氢化酶结构研究进展

氢化酶是微生物代谢产氢过程中的关键酶,也是目前生物制氢领域的研究热点。本文综述了厌氧发酵产氢微生物中氢化酶的分类及特点,以及[Ni—Fe]、[Fe—Fe]和[Fe—Scluster—free]三种氢化酶晶体结构和活性中心结构;阐述了多种微生物来源的氢化酶结构的研究进展,对几种典型氢化酶的结构及活性中心进行了对比分析,并根据当前研究热点,对氢化酶的研究方向进行了展望。本文阐述的内容信息量丰富且具有一定的实用性,对于氢化酶相关领域研究具有重要的意义。     

绿藻高效制氢影响因素的研究

绿藻作为生物能源的研究和开发具有诱人的发展前景。本文概述了绿藻制氢和产氢途径的研究进展,重点介绍了绿藻高效制氢的影响因素--绿藻[Fe]-氢化酶的研究和绿藻制氢的重要控制参数,同时,对绿藻制氢作为生物能源的开发应用前景进行了展望。     

绿色巴夫藻和四列藻种间竞争机制研究

种间竞争是生物普遍存在的一种生命现象 ,可以利用来调控生物的生长和数量变化 ,进行有害生物的防治。藻类植物间也存在明显的竞争现象。Ｈｏｌｍ[8] 报道了硅藻和微囊藻种间的相互作用。Ｈｅｇａｒｔｙ[9] 研究了光强和Ｎ、Ｐ比对棕囊藻和 5种硅藻间竞争的影响。Ｋｕｗａｔａ[10 ] 研究了铵盐对绿藻和蓝藻间竞争作用的影响。Ｄａｖｉｓ[11] 研究了海藻和海草间的竞争。Ｐｉａｚｚｉ[12 ] 研究了两种海洋绿藻生长的竞争情况。刘世枚[1] 研究了两种绿藻种群间的相互作用。陈德辉等[2 ] 对微囊藻和栅藻共培养进行了研究并计算了竞争参数。。绿…     

异源表达【FeFe】氢酶的基因工程大肠杆菌的构建

摘要:【目的】探讨一种构建异源表达【FeFe】氢酶的重组大肠杆菌的新方法。【方法】通过同源重组,依次将来源于丙酮丁醇梭菌中促进【FeFe】氢酶成熟的3 个辅助基因hydE、hydF 和hydG 分别整合到大肠杆菌BW2513-10(缺失氢酶基因) 的丙酮酸甲酸脱氢酶(ybiW)、乳酸脱氢酶(ldh) 和乙醇脱氢酶(adhE) 编码基因位点上。在此基础上进一步将含有来源于丁酸梭菌的氢酶基因的表达载体转化上述重组菌,并对转化子的氢酶活性进行分析。【结果】PCR 和RT-PCR 的检测结果表明,3 个辅助基因都     

衣藻生物制氢的研究进展

综述了利用衣藻生产氢气作为再生能源的研究进展。分别介绍了衣藻产氢的代谢机理、培养条件、衣藻氢化酶的特性以及利用分子生物学手段、生物信息学手段和生物工程技术提高衣藻生物制氢效率的方法,包括氢化酶的氧耐受性的改造、外源氢化酶基因的表达、影响衣藻产氢的关键基因的筛选、利用缺硫培养基和固定化培养方法提高氢气产量等。最后,还对利用衣藻生物制氢的可行性和经济性进行了分析,对其发展方向提出自己的看法。     

厌氧消化微生物氢代谢活性的研究I．产甲烷菌的“MV”氢化酶活性

本文介绍了产甲烷菌纯培养物H一13、CB—12及几种消化污汜中产甲烷菌的“MV”氢化酶话性。对利用H,,co,、甲酸、自然基质等不同营养类型的产甲烷菌的“MV”氢化酶活性进行了测定。试验结果表明,产甲烷菌的“MV”氢化酶活性与试样的产甲烷能力及产甲烷菌纯培养物的旅度呈现明显的正相关。研究中所使用的氢化酶分析方法不受底物浓度的影响。这些现象的揭示,对微生物厌氧消化的研究有着重要的意义。     

雨生红球藻抗氧化系统对活性氧的清除机制

雨生红球藻(Haematococcus pluvialis)是一种淡水单细胞绿藻,隶属绿藻门、团藻目、红球藻科、红球藻属。它受强光、氮饥饿、高盐等胁迫时积累大量的虾青素,含量可高达细胞干重的6.0%以上[1]。相关研究也显示来虾青素具有极强的抗氧化活性[2—4],它的抗氧化活性较α-生育酚强千倍[5],比维生素E高近百倍[6]。雨生红球藻产生     

