极端嗜热厌氧菌Caldicellulosiruptor木质纤维素降解研究

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。     

嗜热厌氧细菌Caldicellulosiruptor bescii降解木质纤维素研究进展

嗜热厌氧菌Caldicellulosiruptor bescii具有强大的木质纤维素降解能力,能以多种模式植物细胞壁多糖如微晶纤维素Avicel和木聚糖,甚至未经预处理的木质纤维素如柳枝稷作为唯一碳源快速生长,该菌还具有少见的厌氧降解木质素的能力。对基因组注释发现,该菌所编码的蛋白大多为多结构域双功能酶,即在多肽链的N端和C端分别是不同家族的糖苷水解酶,间隔以2-3个碳水化合物结合结构域。该菌降解纤维素相关的酶基因多集中于一个植物细胞壁多糖降解利用的基因簇,例如纤维素酶/木聚糖酶、纤维素酶/甘露聚糖酶和纤维素酶/木葡聚糖酶等。C.bescii的木聚糖酶主要属于GH10家族,该家族的酶底物特异性较为宽泛,氨基酸序列的同源性在18.7%-59.5%间。Caldicellulosiruptor属细菌进化出了一系列的机制使得糖苷水解酶和底物、细菌和木质纤维素能更好的吸附在一起,从而有利于木质纤维素的酶解。C.bescii有12个含SLH结构域的蛋白,以及新发现的黏附蛋白Tāpirin,可能参与了木质纤维素的吸附与利用。综述了近年来对C.bescii降解植物细胞壁的糖苷水解酶的基因资源挖掘方面和降解分子机制方面的研究进展,对高效、多功能高效木质纤维素降解酶的设计和优化具有积极的意义。     

嗜热厌氧菌乙醇耐受机制的研究进展

生物能源因其原料具有来源丰富、价格低廉和可再生的优点,作为可替代化石能源的潜在能源受到世界各国的高度重视。有些嗜热厌氧菌因为具有木质纤维素降解能力和高温发酵的成本优势,被视为生物质转化乙醇等能源物质的理想微生物而成为近年来研究的热点,但乙醇耐受性较低是限制嗜热厌氧菌在工业化生产中应用的主要因素之一。本文从以下三个方面介绍嗜热厌氧菌乙醇耐受机制的研究进展：（1）嗜热厌氧菌生产乙醇的代谢途径;（2）嗜热厌氧菌的乙醇耐受机制;（3）提高嗜热厌氧菌乙醇耐受性的方法。     

嗜热真菌纤维素酶的CBD与海栖热袍菌的纤维素酶融合表达

将嗜热真菌毛壳菌纤维素酶Cel7A的纤维素结合结构域编码区与极端嗜热厌氧菌海栖热袍菌的纤维素酶CelB基因进行融合, 构建重组质粒pHsh-CBD-CelB, 并在大肠杆菌中表达。对融合蛋白进行纯化, 通过热处理和离子交换层析, 纯化到的融合蛋白SDS-PAGE 电泳图谱显示为单一条带。对融合蛋白的特性研究, 结果表明融合蛋白降解CMC的最适反应温度为90°C, 结晶纤维素吸附实验表明该融合蛋白具有结合结晶纤维素的能力, 并且融合蛋白降解CMC与结晶纤维素的能力得到提高。     

筛选微生物降解木质纤维素的研究进展

木质纤维素资源是自然界中含量丰富的可再生资源,利用微生物降解木质纤维素是一种重要的策略。在综合国内外对木质纤维素降解微生物的筛选方法和研究策略的基础上,从单一菌株、复合微生物菌系和组学技术三个方面对筛选微生物降解木质纤维素进行了总结和分析,阐述了各个策略的优势特点和应用价值,即单一菌株易于培养但降解能力较低,复合菌系降解能力强但传代稳定性较差,组学技术能够更好的解释微生物降解木质纤维素的机理,为筛选木质纤维素降解微生物提供一定的指导。同时提出使用合成生物学的策略进行相应微生物的筛选,旨在为筛选高效降解木质纤维素的微生物提供一定的参考。     

