossils from before 3 Ga,[111] with critics arguing that they could have been formed by non-biological processes.[54] In 2006, another find of stromatolites was reported from the same part of Australia, in rocks dated to 3.5 Ga.[112]

In modern underwater mats the top layer often consists of photosynthesizing cyanobacteria which create an oxygen-rich environment, while the bottom layer is oxygen-free and often dominated by hydrogen sulfide emitted by the organisms living there.[110] Oxygen is toxic to organisms that are not adapted to it, but greatly increases the metabolic efficiency of oxygen-adapted organisms;[113][114] oxygenic photosynthesis by bacteria in mats increased biological productivity by a factor of between 100 and 1,000. The source of hydrogen atoms used by oxygenic photosynthesis is water, which is much more plentiful than the geologically produced reducing agents required by the earlier non-oxygenic photosynthesis.[115] From this point onwards life itself produced significantly more of the resources it needed than did geochemical processes.[116]

Oxygen became a significant component of Earth's atmosphere about 2.4 Ga.[117] Although eukaryotes may have been present much earlier,[118][119] the oxygenation of the atmosphere was a prerequisite for the evolution of the most complex eukaryotic cells, from which all multicellular organisms are built.[120] The boundary between oxygen-rich and oxygen-free layers in microbial mats would have moved upwards when photosynthesis shut down overnight, and then downwards as it resumed on the next day. This would have created selection pressure for organisms in this intermediate zone to acquire the ability to tolerate and then to use oxygen, possibly via endosymbiosis, where one organism lives inside another and both of them benefit from their association.[18]

Cyanobacteria have the most complete biochemical "toolkits" of all the mat-forming organisms. Hence they are the most self-sufficient, well-adapted to strike out on their own both as floating mats and as the first of the phytoplankton, providing the basis of most marine food chains.[18]

Diversification of eukaryotes

Eukarya
Diaphoretickes

Archaeplastida (Land plants, green algae, red algae, and glaucophytes)

Hacrobia

SAR (Stramenopiles, Alveolata, and Rhizaria)

Excavata

Amorphea

Amoebozoa

Sulcozoa

Opisthokonta

Metazoa (Animals)

Fungi

One possible family tree of eukaryotes[121][122]

Chromatin, nucleus, endomembrane system, and mitochondria

Eukaryotes may have been present long before the oxygenation of the atmosphere,[118] but most modern eukaryotes require oxygen, which is used by their mitochondria to fuel the production of ATP, the internal energy supply of all known cells.[120] In the 1970s, a vigorous debate concluded that eukaryotes emerged as a result of a sequence of endosymbiosis between prokaryotes. For example: a predatory microorganism invaded a large prokaryote, probably an archaean, but instead of killing its prey, the attacker took up residence and evolved into mitochondria; one of these chimeras later tried to swallow a photosynthesizing cyanobacterium, but the victim survived inside the attacker and the new combination became the ancestor of plants; and so on. After each endosymbiosis, the partners eventually eliminated unproductive duplication of genetic functions by re-arranging their genomes, a process which sometimes involved transfer of genes between them.[123][124][125] Another hypothesis proposes that mitochondria were originally sulfur- or hydrogen-metabolising endosymbionts, and became oxygen-consumers later.[126] On the other hand, mitochondria might have been part of eukaryotes' original equipment.[127]

There is a debate about when eukaryotes first appeared: the presence of steranes in Australian shales may indicate eukaryotes at 2.7 Ga;[119] however, an analysis in 2008 concluded that these chemicals infiltrated the rocks less than 2.2 Ga and prove nothing about the origins of eukaryotes.[128] Fossils of the algae Grypania have been reported in 1.85 billion-year-old rocks (originally dated to 2.1 Ga but later revised[21]), indicating that eukaryotes with organelles had already evolved.[129] A diverse collection of fossil algae were found in rocks dated between 1.5 and 1.4 Ga.[130] The earliest known fossils of fungi date from 1.43 Ga.[131]

Plastids

Plastids, the superclass of organelles of which chloroplasts are the best-known exemplar, are thought to have originated from endosymbiotic cyanobacteria. The symbiosis evolved around 1.5 Ga and enabled eukaryotes to carry out oxygenic photosynthesis.[120] Three evolutionary lineages of photosynthetic plastids have since emerged: chloroplasts in green algae and plants, rhodoplasts in red algae and cyanelles in the glaucophytes.[132] Not long after this primary endosymbiosis of plastids, rhodoplasts and chloroplasts were passed down to other bikonts, establishing an eukaryotic assemblage of phytoplankton by the end of the Neoproterozoic Eon.

Sexual reproduction and multicellular organisms

Evolution of sexual reproduction

The defining characteristics of sexual reproduction in eukaryotes are meiosis and fertilization, resulting in genetic recombination, giving offspring 50% of their genes from each parent.[133] By contrast, in asexual reproduction there is no recombination, but occasional horizontal gene transfer. Bacteria also exchange DNA by bacterial conjugation, enabling the spread of resistance to antibiotics and other toxins, and the ability to utilize new metabolites.[134] However, conjugation is not a means of reproduction, and is not limited to members of the same species – there are cases where bacteria transfer DNA to plants and animals.[135]

On the other hand, bacterial transformation is clearly an adaptation for transfer of DNA between bacteria of the same species. This is a complex process involving the products of numerous bacterial genes and can be regarded as a bacterial form of sex.[136][137] This process occurs naturally in at least 67 prokaryotic species (in seven different phyla).[138] Sexual reproduction in eukaryotes may have evolved from bacterial transformation.[139]

The disadvantages of sexual reproduction are well-known: the genetic reshuffle of recombination may break up favorable combinations of genes; and since males do not directly increase the number of offspring in the next generation, an asexual population can out-breed and displace in as little as 50 generations a sexual population that is equal in every other respect.[133] Nevertheless, the great majority of animals, plants, fungi and protists reproduce sexually. There is strong evidence that sexual reproduction arose early in the history of eukaryotes and that the genes controlling it have changed very little since then.[140] How sexual reproduction evolved and survived is an unsolved puzzle.[141]

Horodyskia may have been an early metazoan,[21] or a colonial foraminiferan.[142] It apparently re-arranged itself into fewer but larger main masses as the sediment grew deeper round its base.[21]

The Red Queen hypothesis suggests that sexual reproduction provides protection against parasites, because it is easier for parasites to evolve means of overcoming the defenses of genetically identical clones than those of sexual species that present moving targets, and there is some experimental evidence for this. However, there is still doubt about whether it would explain the survival of sexual species if multiple similar clone species were present, as one of the clones may survive the attacks of parasites for long enough to out-breed the sexual species.[133] Furthermore, contrary to the expectations of the Red Queen hypothesis, Kathryn A. Hanley et al. found that the prevalence, abundance and mean intensity of mites was significantly higher in sexual geckos than in asexuals sharing the same habitat.[143] In addition, biologist Matthew Parker, after reviewing numerous genetic studies on plant disease resistance, failed to find a single example consistent with the concept that pathogens are the primary selective agent responsible for sexual reproduction in the host.[144]

Alexey Kondrashov's deterministic mutation hypothesis (DMH) assumes that each organism has more than one harmful mutation and the combined effects of these mutations are more harmful than the sum of the harm done by each individual mutation. If so, sexual recombination of genes will reduce the harm that bad mutations do to offspring and at the same time eliminate some bad mutations from the gene pool by isolating them in individuals that perish quickly because they have an above-average number of bad mutations. However, the evidence suggests that the DMH's assumptions are shaky because many species have on average less than one harmful mutation per individual and no species that has been investigated shows evidence of synergy between harmful mutations.[133]

The random nature of recombination causes the relative abundance of alternative traits to vary from one generation to another. This genetic drift is insufficient on its own to make sexual reproduction advantageous, but a combination of genetic drift and natural selection may be sufficient. When chance produces combinations of good traits, natural selection gives a large advantage to lineages in which these traits become genetically linked. On the other hand, the benefits of good traits are neutralized if they appear along with bad traits. Sexual recombination gives good traits the opportunities to become linked with other good traits, and mathematical models suggest this may be more than enough to offset the disadvantages of sexual reproduction.[141] Other combinations of hypotheses that are inadequate on their own are also being examined.[133]

The adaptive function of sex remains a major unresolved issue in biology. The competing models to explain it were reviewed by John A. Birdsell and Christopher Wills.[145] The hypotheses discussed above all depend on the possible beneficial effects of random genetic variation produced by genetic recombination. An alternative view is that sex arose and is maintained as a process for repairing DNA damage, and that the genetic variation produced is an occasionally beneficial byproduct.[139][146]

Multicellularity

The simplest definitions of "multicellular," for example "having multiple cells," could include colonial cyanobacteria like Nostoc. Even a technical definition such as "having the same genome but different types of cell" would still include some genera of the green algae Volvox, which have cells that specialize in reproduction.[147] Multicellularity evolved independently in organisms as diverse as sponges and other animals, fungi, plants, brown algae, cyanobacteria, slime molds and myxobacteria.[21][148] For the sake of brevity, this article focuses on the organisms that show the greatest specialization of cells and variety of cell types, although this approach to the evolution of biological complexity could be regarded as "rather anthropocentric."[22]

A slime mold solves a maze. The mold (yellow) explored and filled the maze (left). When the researchers placed sugar (red) at two separate points, the mold concentrated most of its mass there and left only the most efficient connection between the two points (right).[149]

The initial advantages of multicellularity may have included: more efficient sharing of nutrients that are digested outside the cell,[150] increased resistance to predators, many of which attacked by engulfing; the ability to resist currents by attaching to a firm surface; the ability to reach upwards to filter-feed or to obtain sunlight for photosynthesis;[151] the ability to create an internal environment that gives protection against the external one;[22] and even the opportunity for a group of cells to behave "intelligently" by sharing information.[149] These features would also have provided opportunities for other organisms to diversify, by creating more varied environments than flat microbial mats could.[151]

Multicellularity with differentiated cells is beneficial to the organism as a whole but disadvantageous from the point of view of individual cells, most of which lose the opportunity to reproduce themselves. In an asexual multicellular organism, rogue cells which retain the ability to reproduce may take over and reduce the organism to a mass of undifferentiated cells. Sexual reproduction eliminates such rogue cells from the next generation and therefore appears to be a prerequisite for complex multicellularity.[151]

The available evidence indicates that eukaryotes evolved much earlier but remained inconspicuous until a rapid diversification around 1 Ga. The only respect in which eukaryotes clearly surpass bacteria and archaea is their capacity for variety of forms, and sexual reproduction enabled eukaryotes to exploit that advantage by producing organisms with multiple cells that differed in form and function.[151]

By comparing the composition of transcription factor families and regulatory network motifs between unicellular organisms and multicellular organisms, scientists found there are many novel transcription factor families and three novel types of regulatory network motifs in multicellular organisms, and novel family transcription factors are preferentially wired into these novel network motifs which are essential for multicullular development. These results propose a plausible mechanism for the contribution of novel-family transcription factors and novel network motifs to the origin of multicellular organisms at transcriptional regulatory level.[152]

Fossil evidence

The Francevillian biota fossils, dated to 2.1 Ga, are the earliest known fossil organisms that are clearly multicellular.[39] They may have had differentiated cells.[153] Another early multicellular fossil, Qingshania, dated to 1.7 Ga, appears to consist of virtually identical cells. The red algae called Bangiomorpha, dated at 1.2 Ga, is the earliest known organism that certainly has differentiated, specialized cells, and is also the oldest known sexually reproducing organism.[151] The 1.43 billion-year-old fossils interpreted as fungi appear to have been multicellular with differentiated cells.[131] The "string of beads" organism Horodyskia, found in rocks dated from 1.5 Ga to 900 Ma, may have been an early metazoan;[21] however, it has also been interpreted as a colonial foraminiferan.[142]

Emergence of animals

   
   
   
   
Bilaterians
   

Deuterostomes (chordates, hemichordates, echinoderms)

Protostomes
   

Ecdysozoa (arthropods, nematodes, tardigrades, etc.)

   

Lophotrochozoa (molluscs, annelids, brachiopods, etc.)

