鳃的个体发生和古生理学：来自幼鱼和呼吸空气的鱼类的新见解。

Ontogeny and paleophysiology of the gill: new insights from larval and air-breathing fish.

机构信息

Department of Zoology, University of British Columbia, Vancouver, BC V6 T 1Z4, Canada.

出版信息

Respir Physiol Neurobiol. 2012 Dec 1;184(3):293-300. doi: 10.1016/j.resp.2012.07.011. Epub 2012 Aug 8.

DOI:10.1016/j.resp.2012.07.011

Abstract

There are large changes in gill function during development associated with ionoregulation and gas exchange in both larval and air-breathing fish. Physiological studies of larvae indicate that, contrary to accepted dogma but consistent with morphology, the initial function of the gill is primarily ionoregulatory and only secondarily respiratory. In air-breathing fish, as the gill becomes progressively less important in terms of O(2) uptake with expansion of the air-breathing organ, it retains its roles in CO(2) excretion, ion exchange and acid-base balance. The observation that gill morphology and function is strongly influenced by ionoregulatory needs in both larval and air-breathing fish may have evolutionary implications. In particular, it suggests that the inability of the skin to maintain ion and acid-base balance as protovertebrates increased in size and became more active may have been more important in driving gill development than O(2) insufficiency.

摘要

在发育过程中，鱼类的鳃功能会发生巨大变化，包括离子调节和气体交换。对幼鱼的生理学研究表明，与公认的教条相反，但与形态学一致，鳃的最初功能主要是离子调节，其次才是呼吸。在呼吸空气的鱼类中，随着呼吸器官的扩张，鳃在摄取氧气方面的作用逐渐降低，但其在二氧化碳排泄、离子交换和酸碱平衡方面的作用仍然保留。鳃的形态和功能在幼鱼和呼吸空气的鱼类中都受到离子调节需求的强烈影响，这一观察结果可能具有进化意义。特别是，它表明，随着原索动物体型的增大和活动的增加，皮肤维持离子和酸碱平衡的能力降低，这可能比氧气不足对鳃发育的驱动作用更大。

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鳃的个体发生和古生理学：来自幼鱼和呼吸空气的鱼类的新见解。

Ontogeny and paleophysiology of the gill: new insights from larval and air-breathing fish.

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