藻类产氢的氧敏感性。

Oxygen sensitivity of algal H2- production.

作者信息

Ghirardi M L, Togasaki R K, Seibert M

机构信息

Notional Renewable Energy Laboratory, Golden, CO 80401, USA.

出版信息

Appl Biochem Biotechnol. 1997 Spring;63-65:141-51. doi: 10.1007/BF02920420.

DOI:10.1007/BF02920420

PMID:18576077

Abstract

Photoproduction of H2 by green algae utilizes electrons originating from the photosynthetic oxidation of water and does not require metabolic intermediates. However, algal hydrogenases are extremely sensitive to O(2), which limits their usefulness in future commercial H2-production systems. We designed an experimental technique for the selection of O2-tolerant, H2-producing variants of Chlamydomonas reinhardtii based on the ability of wild-type cells to survive a short (20 min) exposure to metronidazole in the presence of controlled concentrations of O2. The number of survivors depends on the metronidazole concentration, light intensity, preinduction of the hydrogenase, and the presence or absence of O2. Finally, we demonstrate that some of the selected survivors in fact exhibit H2-production capacity that is less sensitive to O2 than the original wild-type population.

摘要

绿藻光产生氢气利用的是源自水的光合氧化的电子，且不需要代谢中间体。然而，藻类氢化酶对氧气极其敏感，这限制了它们在未来商业化制氢系统中的应用。我们设计了一种实验技术，基于野生型细胞在受控氧气浓度下短时间（20分钟）暴露于甲硝唑后存活的能力，来筛选莱茵衣藻中耐氧气且能产生氢气的变体。存活者的数量取决于甲硝唑浓度、光照强度、氢化酶的预诱导以及氧气的存在与否。最后，我们证明一些所选的存活者实际上表现出的产氢能力对氧气的敏感度低于原始野生型群体。

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藻类产氢的氧敏感性。

Oxygen sensitivity of algal H2- production.

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