   

Acoelomorpha

Cnidaria (jellyfish, sea anemones, corals)

Ctenophora (comb jellies)

Placozoa

Porifera (sponges): Calcarea

Porifera: Hexactinellida & Demospongiae

Choanoflagellata

Mesomycetozoea

A family tree of the animals[154]

Animals are multicellular eukaryotes,[note 1] and are distinguished from plants, algae, and fungi by lacking cell walls.[155] All animals are motile,[156] if only at certain life stages. All animals except sponges have bodies differentiated into separate tissues, including muscles, which move parts of the animal by contracting, and nerve tissue, which transmits and processes signals.[157] In November 2019, researchers reported the discovery of Caveasphaera, a multicellular organism found in 609-million-year-old rocks, that is not easily defined as an animal or non-animal, which may be related to one of the earliest instances of animal evolution.[158][159] Fossil studies of Caveasphaera have suggested that animal-like embryonic development arose much earlier than the oldest clearly defined animal fossils.[158] and may be consistent with studies suggesting that animal evolution may have begun about 750 million years ago.[159][160]

Nonetheless, the earliest widely accepted animal fossils are the rather modern-looking cnidarians (the group that includes jellyfish, sea anemones and Hydra), possibly from around 580 Ma, although fossils from the Doushantuo Formation can only be dated approximately. Their presence implies that the cnidarian and bilaterian lineages had already diverged.[161]

The Ediacara biota, which flourished for the last 40 million years before the start of the Cambrian,[162] were the first animals more than a very few centimetres long. Many were flat and had a "quilted" appearance, and seemed so strange that there was a proposal to classify them as a separate kingdom, Vendozoa.[163] Others, however, have been interpreted as early molluscs (Kimberella[164][165]), echinoderms (Arkarua[166]), and arthropods (Spriggina,[167] Parvancorina[168]). There is still debate about the classification of these specimens, mainly because the diagnostic features which allow taxonomists to classify more recent organisms, such as similarities to living organisms, are generally absent in the Ediacarans. However, there seems little doubt that Kimberella was at least a triploblastic bilaterian animal, in other words, an animal significantly more complex than the cnidarians.[169]

The small shelly fauna are a very mixed collection of fossils found between the Late Ediacaran and Middle Cambrian periods. The earliest, Cloudina, shows signs of successful defense against predation and may indicate the start of an evolutionary arms race. Some tiny Early Cambrian shells almost certainly belonged to molluscs, while the owners of some "armor plates," Halkieria and Microdictyon, were eventually identified when more complete specimens were found in Cambrian lagerstätten that preserved soft-bodied animals.[170]

Opabinia made the largest single contribution to modern interest in the Cambrian explosion.[171]

In the 1970s there was already a debate about whether the emergence of the modern phyla was "explosive" or gradual but hidden by the shortage of Precambrian animal fossils.[170] A re-analysis of fossils from the Burgess Shale lagerstätte increased interest in the issue when it revealed animals, such as Opabinia, which did not fit into any known phylum. At the time these were interpreted as evidence that the modern phyla had evolved very rapidly in the Cambrian explosion and that the Burgess Shale's "weird wonders" showed that the Early Cambrian was a uniquely experimental period of animal evolution.[172] Later discoveries of similar animals and the development of new theoretical approaches led to the conclusion that many of the "weird wonders" were evolutionary "aunts" or "cousins" of modern groups[173]—for example that Opabinia was a member of the lobopods, a group which includes the ancestors of the arthropods, and that it may have been closely related to the modern tardigrades.[174] Nevertheless, there is still much debate about whether the Cambrian explosion was really explosive and, if so, how and why it happened and why it appears unique in the history of animals.[175]

Deuterostomes and the first vertebrates

Acanthodians were among the earliest vertebrates with jaws.[176]

Most of the animals at the heart of the Cambrian explosion debate are protostomes, one of the two main groups of complex animals. The other major group, the deuterostomes, contains invertebrates such as starfish and sea urchins (echinoderms), as well as chordates (see below). Many echinoderms have hard calcite "shells," which are fairly common from the Early Cambrian small shelly fauna onwards.[170] Other deuterostome groups are soft-bodied, and most of the significant Cambrian deuterostome fossils come from the Chengjiang fauna, a lagerstätte in China.[177] The chordates are another major deuterostome group: animals with a distinct dorsal nerve cord. Chordates include soft-bodied invertebrates such as tunicates as well as vertebrates—animals with a backbone. While tunicate fossils predate the Cambrian explosion,[178] the Chengjiang fossils Haikouichthys and Myllokunmingia appear to be true vertebrates,[30] and Haikouichthys had distinct vertebrae, which may have been slightly mineralized.[179] Vertebrates with jaws, such as the acanthodians, first appeared in the Late Ordovician.[180]

Colonization of land

Adaptation to life on land is a major challenge: all land organisms need to avoid drying-out and all those above microscopic size must create special structures to withstand gravity; respiration and gas exchange systems have to change; reproductive systems cannot depend on water to carry eggs and sperm towards each other.[181][182][183] Although the earliest good evidence of land plants and animals dates back to the Ordovician period (488 to 444 Ma), and a number of microorganism lineages made it onto land much earlier,[184][185] modern land ecosystems only appeared in the Late Devonian, about 385 to 359 Ma.[186] In May 2017, evidence of the earliest known life on land may have been found in 3.48-billion-year-old geyserite and other related mineral deposits (often found around hot springs and geysers) uncovered in the Pilbara Craton of Western Australia.[187][188] In July 2018, scientists reported that the earliest life on land may have been bacteria living on land 3.22 billion years ago.[189] In May 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 were living on land.[190][191][192]

Evolution of terrestrial antioxidants

Oxygen began to accumulate in Earth's atmosphere over 3 Ga, as a by-product of photosynthesis in cyanobacteria (blue-green algae). However, oxygen produces destructive chemical oxydation which was toxic to most previous organisms. Protective endogenous antioxidant enzymes and exogenous dietary antioxidants helped to prevent oxidative damage. For example, brown algae accumulate inorganic mineral antioxidants such as rubidium, vanadium, zinc, iron, copper, molybdenum, selenium and iodine, concentrated more than 30,000 times more than in seawater. Most marine mineral antioxidants act in the cells as essential trace elements in redox and antioxidant metalloenzymes.

When plants and animals began to enter rivers and land about 500 Ma, environmental deficiency of these marine mineral antioxidants was a challenge to the evolution of terrestrial life.[193][194] Terrestrial plants slowly optimized the production of new endogenous antioxidants such as ascorbic acid, polyphenols, flavonoids, tocopherols, etc.

A few of these appeared more recently, in last 200–50 Ma, in fruits and flowers of angiosperm plants. In fact, angiosperms (the dominant type of plant today) and most of their antioxidant pigments evolved during the Late Jurassic period. Plants employ antioxidants to defend their structures against reactive oxygen species produced during photosynthesis. Animals are exposed to the same oxidants, and they have evolved endogenous enzymatic antioxidant systems.[195] Iodine in the form of the iodide ion I- is the most primitive and abundant electron-rich essential element in the diet of marine and terrestrial organisms; it acts as an electron donor and has this ancestral antioxidant function in all iodide-concentrating cells, from primitive marine algae to terrestrial vertebrates.[196]

Evolution of soil

Before the colonization of land there was no soil, a combination of mineral particles and decomposed organic matter. Land surfaces were either bare rock or shifting sand produced by weathering. Water and dissolved nutrients would have drained away very quickly.[186] In the Sub-Cambrian peneplain in Sweden, for example, maximum depth of kaolinitization by Neoproterozoic weathering is about 5 m, while nearby kaolin deposits developed in the Mesozoic are much thicker.[197] It has been argued that in the late Neoproterozoic sheet wash was a dominant process of erosion of surface material due to the lack of plants on land.[198]

Lichens growing on concrete

Films of cyanobacteria, which are not plants but use the same photosynthesis mechanisms, have been found in modern deserts in areas unsuitable for vascular plants. This suggests that microbial mats may have been the first organisms to colonize dry land, possibly in the Precambrian. Mat-forming cyanobacteria could have gradually evolved resistance to desiccation as they spread from the seas to intertidal zones and then to land.[186] Lichens, which are symbiotic combinations of a fungus (almost always an ascomycete) and one or more photosynthesizers (green algae or cyanobacteria),[199] are also important colonizers of lifeless environments,[186] and their ability to break down rocks contributes to soil formation where plants cannot survive.[199] The earliest known ascomycete fossils date from 423 to 419 Ma in the Silurian.[186]

Soil formation would have been very slow until the appearance of burrowing animals, which mix the mineral and organic components of soil and whose feces are a major source of organic components.[186] Burrows have been found in Ordovician sediments, and are attributed to annelids (worms) or arthropods.[186][200]

Plants and the Late Devonian wood crisis

Reconstruction of Cooksonia, a vascular plant from the Silurian
Fossilized trees from the Middle Devonian Gilboa Fossil Forest

In aquatic algae, almost all cells are capable of photosynthesis and are nearly independent. Life on land required plants to become internally more complex and specialized: photosynthesis is most efficient at the top; roots extract water and nutrients from the ground; and the intermediate parts support and transport.[181][201]

Spores of land plants resembling liverworts have been found in Middle Ordovician rocks from 476 Ma. Middle Silurian rocks from 430 Ma contain fossils of true plants, including clubmosses such as Baragwanathia; most were under 10 centimetres (3.9 in) high, and some appear closely related to vascular plants, the group that includes trees.[201]

By the Late Devonian 370 Ma, abundant trees such as Archaeopteris bound the soil so firmly that they changed river systems from mostly braided to mostly meandering.[202] This caused the "Late Devonian wood crisis" because:[203]

  • They removed more carbon dioxide from the atmosphere, reducing the greenhouse effect and thus causing an ice age in the Carboniferous period.[28] This did not repeat in later ecosystems, since the carbon dioxide "locked up" in wood was returned to the atmosphere by decomposition of dead wood, but the earliest fossil evidence of fungi that can decompose wood also comes from the Late Devonian.[204]
  • The increasing depth of plants' roots led to more washing of nutrients into rivers and seas by rain. This caused algal blooms whose high consumption of oxygen caused anoxic events in deeper waters, increasing the extinction rate among deep-water animals.[28]

Land invertebrates

Animals had to change their feeding and excretory systems, and most land animals developed internal fertilization of their eggs.[183] The difference in refractive index between water and air required changes in their eyes. On the other hand, in some ways movement and breathing became easier, and the better transmission of high-frequency sounds in air encouraged the development of hearing.[182]

The relative number of species contributed to the total by each phylum of animals. Nematoda is the phylum with the most individual organisms while arthropoda has the most species.

The oldest known air-breathing animal is Pneumodesmus, an archipolypodan millipede from the Middle Silurian, about 428 Ma.[205][206] Its air-breathing, terrestrial nature is evidenced by the presence of spiracles, the openings to tracheal systems.[207] However, some earlier trace fossils from the Cambrian-Ordovician boundary about 490 Ma are interpreted as the tracks of large amphibious arthropods on coastal sand dunes, and may have been made by euthycarcinoids,[208] which are thought to be evolutionary "aunts" of myriapods.[209] Other trace fossils from the Late Ordovician a little over 445 Ma probably represent land invertebrates, and there is clear evidence of numerous arthropods on coasts and alluvial plains shortly before the Silurian-Devonian boundary, about 415 Ma, including signs that some arthropods ate plants.[210] Arthropods were well pre-adapted to colonise land, because their existing jointed exoskeletons provided protection against desiccation, support against gravity and a means of locomotion that was not dependent on water.[183][211]

The fossil record of other major invertebrate groups on land is poor: none at all for non-parasitic flatworms, nematodes or nemerteans; some parasitic nematodes have been fossilized in amber; annelid worm fossils are known from the Carboniferous, but they may still have been aquatic animals; the earliest fossils of gastropods on land date from the Late Carboniferous, and this group may have had to wait until leaf litter became abundant enough to provide the moist conditions they need.[182]

The earliest confirmed fossils of flying insects date from the Late Carboniferous, but it is thought that insects developed the ability to fly in the Early Carboniferous or even Late Devonian. This gave them a wider range of ecological niches for feeding and breeding, and a means of escape from predators and from unfavorable changes in the environment.[212] About 99% of modern insect species fly or are descendants of flying species.[213]

Early land vertebrates

Acanthostega changed views about the early evolution of tetrapods.[214]
"Fish"

Osteolepiformes

Panderichthyidae

Obruchevichthidae

Acanthostega

Ichthyostega

Tulerpeton

Early labyrinthodonts

Anthracosauria

Amniotes

Family tree of tetrapods[215]

Tetrapods, vertebrates with four limbs, evolved from other rhipidistian fish over a relatively short timespan during the Late Devonian (370 to 360 Ma).[216] The early groups are grouped together as Labyrinthodontia. They retained aquatic, fry-like tadpoles, a system still seen in modern amphibians.

Iodine and T4/T3 stimulate the amphibian metamorphosis and the evolution of nervous systems transforming the aquatic, vegetarian tadpole into a "more evolved" terrestrial, carnivorous frog with better neurological, visuospatial, olfactory and cognitive abilities for hunting.[193] The new hormonal action of T3 was made possible by the formation of T3-receptors in the cells of vertebrates. Firstly, about 600-500 million years ago, in primitive Chordata appeared the alpha T3-receptors with a metamorphosing action and then, about 250-150 million years ago, in the Birds and Mammalia appeared the beta T3-receptors with metabolic and thermogenetic actions.[217]

From the 1950s to the early 1980s it was thought that tetrapods evolved from fish that had already acquired the ability to crawl on land, possibly in order to go from a pool that was drying out to one that was deeper. However, in 1987, nearly complete fossils of Acanthostega from about 363 Ma showed that this Late Devonian transitional animal had legs and both lungs and gills, but could never have survived on land: its limbs and its wrist and ankle joints were too weak to bear its weight; its ribs were too short to prevent its lungs from being squeezed flat by its weight; its fish-like tail fin would have been damaged by dragging on the ground. The current hypothesis is that Acanthostega, which was about 1 metre (3.3 ft) long, was a wholly aquatic predator that hunted in shallow water. Its skeleton differed from that of most fish, in ways that enabled it to raise its head to breathe air while its body remained submerged, including: its jaws show modifications that would have enabled it to gulp air; the bones at the back of its skull are locked together, providing strong attachment points for muscles that raised its head; the head is not joined to the shoulder girdle and it has a distinct neck.[214]

The Devonian proliferation of land plants may help to explain why air breathing would have been an advantage: leaves falling into streams and rivers would have encouraged the growth of aquatic vegetation; this would have attracted grazing invertebrates and small fish that preyed on them; they would have been attractive prey but the environment was unsuitable for the big marine predatory fish; air-breathing would have been necessary because these waters would have been short of oxygen, since warm water holds less dissolved oxygen than cooler marine water and since the decomposition of vegetation would have used some of the oxygen.[214]

Later discoveries revealed earlier transitional forms between Acanthostega and completely fish-like animals.[218] Unfortunately, there is then a gap (Romer's gap) of about 30 Ma between the fossils of ancestral tetrapods and Middle Carboniferous fossils of vertebrates that look well-adapted for life on land, during which only some fossils are found, which had five digits in the terminating point of the four limbs, showing true or crown tetrapods appeared in the gap around 350 Ma. Some of the fossils after this gap look as if the animals which they belonged to were early relatives of modern amphibians, all of which need to keep their skins moist and to lay their eggs in water, while others are accepted as early relatives of the amniotes, whose waterproof skin and egg membranes enable them to live and breed far from water.[215] The Carboniferous Rainforest Collapse may have paved the way for amniotes to become dominant over amphibians.