木质纤维素的微生物降解

木质纤维素广泛存在于自然界中,因结构复杂,其高效降解需要多种微生物的协同互作,由于参与木质纤维素降解的微生物种类繁多,其协同降解机理尚不完全明确。随着微生物分子生物学和组学技术的快速发展,将为微生物协同降解木质纤维素机制的研究提供新的方法和思路。笔者前期研究发现,细菌复合菌系在50℃下表现出强大的木质纤维素降解能力,菌系由可分离培养和暂时不可分离培养细菌组成,但是可分离培养细菌没有降解能力。通过宏基因组和宏转录组研究表明,与木质纤维素降解相关的某些基因表达量发生显著变化,通过组学方法有可能更加深入解释微生物协同降解木质纤维素的微生物学和酶学机理。文中从酶、纯培养菌株和复合菌群三个方面综述了木质纤维素微生物降解研究进展,着重介绍了组学技术在解析复合菌群作用机理方面的现状和应用前景,以期为探索微生物群落协同降解木质纤维素的机理提供借鉴。     

长足大竹象消化道不同分段菌群异质性及竹木质纤维素降解能力

【目的】长足大竹象Cyrtotrachelus buqueti消化道共生菌群参与了竹纤维素的降解。本研究旨在揭示长足大竹象幼虫消化道不同分段共生菌群异质性及木质纤维素的降解能力。【方法】通过对16S rRNA测序对长足大竹象幼虫消化道分段口器(YB)、前肠(YFG)、中肠(YMG)和后肠(YHG)进行菌群组成分析及功能预测;分析各消化道分段核心属细菌基因组中碳水化合物活性酶(carbohydrate active enzyme, CAZy)基因,预测木质纤维素降解能力;应用口器混合菌(MPJ)、前肠混合菌(FJ)、中肠混合菌(MJ)和后肠混合菌(HJ)悬液体外降解竹笋粉,检测共生菌群的木质纤维素的降解能力。【结果】长足大竹象幼虫消化道菌群多样性分析显示,YFG, YMG和YHG的菌群多样性大于YB,YFG的菌群物种多样性最高,而YB最低。YFG, YMG和YHG样本中厚壁菌门(Firmicutes)、拟杆菌门(Bacteroidetes)和变形菌门(Proteobacteria)相对丰度最高,而YB中变形菌门(Proteobacteria)、厚壁菌门(Firmicutes)和放线菌门(Actinobacteria)相对丰度最高。核心属细菌基因组CAZy基因分析表明长足大竹象幼虫消化道中大多数细菌基因组中存在丰富的CAZy基因,且在拟杆菌属Bacteroides细菌基因组中尤为明显,预示其与木质纤维素的降解密切相关。体外降解竹笋粉实验结果表明,长足大竹象幼虫MPJ, FJ, MJ和HJ对竹笋粉纤维素的降解率分别为21.7%, 39.9%, 44.2%和21.0%,对半纤维素降解率分别为72.7%, 52.3%, 65.7%和61.5%,对木质素降解率分别为20.5%, 41.3%, 39.9%和37.9%。【结论】长足大竹象幼虫的消化道菌群的异质性可以影响木质纤维素降解能力,因而这些菌群可以作为分离高效木质纤维素降解菌的重要来源之一。本研究为竹生物质的工业转化利用提供部分参考信息。     

昆虫与生物质能源利用:一个新的交叉学科前沿

昆虫与生物质能源利用密切相关。这些昆虫包括白蚁类、甲虫类、树蜂类、食叶类水生昆虫、衣鱼类、大蚊类等。它们能在树木、枯枝以及落叶上生活,并具有了相当可观的降解和转化木质纤维素的能力,是自然界中协助进行碳循环的一类重要节肢动物。近几年来,这些昆虫独特的肠道消化能力以及它们的生物质催化转化系统已引起了科学家和研究人员的极大兴趣,希望能通过发现新的降解木质纤维素的酶及酶系统、掌握相关的这些酶的表达和其功能控制基因、并能解开昆虫肠道的消化及其相关机制的谜;更高效的降解和转化植物细胞壁中的碳水化合物并用来生产不同种类的生物能源或生物基材料。目前,对这类昆虫高效降解木质纤维素能力的认识和相关降解机制的研究已发展成为一个与生物质能源应用密切相关的新兴研究领域,成为新的交叉学科前沿。本文将简要讨论这类昆虫消化木质纤维素的几种不同作用机制、共生微生物与昆虫所产生的不同木质纤维素酶以及相互间的协同作用的基础上,还探讨了当前第二代生物质能源研究与开发中所面临的主要挑战、消化木质纤维素类昆虫,特别是白蚁所处的独特地位、潜在的科学和应用价值,以及今后的主要研究方向。     