脑炎原虫豚鼠感染模型的实验研究

[目的]建立脑炎原虫感染豚鼠模型,分析白化豚鼠和花色豚鼠在脑炎原虫感染动物模型建立中的异同点。[方法]动物分四组:花色组、白化组、花色应用氢化可的松组、白化应用氢化可的松组,16只/组。发病兔粪便中收集纯化脑炎原虫虫体,灌胃法接种豚鼠,染虫后不同时间点粪便捡虫观察豚鼠染虫率。造模后30天心脏采血,测免疫球蛋白含量,HE染色观察豚鼠主要脏器病变,纯化后虫体行电镜超微结构观察。[结果]接种之后7天内,未用氢化可的松的两组均未检出原虫,用氢化可的松的两组中,白化豚鼠最先在第3天检出,于第6天全部检出,而花色豚鼠最先在第4天检出,在…     

高等植物氢化酶活性研究进展

氢化酶作为一种可催化氢气氧化与质子还原的金属酶,在生物体的氢代谢过程中发挥着关键作用。已有研究表明,氢气干预可对植物的生长发育和抗逆性产生积极影响,同时一些高等植物的内源性产氢现象也已得到证实,然而关于催化内源性产氢的氢化酶目前了解较少。虽然已有多项研究表明,叶绿体可能是高等植物产氢的关键部位,但是鉴于多种植物在种子萌发时仍然可以产氢,而种子萌发过程中叶绿体还没有生成,加上氢化酶在进化上与线粒体复合物Ⅰ具有同源性,在对氢化酶研究现状进行概述的基础上,提出了高等植物线粒体具有氢化酶活性的猜想,并总结了线粒体存在氢化酶活性的初步实验证据,以期为后续线粒体与氢化酶的关系研究提供参考依据。     

衣藻质体分裂相关基因CrFtsZ2的克隆及其进化分析

ＦｔｓＺ(ｆｉｌａｍｅｎｔｉｎｇｔｅｍｐｅｒａｔｕｒｅｓｅｎｓｉｔｉｖｅ)是一类从大肠杆菌温度敏感型突变体中分离到的基因 .该基因与Ｅ .ｃｏｌｉ细胞分裂密切相关 .突变体由于细胞分裂受阻而呈现“长丝状”[1] .此类基因于 1980年首次被克隆[2 ] .随后的研究表明 ,ＦｔｓＺ蛋白在Ｅ .ｃｏｌｉ分裂细胞的凹陷处形成环状多聚体 ,Ｚ环 ,是Ｅ .ｃｏｌｉ细胞分裂的限制因子[3 ] .衣藻属于绿藻 ,在现存的所有单细胞真核藻类中 ,绿藻是与陆生植物亲缘关系最近的一支[4] .由于衣藻为单细胞真核生物 ,并且仅含有一个巨大的叶绿体 ,因而是研究…     

Functional studies of [FeFe] hydrogenase maturation in an Escherichia coli biosynthetic system

Maturation of [FeFe] hydrogenases requires the biosynthesis and insertion of the catalytic iron-sulfur cluster, the H cluster. Two radical S-adenosylmethionine (SAM) proteins proposed to function in H cluster biosynthesis, HydEF and HydG, were recently identified in the hydEF-1 mutant of the green alga Chlamydomonas reinhardtii (M. C. Posewitz, P. W. King, S. L. Smolinski, L. Zhang, M. Seibert, and M. L. Ghirardi, J. Biol. Chem. 279:25711-25720, 2004). Previous efforts to study [FeFe] hydrogenase maturation in Escherichia coli by coexpression of C. reinhardtii HydEF and HydG and the HydA1 [FeFe] hydrogenase were hindered by instability of the hydEF and hydG expression clones. A more stable [FeFe] hydrogenase expression system has been achieved in E. coli by cloning and coexpression of hydE, hydF, and hydG from the bacterium Clostridium acetobutylicum. Coexpression of the C. acetobutylicum maturation proteins with various algal and bacterial [FeFe] hydrogenases in E. coli resulted in purified enzymes with specific activities that were similar to those of the enzymes purified from native sources. In the case of structurally complex [FeFe] hydrogenases, maturation of the catalytic sites could occur in the absence of an accessory iron-sulfur cluster domain. Initial investigations of the structure and function of the maturation proteins HydE, HydF, and HydG showed that the highly conserved radical-SAM domains of both HydE and HydG and the GTPase domain of HydF were essential for achieving biosynthesis of active [FeFe] hydrogenases. Together, these results demonstrate that the catalytic domain and a functionally complete set of Hyd maturation proteins are fundamental to achieving biosynthesis of catalytic [FeFe] hydrogenases.     

