Archaea

Archaea

Scientific classification

Domain*:

Archaea

Phyla* & classes

Crenarchaeota
Euryarchaeota
    Halobacteria
    Methanobacteria
    Methanococci
    Methanopyri
    Archeoglobi
    Thermoplasmata
    Thermococci
Korarchaeota
Nanoarchaeota

* Or kingdom (see text)

The Archaea are one of the three major groups of living organisms, together with the bacteria and eukaryotes. They are prokaryotes, like bacteria, and were originally included among them. Their separate identity was discovered in the late 1970s by Dr. Carl Woese at the University of Illinois by genetic comparison. Originally they were termed the Archaebacteria, and the other prokaryotes the Eubacteria, but now there is a growing tendency to restrict the term bacteria to the latter and the names have adjusted accordingly. The Archaea may be treated as a single kingdom or as a domain, in which case the subgroups may be ranked as kingdoms.

Archaea differ from the true bacteria in many important respects, as well as from the eukaryotes. These differences include:

wall structures and chemistry (lack of peptidoglycan and Gram staining)
lipidic membrane structure (their lipid bilayers consist of branched chain hydrocarbons linked by ether linkages to glycerol)
metabolism (methanogens, sulfate reducers...)

Many Archaea live in extreme environments, including water whose temperature exceeds that of boiling water, like geysers, very salty, acid or alkaline water or black smokers. They are very diverse, both in morphology and physiology. Some are single-celled, while others form filaments or aggregates. They may be spherical, rod-shaped, spiral, lobed. Their size varies in diameter from 0.1 to more than 15 ÃÂÃÂµm (filaments up to 200 ÃÂÃÂµm).

They show a great diversity in multiplication modes, which may be by binary fission, budding or fragmentation. For a nutrional point of view, they range from being chemolithoautotrophic to organotrophic. Physiologically, they can be aerobic, facultatively anaerobic, or stricly anaerobic. Some are mesophiles, others hyperthermophiles (may live over 100ÃÂÃÂ°C). Though most of them live in high-temperature, anaerobic, hypersaline environment, some have also been found in cold places. They are mostly found in aquatic and terrestrial habitats, but a few have been found in animal digestive systems. The environmental conditions archaea prefer and their unusual biochemistry make them usually harmless to organisms belonging to the other two domains. No case of infection of a human with archaea has been reported so far.

There are two main groups of Archaea, the Crenarchaeota and Euryarchaeota. The Korarchaeota have been described from RNA samples, but the actual organisms remain unknown, and the Nanoarchaeota are known from a single species discovered in 2002, Nanoarchaeum equitum. The Archaea appear to be close relatives of the eukaryotes, and some work has suggested that the Euryarchaeota may be closer to them than the Crenarchaeota, though more recent studies support their monophyly. Woese argued that the Bacteria, Archaea, and eukaryotes all diverged separately from an ancestral progenote, but this has little support, and a few authors consider the Archaea and eukaryotes highly derived Bacteria (making that kingdom paraphyletic).

See also: extremophile -- phylogeny -- rRNA

External links

Extremophiles Bioprospecting for antimicrobials, Dr Sarah Maloney Citat: "...Ground breaking research on extremophiles continues to this day, with the recently discovered 22nd genetically encoded amino acid ? pyrrolysine ? from the archaeon, Methanosarcina barkeri, (Hao et al., 2002; Srinivasan et al., 2002)...."
BBC News July 21, 1999: Toughest bug reveals genetic secrets Citat: "...It [Pyrococcus abyssi] likes conditions that the vast majority of other organisms would find impossible to live in. It thrives best at temperatures of about 103 degrees [Celsius] and under pressures of about 200 atmospheres...."
Pyrococcus abyssi Home page at Genoscope