Dinosaurs, birds and mammals

Amniotes
Synapsids

Early synapsids (extinct)

Pelycosaurs

Extinct pelycosaurs

Therapsids

Extinct therapsids

Mammaliaformes
   

Extinct mammaliaforms

   

Mammals

Sauropsids

Anapsids; whether turtles belong here is debated[219]

   

Captorhinidae and Protorothyrididae (extinct)

Diapsids

Araeoscelidia (extinct)

   
   

Squamata (lizards and snakes)

Archosaurs

Extinct archosaurs

Crocodilians

   

Pterosaurs (extinct)

Dinosaurs
Theropods
   

Extinct
theropods

   

Birds

Sauropods
(extinct)

   

Ornithischians (extinct)

Possible family tree of dinosaurs, birds and mammals[220][221]

Amniotes, whose eggs can survive in dry environments, probably evolved in the Late Carboniferous period (330 to 298.9 Ma). The earliest fossils of the two surviving amniote groups, synapsids and sauropsids, date from around 313 Ma.[220][221] The synapsid pelycosaurs and their descendants the therapsids are the most common land vertebrates in the best-known Permian (298.9 to 251.902 Ma) fossil beds. However, at the time these were all in temperate zones at middle latitudes, and there is evidence that hotter, drier environments nearer the Equator were dominated by sauropsids and amphibians.[222]

The Permian–Triassic extinction event wiped out almost all land vertebrates,[223] as well as the great majority of other life.[224] During the slow recovery from this catastrophe, estimated to have taken 30 million years,[225] a previously obscure sauropsid group became the most abundant and diverse terrestrial vertebrates: a few fossils of archosauriformes ("ruling lizard forms") have been found in Late Permian rocks,[226] but, by the Middle Triassic, archosaurs were the dominant land vertebrates. Dinosaurs distinguished themselves from other archosaurs in the Late Triassic, and became the dominant land vertebrates of the Jurassic and Cretaceous periods (201.3 to 66 Ma).[227]

During the Late Jurassic, birds evolved from small, predatory theropod dinosaurs.[228] The first birds inherited teeth and long, bony tails from their dinosaur ancestors,[228] but some had developed horny, toothless beaks by the very Late Jurassic[229] and short pygostyle tails by the Early Cretaceous.[230]

While the archosaurs and dinosaurs were becoming more dominant in the Triassic, the mammaliaform successors of the therapsids evolved into small, mainly nocturnal insectivores. This ecological role may have promoted the evolution of mammals, for example nocturnal life may have accelerated the development of endothermy ("warm-bloodedness") and hair or fur.[231] By 195 Ma in the Early Jurassic there were animals that were very like today's mammals in a number of respects.[232] Unfortunately, there is a gap in the fossil record throughout the Middle Jurassic.[233] However, fossil teeth discovered in Madagascar indicate that the split between the lineage leading to monotremes and the one leading to other living mammals had occurred by 167 Ma.[234] After dominating land vertebrate niches for about 150 Ma, the non-avian dinosaurs perished in the Cretaceous–Paleogene extinction event (66 Ma) along with many other groups of organisms.[235] Mammals throughout the time of the dinosaurs had been restricted to a narrow range of taxa, sizes and shapes, but increased rapidly in size and diversity after the extinction,[236][237] with bats taking to the air within 13 million years,[238] and cetaceans to the sea within 15 million years.[239]

Flowering plants

Gymnosperms

Gnetales
(gymnosperm)

Welwitschia
(gymnosperm)

Ephedra
(gymnosperm)

Bennettitales

Angiosperms
(flowering plants)

One possible family tree of flowering plants[240]
Gymnosperms

Angiosperms
(flowering plants)

Cycads
(gymnosperm)

Bennettitales

Ginkgo

Gnetales
(gymnosperm)

Conifers
(gymnosperm)

Another possible family tree[241]

The first flowering plants appeared around 130 Ma.[242] The 250,000 to 400,000 species of flowering plants outnumber all other ground plants combined, and are the dominant vegetation in most terrestrial ecosystems. There is fossil evidence that flowering plants diversified rapidly in the Early Cretaceous, from 130 to 90 Ma,[240][241] and that their rise was associated with that of pollinating insects.[241] Among modern flowering plants Magnolia are thought to be close to the common ancestor of the group.[240] However, paleontologists have not succeeded in identifying the earliest stages in the evolution of flowering plants.[240][241]

Social insects

These termite mounds have survived a bush fire.

The social insects are remarkable because the great majority of individuals in each colony are sterile. This appears contrary to basic concepts of evolution such as natural selection and the selfish gene. In fact, there are very few eusocial insect species: only 15 out of approximately 2,600 living families of insects contain eusocial species, and it seems that eusociality has evolved independently only 12 times among arthropods, although some eusocial lineages have diversified into several families. Nevertheless, social insects have been spectacularly successful; for example although ants and termites account for only about 2% of known insect species, they form over 50% of the total mass of insects. Their ability to control a territory appears to be the foundation of their success.[243]

The sacrifice of breeding opportunities by most individuals has long been explained as a consequence of these species' unusual haplodiploid method of sex determination, which has the paradoxical consequence that two sterile worker daughters of the same queen share more genes with each other than they would with their offspring if they could breed.[244] However, E. O. Wilson and Bert Hölldobler argue that this explanation is faulty: for example, it is based on kin selection, but there is no evidence of nepotism in colonies that have multiple queens. Instead, they write, eusociality evolves only in species that are under strong pressure from predators and competitors, but in environments where it is possible to build "fortresses"; after colonies have established this security, they gain other advantages through co-operative foraging. In support of this explanation they cite the appearance of eusociality in bathyergid mole rats,[243] which are not haplodiploid.[245]

The earliest fossils of insects have been found in Early Devonian rocks from about 400 Ma, which preserve only a few varieties of flightless insect. The Mazon Creek lagerstätten from the Late Carboniferous, about 300 Ma, include about 200 species, some gigantic by modern standards, and indicate that insects had occupied their main modern ecological niches as herbivores, detritivores and insectivores. Social termites and ants first appear in the Early Cretaceous, and advanced social bees have been found in Late Cretaceous rocks but did not become abundant until the Middle Cenozoic.[246]

Humans

The idea that, along with other life forms, modern-day humans evolved from an ancient, common ancestor was proposed by Robert Chambers in 1844 and taken up by Charles Darwin in 1871.[247] Modern humans evolved from a lineage of upright-walking apes that has been traced back over 6 Ma to Sahelanthropus.[248] The first known stone tools were made about 2.5 Ma, apparently by Australopithecus garhi, and were found near animal bones that bear scratches made by these tools.[249] The earliest hominines had chimpanzee-sized brains, but there has been a fourfold increase in the last 3 Ma; a statistical analysis suggests that hominine brain sizes depend almost completely on the date of the fossils, while the species to which they are assigned has only slight influence.[250] There is a long-running debate about whether modern humans evolved all over the world simultaneously from existing advanced hominines or are descendants of a single small population in Africa, which then migrated all over the world less than 200,000 years ago and replaced previous hominine species.[251] There is also debate about whether anatomically modern humans had an intellectual, cultural and technological "Great Leap Forward" under 100,000 years ago and, if so, whether this was due to neurological changes that are not visible in fossils.[252]

Mass extinctions

Marine extinction intensity during the Phanerozoic
%
Millions of years ago
(H)
Cap
Apparent extinction intensity, i.e. the fraction of genera going extinct at any given time, as reconstructed from the fossil record. (Graph not meant to include the recent, ongoing Holocene extinction event).

Life on Earth has suffered occasional mass extinctions at least since 542 Ma. Although they were disasters at the time, mass extinctions have sometimes accelerated the evolution of life on Earth. When dominance of particular ecological niches passes from one group of organisms to another, it is rarely because the new dominant group is "superior" to the old and usually because an extinction event eliminates the old dominant group and makes way for the new one.[37][253]

All genera
"Well-defined" genera
Trend line
"Big Five" mass extinctions
Other mass extinctions
Million years ago
Thousands of genera
Phanerozoic biodiversity as shown by the fossil record

The fossil record appears to show that the gaps between mass extinctions are becoming longer and the average and background rates of extinction are decreasing. Both of these phenomena could be explained in one or more ways:[254]

  • The oceans may have become more hospitable to life over the last 500 Ma and less vulnerable to mass extinctions: dissolved oxygen became more widespread and penetrated to greater depths; the development of life on land reduced the run-off of nutrients and hence the risk of eutrophication and anoxic events; and marine ecosystems became more diversified so that food chains were less likely to be disrupted.[255][256]
  • Reasonably complete fossils are very rare, most extinct organisms are represented only by partial fossils, and complete fossils are rarest in the oldest rocks. So paleontologists have mistakenly assigned parts of the same organism to different genera, which were often defined solely to accommodate these finds—the story of Anomalocaris is an example of this. The risk of this mistake is higher for older fossils because these are often both unlike parts of any living organism and poorly conserved. Many of the "superfluous" genera are represented by fragments which are not found again and the "superfluous" genera appear to become extinct very quickly.[254]

Biodiversity in the fossil record, which is "...the number of distinct genera alive at any given time; that is, those whose first occurrence predates and whose last occurrence postdates that time"[257] shows a different trend: a fairly swift rise from 542 to 400 Ma; a slight decline from 400 to 200 Ma, in which the devastating Permian–Triassic extinction event is an important factor; and a swift rise from 200 Ma to the present.[257]

See also

Footnotes

  1. Myxozoa were thought to be an exception, but are now thought to be heavily modified members of the Cnidaria. Jímenez-Guri, Eva; Philippe, Hervé; Okamura, Beth; et al. (July 6, 2007). "Buddenbrockia Is a Cnidarian Worm". Science. 317 (5834): 116–118. Bibcode:2007Sci...317..116J. doi:10.1126/science.1142024. ISSN 0036-8075. PMID 17615357. S2CID 5170702.

