A variety of
geologic and environmental settings have been proposed for an origin of life. These theories are often in competition with one another as there are many views of prebiotic compound availability, geophysical setting, and early life characteristics. The first organism on Earth likely differed from
LUCA. Between the first appearance of life and where all modern phylogenies began branching, an unknown amount of time passed, with unknown gene transfers, extinctions, and adaptation to environmental niches. Modern phylogenies provide more genetic evidence about LUCA than about its precursors.
Deep sea hydrothermal vents Hot fluids may be putative fossilized
microorganisms, found in white smoker
hydrothermal vent precipitates. They may have lived as early as 4.28 Gya (billion years ago), relatively soon after the
formation of the oceans 4.41 Gya, not long after the
formation of the Earth 4.54 Gya. Analysis of the
tree of life places thermophilic and hyperthermophilic bacteria and archaea closest to the root, suggesting that life may have evolved in a hot environment. The deep sea or alkaline hydrothermal vent theory posits that life began at submarine hydrothermal vents.
William Martin and
Michael Russell have suggested that this could have been in metal-sulphide-walled compartments acting as precursors for cell walls. These form where hydrogen-rich fluids emerge from below the sea floor, as a result of
serpentinization of ultra-
mafic olivine with seawater and a pH interface with carbon dioxide-rich ocean water. The vents form a sustained chemical energy source derived from redox reactions, in which electron donors (molecular hydrogen) react with electron acceptors (carbon dioxide); see
iron–sulfur world theory. These are
exothermic reactions. This movement of ions across the membrane depends on two factors: Starting in 1981, researchers proposed that life might have started at hydrothermal vents, that spontaneous chemistry in the Earth's crust driven by rock–water interactions at disequilibrium thermodynamically underpinned life's origin, and that the founding lineages of the archaea and bacteria were H2-dependent autotrophs that used CO2 as their terminal acceptor in energy metabolism. In 2016, Martin suggested that the LUCA "may have depended heavily on the geothermal energy of the vent to survive". Researchers were able to generate RNA oligomers of up to 4 units in length. This RNA was synthesized using activated ribonucleotides. Additionally, these RNA oligomers could only be synthesized under certain conditions. Pores at deep sea hydrothermal vents are suggested to have been occupied by membrane-bound compartments which promoted biochemical reactions. Metabolic intermediates in the Krebs cycle, gluconeogenesis, amino acid bio-synthetic pathways, glycolysis, the pentose phosphate pathway, and including sugars like ribose, and lipid precursors can occur non-enzymatically at conditions relevant to deep-sea alkaline hydrothermal vents. If the deep marine hydrothermal setting was the site, then life could have arisen as early as . If life evolved in the ocean at depths of more than ten meters, it would have been shielded both from impacts and the then high levels of solar ultraviolet radiation. The available energy in hydrothermal vents is maximized at 100–150 °C, the temperatures at which
hyperthermophilic bacteria and
thermoacidophilic archaea live.
Arguments against a vent setting Arguments against a hydrothermal origin of life state that hyperthermophily was a result of
convergent evolution in bacteria and archaea, and that a
mesophilic environment is more likely. Production of prebiotic organic compounds at hydrothermal vents is estimated to be . While key prebiotic compounds, such as methane, are found at vents, they are in far lower concentrations than in a Miller-Urey Experiment environment. Some organic compounds once thought to have been formed at vents are now understood to have been formed by other geological processes and inherited by vents. Methane, for example, was once thought to have been synthesized by catalysis after serpentinization, but more likely comes from leached fluid inclusions formed deeper in oceanic crust from magmatic carbon. The concentrations of methane the rate is 2–4 orders of magnitude lower than those in Miller-Urey experiments. Other counter-arguments include the inability to concentrate prebiotic materials, due to strong dilution by seawater. This open system cycles compounds through vent minerals, leaving little residence time to accumulate. All modern cells rely on phosphates for nucleotide backbone and potassium for protein formation, making it likely that the first life forms shared these functions. These elements were not available in high quantities in the Archaean oceans, as both primarily come from the weathering of continental rocks on land, far from vents, and phosphate is lost into relatively insoluble
apatite. However, phosphate can be concentrated in lakes, as in the modern
Last Chance Lake. Submarine hydrothermal vents are not conducive to condensation reactions needed for polymerisation of macromolecules. An older argument was that key polymers were encapsulated in vesicles after condensation, which supposedly would not happen in saltwater. However, while salinity inhibits vesicle formation from low-diversity mixtures of fatty acids,
Surface bodies of water Surface bodies of water provide environments that dry out and rewet. Wet-dry cycles concentrate prebiotic compounds and enable
condensation reactions to polymerise macromolecules. Moreover, lakes and ponds receive detrital input from weathering of continental
apatite-containing rocks, the most common source of phosphates. The amount of exposed continental crust in the Hadean is unknown, but models of early ocean depths and rates of ocean island and continental crust growth make it plausible that there was exposed land. Another line of evidence for a surface start to life is the requirement for
Ultraviolet radiation (UV) for organism function. UV is necessary for the formation of the U+C nucleotide
base pair by partial
hydrolysis and nucleobase loss. Simultaneously, UV can be harmful and sterilising to life, especially for simple early lifeforms with little ability to repair radiation damage. Radiation levels from a young Sun were likely greater, and, with no
ozone layer, harmful shortwave UV rays would reach the surface of Earth. For life to begin, a shielded environment with influx from UV-exposed sources is necessary to both benefit and protect from UV. Shielding under ice, liquid water, mineral surfaces (e.g. clay) or regolith is possible in a range of surface water settings.