降解纤维素的“超分子机器”研究进展

综述了目前关于纤维小体组装模式、纤维小体结构多样性及人工设计纤维小体等方面的研究进展.纤维小体是某些厌氧菌产生的由多个亚基共同组装而成的大分子机器,是致力于组织、协调多种酶组分协同高效催化降解木质纤维素的胞外蛋白质复合体.纤维小体是厌氧微生物水解纤维素的主体,具有非常高效的打破结晶纤维素的结晶结构和降解纤维素链的作用.纤维小体对木质纤维素降解的高效性来自于其自发组装而成的复杂的高级结构,其结构的复杂性因不同的厌氧微生物而有所不同.     

微生物降解木质纤维素类生物质固废的研究进展

自然界中的细菌、真菌、放线菌及某些病毒是降解木质纤维素的主要微生物,它们在生物质固废能源的转化和利用上起桥梁作用,能变废为宝,实现生物质固废的资源化利用。根据生物质固废相关处理技术及生物质固废资源化成果转化,总结微生物降解生物质固废的有关处理技术及应用。在综合国内外现有研究成果的基础上,以木质纤维素类生物质固废为例,从微生物种类和生物质固废资源化成果转化两个方面对微生物降解木质纤维素类生物质固废有关技术进行分析,提出每项技术存在的问题,并展望每项技术的发展前景。     

Lignocellulose solubilization and conversion by extremely thermophilic Caldicellulosiruptor bescii improves by maintaining metabolic activity

The extreme thermophile Caldicellulosiruptor bescii solubilizes and metabolizes the carbohydrate content of lignocellulose, a process that ultimately ceases because of biomass recalcitrance, accumulation of fermentation products, inhibition by lignin moieties, and reduction of metabolic activity. Deconstruction of low loadings of lignocellulose (5 g/L), either natural or transgenic, whether unpretreated or subjected to hydrothermal processing, by C. bescii typically results in less than 40% carbohydrate solubilization. Mild alkali pretreatment (up to 0.09 g NaOH/g biomass) improved switchgrass carbohydrate solubilization by C. bescii to over 70% compared to less than 30% for no pretreatment, with two-thirds of the carbohydrate content in the treated switchgrass converted to acetate and lactate. C. bescii grown on high loadings of unpretreated switchgrass (50 g/L) retained in a pH-controlled bioreactor slowly purged (τ = 80 hr) with growth media without a carbon source improved carbohydrate solubilization to over 40% compared to batch culture at 29%. But more significant was the doubling of solubilized carbohydrate conversion to fermentation products, which increased from 40% in batch to over 80% in the purged system, an improvement attributed to maintaining the bioreactor culture in a metabolically active state. This strategy should be considered for optimizing solubilization and conversion of lignocellulose by C. bescii and other lignocellulolytic microorganisms.     

Growth of lithotrophic ammonia-oxidizing bacteria on hydroxylamine

Abstract A new obligately anaerobic, extremely thermophilic, cellulolytic bacterium is described. The strain designated Tp8T 6331 is differentiated from thermophilic cellulolytic clostridia on the basis of physiological characteristics and phylogenetic position within the Bacillus/Clostridium subphylum of the Gram-positive bacteria. Strain Tp8T 6331 is assigned to a new genus Caldicellulosiruptor , as Caldicellulosiruptor saccharolyticus gen., nov., sp. nov.     