References

  1. Pearce, Ben K.D.; Tupper, Andrew S.; Pudritz, Ralph E.; et al. (March 1, 2018). "Constraining the Time Interval for the Origin of Life on Earth". Astrobiology. 18 (3): 343–364. arXiv:1808.09460. Bibcode:2018AsBio..18..343P. doi:10.1089/ast.2017.1674. ISSN 1531-1074. PMID 29570409. S2CID 4419671.
  2. Rosing, Minik T. (January 29, 1999). "13C-Depleted Carbon Microparticles in >3700-Ma Sea-Floor Sedimentary Rocks from West Greenland". Science. 283 (5402): 674–676. Bibcode:1999Sci...283..674R. doi:10.1126/science.283.5402.674. ISSN 0036-8075. PMID 9924024.
  3. 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.
  4. Papineau, Dominic; De Gregorio, Bradley T.; Cody, George D.; et al. (June 2011). "Young poorly crystalline graphite in the >3.8-Gyr-old Nuvvuagittuq banded iron formation". Nature Geoscience. 4 (6): 376–379. Bibcode:2011NatGe...4..376P. doi:10.1038/ngeo1155. ISSN 1752-0894.
  5. Bell, Elizabeth A.; Boehnke, Patrick; Harrison, T. Mark; et al. (November 24, 2015). "Potentially biogenic carbon preserved in a 4.1 billion-year-old zircon" (PDF). Proceedings of the National Academy of Sciences. 112 (47): 14518–14521. Bibcode:2015PNAS..11214518B. doi:10.1073/pnas.1517557112. ISSN 0027-8424. PMC 4664351. PMID 26483481. Archived (PDF) from the original on 2020-02-13. Retrieved 2020-02-14.
  6. Nemchin, Alexander A.; Whitehouse, Martin J.; Menneken, Martina; et al. (July 3, 2008). "A light carbon reservoir recorded in zircon-hosted diamond from the Jack Hills". Nature. 454 (7200): 92–95. Bibcode:2008Natur.454...92N. doi:10.1038/nature07102. ISSN 0028-0836. PMID 18596808. S2CID 4415308.
  7. Futuyma 2005
  8. Dybas, Cheryl; Fryling, Kevin (May 2, 2016). "Researchers find that Earth may be home to 1 trillion species" (Press release). Alexandria, VA: National Science Foundation. News Release 16-052. Archived from the original on 2016-05-04. Retrieved 2016-12-11.
  9. Chapman 2009.
  10. Novacek, Michael J. (November 8, 2014). "Prehistory's Brilliant Future". Sunday Review. The New York Times. New York. ISSN 0362-4331. Archived from the original on 2014-11-10. Retrieved 2014-12-25. "A version of this article appears in print on Nov. 9, 2014, Section SR, Page 6 of the New York edition with the headline: Prehistory's Brilliant Future."
  11. "Catalogue of Life: 2019 Annual Checklist". Species 2000; Integrated Taxonomic Information System. 2019. Retrieved 2020-02-16.
  12. McKinney 1997, p. 110.
  13. Stearns & Stearns 1999, p. x.
  14. Nutman, Allen P.; Bennett, Vickie C.; Friend, Clark R.L.; et al. (September 22, 2016). "Rapid emergence of life shown by discovery of 3,700-million-year-old microbial structures" (PDF). Nature. 537 (7621): 535–538. Bibcode:2016Natur.537..535N. doi:10.1038/nature19355. ISSN 0028-0836. PMID 27580034. S2CID 205250494. Archived from the original on 2020-01-02. Retrieved 2020-02-17.
  15. Borenstein, Seth (October 19, 2015). "Hints of life on what was thought to be desolate early Earth". Associated Press. Archived from the original on 2018-07-12. Retrieved 2020-02-17.
  16. Dodd, Matthew S.; Papineau, Dominic; Grenne, Tor; et al. (March 2, 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. ISSN 0028-0836. PMID 28252057. S2CID 2420384. Archived (PDF) from the original on 2020-02-13. Retrieved 2020-02-18.
  17. Zimmer, Carl (March 1, 2017). "Scientists Say Canadian Bacteria Fossils May Be Earth's Oldest". Matter. The New York Times. New York. ISSN 0362-4331. Archived from the original on 2020-01-04. Retrieved 2017-03-02. "A version of this article appears in print on March 2, 2017, Section A, Page 9 of the New York edition with the headline: Artful Squiggles in Rocks May Be Earth's Oldest Fossils."
  18. Nisbet, Euan G.; Fowler, C.M.R. (December 7, 1999). "Archaean metabolic evolution of microbial mats". Proceedings of the Royal Society B. 266 (1436): 2375–2382. doi:10.1098/rspb.1999.0934. ISSN 0962-8452. PMC 1690475.
  19. Anbar, Ariel D.; Yun, Duan; Lyons, Timothy W.; et al. (September 28, 2007). "A Whiff of Oxygen Before the Great Oxidation Event?". Science. 317 (5846): 1903–1906. Bibcode:2007Sci...317.1903A. doi:10.1126/science.1140325. ISSN 0036-8075. PMID 17901330. S2CID 25260892.
  20. Knoll, Andrew H.; Javaux, Emmanuelle J.; Hewitt, David; et al. (June 29, 2006). "Eukaryotic organisms in Proterozoic oceans". Philosophical Transactions of the Royal Society B. 361 (1470): 1023–1038. doi:10.1098/rstb.2006.1843. ISSN 0962-8436. PMC 1578724. PMID 16754612.
  21. Fedonkin, Mikhail A. (March 31, 2003). "The origin of the Metazoa in the light of the Proterozoic fossil record" (PDF). Paleontological Research. 7 (1): 9–41. doi:10.2517/prpsj.7.9. ISSN 1342-8144. S2CID 55178329. Archived from the original (PDF) on 2009-02-26. Retrieved 2008-09-02.
  22. Bonner, John Tyler (January 7, 1998). "The origins of multicellularity". Integrative Biology. 1 (1): 27–36. doi:10.1002/(SICI)1520-6602(1998)1:1<27::AID-INBI4>3.0.CO;2-6. ISSN 1757-9694.
  23. Otto, Sarah P.; Lenormand, Thomas (April 1, 2002). "Resolving the paradox of sex and recombination". Nature Reviews Genetics. 3 (4): 252–261. doi:10.1038/nrg761. ISSN 1471-0056. PMID 11967550. S2CID 13502795.
  24. Letunic, Ivica; Bork, Peer. "iTOL: Interactive Tree of Life". Heidelberg, Germany: European Molecular Biology Laboratory. Retrieved 2015-07-21.
  25. Fedonkin, Mikhail A.; Simonetta, Alberto; Ivantsov, Andrei Yu. (January 1, 2007). "New data on Kimberella, the Vendian mollusc-like organism (White Sea region, Russia): palaeoecological and evolutionary implications" (PDF). Geological Society Special Publications. 286 (1): 157–179. Bibcode:2007GSLSP.286..157F. doi:10.1144/SP286.12. ISSN 0375-6440. S2CID 331187. Archived (PDF) from the original on 2017-08-11. Retrieved 2020-02-18.
  26. Strother, Paul K.; Battison, Leila; Brasier, Martin D.; et al. (May 26, 2011). "Earth's earliest non-marine eukaryotes". Nature. 473 (7348): 505–509. Bibcode:2011Natur.473..505S. doi:10.1038/nature09943. ISSN 0028-0836. PMID 21490597. S2CID 4418860.
  27. Beraldi-Campesi, Hugo (February 23, 2013). "Early life on land and the first terrestrial ecosystems". Ecological Processes. 2 (1): 1–17. doi:10.1186/2192-1709-2-1. ISSN 2192-1709.
  28. Algeo, Thomas J.; Scheckler, Stephen E. (January 29, 1998). "Terrestrial-marine teleconnections in the Devonian: links between the evolution of land plants, weathering processes, and marine anoxic events". Philosophical Transactions of the Royal Society B. 353 (1365): 113–130. doi:10.1098/rstb.1998.0195. ISSN 0962-8436. PMC 1692181.
  29. Jun-Yuan, Chen; Oliveri, Paola; Chia-Wei, Li; et al. (April 25, 2000). "Precambrian animal diversity: Putative phosphatized embryos from the Doushantuo Formation of China". Proc. Natl. Acad. Sci. U.S.A. 97 (9): 4457–4462. Bibcode:2000PNAS...97.4457C. doi:10.1073/pnas.97.9.4457. ISSN 0027-8424. PMC 18256. PMID 10781044.
  30. D-G., Shu; H-L., Luo; Conway Morris, Simon; et al. (November 4, 1999). "Lower Cambrian vertebrates from south China" (PDF). Nature. 402 (6757): 42–46. Bibcode:1999Natur.402...42S. doi:10.1038/46965. ISSN 0028-0836. S2CID 4402854. Archived from the original (PDF) on 2009-02-26. Retrieved 2015-01-22.
  31. Hoyt, Donald F. (February 17, 1997). "Synapsid Reptiles". ZOO 138 Vertebrate Zoology (Lecture). Pomona, CA: California State Polytechnic University, Pomona. Archived from the original on 2009-05-20. Retrieved 2015-01-22.
  32. Barry, Patrick L. (January 28, 2002). Phillips, Tony (ed.). "The Great Dying". Science@NASA. Marshall Space Flight Center. Archived from the original on 2010-04-10. Retrieved 2015-01-22.
  33. Tanner, Lawrence H.; Lucas, Spencer G.; Chapman, Mary G. (March 2004). "Assessing the record and causes of Late Triassic extinctions" (PDF). Earth-Science Reviews. 65 (1–2): 103–139. Bibcode:2004ESRv...65..103T. doi:10.1016/S0012-8252(03)00082-5. Archived from the original (PDF) on 2007-10-25. Retrieved 2007-10-22.
  34. Benton 1997
  35. Fastovsky, David E.; Sheehan, Peter M. (March 2005). "The Extinction of the Dinosaurs in North America" (PDF). GSA Today. 15 (3): 4–10. doi:10.1130/1052-5173(2005)015<4:TEOTDI>2.0.CO;2. ISSN 1052-5173. Archived (PDF) from the original on 2019-03-22. Retrieved 2015-01-23.
  36. Roach, John (June 20, 2007). "Dinosaur Extinction Spurred Rise of Modern Mammals". National Geographic News. Washington, D.C.: National Geographic Society. Archived from the original on 2008-05-11. Retrieved 2020-02-21.
  37. Van Valkenburgh, Blaire (May 1, 1999). "Major Patterns in the History of Carnivorous Mammals". Annual Review of Earth and Planetary Sciences. 27: 463–493. Bibcode:1999AREPS..27..463V. doi:10.1146/annurev.earth.27.1.463. ISSN 1545-4495.
  38. Erwin, Douglas H. (December 19, 2015). "Early metazoan life: divergence, environment and ecology". Philosophical Transactions of the Royal Society B. 370 (1684). doi:10.1098/rstb.2015.0036. ISSN 0962-8436. PMC 4650120. PMID 26554036. Article 20150036.
  39. El Albani, Abderrazak; Bengtson, Stefan; Canfield, Donald E.; et al. (July 1, 2010). "Large colonial organisms with coordinated growth in oxygenated environments 2.1 Gyr ago". Nature. 466 (7302): 100–104. Bibcode:2010Natur.466..100A. doi:10.1038/nature09166. ISSN 0028-0836. PMID 20596019. S2CID 4331375.
  40. Dalrymple 1991
  41. Galimov, Erik M.; Krivtsov, Anton M. (December 2005). "Origin of the Earth—Moon system". Journal of Earth System Science. 114 (6): 593–600. Bibcode:2005JESS..114..593G. CiteSeerX 10.1.1.502.314. doi:10.1007/BF02715942. ISSN 0253-4126. S2CID 56094186. Retrieved 2020-02-22.
  42. Thompson, Andrea (September 25, 2008). "Oldest Rocks on Earth Found". Live Science. Watsonville, CA: Imaginova. Retrieved 2015-01-23.
  43. Cohen, Barbara A.; Swindle, Timothy D.; Kring, David A. (December 1, 2000). "Support for the Lunar Cataclysm Hypothesis from Lunar Meteorite Impact Melt Ages". Science. 290 (5497): 1754–1756. Bibcode:2000Sci...290.1754C. doi:10.1126/science.290.5497.1754. ISSN 0036-8075. PMID 11099411.
  44. "Early Earth Likely Had Continents And Was Habitable" (Press release). Boulder, CO: University of Colorado. November 17, 2005. Archived from the original on 2015-01-24. Retrieved 2015-01-23.
  45. Cavosie, Aaron J.; Valley, John W.; Wilde, Simon A.; Edinburgh Ion Microprobe Facility (July 15, 2005). "Magmatic δ18O in 4400–3900 Ma detrital zircons: A record of the alteration and recycling of crust in the Early Archean". Earth and Planetary Science Letters. 235 (3–4): 663–681. Bibcode:2005E&PSL.235..663C. doi:10.1016/j.epsl.2005.04.028. ISSN 0012-821X.
  46. Garwood, Russell J. (2012). "Patterns In Palaeontology: The first 3 billion years of evolution". Palaeontology Online. 2 (Article 11): 1–14. Archived from the original on 2012-12-09. Retrieved 2020-02-25.
  47. Britt, Robert Roy (July 24, 2002). "Evidence for Ancient Bombardment of Earth". Space.com. Watsonville, CA: Imaginova. Archived from the original on 2006-04-15. Retrieved 2015-01-23.
  48. Valley, John W.; Peck, William H.; King, Elizabeth M.; et al. (April 1, 2002). "A cool early Earth" (PDF). Geology. 30 (4): 351–354. Bibcode:2002Geo....30..351V. doi:10.1130/0091-7613(2002)030<0351:ACEE>2.0.CO;2. ISSN 0091-7613. PMID 16196254. Retrieved 2008-09-13.
  49. Dauphas, Nicolas; Robert, François; Marty, Bernard (December 2000). "The Late Asteroidal and Cometary Bombardment of Earth as Recorded in Water Deuterium to Protium Ratio". Icarus. 148 (2): 508–512. Bibcode:2000Icar..148..508D. doi:10.1006/icar.2000.6489. ISSN 0019-1035.
  50. Scalice, Daniella (May 20, 2009). Fletcher, Julie (ed.). "Microbial Habitability During the Late Heavy Bombardment". Astrobiology. Mountain View, CA: NASA Astrobiology Program. Archived from the original on 2015-01-24. Retrieved 2020-02-25.
