Hyperthermophiles in the history of life.

Ciba Foundation symposium Pub Date : 2007-09-28 DOI:10.1002/9780470514986.CH1

K. Stetter

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引用次数: 29

Abstract

Prokaryotes requiring extremely high growth temperatures (optimum 80-110 degrees C) have recently been isolated from water-containing terrestrial, subterranean and submarine high temperature environments. These hyperthermophiles consist of primary producers and consumers of organic matter, forming unique high temperature ecosystems. Surprisingly, within the 16S rRNA-based phylogenetic tree, hyperthermophiles occupy all the shortest and deepest branches closest to the root. Therefore, they appear to be the most primitive extant organisms. Most of them (the primary producers) are able to grow chemolithoautotrophically, using CO2 as sole carbon source and inorganic energy sources, suggesting a hyperthermophilic autotrophic common ancestor. They gain energy from various kinds of respiration. Molecular hydrogen and reduced sulfur compounds serve as electron donors while CO2, oxidized sulfur compounds, NO3- and O2 (only rarely) serve as electron acceptors. Growth demands of hyperthermophiles fit the scenario of a hot volcanism-dominated primitive Earth. Similar anaerobic chemolithoautotrophic hyperthermophiles, completely independent of a sun, could even exist on other planets provided that active volcanism and liquid water were present.

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生命历史上的超级嗜热生物。

需要极高生长温度(最适80-110℃)的原核生物最近已从含水的陆地、地下和海底高温环境中分离出来。这些超嗜热生物是有机物的初级生产者和消费者，形成了独特的高温生态系统。令人惊讶的是，在以16S rrna为基础的系统发育树中，超嗜热生物占据了所有最接近根的最短和最深的分支。因此，它们似乎是现存的最原始的生物。它们中的大多数(初级生产者)能够以CO2作为唯一的碳源和无机能源进行化能化石自养生长，表明它们是一个超嗜热自养的共同祖先。它们通过各种呼吸获得能量。氢分子和还原硫化合物是电子给体，而二氧化碳、氧化硫化合物、NO3-和O2(很少)是电子受体。超嗜热生物的生长需求符合热火山主导的原始地球的情景。类似的厌氧化石化自养型超嗜热生物，完全独立于太阳，甚至可能存在于其他行星上，只要存在活跃的火山活动和液态水。

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