典型产纤维小体梭菌的遗传改造及其在纤维素乙醇中的应用研究进展

以解纤维梭菌(Clostridium cellulolyticum)和热纤梭菌(Clostridium thermocellum)为代表的产纤维小体梭菌可以直接完成从木质纤维素原料到乙醇的生物转化,是用于通过整合生物加工技术生产纤维素乙醇的优良候选菌株。然而,这些产纤维小体梭菌的纤维素降解效率及乙醇产量尚不能满足工业化生产的要求,其遗传改造技术的不成熟严重制约了通过定向代谢工程改造提高生产性能的进程。针对这些典型的产纤维小体菌株,各国科学家近年来在基于二类内含子的嗜中温及嗜高温遗传改造平台建立方面取得了较大突破,并通过靶向代谢工程改造,显著提高纤维素乙醇的产量。笔者对这些前期研究工作以及国内外相关研究成果进行系统的总结,并对构建的遗传改造工具的应用前景进行展望。     

酿酒酵母人造纤维小体的研究进展简

纤维素乙醇的统合生物加工过程（consolidated bioprocessing,CBP）是将（半）纤维素酶生产、纤维素水解和乙醇发酵过程组合,通过一种微生物完成的生物加工过程。 CBP有利于降低生物转化过程的成本,受到研究者的普遍关注。酿酒酵母（ Saccharomyces cerevisiae）作为传统的乙醇生产菌株,是极具潜力的CBP底盘细胞。纤维小体是某些厌氧微生物细胞表面由纤维素酶系与支架蛋白组成的大分子复合物,它能高效降解木质纤维,在酿酒酵母表面展示纤维小体已成为构建CBP细胞的研究热点。笔者综述了人造纤维小体在酿酒酵母细胞表面展示组装的研究进展,重点阐述了纤维小体各元件的设计和改造,并针对酿酒酵母分泌途径的改造,提出提高人造纤维小体分泌组装的可能性策略。     

酿酒酵母 L-阿拉伯糖转化乙醇代谢工程的研究进展简

L-阿拉伯糖是木质纤维素原料中一种重要的五碳糖组分,但传统的乙醇生产菌株酿酒酵母（ Saccharomyces cerevisiae）不能利用L 阿拉伯糖。通过代谢途径工程手段,在酿酒酵母中引入L 阿拉伯糖初始代谢途径可以获得能利用L 阿拉伯糖乙醇发酵的重组菌株。并且,通过代谢途径的疏通以及吸收系统的优化可以强化重组菌株代谢L 阿拉伯糖的能力。笔者从以上角度综述了近年来酿酒酵母转化L 阿拉伯糖生产乙醇的研究进展。     

草鱼肠道纤维素降解细菌的分离与鉴定简

为更好地弄清草鱼(Ctenopharyngodon idella)肠道纤维素降解细菌的种类,采用羧甲基纤维素(CMC)作为唯一碳源的选择性培养基,分别从草鱼肠道内容物和肠道黏膜中分离到了40株产纤维素酶细菌。16S rRNA基因序列的分析结果显示,大多数产纤维素酶细菌为气单胞菌属(Aeromonas)的种类,其次为肠杆菌属(Enterobacter)的细菌以及未经分离纯培养的细菌(Uncultured bacterium)。进一步研究细菌产纤维素酶能力发现,纤维素酶活性显著性高于其他菌株的分别是A.veronii MC2、A.veronii BC6、肠杆菌科(Enterobacteriaceae)中一种未经分离纯培养的细菌BM3(Uncultured bacterium BM3)和A.jandaei HC9。草鱼肠道中简答气单胞菌(A.jandaei)、类志贺邻单胞菌(Plesiomonas shigelloides)、阴沟肠杆菌(E.cloacae)以及产气肠杆菌(E.aerogenes)是被作为产纤维素酶细菌的首次报道。     

粗糙脉孢菌木质纤维素降解利用研究进展简

粗糙脉孢菌作为木质纤维素降解真菌,不仅具有完整的木质纤维素降解酶系,而且还拥有全基因组基因敲除突变体库,是研究丝状真菌纤维素酶表达分泌和木质纤维素降解机制的优秀体系。近年来,国内外利用粗糙脉孢菌系统,在木质纤维素降解机制方面取得了显著进展,包括纤维素酶信号传导、调控以及生物质降解后糖的转运利用等。笔者就相关方面的进展进行综述,并对利用粗糙脉孢菌研究木质纤维素降解利用进行展望,总结和分析木质纤维素降解机制研究的国际前沿动态,有助于加深本领域研究人员对真菌体系纤维素降解机制的理解。     

极端嗜热厌氧菌 Caldicellulosiruptor 木质纤维素降解研究简

随着能源危机的加剧,木质纤维素作为生产生物能源的重要原料得到人们的广泛关注。目前,极端嗜热厌氧菌Caldicellulosiruptor属已发现8个种,具有高效的木质纤维素降解能力,甚至可以作用于未经预处理的木质纤维素。自从20世纪80年代以来,人们在Caldicellulosiruptor属的菌株生理生化性质、木质纤维素降解机制及转化能力、基因组、转录组及蛋白质组、遗传转化体系等方面,都取得了一系列研究成果。笔者对嗜热厌氧菌Caldicellulosiruptor属木质纤维素降解的研究现状及前景进行综述及展望。     