  51. Brasier, Martin; McLoughlin, Nicola; Green, Owen; et al. (June 2006). "A fresh look at the fossil evidence for early Archaean cellular life" (PDF). Philosophical Transactions of the Royal Society B. 361 (1470): 887–902. doi:10.1098/rstb.2006.1835. ISSN 0962-8436. PMC 1578727. PMID 16754605. Archived (PDF) from the original on 2007-07-30. Retrieved 2008-08-30.
  52. Schopf, J. William (April 30, 1993). "Microfossils of the Early Archean Apex Chert: New Evidence of the Antiquity of Life". Science. 260 (5108): 640–646. Bibcode:1993Sci...260..640S. doi:10.1126/science.260.5108.640. ISSN 0036-8075. PMID 11539831. S2CID 2109914.
  53. Mojzsis, Stephen J.; Arrhenius, Gustaf; McKeegan, Kevin D.; et al. (November 7, 1996). "Evidence for life on Earth before 3,800 million years ago". Nature. 384 (6604): 55–59. Bibcode:1996Natur.384...55M. doi:10.1038/384055a0. hdl:2060/19980037618. ISSN 0028-0836. PMID 8900275. S2CID 4342620.
  54. Grotzinger, John P.; Rothman, Daniel H. (October 3, 1996). "An abiotic model for stromatolite morphogenesis". Nature. 383 (6599): 423–425. Bibcode:1996Natur.383..423G. doi:10.1038/383423a0. ISSN 0028-0836. S2CID 4325802.
  55. Fedo, Christopher M.; Whitehouse, Martin J. (May 24, 2002). "Metasomatic Origin of Quartz-Pyroxene Rock, Akilia, Greenland, and Implications for Earth's Earliest Life". Science. 296 (5572): 1448–1452. Bibcode:2002Sci...296.1448F. doi:10.1126/science.1070336. ISSN 0036-8075. PMID 12029129. S2CID 10367088.
  56. Schopf, J. William (June 29, 2006). "Fossil evidence of Archaean life". Philosophical Transactions of the Royal Society B. 361 (1470): 869–885. doi:10.1098/rstb.2006.1834. ISSN 0962-8436. PMC 1578735. PMID 16754604.
  57. Drake, Nadia (March 1, 2017). "This May Be the Oldest Known Sign of Life on Earth". National Geographic News. Washington, D.C.: National Geographic Society. Archived from the original on 2019-10-23. Retrieved 2020-02-26.
  58. Ciccarelli, Francesca D.; Doerks, Tobias; von Mering, Christian; et al. (March 3, 2006). "Toward Automatic Reconstruction of a Highly Resolved Tree of Life" (PDF). Science. 311 (5765): 1283–1287. Bibcode:2006Sci...311.1283C. CiteSeerX 10.1.1.381.9514. doi:10.1126/science.1123061. PMID 16513982. S2CID 1615592. Archived from the original (PDF) on 2007-08-24.
  59. Mason, Stephen F. (September 6, 1984). "Origins of biomolecular handedness". Nature. 311 (5981): 19–23. Bibcode:1984Natur.311...19M. doi:10.1038/311019a0. ISSN 0028-0836. PMID 6472461. S2CID 103653.
  60. Orgel, Leslie E. (October 1994). "The Origin of Life on the Earth" (PDF). Scientific American. Vol. 271, no. 4. pp. 76–83. Bibcode:1994SciAm.271d..76O. doi:10.1038/scientificamerican1094-76. ISSN 0036-8733. PMID 7524147. Archived from the original on 2001-01-24. Retrieved 2008-08-30.
  61. Bennett 2008, pp. 82–85
  62. Schulze-Makuch, Dirk; Irwin, Louis N. (April 2006). "The prospect of alien life in exotic forms on other worlds". Naturwissenschaften. 93 (4): 155–172. Bibcode:2006NW.....93..155S. doi:10.1007/s00114-005-0078-6. ISSN 0028-1042. PMID 16525788. S2CID 3207913.
  63. Peretó, Juli (March 2005). "Controversies on the origin of life" (PDF). International Microbiology. 8 (1): 23–31. ISSN 1139-6709. PMID 15906258. Archived from the original (PDF) on 2007-06-04. Retrieved 2007-10-07.
  64. Szathmáry, Eörs (February 3, 2005). "In search of the simplest cell". Nature. 433 (7025): 469–470. Bibcode:2005Natur.433..469S. doi:10.1038/433469a. ISSN 0028-0836. PMID 15690023. S2CID 4360797.
  65. Luisi, Pier Luigi; Ferri, Francesca; Stano, Pasquale (January 2006). "Approaches to semi-synthetic minimal cells: a review". Naturwissenschaften. 93 (1): 1–13. Bibcode:2006NW.....93....1L. doi:10.1007/s00114-005-0056-z. ISSN 0028-1042. PMID 16292523. S2CID 16567006.
  66. Joyce, Gerald F. (July 11, 2002). "The antiquity of RNA-based evolution". Nature. 418 (6894): 214–221. Bibcode:2002Natur.418..214J. doi:10.1038/418214a. ISSN 0028-0836. PMID 12110897. S2CID 4331004.
  67. Hoenigsberg, Hugo (December 30, 2003). "Evolution without speciation but with selection: LUCA, the Last Universal Common Ancestor in Gilbert's RNA world". Genetics and Molecular Research. 2 (4): 366–375. ISSN 1676-5680. PMID 15011140. Archived from the original on 2004-06-02. Retrieved 2008-08-30.
  68. Trevors, Jack T.; Abel, David L. (November 2004). "Chance and necessity do not explain the origin of life". Cell Biology International. 28 (11): 729–739. doi:10.1016/j.cellbi.2004.06.006. ISSN 1065-6995. PMID 15563395. S2CID 30633352.
  69. Forterre, Patrick; Benachenhou-Lahfa, Nadia; Confalonieri, Fabrice; et al. (1992). Adoutte, André; Perasso, Roland (eds.). "The nature of the last universal ancestor and the root of the tree of life, still open questions". BioSystems. 28 (1–3): 15–32. doi:10.1016/0303-2647(92)90004-I. ISSN 0303-2647. PMID 1337989. Part of a special issue: 9th Meeting of the International Society for Evolutionary Protistology, July 3–7, 1992, Orsay, France.
  70. Cech, Thomas R. (August 11, 2000). "The Ribosome Is a Ribozyme". Science. 289 (5481): 878–879. doi:10.1126/science.289.5481.878. ISSN 0036-8075. PMID 10960319. S2CID 24172338.
  71. Pearce, Ben K. D.; Pudritz, Ralph E.; Semenov, Dmitry A.; et al. (October 24, 2017). "Origin of the RNA world: The fate of nucleobases in warm little ponds". Proceedings of the National Academy of Sciences. 114 (43): 11327–11332. arXiv:1710.00434. Bibcode:2017PNAS..11411327P. doi:10.1073/pnas.1710339114. ISSN 0027-8424. PMC 5664528. PMID 28973920.
  72. Johnston, Wendy K.; Unrau, Peter J.; Lawrence, Michael S.; et al. (May 18, 2001). "RNA-Catalyzed RNA Polymerization: Accurate and General RNA-Templated Primer Extension" (PDF). Science. 292 (5520): 1319–1325. Bibcode:2001Sci...292.1319J. CiteSeerX 10.1.1.70.5439. doi:10.1126/science.1060786. ISSN 0036-8075. PMID 11358999. S2CID 14174984. Archived (PDF) from the original on 2006-09-09.
  73. Levy, Matthew; Miller, Stanley L. (July 7, 1998). "The stability of the RNA bases: Implications for the origin of life". Proc. Natl. Acad. Sci. U.S.A. 95 (14): 7933–7938. Bibcode:1998PNAS...95.7933L. doi:10.1073/pnas.95.14.7933. ISSN 0027-8424. PMC 20907. PMID 9653118.
  74. Orgel, Leslie E. (November 17, 2000). "A Simpler Nucleic Acid". Science. 290 (5495): 1306–1307. doi:10.1126/science.290.5495.1306. ISSN 0036-8075. PMID 11185405. S2CID 83662769.
  75. Nelson, Kevin E.; Levy, Matthew; Miller, Stanley L. (April 11, 2000). "Peptide nucleic acids rather than RNA may have been the first genetic molecule". Proc. Natl. Acad. Sci. U.S.A. 97 (8): 3868–3871. Bibcode:2000PNAS...97.3868N. doi:10.1073/pnas.97.8.3868. ISSN 0027-8424. PMC 18108. PMID 10760258.
  76. Martin, William; Russell, Michael J. (January 29, 2003). "On the origins of cells: a hypothesis for the evolutionary transitions from abiotic geochemistry to chemoautotrophic prokaryotes, and from prokaryotes to nucleated cells". Philosophical Transactions of the Royal Society B. 358 (1429): 59–85. doi:10.1098/rstb.2002.1183. ISSN 0962-8436. PMC 1693102. PMID 12594918.
  77. Wächtershäuser, Günter (August 25, 2000). "Life as We Don't Know It". Science. 289 (5483): 1307–1308. doi:10.1126/science.289.5483.1307. ISSN 0036-8075. PMID 10979855. S2CID 170713742.
  78. Trevors, Jack T.; Psenner, Roland (December 2001). "From self-assembly of life to present-day bacteria: a possible role for nanocells". FEMS Microbiology Reviews. 25 (5): 573–582. doi:10.1111/j.1574-6976.2001.tb00592.x. ISSN 0168-6445. PMID 11742692.
  79. Segré, Daniel; Ben-Eli, Dafna; Deamer, David W.; et al. (February 2001). "The Lipid World" (PDF). Origins of Life and Evolution of Biospheres. 31 (1–2): 119–145. Bibcode:2001OLEB...31..119S. doi:10.1023/A:1006746807104. ISSN 0169-6149. PMID 11296516. S2CID 10959497. Archived (PDF) from the original on 2015-06-26. Retrieved 2020-02-28.
  80. Cairns-Smith 1968, pp. 57–66
  81. Ferris, James P. (June 1999). "Prebiotic Synthesis on Minerals: Bridging the Prebiotic and RNA Worlds". The Biological Bulletin. 196 (3): 311–314. doi:10.2307/1542957. ISSN 0006-3185. JSTOR 1542957. PMID 10390828. "This paper was originally presented at a workshop titled Evolution: A Molecular Point of View."
  82. Hanczyc, Martin M.; Fujikawa, Shelly M.; Szostak, Jack W. (October 24, 2003). "Experimental Models of Primitive Cellular Compartments: Encapsulation, Growth, and Division". Science. 302 (5645): 618–622. Bibcode:2003Sci...302..618H. doi:10.1126/science.1089904. ISSN 0036-8075. PMC 4484575. PMID 14576428.
  83. Hartman, Hyman (October 1998). "Photosynthesis and the Origin of Life". Origins of Life and Evolution of Biospheres. 28 (4–6): 512–521. Bibcode:1998OLEB...28..515H. doi:10.1023/A:1006548904157. ISSN 0169-6149. PMID 11536891. S2CID 2464.
  84. Deamer, David (February 10, 2021). "Where Did Life Begin? Testing Ideas in Prebiotic Analogue Conditions". Life. 11 (2): 134. doi:10.3390/life11020134. ISSN 2075-1729. PMC 7916457. PMID 33578711.
  85. Damer, Bruce; Deamer, David (2020-04-01). "The Hot Spring Hypothesis for an Origin of Life". Astrobiology. 20 (4): 429–452. Bibcode:2020AsBio..20..429D. doi:10.1089/ast.2019.2045. ISSN 1531-1074. PMC 7133448. PMID 31841362.
  86. Des Marais, David J.; Walter, Malcolm R. (2019-12-01). "Terrestrial Hot Spring Systems: Introduction". Astrobiology. 19 (12): 1419–1432. Bibcode:2019AsBio..19.1419D. doi:10.1089/ast.2018.1976. ISSN 1531-1074. PMC 6918855. PMID 31424278.
  87. Mulkidjanian, Armen Y.; Bychkov, Andrew Yu.; Dibrova, Daria V.; Galperin, Michael Y.; Koonin, Eugene V. (2012-04-03). "Origin of first cells at terrestrial, anoxic geothermal fields". Proceedings of the National Academy of Sciences. 109 (14): E821-30. doi:10.1073/pnas.1117774109. ISSN 0027-8424. PMC 3325685. PMID 22331915.
  88. Patel, Bhavesh H.; Percivalle, Claudia; Ritson, Dougal J.; Duffy, Colm D.; Sutherland, John D. (March 16, 2015). "Common origins of RNA, protein and lipid precursors in a cyanosulfidic protometabolism". Nature Chemistry. 7 (4): 301–307. Bibcode:2015NatCh...7..301P. doi:10.1038/nchem.2202. ISSN 1755-4349. PMC 4568310. PMID 25803468.
  89. Van Kranendonk, Martin J.; Baumgartner, Raphael; Djokic, Tara; Ota, Tsutomu; Steller, Luke; Garbe, Ulf; Nakamura, Eizo (2021-01-01). "Elements for the Origin of Life on Land: A Deep-Time Perspective from the Pilbara Craton of Western Australia". Astrobiology. 21 (1): 39–59. Bibcode:2021AsBio..21...39V. doi:10.1089/ast.2019.2107. ISSN 1531-1074. PMID 33404294. S2CID 230783184.
  90. Milshteyn, Daniel; Damer, Bruce; Havig, Jeff; Deamer, David (2018-05-10). "Amphiphilic Compounds Assemble into Membranous Vesicles in Hydrothermal Hot Spring Water but Not in Seawater". Life. 8 (2): 11. doi:10.3390/life8020011. ISSN 2075-1729. PMC 6027054. PMID 29748464.
  91. "Origin of life: Chemistry of seabed's hot vents could explain emergence of life". ScienceDaily. Retrieved 2022-10-07.
  92. Burcar, Bradley T.; Barge, Laura M.; Trail, Dustin; Watson, E. Bruce; Russell, Michael J.; McGown, Linda B. (2015-07-01). "RNA Oligomerization in Laboratory Analogues of Alkaline Hydrothermal Vent Systems". Astrobiology. 15 (7): 509–522. Bibcode:2015AsBio..15..509B. doi:10.1089/ast.2014.1280. ISSN 1531-1074. PMID 26154881.
  93. Jordan, Sean F.; Rammu, Hanadi; Zheludev, Ivan N.; Hartley, Andrew M.; Maréchal, Amandine; Lane, Nick (November 4, 2019). "Promotion of protocell self-assembly from mixed amphiphiles at the origin of life" (PDF). Nature Ecology & Evolution. 3 (12): 1705–1714. doi:10.1038/s41559-019-1015-y. ISSN 2397-334X. PMID 31686020. S2CID 207891212.
  94. Colín-García, María; Heredia, Alejandro; Cordero, Guadalupe; Camprubí, Antoni; Negrón-Mendoza, Alicia; Ortega-Gutiérrez, Fernando; Beraldi, Hugo; Ramos-Bernal, Sergio (2016). "Hydrothermal vents and prebiotic chemistry: a review". Boletín de la Sociedad Geológica Mexicana. Retrieved 2022-10-07.
  95. Lane, Nick; Allen, John F.; Martin, William (2010-01-27). "How did LUCA make a living? Chemiosmosis in the origin of life". BioEssays. 32 (4): 271–280. doi:10.1002/bies.200900131. PMID 20108228.