Isolation and first EPR characterization of the [FeFe]-hydrogenases from green algae

Hydrogenase expression in Chlamydomonas reinhardtii can be artificially induced by anaerobic adaptation or is naturally established under sulphur deprivation. In comparison to anaerobic adaptation, sulphur-deprived algal cultures show considerably higher expression rates of the [FeFe]-hydrogenase (HydA1) and develop a 25-fold higher in vitro hydrogenase activity. Based on this efficient induction principle we have established a novel purification protocol for the isolation of HydA1 that can also be used for other green algae. From an eight liter C. reinhardtii culture 0.52 mg HydA1 with a specific activity of 741 micromol H2 min(-1) mg(-1) was isolated. Similar amounts were also purified from Chlorococcum submarinum and Chlamydomonas moewusii. The extraordinarily large yields of protein allowed a spectroscopic characterization of the active site of these smallest [FeFe]-hydrogenases for the first time. An initial analysis by EPR spectroscopy shows characteristic axial EPR signals of the CO inhibited forms that are typical for the Hox-CO state of the active site from [FeFe]-hydrogenases. However, deviations in the g-tensor components have been observed that indicate distinct differences in the electronic structure between the various hydrogenases. At cryogenic temperatures, light-induced changes in the EPR spectra were observed and are interpreted as a photodissociation of the inhibiting CO ligand.     

Synthetic biology for improved hydrogen production in Chlamydomonas reinhardtii

Hydrogen is a clean alternative to fossil fuels. It has applications for electricity generation and transportation and is used for the manufacturing of ammonia and steel. However, today, H₂ is almost exclusively produced from coal and natural gas. As such, methods to produce H₂ that do not use fossil fuels need to be developed and adopted. The biological manufacturing of H₂ may be one promising solution as this process is clean and renewable. Hydrogen is produced biologically via enzymes called hydrogenases. There are three classes of hydrogenases namely [FeFe], [NiFe] and [Fe] hydrogenases. The [FeFe] hydrogenase HydA1 from the model unicellular algae Chlamydomonas reinhardtii has been studied extensively and belongs to the A1 subclass of [FeFe] hydrogenases that have the highest turnover frequencies amongst hydrogenases (21,000 ± 12,000 H₂ s⁻¹ for CaHydA from Clostridium acetobutyliticum). Yet to date, limitations in C. reinhardtii H₂ production pathways have hampered commercial scale implementation, in part due to O₂ sensitivity of hydrogenases and competing metabolic pathways, resulting in low H₂ production efficiency. Here, we describe key processes in the biogenesis of HydA1 and H₂ production pathways in C. reinhardtii. We also summarize recent advancements of algal H₂ production using synthetic biology and describe valuable tools such as high-throughput screening (HTS) assays to accelerate the process of engineering algae for commercial biological H₂ production.     

Genomic Analysis Reveals Multiple [FeFe] Hydrogenases and Hydrogen Sensors Encoded by Treponemes from the H<Subscript>2</Subscript>-Rich Termite Gut

We have completed a bioinformatic analysis of the hydrogenases encoded in the genomes of three termite gut treponeme isolates: hydrogenotrophic, homoacetogenic Treponema primitia strains ZAS-1 and ZAS-2, and the hydrogen-producing, sugar-fermenting Treponema azotonutricium ZAS-9. H₂ is an important free intermediate in the breakdown of wood by termite gut microbial communities, reaching concentrations in some species exceeding those measured for any other biological system. The spirochetes encoded 4, 8, and 5 [FeFe] hydrogenase-like proteins, identified by their H domains, respectively, but no other recognizable hydrogenases. The [FeFe] hydrogenases represented many sequence families previously proposed in an analysis of termite gut metagenomic data. Each strain encoded both putative [FeFe] hydrogenase enzymes and evolutionarily related hydrogen sensor/transducer proteins likely involved in phosphorelay or methylation pathways, and possibly even chemotaxis. A new family of [FeFe] hydrogenases (FDH-Linked) is proposed that may form a multimeric complex with formate dehydrogenase to provide reducing equivalents for reductive acetogenesis in T. primitia. The many and diverse [FeFe] hydrogenase-like proteins encoded within the sequenced genomes of the termite gut treponemes has enabled the discovery of a putative new class of [FeFe] hydrogenase proteins potentially involved in acetogenesis and furthered present understanding of many families, including sensory, of H domain proteins beyond what was possible through the use of fragmentary termite gut metagenome sequence data alone, from which they were initially defined.     