Hot springs Most branching phylogenies are thermophilic or hyperthermophilic, making it possible that LUCA and preceding lifeforms were similarly thermophilic. Hot springs are formed from the heating of groundwater by geothermal activity. This intersection allows for influxes of material from deep penetrating waters and from surface runoff that transports eroded continental sediments. Interconnected groundwater systems create a mechanism for distribution of life to wider area. Mineral deposits in these environments under an anoxic atmosphere would have suitable pH, contain precipitates of photocatalytic sulfide minerals that absorb harmful ultraviolet radiation, and have wet-dry cycles that concentrate substrate solutions enough for spontaneous formation of biopolymers created both by chemical reactions in the hydrothermal environment, and by exposure to
UV light during transport from vents to adjacent pools. The hypothesized pre-biotic environments are similar to hydrothermal vents, with additional components that help explain peculiarities of the LUCA. Potential sources of organics at hot springs might have been transported by interplanetary dust particles, extraterrestrial projectiles, or atmospheric or geochemical synthesis. Hot springs could have been abundant in volcanic landmasses during the Hadean. Evidence for mesophily from biomolecular studies includes Galtier's
G+C nucleotide thermometer. G+C are more abundant in thermophiles due to the added stability of an additional hydrogen bond not present between A+T nucleotides.
rRNA sequencing of modern lifeforms shows that
LUCA's reconstructed G+C content was likely representative of moderate temperatures. The
reverse gyrase topoisomerase is found exclusively in thermophiles and hyperthermophiles, as it allows for coiling of DNA. This enzyme requires the complex molecule
ATP to function. If an origin of life is hypothesised to involve a simple organism that had not yet evolved a membrane, let alone ATP, this would make the existence of reverse gyrase improbable. Moreover, phylogenetic studies show that reverse gyrase originated in archaea, and transferred to bacteria by horizontal gene transfer, implying it was not present in the LUCA.
Icy surface bodies of water Cold-start theories presuppose large ice-covered regions. Stellar evolution models predict that the Sun's luminosity was ≈25% weaker than it is today. Fuelner states that although this significant decrease in solar energy would have formed an icy planet, there is strong evidence for the presence of liquid water, possibly driven by a greenhouse effect. This would mean an early Earth with both liquid oceans and icy poles. Ice melts that form from ice sheets or glacier melts create freshwater pools, another niche capable of wet-dry cycles. While surface pools would be exposed to intense UV radiation, bodies of water within and under ice would be shielded, while remaining connected to exposed areas through ice cracks. Impact melting would allow freshwater and meteoritic input, creating prebiotic components. Near-seawater levels of sodium chloride destabilize fatty acid membrane self-assembly, making freshwater settings appealing for early membranous life. Icy environments would trade the faster reaction rates that occur in warm environments for increased stability and accumulation of larger polymers. Experiments simulating Europa-like conditions of ≈20 °C have synthesised amino acids and adenine, showing that Miller-Urey type syntheses can occur at low temperatures.
Inside the continental crust An alternative geological environment has been proposed by the geologist Ulrich Schreiber and the physical chemist Christian Mayer: the
continental crust.
Tectonic fault zones could present a stable and well-protected environment for long-term prebiotic evolution. Inside these systems of cracks and cavities, water and carbon dioxide present the bulk solvents. Their phase state could vary between liquid, gaseous and
supercritical, depending on pressure and temperature. When forming two separate phases (e.g. liquid water and supercritical carbon dioxide in depths of little more than 1 km), the system provides optimal conditions for
phase transfer reactions. Concurrently, the contents of the tectonic fault zones are being supplied by a multitude of inorganic educts (e.g. carbon monoxide, hydrogen, ammonia, hydrogen cyanide, nitrogen, and even phosphate from dissolved apatite) and simple organic molecules formed by hydrothermal chemistry (e.g. amino acids, long-chain amines, fatty acids, long-chain aldehydes). Part of the tectonic fault zones is at a depth of around 1000 m. For the carbon dioxide part of the bulk solvent, it provides temperature and pressure conditions near the
phase transition point between the supercritical and the gaseous state. This allows
lipophilic organic molecules that dissolve well in
supercritical CO2 to accumulate, but not in its gaseous state, leading to their local precipitation. Periodic pressure variations such as caused by
geysers or
tidal influences result in periodic phase transitions, keeping the local reaction environment in a constant
non-equilibrium state. In presence of
amphiphilic compounds (such as the long chain amines and fatty acids), subsequent generations of vesicles are formed that are constantly selected for their stability. == Homochirality ==