  96. Westall, F.; Hickman-Lewis, K.; Hinman, N.; Gautret, P.; Campbell, K.a.; Bréhéret, J.g.; Foucher, F.; Hubert, A.; Sorieul, S.; Dass, A.v.; Kee, T.p.; Georgelin, T.; Brack, A. (2018-03-01). "A Hydrothermal-Sedimentary Context for the Origin of Life". Astrobiology. 18 (3): 259–293. Bibcode:2018AsBio..18..259W. doi:10.1089/ast.2017.1680. ISSN 1531-1074. PMC 5867533. PMID 29489386.
  97. Lane, Nick; Martin, William F. (2012-12-21). "The Origin of Membrane Bioenergetics". Cell. 151 (7): 1406–1416. doi:10.1016/j.cell.2012.11.050. ISSN 0092-8674. PMID 23260134. S2CID 15028935.
  98. Weiss, Madeline C.; Sousa, Filipa L.; Mrnjavac, Natalia; Neukirchen, Sinje; Roettger, Mayo; Nelson-Sathi, Shijulal; Martin, William F. (2016-07-25). "The physiology and habitat of the last universal common ancestor" (PDF). Nature Microbiology. 1 (9): 16116. doi:10.1038/nmicrobiol.2016.116. ISSN 2058-5276. PMID 27562259. S2CID 2997255.
  99. Weiss, Madeline C.; Preiner, Martina; Xavier, Joana C.; Zimorski, Verena; Martin, William F. (2018-08-16). "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. ISSN 1553-7404. PMC 6095482. PMID 30114187.
  100. O'Leary 2008
  101. Arrhenius 1980, p. 32
  102. Hoyle, Fred; Wickramasinghe, Nalin C. (November 1979). "On the Nature of Interstellar Grains". Astrophysics and Space Science. 66 (1): 77–90. Bibcode:1979Ap&SS..66...77H. doi:10.1007/BF00648361. ISSN 0004-640X. S2CID 115165958.
  103. Crick, Francis H.; Orgel, Leslie E. (July 1973). "Directed Panspermia". Icarus. 19 (3): 341–346. Bibcode:1973Icar...19..341C. doi:10.1016/0019-1035(73)90110-3. ISSN 0019-1035.
  104. Warmflash, David; Weiss, Benjamin (November 2005). "Did Life Come From Another World?". Scientific American. Vol. 293, no. 5. pp. 64–71. Bibcode:2005SciAm.293e..64W. doi:10.1038/scientificamerican1105-64. ISSN 0036-8733. PMID 16318028.
  105. Wickramasinghe, Nalin C.; Wickramasinghe, Janaki T. (September 2008). "On the possibility of microbiota transfer from Venus to Earth". Astrophysics and Space Science. 317 (1–2): 133–137. Bibcode:2008Ap&SS.317..133W. CiteSeerX 10.1.1.470.2347. doi:10.1007/s10509-008-9851-2. ISSN 0004-640X. S2CID 14623053.
  106. Clancy, Brack & Horneck 2005
  107. Horneck, Gerda; Klaus, David M.; Mancinelli, Rocco L. (March 2010). "Space Microbiology". Microbiology and Molecular Biology Reviews. 74 (1): 121–156. Bibcode:2010MMBR...74..121H. doi:10.1128/mmbr.00016-09. PMC 2832349. PMID 20197502.
  108. Than, Ker (August 23, 2007). "Claim of Martian Life Called 'Bogus'". Space.com. Watsonville, CA: Imaginova. Archived from the original on 2011-05-08. Retrieved 2015-01-25.
  109. Krumbein et al. 2003, pp. 1–28
  110. Risatti, J. Bruno; Capman, William C.; Stahl, David A. (October 11, 1994). "Community structure of a microbial mat: The phylogenetic dimension". Proc. Natl. Acad. Sci. U.S.A. 91 (21): 10173–10177. Bibcode:1994PNAS...9110173R. doi:10.1073/pnas.91.21.10173. ISSN 0027-8424. PMC 44980. PMID 7937858.
  111. "Biodiversity rocks". Nature (Editor's summary). 441 (7094). June 8, 2006. ISSN 0028-0836. Archived from the original on 2006-06-19. Retrieved 2020-03-03.
  112. Allwood, Abigail C.; Walter, Malcolm R.; Kamber, Balz S.; et al. (June 8, 2006). "Stromatolite reef from the Early Archaean era of Australia". Nature. 441 (7094): 714–718. Bibcode:2006Natur.441..714A. doi:10.1038/nature04764. ISSN 0028-0836. PMID 16760969. S2CID 4417746.
  113. Abele, Doris (November 7, 2002). "Toxic oxygen: The radical life-giver" (PDF). Nature. 420 (6911): 27. Bibcode:2002Natur.420...27A. doi:10.1038/420027a. ISSN 0028-0836. PMID 12422197. S2CID 4317378. Retrieved 2020-03-03.
  114. Westerdahl, Becky B. (2007). "Introduction to Aerobic Respiration". Biological Science 10V (Lecture). Davis, CA: University of California, Davis. Archived from the original on 2007-10-29. Retrieved 2008-07-14.
  115. Blankenship, Robert E. (January 1, 2001). "Molecular evidence for the evolution of photosynthesis". Trends in Plant Science. 6 (1): 4–6. doi:10.1016/S1360-1385(00)01831-8. PMID 11164357.
  116. Hoehler, Tori M.; Bebout, Brad M.; Des Marais, David J. (July 19, 2001). "The role of microbial mats in the production of reduced gases on the early Earth". Nature. 412 (6844): 324–327. Bibcode:2001Natur.412..324H. doi:10.1038/35085554. ISSN 0028-0836. PMID 11460161. S2CID 4365775.
  117. Goldblatt, Colin; Lenton, Timothy M.; Watson, Andrew J. (2006). "The Great Oxidation at ~2.4 Ga as a bistability in atmospheric oxygen due to UV shielding by ozone" (PDF). Geophysical Research Abstracts. 8 (770). ISSN 1029-7006. SRef-ID: 1607-7962/gra/EGU06-A-00770. Archived (PDF) from the original on 2007-09-26. Retrieved 2020-03-05.
  118. Glansdorff, Nicolas; Ying, Xu; Labedan, Bernard (July 9, 2008). "The Last Universal Common Ancestor: emergence, constitution and genetic legacy of an elusive forerunner". Biology Direct. 3 (29): 29. doi:10.1186/1745-6150-3-29. ISSN 1745-6150. PMC 2478661. PMID 18613974.
  119. Brocks, Jochen J.; Logan, Graham A.; Buick, Roger; et al. (August 13, 1999). "Archean Molecular Fossils and the Early Rise of Eukaryotes". Science. 285 (5430): 1033–1036. Bibcode:1999Sci...285.1033B. CiteSeerX 10.1.1.516.9123. doi:10.1126/science.285.5430.1033. ISSN 0036-8075. PMID 10446042.
  120. Hedges, S. Blair; Blair, Jaime E.; Venturi, Maria L.; et al. (January 28, 2004). "A molecular timescale of eukaryote evolution and the rise of complex multicellular life". BMC Evolutionary Biology. 4: 2. doi:10.1186/1471-2148-4-2. ISSN 1471-2148. PMC 341452. PMID 15005799.
  121. Adl, Sina M.; Simpson, Alastair G.B.; Lane, Christopher E.; et al. (September 2012). "The revised classification of eukaryotes" (PDF). Journal of Eukaryotic Microbiology. 59 (5): 429–514. doi:10.1111/j.1550-7408.2012.00644.x. ISSN 1066-5234. PMC 3483872. PMID 23020233. Archived from the original (PDF) on 2013-12-16. Retrieved 2020-03-06.
  122. Burki, Fabien (May 2014). "The Eukaryotic Tree of Life from a Global Phylogenomic Perspective". Cold Spring Harbor Perspectives in Biology. 6 (5): a016147. doi:10.1101/cshperspect.a016147. ISSN 1943-0264. PMC 3996474. PMID 24789819.
  123. Margulis 1981
  124. Vellai, Tibor; Vida, Gábor (August 7, 1999). "The origin of eukaryotes: the difference between prokaryotic and eukaryotic cells". Proceedings of the Royal Society B. 266 (1428): 1571–1577. doi:10.1098/rspb.1999.0817. ISSN 0962-8452. PMC 1690172. PMID 10467746.
  125. Selosse, Marc-André; Abert, Béatrice; Godelle, Bernard (March 1, 2001). "Reducing the genome size of organelles favours gene transfer to the nucleus". Trends in Ecology & Evolution. 16 (3): 135–141. doi:10.1016/S0169-5347(00)02084-X. ISSN 0169-5347. PMID 11179577.
  126. Pisani, Davide; Cotton, James A.; McInerney, James O. (August 2007). "Supertrees Disentangle the Chimerical Origin of Eukaryotic Genomes". Molecular Biology and Evolution. 24 (8): 1752–1760. doi:10.1093/molbev/msm095. ISSN 0737-4038. PMID 17504772.
  127. Gray, Michael W.; Burger, Gertraud; Lang, B. Franz (March 5, 1999). "Mitochondrial Evolution". Science. 283 (5407): 1476–1481. Bibcode:1999Sci...283.1476G. doi:10.1126/science.283.5407.1476. ISSN 0036-8075. PMC 3428767. PMID 10066161.
  128. Rasmussen, Birger; Fletcher, Ian R.; Brocks, Jochen J.; et al. (October 23, 2008). "Reassessing the first appearance of eukaryotes and cyanobacteria". Nature. 455 (7216): 1101–1104. Bibcode:2008Natur.455.1101R. doi:10.1038/nature07381. ISSN 0028-0836. PMID 18948954. S2CID 4372071.
  129. Tsu-Ming, Han; Runnegar, Bruce (July 10, 1992). "Megascopic eukaryotic algae from the 2.1-billion-year-old negaunee iron-formation, Michigan". Science. 257 (5067): 232–235. Bibcode:1992Sci...257..232H. doi:10.1126/science.1631544. ISSN 0036-8075. PMID 1631544.
  130. Javaux, Emmanuelle J.; Knoll, Andrew H.; Walter, Malcolm R. (July 2004). "TEM evidence for eukaryotic diversity in mid-Proterozoic oceans". Geobiology. 2 (3): 121–132. doi:10.1111/j.1472-4677.2004.00027.x. ISSN 1472-4677. S2CID 53600639.
  131. Butterfield, Nicholas J. (Winter 2005). "Probable Proterozoic fungi". Paleobiology. 31 (1): 165–182. doi:10.1666/0094-8373(2005)031<0165:PPF>2.0.CO;2. ISSN 0094-8373. S2CID 86332371. Archived from the original on 2018-12-23. Retrieved 2020-03-10.
  132. Wise, Robert R. (2006). "1. The Diversity of Plastid Form and Function". Advances in Photosynthesis and Respiration. Vol. 23. Springer. pp. 3–26. doi:10.1007/978-1-4020-4061-0_1. ISBN 978-1-4020-4060-3.
  133. Neiman, Maurine; Jokela, Jukka (2010). "Sex: Advantage". Encyclopedia of Life Sciences. Hoboken, NJ: John Wiley & Sons. doi:10.1002/9780470015902.a0001716.pub2. ISBN 978-0-470-01617-6.
  134. Holmes & Jobling 1996
  135. Christie, Peter J. (April 2001). "Type IV secretion: intercellular transfer of macromolecules by systems ancestrally related to conjugation machines". Molecular Microbiology. 40 (2): 294–305. doi:10.1046/j.1365-2958.2001.02302.x. ISSN 0950-382X. PMC 3922410. PMID 11309113.
  136. Michod, Richard E.; Bernstein, Harris; Nedelcu, Aurora M. (May 2008). "Adaptive value of sex in microbial pathogens" (PDF). Infection, Genetics and Evolution. 8 (3): 267–285. doi:10.1016/j.meegid.2008.01.002. ISSN 1567-1348. PMID 18295550.
  137. Bernstein, Harris; Bernstein, Carol (July 2010). "Evolutionary Origin of Recombination during Meiosis". BioScience. 60 (7): 498–505. doi:10.1525/bio.2010.60.7.5. ISSN 0006-3568. S2CID 86663600.
  138. Johnsborg, Ola; Eldholm, Vegard; Håvarstein, Leiv Sigve (December 2007). "Natural genetic transformation: prevalence, mechanisms and function". Research in Microbiology. 158 (10): 767–778. doi:10.1016/j.resmic.2007.09.004. ISSN 0923-2508. PMID 17997281.
  139. Bernstein, Bernstein & Michod 2012, pp. 1–50
  140. Ramesh, Marilee A.; Malik, Shehre-Banoo; Logsdon, John M. Jr. (January 26, 2005). "A Phylogenomic Inventory of Meiotic Genes: Evidence for Sex in Giardia and an Early Eukaryotic Origin of Meiosis". Current Biology. 15 (2): 185–191. doi:10.1016/j.cub.2005.01.003. ISSN 0960-9822. PMID 15668177. S2CID 17013247.
  141. Otto, Sarah P.; Gerstein, Aleeza C. (August 2006). "Why have sex? The population genetics of sex and recombination". Biochemical Society Transactions. 34 (4): 519–522. doi:10.1042/BST0340519. ISSN 0300-5127. PMID 16856849.
  142. Lin Dong; Shuhai Xiao; Bing Shen; et al. (January 1, 2008). "Silicified Horodyskia and Palaeopascichnus from upper Ediacaran cherts in South China: tentative phylogenetic interpretation and implications for evolutionary stasis". Journal of the Geological Society. 165 (1): 367–378. Bibcode:2008JGSoc.165..367D. doi:10.1144/0016-76492007-074. ISSN 0016-7649. S2CID 129309037.
  143. Hanley, Kathryn A.; Fisher, Robert N.; Case, Ted J. (June 1995). "Lower Mite Infestations in an Asexual Gecko Compared With Its Sexual Ancestors". Evolution. 49 (3): 418–426. doi:10.2307/2410266. ISSN 0014-3820. JSTOR 2410266. PMID 28565091.
  144. Parker, Matthew A. (September 1994). "Pathogens and sex in plants". Evolutionary Ecology. 8 (5): 560–584. doi:10.1007/bf01238258. ISSN 0269-7653. S2CID 31756267.
  145. Birdsell & Wills 2003, pp. 27–137
  146. Bernstein, Hopf & Michod 1987, pp. 323–370
  147. Bell, Graham; Mooers, Arne O. (March 1997). "Size and complexity among multicellular organisms" (PDF). Biological Journal of the Linnean Society. 60 (3): 345–363. doi:10.1111/j.1095-8312.1997.tb01500.x. ISSN 0024-4066. Retrieved 2015-02-02.
  148. Kaiser, Dale (December 2001). "Building a Multicellular Organism". Annual Review of Genetics. 35: 103–123. doi:10.1146/annurev.genet.35.102401.090145. ISSN 0066-4197. PMID 11700279.
  149. Nakagaki, Toshiyuki; Yamada, Hiroyasu; Tóth, Ágota (September 28, 2000). "Maze-solving by an amoeboid organism". Nature. 407 (6803): 470. Bibcode:2000Natur.407..470N. doi:10.1038/35035159. ISSN 0028-0836. PMID 11028990. S2CID 205009141.
