氧气作为早期节肢动物微底栖生物进化的驱动力。
Oxygen as a driver of early arthropod micro-benthos evolution.
机构信息
Department of Geology, University of Leicester, Leicester, United Kingdom.
出版信息
PLoS One. 2011;6(12):e28183. doi: 10.1371/journal.pone.0028183. Epub 2011 Dec 2.
BACKGROUND
We examine the physiological and lifestyle adaptations which facilitated the emergence of ostracods as the numerically dominant Phanerozoic bivalve arthropod micro-benthos.
METHODOLOGY/PRINCIPAL FINDINGS: The PO(2) of modern normoxic seawater is 21 kPa (air-equilibrated water), a level that would cause cellular damage if found in the tissues of ostracods and much other marine fauna. The PO(2) of most aquatic breathers at the cellular level is much lower, between 1 and 3 kPa. Ostracods avoid oxygen toxicity by migrating to waters which are hypoxic, or by developing metabolisms which generate high consumption of O(2). Interrogation of the Cambrian record of bivalve arthropod micro-benthos suggests a strong control on ecosystem evolution exerted by changing seawater O(2) levels. The PO(2) of air-equilibrated Cambrian-seawater is predicted to have varied between 10 and 30 kPa. Three groups of marine shelf-dwelling bivalve arthropods adopted different responses to Cambrian seawater O(2). Bradoriida evolved cardiovascular systems that favoured colonization of oxygenated marine waters. Their biodiversity declined during intervals associated with black shale deposition and marine shelf anoxia and their diversity may also have been curtailed by elevated late Cambrian (Furongian) oxygen-levels that increased the PO(2) gradient between seawater and bradoriid tissues. Phosphatocopida responded to Cambrian anoxia differently, reaching their peak during widespread seabed dysoxia of the SPICE event. They lacked a cardiovascular system and appear to have been adapted to seawater hypoxia. As latest Cambrian marine shelf waters became well oxygenated, phosphatocopids went extinct. Changing seawater oxygen-levels and the demise of much of the seabed bradoriid micro-benthos favoured a third group of arthropod micro-benthos, the ostracods. These animals adopted lifestyles that made them tolerant of changes in seawater O(2). Ostracods became the numerically dominant arthropod micro-benthos of the Phanerozoic.
CONCLUSIONS/SIGNIFICANCE: Our work has implications from an evolutionary context for understanding how oxygen-level in marine ecosystems drives behaviour.
背景
我们研究了生理和生活方式的适应性,这些适应性促进了介形类动物成为显生宙双壳类节肢动物微生物区系中数量最多的物种。
方法/主要发现:现代常氧海水中的 PO₂为 21 kPa(与空气平衡的水),如果在介形类动物和其他大多数海洋动物的组织中发现这种水平,将会导致细胞损伤。大多数水生呼吸动物的细胞内 PO₂水平要低得多,在 1 到 3 kPa 之间。介形类动物通过迁移到缺氧的水域或通过产生高耗氧量的新陈代谢来避免氧气毒性。对寒武纪双壳类节肢动物微生物区系的记录进行询问表明,海水氧水平的变化对生态系统进化有很强的控制作用。与空气平衡的寒武纪海水的 PO₂预计在 10 到 30 kPa 之间变化。三组生活在海洋大陆架上的双壳类节肢动物对寒武纪海水氧采取了不同的反应。Bradoriida 进化出了心血管系统,有利于在含氧的海洋水域中殖民。它们的生物多样性在与黑色页岩沉积和海洋大陆架缺氧有关的间隔期间下降,它们的多样性也可能因晚寒武纪(芙蓉世)氧气水平的升高而受到限制,这增加了海水和 bradoriid 组织之间的 PO₂梯度。磷虾类对寒武纪缺氧的反应不同,在 SPICE 事件广泛的海底缺氧期间达到顶峰。它们没有心血管系统,似乎适应了海水缺氧。随着最新的寒武纪海洋大陆架水域变得富含氧气,磷虾类灭绝了。海水含氧量的变化和大部分海底 bradoriid 微生物区系的消亡有利于第三组节肢动物微生物区系,即介形类动物。这些动物采取了使它们能够耐受海水 O₂变化的生活方式。介形类动物成为显生宙数量最多的节肢动物微生物区系。
结论/意义:我们的工作从进化的角度对理解海洋生态系统中的氧气水平如何驱动行为具有重要意义。
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