螺带桨搅拌在木质纤维素酸预处理反应器中的应用简

在干式稀酸预处理的反应器中采用螺带桨搅拌器,对秸秆预处理体系进行混合。在带有螺带式搅拌的预处理过程中,在质量分数2.0％和2.5％的H2 SO4用量条件下,预处理后72 h秸秆的酶解糖化得率分别为77.55％和87.11％,比静态预处理得到的得率分别增长了7.6％和2.4％,抑制物的生成显著降低。通过计算流体力学方法验证,螺带桨搅拌器可以有效地改善玉米秸秆在稀酸预处理过程中的蒸汽和秸秆两相的混合情况。     

木质纤维素酶基因资源挖掘及真菌酶系改造简

简述了木质纤维素酶基因资源挖掘的策略和方法及其在丝状真菌酶系改造中的应用。从候选基因的获取（木质纤维素酶基因资源的挖掘和高效利用）、外源基因的表达、酶系的复配和重构等方面综述了丝状真菌酶系改造的最新进展,并提出了丝状真菌酶系改造中亟须解决的关键问题。     

微生物木糖发酵产乙醇的代谢工程

利用木质纤维素发酵生产乙醇具有广泛的应用前景。而自然界中缺少有效转化木糖为乙醇的微生物是充分利用纤维素水解产物、提高乙醇产率、降低生产成本的关键因素。多年来研究者利用分子生物学技术对微生物菌株进行了代谢工程改造,使其能更有效地利用木糖生产乙醇。以下主要对运动发酵单胞菌、大肠杆菌和酵母等候选产乙醇微生物的木糖代谢工程研究进展进行了概述。     

纤维素乙醇工程化探讨

出于对能源安全、大气污染的担忧以及促进农村经济发展的考虑,世界许多国家使用乙醇作为含氧添加剂或交通运输燃料来替代汽油。纤维素乙醇生产原料丰富,且具有明显的低碳排放特性而备受关注。随着全球范围内几套大型纤维素乙醇示范装置的相继试车,工程化问题将得到解决,并有望在2015-2016年完成装置的经济性考核,逐步进入商业化阶段。为避免原料"与人争粮,与粮争地",1代燃料乙醇将逐步向2代纤维素乙醇过渡。本文在综述近期国内外纤维素乙醇产业化概况的基础上,从化学工程和生物工程的角度对预处理、酶制剂及酶解工艺、戊糖/己糖共发酵菌株及工艺、装备等几个方面的技术进展进行剖析,讨论了工程化遇到的主要问题,探讨了我国纤维素乙醇技术的发展方向。     

Improved ethanol tolerance and production in strains of Clostridium thermocellum

Two Clostridium thermocellum strains were improved for ethanol tolerance, to 5% (v/v), by gradual adaptation and mutation. The best mutant gave an ethanol yield of 0.37 g/g substrate, with a growth yield 1.5 times more than its parent. Accumulation of acids and reducing sugars by the mutant strain with 5% (v/v) ethanol was lower than that of the parent strain with 1.5% (v/v) ethanol.     

产乙醇工程菌研究进展

伴随着21世纪的到来,低油价的时代也悄然落幕。简要概述了燃料乙醇产生菌代谢工程的研究进展,包括了利用淀粉、戊糖及纤维素的工程酵母构建,运动发酵单胞菌利用戊糖工程菌的构建,引入外源乙醇合成途径的大肠埃希氏菌和产酸克雷伯氏菌等。对燃料乙醇的重视将促进开发能利用廉价原料和要求粗放的工程菌株用于高产乙醇的生产过程,以降低成本和能耗,其中能利用生淀粉的工程酵母及利用木质纤维素水解物的运动发酵单胞菌工程菌有较大的工业化潜力。     

Major characteristics of the cellulolytic system of Clostridium thermocellum coincide with those of the purified cellulosome

The properties of the cellulosome (a cellulose-binding, multiple cellulase-containing protein complex isolated from Clostridium thermocellum) have been compared with the previously reported characteristics for crude cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] preparations. Similar to the crude enzyme system, true cellulolytic activity was demonstrated for the purified cellulosome on the basis of extensive solubilization of microcrystalline cellulose. The cellulolytic activity of the purified cellulosome was enhanced both by calcium ions and by thiols, and was inhibited by cellobiose (the major end product of the cellulosome-mediated cellulose degradation). In addition, at low ionic strength, cellulose-adsorbed cellulosome was detached intact from the cellulose matrix. Using controlled conditions, maximum enzymatic activity was shown to correspond to suboptimal conditions of cellulosome adsorption to cellulose. The results suggest that previous data accumulated for the crude cellulase system in C. thermocellum essentially reflect the contribution of the cellulosome.     