Genetic diversity and amplification of different clostridial [FeFe] hydrogenases by group-specific degenerate primers

Aims: The aim of this study was to explore and characterize the genetic diversity of [FeFe] hydrogenases in a representative set of strains from Clostridium sp. and to reveal the existence of neither yet detected nor characterized [FeFe] hydrogenases in hydrogen‐producing strains. Methods and Results: The genomes of 57 Clostridium strains (34 different genotypic species), representing six phylogenetic clusters based on their 16S rRNA sequence analysis (cluster I, III, XIa, XIb, XIV and XVIII), were screened for different [FeFe] hydrogenases. Based on the obtained alignments, ten pairs of [FeFe] hydrogenase cluster‐specific degenerate primers were newly designed. Ten Clostridium strains were screened by PCRs to assess the specificity of the primers designed and to examine the genetic diversity of [FeFe] hydrogenases. Using this approach, a diversity of hydrogenase genes was discovered in several species previously shown to produce hydrogen in bioreactors: Clostridium sartagoforme, Clostridium felsineum, Clostridium roseum and Clostridium pasteurianum. Conclusions: The newly designed [FeFe] hydrogenase cluster‐specific primers, targeting the cluster‐conserved regions, allow for a direct amplification of a specific hydrogenase gene from the species of interest. Significance and Impact of the Study: Using this strategy for a screening of different Clostridium ssp. will provide new insights into the diversity of hydrogenase genes and should be a first step to study a complex hydrogen metabolism of this genus.     

Application of gene-shuffling for the rapid generation of novel [FeFe]-hydrogenase libraries

A gene-shuffling technique was identified, optimized and used to generate diverse libraries of recombinant [FeFe]-hydrogenases. Six native [FeFe]-hydrogenase genes from species of Clostridia were first cloned and separately expressed in Escherichia coli concomitantly with the assembly proteins required for [FeFe]-hydrogenase maturation. All enzymes, with the exception of C. thermocellum HydA, exhibited significant activity when expressed. Single-stranded DNA fragments from genes encoding the two most active [FeFe]-hydrogenases were used to optimize a gene-shuffling protocol and generate recombinant enzyme libraries. Random sampling demonstrates that several shuffled products are active. This represents the first successful application of gene-shuffling using hydrogenases. Moreover, we demonstrate that a single set of [FeFe]-hydrogenase maturation proteins is sufficient for the heterologous assembly of the bioinorganic active site of several native and shuffled [FeFe]-hydrogenases.     

Desulfovibrio vulgaris Hildenborough HydE and HydG interact with the HydA subunit of the [FeFe] hydrogenase

HydE, HydF, and HydG participate in the synthesis of the complex di-iron center of [FeFe] hydrogenases. The hydE, hydF, hydG, hydA, and hydB genes of Desulfovibrio vulgaris Hildenborough were cloned and His-tag pull-down assays were used to study the potential interaction between HydE, HydF, and HydG with the HydA and HydB protein subunits of the D. vulgaris [FeFe] hydrogenase. Interaction of HydE and HydG with HydA was demonstrated. HydF did not interact with HydA, and none of the accessory proteins appeared to interact with HydB. This suggests that specific protein-protein interactions may be required during [FeFe] cluster synthesis and/or insertion.     

Selenium is involved in regulation of periplasmic hydrogenase gene expression in Desulfovibrio vulgaris Hildenborough

Desulfovibrio vulgaris Hildenborough is a good model organism to study hydrogen metabolism in sulfate-reducing bacteria. Hydrogen is a key compound for these organisms, since it is one of their major energy sources in natural habitats and also an intermediate in the energy metabolism. The D. vulgaris Hildenborough genome codes for six different hydrogenases, but only three of them, the periplasmic-facing [FeFe], [FeNi]1, and [FeNiSe] hydrogenases, are usually detected. In this work, we studied the synthesis of each of these enzymes in response to different electron donors and acceptors for growth as well as in response to the availability of Ni and Se. The formation of the three hydrogenases was not very strongly affected by the electron donors or acceptors used, but the highest levels were observed after growth with hydrogen as electron donor and lowest with thiosulfate as electron acceptor. The major effect observed was with inclusion of Se in the growth medium, which led to a strong repression of the [FeFe] and [NiFe]1 hydrogenases and a strong increase in the [NiFeSe] hydrogenase that is not detected in the absence of Se. Ni also led to increased formation of the [NiFe]1 hydrogenase, except for growth with H2, where its synthesis is very high even without Ni added to the medium. Growth with H2 results in a strong increase in the soluble forms of the [NiFe]1 and [NiFeSe] hydrogenases. This study is an important contribution to understanding why D. vulgaris Hildenborough has three periplasmic hydrogenases. It supports their similar physiological role in H2 oxidation and reveals that element availability has a strong influence in their relative expression.