  150. Koschwanez, John H.; Foster, Kevin R.; Murray, Andrew W. (August 9, 2011). "Sucrose Utilization in Budding Yeast as a Model for the Origin of Undifferentiated Multicellularity". PLOS Biology. 9 (8): e1001122. doi:10.1371/journal.pbio.1001122. ISSN 1544-9173. PMC 3153487. PMID 21857801.
  151. Butterfield, Nicholas J. (Summer 2000). "Bangiomorpha pubescens n. gen., n. sp.: implications for the evolution of sex, multicellularity, and the Mesoproterozoic/Neoproterozoic radiation of eukaryotes". Paleobiology. 26 (3): 386–404. doi:10.1666/0094-8373(2000)026<0386:BPNGNS>2.0.CO;2. ISSN 0094-8373. S2CID 36648568. Retrieved 2015-02-01.
  152. Jinpu, Jin; Kun, He; Xing, Tang; et al. (July 2015). "An Arabidopsis transcriptional regulatory map reveals distinct functional and evolutionary features of novel transcription factors". Molecular Biology and Evolution. 32 (7): 1767–1773. doi:10.1093/molbev/msv058. ISSN 0737-4038. PMC 4476157. PMID 25750178.
  153. Dickey, Gwyneth (July 31, 2010). "Evidence for earlier multicellular life" (PNG). Science News. Vol. 178, no. 3. p. 17. doi:10.1002/scin.5591780322. ISSN 0036-8423. Retrieved 2015-02-02.
  154. Gaidos, Eric J.; Dubuc, Timothy; Dunford, Mike; et al. (December 2007). "The Precambrian emergence of animal life: a geobiological perspective". Geobiology. 5 (4): 351–373. doi:10.1111/j.1472-4669.2007.00125.x. ISSN 1472-4677. S2CID 85934803.
  155. Davidson, Michael W. (May 26, 2005). "Animal Cell Structure". Molecular Expressions. Tallahassee, FL: Florida State University. Retrieved 2008-09-03.
  156. Saupe, Stephen G. (January 3, 2004). "Concepts of Biology". Concepts of Biology (BIOL116) (Lecture). St. Joseph, MN: College of Saint Benedict and Saint John's University. Retrieved 2008-09-03.
  157. Hinde 2001, pp. 28–57
  158. Chen, Xiaozheng (November 27, 2019). "Researchers say animal-like embryos preceded animal appearance" (Press release). American Association for the Advancement of Science. EurekAlert!. Archived from the original on 2019-11-28. Retrieved 2019-11-28.
  159. Zimmer, Carl (27 November 2019). "Is This the First Fossil of an Embryo? - Mysterious 609-million-year-old balls of cells may be the oldest animal embryos — or something else entirely". Matter. The New York Times. New York. ISSN 0362-4331. Retrieved 28 November 2019.
  160. Cunningham, John A.; Liu, Alexander G.; Bengtson, Stefan; et al. (January 2017). "The origin of animals: Can molecular clocks and the fossil record be reconciled?". BioEssays. 39 (1): e201600120. doi:10.1002/bies.201600120. ISSN 0265-9247. PMID 27918074.
  161. Jun-Yuan, Chen; Oliveri, Paola; Feng, Gao; et al. (August 1, 2002). "Precambrian Animal Life: Probable Developmental and Adult Cnidarian Forms from Southwest China" (PDF). Developmental Biology. 248 (1): 182–196. doi:10.1006/dbio.2002.0714. ISSN 0012-1606. PMID 12142030. Archived from the original (PDF) on May 26, 2013. Retrieved 2015-02-04.
  162. Grazhdankin, Dima (June 2004). "Patterns of distribution in the Ediacaran biotas: facies versus biogeography and evolution". Paleobiology. 30 (2): 203–221. doi:10.1666/0094-8373(2004)030<0203:PODITE>2.0.CO;2. ISSN 0094-8373. S2CID 129376371.
  163. Seilacher, Adolf (August 1992). "Vendobionta and Psammocorallia: lost constructions of Precambrian evolution". Journal of the Geological Society. 149 (4): 607–613. Bibcode:1992JGSoc.149..607S. doi:10.1144/gsjgs.149.4.0607. ISSN 0016-7649. S2CID 128681462. Retrieved 2015-02-04.
  164. Martin, Mark W.; Grazhdankin, Dmitriy V.; Bowring, Samuel A.; et al. (May 5, 2000). "Age of Neoproterozoic Bilaterian Body and Trace Fossils, White Sea, Russia: Implications for Metazoan Evolution". Science. 288 (5467): 841–845. Bibcode:2000Sci...288..841M. doi:10.1126/science.288.5467.841. ISSN 0036-8075. PMID 10797002.
  165. Fedonkin, Mikhail A.; Waggoner, Benjamin M. (August 28, 1997). "The late Precambrian fossil Kimberella is a mollusc-like bilaterian organism". Nature. 388 (6645): 868–871. Bibcode:1997Natur.388..868F. doi:10.1038/42242. ISSN 0028-0836. S2CID 4395089.
  166. Mooi, Rich; David, Bruno (December 1998). "Evolution Within a Bizarre Phylum: Homologies of the First Echinoderms". American Zoologist. 38 (6): 965–974. doi:10.1093/icb/38.6.965. ISSN 0003-1569.
  167. McMenamin, Mark A. S. (September 2003). Spriggina is a trilobitoid ecdysozoan. Geoscience Horizons Seattle 2003. Abstracts with Programs. Vol. 35. Boulder, CO: Geological Society of America. p. 105. ISSN 0016-7592. OCLC 249088612. Archived from the original on 2016-04-12. Retrieved 2007-11-24. Paper No. 40-2 presented at the Geological Society of America's 2003 Seattle Annual Meeting (November 2–5, 2003) on November 2, 2003, at the Washington State Convention Center.
  168. Jih-Pai, Lin; Gon, Samuel M., III; Gehling, James G.; et al. (2006). "A Parvancorina-like arthropod from the Cambrian of South China". Historical Biology. 18 (1): 33–45. doi:10.1080/08912960500508689. ISSN 0891-2963. S2CID 85821717.
  169. Butterfield, Nicholas J. (December 2006). "Hooking some stem-group 'worms': fossil lophotrochozoans in the Burgess Shale". BioEssays. 28 (12): 1161–1166. doi:10.1002/bies.20507. ISSN 0265-9247. PMID 17120226. S2CID 29130876.
  170. Bengtson 2004, pp. 67–78
  171. Gould 1989, pp. 124–136
  172. Gould 1989
  173. Budd, Graham E. (February 2003). "The Cambrian Fossil Record and the Origin of the Phyla". Integrative and Comparative Biology. 43 (1): 157–165. doi:10.1093/icb/43.1.157. ISSN 1540-7063. PMID 21680420.
  174. Budd, Graham E. (March 1996). "The morphology of Opabinia regalis and the reconstruction of the arthropod stem-group". Lethaia. 29 (1): 1–14. doi:10.1111/j.1502-3931.1996.tb01831.x. ISSN 0024-1164.
  175. Marshall, Charles R. (May 30, 2006). "Explaining the Cambrian 'Explosion' of Animals". Annual Review of Earth and Planetary Sciences. 34: 355–384. Bibcode:2006AREPS..34..355M. doi:10.1146/annurev.earth.33.031504.103001. ISSN 1545-4495. S2CID 85623607.
  176. Janvier, Philippe (2001). "Vertebrata (Vertebrates)". Encyclopedia of Life Sciences. Hoboken, NJ: John Wiley & Sons. doi:10.1038/npg.els.0001531. ISBN 978-0-470-01617-6.
  177. Conway Morris, Simon (August 2, 2003). "Once we were worms". New Scientist. Vol. 179, no. 2406. p. 34. ISSN 0262-4079. Archived from the original on 2008-07-25. Retrieved 2008-09-05.
  178. Jun-Yuan Chen; Di-Ying Huang; Qing-Qing Peng; et al. (July 8, 2003). "The first tunicate from the Early Cambrian of South China". Proc. Natl. Acad. Sci. U.S.A. 100 (14): 8314–8318. Bibcode:2003PNAS..100.8314C. doi:10.1073/pnas.1431177100. ISSN 0027-8424. PMC 166226. PMID 12835415.
  179. D.-G. Shu; Conway Morris, Simon; J. Han; et al. (January 30, 2003). "Head and backbone of the Early Cambrian vertebrate Haikouichthys". Nature. 421 (6922): 526–529. Bibcode:2003Natur.421..526S. doi:10.1038/nature01264. ISSN 0028-0836. PMID 12556891. S2CID 4401274.
  180. Sansom, Smith & Smith 2001, pp. 156–171
  181. Cowen 2000, pp. 120–122
  182. Selden 2001, "Terrestrialization of Animals," pp. 71–74
  183. Garwood, Russell J.; Edgecombe, Gregory D. (September 2011). "Early Terrestrial Animals, Evolution, and Uncertainty". Evolution: Education and Outreach. 4 (3): 489–501. doi:10.1007/s12052-011-0357-y. ISSN 1936-6434.
  184. Battistuzzi, Fabia U.; Feijao, Andreia; Hedges, S. Blair (November 9, 2004). "A genomic timescale of prokaryote evolution: insights into the origin of methanogenesis, phototrophy, and the colonization of land". BMC Evolutionary Biology. 4: 44. doi:10.1186/1471-2148-4-44. ISSN 1471-2148. PMC 533871. PMID 15535883.
  185. Weber, Büdel & Belnap 2016, pp. 37–54, Chapter 3: "Terrestrial Ecosystems in the Precambrian" by Hugo Beraldi-Campesi and Gregory J. Retallack. doi:10.1007/978-3-319-30214-0_3: "...terrestrial ecosystems were indeed present, full of life, and functional since the Archean."
  186. Shear 2000, "The Early Development of Terrestrial Ecosystems," pp. 169–184
  187. Smith, Deborah (May 10, 2017). "Oldest evidence of life on land found in 3.48 billion-year-old Australian rocks" (Press release). Sydney, Australia: UNSW Media. Retrieved 2020-07-14.
  188. Djokic, Tara; Van Kranendonk, Martin J.; Campbell, Kathleen A.; et al. (May 9, 2017). "Earliest signs of life on land preserved in ca. 3.5 Ga hot spring deposits". Nature Communications. 8: 15263. Bibcode:2017NatCo...815263D. doi:10.1038/ncomms15263. ISSN 2041-1723. PMC 5436104. PMID 28486437.
  189. Homann, Martin; Sansjofre, Pierre; Van Zuilen, Mark; et al. (September 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. ISSN 1752-0894. S2CID 134935568.
  190. Zimmer, Carl (May 22, 2019). "A Billion-Year-Old Fungus May Hold Clues to Life's Arrival on Land". Matter. The New York Times. New York. ISSN 0362-4331. Archived from the original on 2019-05-23. Retrieved 2019-05-23. "A version of this article appears in print on May 28, 2019, Section D, Page 3 of the New York edition with the headline: Finding a Clue to Life's Arrival."
  191. Loron, Corentin C.; François, Camille; Rainbird, Robert H.; et al. (June 13, 2019). "Early fungi from the Proterozoic era in Arctic Canada". Nature. 570 (7760): 232–235. Bibcode:2019Natur.570..232L. doi:10.1038/s41586-019-1217-0. ISSN 0028-0836. PMID 31118507. S2CID 162180486.
  192. Timmer, John (May 22, 2019). "Billion-year-old fossils may be early fungus". Ars Technica. Archived from the original on 2019-05-22. Retrieved May 23, 2019.
  193. Venturi, Sebastiano (September 2011). "Evolutionary Significance of Iodine". Current Chemical Biology. 5 (3): 155–162. doi:10.2174/187231311796765012. ISSN 2212-7968.
  194. Crockford, Susan J. (August 2009). "Evolutionary roots of iodine and thyroid hormones in cell-cell signaling". Integrative and Comparative Biology. 49 (2): 155–166. doi:10.1093/icb/icp053. ISSN 1557-7023. PMID 21669854.
  195. Venturi, Sebastiano; Donati, Francesco M.; Venturi, Alessandro; et al. (August 2000). "Environmental Iodine Deficiency: A Challenge to the Evolution of Terrestrial Life?". Thyroid. 10 (8): 727–729. doi:10.1089/10507250050137851. ISSN 1050-7256. PMID 11014322.
  196. Küpper, Frithjof C.; Carpenter, Lucy J.; McFiggans, Gordon B.; et al. (May 13, 2008). "Iodide accumulation provides kelp with an inorganic antioxidant impacting atmospheric chemistry". Proc. Natl. Acad. Sci. U.S.A. 105 (19): 6954–6958. Bibcode:2008PNAS..105.6954K. doi:10.1073/pnas.0709959105. ISSN 0027-8424. PMC 2383960. PMID 18458346.
  197. Lidmar-Bergström, Karna; Bonow, Johan M.; Japsen, Peter (January 2013). "Stratigraphic Landscape Analysis and geomorphological paradigms: Scandinavia as an example of Phanerozoic uplift and subsidence". Global and Planetary Change. 100: 153–171. Bibcode:2013GPC...100..153L. doi:10.1016/j.gloplacha.2012.10.015. ISSN 0921-8181.
  198. Lidmar-Bergström, Karna (December 1993). "Denudation surfaces and tectonics in the southernmost part of the Baltic Shield". Precambrian Research. 64 (1–4): 337–345. Bibcode:1993PreR...64..337L. doi:10.1016/0301-9268(93)90086-H. ISSN 0301-9268.
  199. Hawksworth, David L. (2002). "Lichens". Encyclopedia of Life Sciences. Hoboken, NJ: John Wiley & Sons. doi:10.1038/npg.els.0000368. ISBN 978-0-470-01617-6. S2CID 241563883.
  200. Retallack, Gregory J.; Feakes, Carolyn R. (January 2, 1987). "Trace Fossil Evidence for Late Ordovician Animals on Land". Science. 235 (4784): 61–63. Bibcode:1987Sci...235...61R. doi:10.1126/science.235.4784.61. ISSN 0036-8075. PMID 17769314. S2CID 37351505.
  201. Kenrick, Paul; Crane, Peter R. (September 4, 1997). "The origin and early evolution of plants on land" (PDF). Nature. 389 (6646): 33–39. Bibcode:1997Natur.389...33K. doi:10.1038/37918. ISSN 0028-0836. S2CID 3866183. Retrieved 2015-02-10.
  202. Scheckler 2001, "Afforestation—the First Forests," pp. 67–70
