伊夫塔克·雅克比手持两管物质:他的左手拿着从植物中提取的细胞膜;右手则拿着铁氧还蛋白,该物质将有效提高氢能产量。
伊夫塔克·雅克比(左)与张曙光
一个国际合作研究小组近日宣布,他们找到可提高海藻的氢气产量的方法,这或将使未来氢能大规模、低成本获取的想法成为现实。研究报告发表在近期的美国《国家科学院院刊》(PNAS)上。
通常情况下,许多藻类、细菌及水生物都可以通过吸收光能来分解水分子,从而释放氢气。
论文第一作者伊夫塔克·雅克比(Iftach Yacoby)解释说,藻类产生的氢气只是一种副产物,产量很少。但如果向海藻生存的环境中加入一种酶,便可抑制海藻的产糖量(只能是抑制,不能停止,否则海藻将无法生存),从而使得氢气的产量得到提升。经过研究,他们发现加入指定酶后,海藻所产生的氢气总量增加了4倍。
这项研究的领导人、美国麻省理工学院(MIT)生物医学工程中心副主任张曙光(Shuguang Zhang)说:“这一研究过程有很大可能实现产业化”,“你必须懂得这一过程所产生的实用价值,从而将氢燃料生产发展到商业规模,这只是时间和金钱的问题”,“费用问题解决了,我们将加快其实现的速度”。
张曙光表示,他的小组还将在此基础上深入研究如何提高氢气的产率。
相关仪器:NuPAGE® Novex® Bis-Tris凝胶系统
完成人:张曙光课题组/保罗·金课题组
实验室:美国麻省理工学院生物医学工程中心 国立可再生能源实验室生物科学中心 以色列特拉维夫大学生物化学与分子生物学系
生物探索推荐英文原文:
Photosynthetic electron partitioning between [FeFe]-hydrogenase and ferredoxin:NADP+-oxidoreductase (FNR) enzymes in vitro
Abstract:Photosynthetic water splitting, coupled to hydrogenase-catalyzed hydrogen production, is considered a promising clean, renewable source of energy. It is widely accepted that the oxygen sensitivity of hydrogen production, combined with competition between hydrogenases and NADPH-dependent carbon dioxide fixation are the main limitations for its commercialization. Here we provide evidence that, under the anaerobic conditions that support hydrogen production, there is a significant loss of photosynthetic electrons toward NADPH production in vitro. To elucidate the basis for competition, we bioengineered a ferredoxin-hydrogenase fusion and characterized hydrogen production kinetics in the presence of Fd, ferredoxin:NADP+-oxidoreductase (FNR), and NADP+. Replacing the hydrogenase with a ferredoxin-hydrogenase fusion switched the bias of electron transfer from FNR to hydrogenase and resulted in an increased rate of hydrogen photoproduction. These results suggest a new direction for improvement of biohydrogen production and a means to further resolve the mechanisms that control partitioning of photosynthetic electron transport.