Genetic engineering of Clostridium thermocellum DSM1313 for enhanced ethanol production

Background

The twin problem of shortage in fossil fuel and increase in environmental pollution can be partly addressed by blending of ethanol with transport fuel. Increasing the ethanol production for this purpose without affecting the food security of the countries would require the use of cellulosic plant materials as substrate. Clostridium thermocellum is an anaerobic thermophilic bacterium with cellulolytic property and the ability to produce ethanol. But its application as biocatalyst for ethanol production is limited because pyruvate ferredoxin oxidoreductase, which diverts pyruvate to ethanol production pathway, has low affinity to the substrate. Therefore, the present study was undertaken to genetically modify C. thermocellum for enhancing its ethanol production capacity by transferring pyruvate carboxylase (pdc) and alcohol dehydrogenase (adh) genes of the homoethanol pathway from Zymomonas mobilis.

Results

The pdc and adh genes from Z. mobilis were cloned in pNW33N, and transformed to Clostridium thermocellum DSM 1313 by electroporation to generate recombinant CTH-pdc, CTH-adh and CTH-pdc-adh strains that carried heterologous pdc, adh, and both genes, respectively. The plasmids were stably maintained in the recombinant strains. Though both pdc and adh were functional in C. thermocellum, the presence of adh severely limited the growth of the recombinant strains, irrespective of the presence or absence of the pdc gene. The recombinant CTH-pdc strain showed two-fold increase in pyruvate carboxylase activity and ethanol production when compared with the wild type strain.

Conclusions

Pyruvate decarboxylase gene of the homoethanol pathway from Z mobilis was functional in recombinant C. thermocellum strain and enhanced its ability to produced ethanol. Strain improvement and bioprocess optimizations may further increase the ethanol production from this recombinant strain.

     

兼性厌氧复合菌群H纤维素降解和产乙醇能力及生态组成初探

通过限制性培养条件和连续继代培养,筛选获得了一组具有高效稳定降解纤维素能力的复合菌群H。该菌群在传代30代以上仍能保持各项性状稳定,其工作pH为6～9,3 d可以完全降解置于100 mL PCS缓冲液培养基中的滤纸,发酵液中能够检出1.54 g/L乙醇。通过16S rDNA扩增和DGGE的方法,对菌群在不同阶段的微生物组成进行了研究,确定了琥珀酸嗜热梭菌Clostridium thermo succinogene、产气荚膜梭菌Clostridium straminisolvens和紫色板蓝根梭菌Clostridium isatidis等多种可直接实现纤维素到乙醇转化的菌株。菌群通过菌种之间的协同作用,共同维持了体系的稳定及降解能力的稳定。明确菌系的组成,对于进一步研究菌群降解机理、优化菌群和提高乙醇产率意义重大。     

Thiolase engineering for enhanced butanol production in Clostridium acetobutylicum

Biosynthetic thiolases catalyze the condensation of two molecules acetyl‐CoA to acetoacetyl‐CoA and represent key enzymes for carbon–carbon bond forming metabolic pathways. An important biotechnological example of such a pathway is the clostridial n‐butanol production, comprising various natural constraints that limit titer, yield, and productivity. In this study, the thiolase of Clostridium acetobutylicum, the model organism for solventogenic clostridia, was specifically engineered for reduced sensitivity towards its physiological inhibitor coenzyme A (CoA‐SH). A high‐throughput screening assay in 96‐well microtiter plates was developed employing Escherichia coli as host cells for expression of a mutant thiolase gene library. Screening of this library resulted in the identification of a thiolase derivative with significantly increased activity in the presence of free CoA‐SH. This optimized thiolase comprised three amino acid substitutions (R133G, H156N, G222V) and its gene was expressed in C. acetobutylicum ATCC 824 to assess the effect of reduced CoA‐SH sensitivity on solvent production. In addition to a clearly delayed ethanol and acetone formation, the ethanol and butanol titers were increased by 46% and 18%, respectively, while the final acetone concentrations were similar to the vector control strain. These results demonstrate that thiolase engineering constitutes a suitable methodology applicable to improve clostridial butanol production, but other biosynthetic pathways involving thiolase‐mediated carbon flux limitations might also be subjected to this new metabolic engineering approach. Biotechnol. Bioeng. 2013; 110: 887–897. © 2012 Wiley Periodicals, Inc.     

Genetic engineering of Bacillus subtilis for the commercial production of riboflavin

Recombinant DNA engineering was combined with mutant selection and fermentation improvement to develop a strain of Bacillus subtilis that produces commercially attractive levels of riboflavin. The B. subtilis riboflavin production strain contains multiple copies of a modified B. subtilis riboflavin biosynthetic operon (rib operon) integrated at two different sites in the B. subtilis chromosome. The modified rib operons are expressed constitutively from strong phage promoters located at the 5′ end and in an internal region of the operon. The engineered strain also contains purine analog-resistant mutations designed to deregulate the purine pathway (GTP is the precursor for riboflavin), and a riboflavin analog-resistant mutation in ribC that deregulates the riboflavin biosynthetic pathway. Received 22 June 1998/ Accepted in revised form 6 November 1998