The
age of the Earth is about 4.54 billion years. Scientific evidence suggests that
life began on Earth at least 3.5
billion years ago. The earliest evidence for
life on Earth is
graphite found to be
biogenic in 3.7-billion-year-old
metasedimentary rocks discovered in
Western Greenland and
microbial mat fossils found in 3.48-billion-year-old
sandstone discovered in
Western Australia. In 2015, possible remains of
biotic matter were found in 4.1-billion-year-old rocks in Western Australia. Although probable prokaryotic cell
fossils date to almost 3.5
billion years ago, most prokaryotes do not have distinctive morphologies, and fossil shapes cannot be used to identify them as archaea. Instead,
chemical fossils of unique
lipids are more informative because such compounds do not occur in other organisms. Some publications suggest that archaeal or eukaryotic lipid remains are present in
shales dating from 2.7 billion years ago, though such data have since been questioned. These lipids have also been detected in even older rocks from west
Greenland. The oldest such traces come from the
Isua district, which includes Earth's oldest known sediments, formed 3.8 billion years ago. The archaeal lineage may be the most ancient that exists on Earth. Woese argued that the bacteria, archaea, and eukaryotes represent separate lines of descent that diverged early on from an ancestral colony of organisms. One possibility is that this occurred before the
evolution of cells, when the lack of a typical cell membrane allowed unrestricted
lateral gene transfer, and that the common ancestors of the three domains arose by fixation of specific subsets of genes. Since archaea and bacteria are no more related to each other than they are to eukaryotes, the term
prokaryote may suggest a false similarity between them. However, structural and functional similarities between lineages often occur because of shared ancestral traits or
evolutionary convergence. These similarities are known as a
grade, and
prokaryotes are best thought of as a grade of life, characterized by such features as an absence of membrane-bound organelles.
Comparison with other domains The following table compares some major characteristics of the three domains, to illustrate their similarities and differences. Archaea were split off as a third domain because of the large differences in their ribosomal RNA structure. The particular molecule
16S rRNA is key to the production of proteins in all organisms. Because this function is so central to life, organisms with mutations in their 16S rRNA are unlikely to survive, leading to great (but not absolute) stability in the structure of this polynucleotide over generations. 16S rRNA is large enough to show organism-specific variations, but still small enough to be compared quickly. In 1977, Carl Woese, a microbiologist studying the genetic sequences of organisms, developed a new comparison method that involved splitting the RNA into fragments that could be sorted and compared with other fragments from other organisms. The more similar the patterns between species, the more closely they are related. Woese used his new rRNA comparison method to categorize and contrast different organisms. He compared a variety of species and happened upon a group of methanogens with rRNA vastly different from any known prokaryotes or eukaryotes. This led to the conclusion that Archaea and Eukarya shared a common ancestor more recent than Eukarya and Bacteria. Another unique feature of archaea, found in no other organisms, is
methanogenesis (the metabolic production of methane). Methanogenic archaea play a pivotal role in ecosystems with organisms that derive energy from oxidation of methane, many of which are bacteria, as they are often a major source of methane in such environments and can play a role as primary producers.
Methanogens also play a critical role in the
carbon cycle, breaking down organic carbon into methane, which is also a major greenhouse gas. This difference in the biochemical structure of Bacteria and Archaea has been explained by researchers through evolutionary processes. It is theorized that both
domains originated at deep sea alkaline
hydrothermal vents. At least twice, microbes evolved lipid biosynthesis and cell wall biochemistry. It has been suggested that the
last universal common ancestor was a non-free-living organism. It may have had a permeable membrane composed of bacterial simple chain amphiphiles (fatty acids), including archaeal simple chain amphiphiles (isoprenoids). These stabilize fatty acid membranes in seawater; this property may have driven the divergence of bacterial and archaeal membranes, "with the later biosynthesis of phospholipids giving rise to the unique G1P and G3P headgroups of archaea and bacteria respectively. If so, the properties conferred by membrane isoprenoids place the lipid divide as early as the origin of life".
Relationship to bacteria The relationships among the
three domains are of central importance for understanding the origin of life. Most of the
metabolic pathways, which are the object of the majority of an organism's genes, are common between Archaea and Bacteria, while most genes involved in
gene expression are common between Archaea and Eukarya. Within prokaryotes, archaeal cell structure is most similar to that of
Gram-positive bacteria, largely because both have a single lipid bilayer and usually contain a thick sacculus (exoskeleton) of varying chemical composition. In some phylogenetic trees based upon different gene / protein sequences of prokaryotic
homologs, the archaeal homologs are more closely related to those of gram-positive bacteria. but the phylogeny of these genes was interpreted to reveal inter-domain gene transfer, and might not reflect the organismal relationship(s). It has been proposed that the archaea evolved from Gram-positive bacteria in response to antibiotic
selection pressure. This is suggested by the observation that archaea are resistant to a wide variety of antibiotics that are produced primarily by Gram-positive bacteria,
Cavalier-Smith has made a similar suggestion, the
Neomura hypothesis. This proposal is also supported by other work investigating protein structural relationships and studies that suggest that gram-positive bacteria may constitute the earliest branching lineages within the prokaryotes.
Relation to eukaryotes , a merger of an Promethearchaeati / "Asgard" archaean and an aerobic bacterium created the
eukaryotes, with aerobic
mitochondria; a second merger added
chloroplasts, creating the
green plants. The evolutionary relationship between archaea and
eukaryotes remains unclear. Aside from the similarities in cell structure and function that are discussed below, many genetic trees group the two. Complicating factors include claims that the relationship between eukaryotes and the archaeal phylum
Thermoproteota is closer than the relationship between the
Methanobacteriati and the phylum Thermoproteota and the presence of archaea-like genes in certain bacteria, such as
Thermotoga maritima, from
horizontal gene transfer. The standard hypothesis states that the ancestor of the eukaryotes diverged early from the Archaea, and that eukaryotes arose through
symbiogenesis, the fusion of an archaean and a eubacterium, which formed the
mitochondria; this hypothesis explains the genetic similarities between the groups. A lineage of archaea discovered in 2015,
Lokiarchaeum (of the proposed new phylum "
Lokiarchaeota"), named for a
hydrothermal vent called
Loki's Castle in the Arctic Ocean, was found to be the most closely related to eukaryotes known at that time. It has been called a transitional organism between prokaryotes and eukaryotes. Several sister phyla of "Lokiarchaeota" have since been found ("
Thorarchaeota", "
Odinarchaeota", "
Heimdallarchaeota"), all together comprising a newly proposed
supergroup "Asgard". Details of the relation of Promethearchaeati / "Asgard" members and eukaryotes are still under consideration, although, in January 2020, scientists reported that
Promethearchaeum syntrophicum, a type of Promethearchaeati / "Asgard" archaea, may be a possible link between simple
prokaryotic and complex
eukaryotic microorganisms about two billion years ago. ==Morphology==