  203. The phrase "Late Devonian wood crisis" is used at "Tetrapoda: Acanthostega". Palaeos. Retrieved 2015-02-10.
  204. Taylor, Thomas N.; Osborn, Jeffrey M. (February 1996). "The importance of fungi in shaping the paleoecosystem". Review of Palaeobotany and Palynology. 90 (3–4): 249–262. doi:10.1016/0034-6667(95)00086-0. ISSN 0034-6667.
  205. Wilson, Heather M.; Anderson, Lyall I. (January 2004). "Morphology and taxonomy of Paleozoic millipedes (Diplopoda: Chilognatha: Archipolypoda) from Scotland". Journal of Paleontology. 78 (1): 169–184. doi:10.1666/0022-3360(2004)078<0169:MATOPM>2.0.CO;2. ISSN 0022-3360. S2CID 131201588.
  206. Selden, Paul; Read, Helen J. (2008). "The Oldest Land Animals: Silurian Millipedes from Scotland" (PDF). Bulletin of the British Myriapod and Isopod Group. 23: 36–37. ISSN 0267-2154. Retrieved 2015-07-21.
  207. Shear, William A.; Edgecombe, Gregory D. (March–May 2010). "The geological record and phylogeny of the Myriapoda". Arthropod Structure & Development. 39 (2–3): 174–190. doi:10.1016/j.asd.2009.11.002. ISSN 1467-8039. PMID 19944188.
  208. MacNaughton, Robert B.; Cole, Jennifer M.; Dalrymple, Robert W.; et al. (May 2002). "First steps on land: Arthropod trackways in Cambrian-Ordovician eolian sandstone, southeastern Ontario, Canada". Geology. 30 (5): 391–394. Bibcode:2002Geo....30..391M. doi:10.1130/0091-7613(2002)030<0391:FSOLAT>2.0.CO;2. ISSN 0091-7613.
  209. Vaccari, N. Emilio; Edgecombe, Gregory D.; Escudero, C. (July 29, 2004). "Cambrian origins and affinities of an enigmatic fossil group of arthropods". Nature. 430 (6999): 554–557. Bibcode:2004Natur.430..554V. doi:10.1038/nature02705. ISSN 0028-0836. PMID 15282604. S2CID 4419235.
  210. Buatois, Luis A.; Mangano, M. Gabriela; Genise, Jorge F.; et al. (June 1998). "The Ichnologic Record of the Continental Invertebrate Invasion: Evolutionary Trends in Environmental Expansion, Ecospace Utilization, and Behavioral Complexity". PALAIOS. 13 (3): 217–240. Bibcode:1998Palai..13..217B. doi:10.2307/3515447. ISSN 0883-1351. JSTOR 3515447.
  211. Cowen 2000, p. 126
  212. Grimaldi & Engel 2005, pp. 155–160
  213. Grimaldi & Engel 2005, p. 12
  214. Clack, Jennifer A. (December 2005). "Getting a Leg Up on Land". Scientific American. Vol. 293, no. 6. pp. 100–107. Bibcode:2005SciAm.293f.100C. doi:10.1038/scientificamerican1205-100. ISSN 0036-8733. PMID 16323697.
  215. Ahlberg, Per E.; Milner, Andrew R. (April 7, 1994). "The origin and early diversification of tetrapods". Nature. 368 (6471): 507–514. Bibcode:1994Natur.368..507A. doi:10.1038/368507a0. ISSN 0028-0836. S2CID 4369342.
  216. Gordon, Malcolm S.; Graham, Jeffrey B.; Wang, Tobias (September–October 2004). "Introduction to the Special Collection: Revisiting the Vertebrate Invasion of the Land". Physiological and Biochemical Zoology. 77 (5): 697–699. doi:10.1086/425182. ISSN 1522-2152. S2CID 83750933.
  217. Venturi and Bégin 2010, "Thyroid Hormone, Iodine and Human Brain Evolution," pp. 105–124
  218. Daeschler, Edward B.; Shubin, Neil H.; Jenkins, Farish A. Jr. (April 6, 2006). "A Devonian tetrapod-like fish and the evolution of the tetrapod body plan" (PDF). Nature. 440 (7085): 757–763. Bibcode:2006Natur.440..757D. doi:10.1038/nature04639. ISSN 0028-0836. PMID 16598249. S2CID 4413217. Retrieved 2020-07-26.
  219. deBraga, Michael; Rieppel, Olivier (July 1997). "Reptile phylogeny and the interrelationships of turtles". Zoological Journal of the Linnean Society. 120 (3): 281–354. doi:10.1111/j.1096-3642.1997.tb01280.x. ISSN 0024-4082.
  220. Benton, Michael J.; Donoghue, Philip C. J. (January 2007). "Paleontological Evidence to Date the Tree of Life". Molecular Biology and Evolution. 24 (1): 26–53. doi:10.1093/molbev/msl150. ISSN 0737-4038. PMID 17047029.
  221. Benton, Michael J. (May 1990). "Phylogeny of the major tetrapod groups: Morphological data and divergence dates". Journal of Molecular Evolution. 30 (5): 409–424. Bibcode:1990JMolE..30..409B. doi:10.1007/BF02101113. ISSN 0022-2844. PMID 2111854. S2CID 35082873.
  222. Sidor, Christian A.; O'Keefe, F. Robin; Damiani, Ross; et al. (April 14, 2005). "Permian tetrapods from the Sahara show climate-controlled endemism in Pangaea". Nature. 434 (7035): 886–889. Bibcode:2005Natur.434..886S. doi:10.1038/nature03393. ISSN 0028-0836. PMID 15829962. S2CID 4416647.
  223. Smith, Roger; Botha, Jennifer (September–October 2005). "The recovery of terrestrial vertebrate diversity in the South African Karoo Basin after the end-Permian extinction". Comptes Rendus Palevol. 4 (6–7): 623–636. doi:10.1016/j.crpv.2005.07.005. ISSN 1631-0683.
  224. Benton 2005
  225. Sahney, Sarda; Benton, Michael J. (April 7, 2008). "Recovery from the most profound mass extinction of all time". Proceedings of the Royal Society B. 275 (1636): 759–765. doi:10.1098/rspb.2007.1370. ISSN 0962-8452. PMC 2596898. PMID 18198148.
  226. Gauthier et al. 1989, p. 345
  227. Benton, Michael J. (March 1983). "Dinosaur Success in the Triassic: A Noncompetitive Ecological Model" (PDF). The Quarterly Review of Biology. 58 (1): 29–55. doi:10.1086/413056. ISSN 0033-5770. JSTOR 2828101. S2CID 13846947. Archived from the original (PDF) on 2008-09-11. Retrieved 2008-09-08.
  228. Padian 2004, pp. 210–231
  229. Hou, Lian-hai; Zhou, Zhonghe; Martin, Larry D.; et al. (October 19, 1995). "A beaked bird from the Jurassic of China". Nature. 377 (6550): 616–618. Bibcode:1995Natur.377..616H. doi:10.1038/377616a0. ISSN 0028-0836. S2CID 4357707.
  230. Clarke, Julia A.; Zhou, Zhonghe; Zhang, Fucheng (March 2006). "Insight into the evolution of avian flight from a new clade of Early Cretaceous ornithurines from China and the morphology of Yixianornis grabaui". Journal of Anatomy. 208 (3): 287–308. doi:10.1111/j.1469-7580.2006.00534.x. ISSN 1469-7580. PMC 2100246. PMID 16533313.
  231. Ruben, John A.; Jones, Terry D. (August 2000). "Selective Factors Associated with the Origin of Fur and Feathers". American Zoologist. 40 (4): 585–596. doi:10.1093/icb/40.4.585. ISSN 0003-1569.
  232. Zhe-Xi, Luo; Crompton, Alfred W.; Ai-Lin, Sun (May 25, 2001). "A New Mammaliaform from the Early Jurassic and Evolution of Mammalian Characteristics". Science. 292 (5521): 1535–1540. Bibcode:2001Sci...292.1535L. doi:10.1126/science.1058476. ISSN 0036-8075. PMID 11375489. S2CID 8738213.
  233. Cifelli, Richard L. (November 2001). "Early mammalian radiations". Journal of Paleontology. 75 (6): 1214–1226. doi:10.1666/0022-3360(2001)075<1214:EMR>2.0.CO;2. ISSN 0022-3360. S2CID 85882683. Retrieved 2015-02-16.
  234. Flynn, John J.; Parrish, J. Michael; Rakotosamimanana, Berthe; et al. (September 2, 1999). "A Middle Jurassic mammal from Madagascar". Nature. 401 (6748): 57–60. Bibcode:1999Natur.401...57F. doi:10.1038/43420. ISSN 0028-0836. S2CID 40903258.
  235. MacLeod, Norman; Rawson, Peter F.; Forey, Peter L.; et al. (April 1997). "The Cretaceous–Tertiary biotic transition". Journal of the Geological Society. 154 (2): 265–292. Bibcode:1997JGSoc.154..265M. doi:10.1144/gsjgs.154.2.0265. ISSN 0016-7649. S2CID 129654916. Retrieved 2015-02-16.
  236. Alroy, John (March 1999). "The Fossil Record of North American Mammals: Evidence for a Paleocene Evolutionary Radiation". Systematic Biology. 48 (1): 107–118. doi:10.1080/106351599260472. ISSN 1063-5157. PMID 12078635.
  237. Archibald, J. David; Deutschman, Douglas H. (June 2001). "Quantitative Analysis of the Timing of the Origin and Diversification of Extant Placental Orders" (PDF). Journal of Mammalian Evolution. 8 (2): 107–124. doi:10.1023/A:1011317930838. ISSN 1064-7554. S2CID 15581162. Archived (PDF) from the original on 2009-07-09. Retrieved 2015-02-16.
  238. Simmons, Nancy B.; Seymour, Kevin L.; Habersetzer, Jörg; et al. (February 14, 2008). "Primitive Early Eocene bat from Wyoming and the evolution of flight and echolocation". Nature. 451 (7180): 818–821. Bibcode:2008Natur.451..818S. doi:10.1038/nature06549. hdl:2027.42/62816. ISSN 0028-0836. PMID 18270539. S2CID 4356708.
  239. Thewissen, Madar & Hussain 1996
  240. Crane, Friis and Pedersen 2000, "The Origin and Early Diversification of Angiosperms," pp. 233–250
  241. Crepet, William L. (November 21, 2000). "Progress in understanding angiosperm history, success, and relationships: Darwin's abominably 'perplexing phenomenon'". Proc. Natl. Acad. Sci. U.S.A. 97 (24): 12939–12941. Bibcode:2000PNAS...9712939C. doi:10.1073/pnas.97.24.12939. ISSN 0027-8424. PMC 34068. PMID 11087846.
  242. "evolution: plant timeline". Encyclopædia Britannica Online. Encyclopædia Britannica, Inc. 1996. ISBN 9780691185507. OCLC 42796406. Archived from the original on 2015-03-27. Retrieved 2020-10-23.
  243. Wilson, Edward O.; Hölldobler, Bert (September 20, 2005). "Eusociality: Origin and consequences". Proc. Natl. Acad. Sci. U.S.A. 102 (38): 13367–13371. Bibcode:2005PNAS..10213367W. doi:10.1073/pnas.0505858102. ISSN 0027-8424. PMC 1224642. PMID 16157878.
  244. Hughes, William O. H.; Oldroyd, Benjamin P.; Beekman, Madeleine; Ratnieks, Francis L. W. (May 30, 2008). "Ancestral Monogamy Shows Kin Selection Is Key to the Evolution of Eusociality". Science. 320 (5880): 1213–1216. Bibcode:2008Sci...320.1213H. doi:10.1126/science.1156108. ISSN 0036-8075. PMID 18511689. S2CID 20388889.
  245. Lovegrove, Barry G. (January 1991). "The evolution of eusociality in molerats (Bathyergidae): a question of risks, numbers, and costs". Behavioral Ecology and Sociobiology. 28 (1): 37–45. doi:10.1007/BF00172137. ISSN 0340-5443. S2CID 36466393.
  246. Labandeira & Eble 1999
  247. Montgomery, Stephen (2009). "Darwin & The Descent of Man". Charles Darwin & Evolution. Cambridge: Christ's College. Archived from the original on 2019-06-20. Retrieved 2020-11-19.{{cite web}}: CS1 maint: unfit URL (link)
  248. Brunet, Michel; Guy, Franck; Pilbeam, David; et al. (July 11, 2002). "A new hominid from the Upper Miocene of Chad, Central Africa". Nature. 418 (6894): 145–151. Bibcode:2002Natur.418..145B. doi:10.1038/nature00879. ISSN 0028-0836. PMID 12110880. S2CID 1316969.
  249. de Heinzelin, Jean; Clark, J. Desmond; White, Tim; et al. (April 23, 1999). "Environment and Behavior of 2.5-Million-Year-Old Bouri Hominids". Science. 284 (5414): 625–629. Bibcode:1999Sci...284..625D. doi:10.1126/science.284.5414.625. ISSN 0036-8075. PMID 10213682.
  250. De Miguel, Carmen; Henneberg, Maciej (2001). "Variation in hominid brain size: How much is due to method?". HOMO: Journal of Comparative Human Biology. 52 (1): 3–58. doi:10.1078/0018-442X-00019. ISSN 0018-442X. PMID 11515396.
  251. Leakey 1994, pp. 87–89
  252. Mellars, Paul (June 20, 2006). "Why did modern human populations disperse from Africa ca. 60,000 years ago? A new model". Proc. Natl. Acad. Sci. U.S.A. 103 (25): 9381–9386. Bibcode:2006PNAS..103.9381M. doi:10.1073/pnas.0510792103. ISSN 0027-8424. PMC 1480416. PMID 16772383.
  253. Benton 2005a, Chapter 6: "Tetrapods of the Triassic"
  254. MacLeod, Norman (1999). "Extinction!". FirstScience.com. Archived from the original on 2000-08-19. Retrieved 2020-12-25.
  255. Martin, Ronald E. (June 1995). "Cyclic and secular variation in microfossil biomineralization: clues to the biogeochemical evolution of Phanerozoic oceans". Global and Planetary Change. 11 (1–2): 1–23. Bibcode:1995GPC....11....1M. doi:10.1016/0921-8181(94)00011-2. ISSN 0921-8181.
  256. Martin, Ronald E. (June 1996). "Secular Increase in Nutrient Levels through the Phanerozoic: Implications for Productivity, Biomass, and Diversity of the Marine Biosphere". PALAIOS. 11 (3): 209–219. Bibcode:1996Palai..11..209M. doi:10.2307/3515230. ISSN 0883-1351. JSTOR 3515230.
  257. Rohde, Robert A.; Muller, Richard A. (March 10, 2005). "Cycles in fossil diversity" (PDF). Nature. 434 (7030): 208–210. Bibcode:2005Natur.434..208R. doi:10.1038/nature03339. ISSN 0028-0836. PMID 15758998. S2CID 32520208. Retrieved 2008-09-22.

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