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亚心型四爿藻在CCCP作用下的光生物产氢的代谢途径 被引量:2

Electron transport pathways of hydrogen photobiological production metabolism in CCCP-treated Tetraselmis subcordiformis
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摘要 以添加CCCP(羰基氰化物间氯苯腙,Carbonyl cyanide m-chlorophenylhydrazone)的海洋绿藻亚心型四爿藻光生物制氢为研究体系,使用作用于光合系统不同位点的抑制剂研究该藻产氢过程不同时段的代谢途径。结果表明:四爿藻光生物产氢前期电子主要来自PS Ⅱ光解水以及胞内分解代谢,电子经由光合电子传递链传递至氢酶产生氢气;而后期释放的氢气则是通过不依赖光合电子传递链的发酵途径产生。产氢过程厌氧发酵代谢途径主要产物是乙酸、乙醇,其中乙醇代谢途径和氢酶竞争NAD(P)H,不利于氢气的积累。 The CCCP-treated marine microalga Tetraselmis subcordiformis could photo-produce hy-drogen for sevaral days.Effect of photosynthetic inhibitors on hydrogen production helped to draw the network of hydrogen metabolism by CCCP-treated T.subcordiformis: at the beginning of hydrogen production,electrons provided to hydrogenase are mainly from photolysis and photofermentation via PS I and electron chain;thereafter,fermentative hydrogen production is considered as the most responsible for providing electrons to hydrogenase,which is independent of photosystem electron transfer chain. Fermentative metabolites assay indicated that light and DBMIB inhibited fermentative ethanol production that is the competitive pathway for the cellular reducing power,resulting in higher photo-hydrogen yield.
作者 纪超凡 虞星炬 薛松 陈兆安 张卫
机构地区 中国科学院大连化学物理研究所 中国科学院研究生院 Universite de Nantes Flinders University
出处 《微生物学通报》 CAS CSCD 北大核心 2011年第11期1666-1672,共7页 Microbiology China
基金 国家重点基础研究发展计划项目(No.2009CB220004)
关键词 亚心型四爿藻 产氢代谢 厌氧发酵 CCCP Tetraselmis subcordiformis Hydrogen metabolism Anerobic fermentation CCCP
分类号 TQ116.2 [化学工程—无机化工]
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参考文献19

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同被引文献46

  • 1王海宾,贾万利,柳耀辉.生物制氢的现状与发展趋势[J].生物技术,2005,15(4):90-93. 被引量:12
  • 2冉春秋,张卫,虞星炬,金美芳,邓麦村.解偶联剂CCCP对莱茵衣藻光照产氢过程的调控[J].高等学校化学学报,2006,27(1):62-66. 被引量:11
  • 3谭万能,李志安,邹碧.植物对重金属耐性的分子生态机理[J].植物生态学报,2006,30(4):703-712. 被引量:50
  • 4郑安桥,张先中,苏亚欣.生物质气化制氢研究现状[J].能源与环境,2007(2):72-75. 被引量:5
  • 5Ilgi Karapinar Kapdan, Fikret Kargi. Bio-hydrogen production fromwaste materialsfJ]. Enzyme and Microbial Technology,2006,38(5):569-582.
  • 6Elif Kirtay. Recent advances in production of hydrogen from bio-mass[J].Energy Conversion and Management,2011,52(4):1778-1789.
  • 7Skj K, Knutsen G, Kallqvist T, et al. H2 production from marine andfreshwater species of green algae during sulfur deprivation andconsiderations for bioreactor design[J] .International Journal ofHydrogen Energy,2008,33(2):511-521.
  • 8Kamp C, Silakov A, Winkler M, et al. Isolation and first EPRcharacterization of the [FeFe]- hydrogenases from green algae [J].Biochimica Et Biophysica Acta- Bioener^etics,2008,1777(5):410-416.
  • 9Jeffrey Moseley, Jeanette Quinn, Mats Eriksson, et al. The Crdlgene encodes a putative di-iron enzyme required for photosystem Iaccumulation in copper deficiency and hypoxia in Chlamydomonasreinhardtii[J].EMBO J,2000,19(10):2139-2151.
  • 10Anastasios Melis,Liping Zhang, Marc Forestier, et al. SustainedPhotobiological Hydrogen Gas Production upon ReversibleInactivation of Oxygen Evolution in the Green AlgaChlamydomonasreinhardtiil[J]. Plant Physiology,2000,122(1):127-135.

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微生物学通报
2011年 第11期

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