Complete genome sequences for the anaerobic, extremely thermophilic plant biomass-degrading bacteria Caldicellulosiruptor hydrothermalis, Caldicellulosiruptor kristjanssonii, Caldicellulosiruptor kronotskyensis, Caldicellulosiruptor owensensis, and Caldicellulosiruptor lactoaceticus

The genus Caldicellulosiruptor contains the most thermophilic, plant biomass-degrading bacteria isolated to date. Previously, genome sequences from three cellulolytic members of this genus were reported (C. saccharolyticus, C. bescii, and C. obsidiansis). To further explore the physiological and biochemical basis for polysaccharide degradation within this genus, five additional genomes were sequenced: C. hydrothermalis, C. kristjanssonii, C. kronotskyensis, C. lactoaceticus, and C. owensensis. Taken together, the seven completed and one draft-phase Caldicellulosiruptor genomes suggest that, while central metabolism is highly conserved, significant differences in glycoside hydrolase inventories and numbers of carbohydrate transporters exist, a finding which likely relates to variability observed in plant biomass degradation capacity.     

Metabolically engineered Caldicellulosiruptor bescii as a platform for producing acetone and hydrogen from lignocellulose

The production of volatile industrial chemicals utilizing metabolically engineered extreme thermophiles offers the potential for processes with simultaneous fermentation and product separation. An excellent target chemical for such a process is acetone (T_b = 56°C), ideally produced from lignocellulosic biomass. Caldicellulosiruptor bescii (T_opt 78°C), an extremely thermophilic fermentative bacterium naturally capable of deconstructing and fermenting lignocellulose, was metabolically engineered to produce acetone. When the acetone pathway construct was integrated into a parent strain containing the bifunctional alcohol dehydrogenase from Clostridium thermocellum, acetone was produced at 9.1 mM (0.53 g/L), in addition to minimal ethanol 3.3 mM (0.15 g/L), along with net acetate consumption. This demonstrates that C. bescii can be engineered with balanced pathways in which renewable carbohydrate sources are converted to useful metabolites, primarily acetone and H₂, without net production of its native fermentation products, acetate and lactate.     

S-layer homology domain proteins Csac_0678 and Csac_2722 are implicated in plant polysaccharide deconstruction by the extremely thermophilic bacterium Caldicellulosiruptor saccharolyticus

The genus Caldicellulosiruptor contains extremely thermophilic bacteria that grow on plant polysaccharides. The genomes of Caldicellulosiruptor species reveal certain surface layer homology (SLH) domain proteins that have distinguishing features, pointing to a role in lignocellulose deconstruction. Two of these proteins in Caldicellulosiruptor saccharolyticus (Csac_0678 and Csac_2722) were examined from this perspective. In addition to three contiguous SLH domains, the Csac_0678 gene encodes a glycoside hydrolase family 5 (GH5) catalytic domain and a family 28 carbohydrate-binding module (CBM); orthologs to Csac_0678 could be identified in all genome-sequenced Caldicellulosiruptor species. Recombinant Csac_0678 was optimally active at 75°C and pH 5.0, exhibiting both endoglucanase and xylanase activities. SLH domain removal did not impact Csac_0678 GH activity, but deletion of the CBM28 domain eliminated binding to crystalline cellulose and rendered the enzyme inactive on this substrate. Csac_2722 is the largest open reading frame (ORF) in the C. saccharolyticus genome (predicted molecular mass of 286,516 kDa) and contains two putative sugar-binding domains, two Big4 domains (bacterial domains with an immunoglobulin [Ig]-like fold), and a cadherin-like (Cd) domain. Recombinant Csac_2722, lacking the SLH and Cd domains, bound to cellulose and had detectable carboxymethylcellulose (CMC) hydrolytic activity. Antibodies directed against Csac_0678 and Csac_2722 confirmed that these proteins bound to the C. saccharolyticus S-layer. Their cellular localization and functional biochemical properties indicate roles for Csac_0678 and Csac_2722 in recruitment and hydrolysis of complex polysaccharides and the deconstruction of lignocellulosic biomass. Furthermore, these results suggest that related SLH domain proteins in other Caldicellulosiruptor genomes may also be important contributors to plant biomass utilization.     

Phylogenetic, microbiological, and glycoside hydrolase diversities within the extremely thermophilic, plant biomass-degrading genus Caldicellulosiruptor

Phylogenetic, microbiological, and comparative genomic analyses were used to examine the diversity among members of the genus Caldicellulosiruptor, with an eye toward the capacity of these extremely thermophilic bacteria to degrade the complex carbohydrate content of plant biomass. Seven species from this genus (C. saccharolyticus, C. bescii, C. hydrothermalis, C. owensensis, C. kronotskyensis, C. lactoaceticus, and C. kristjanssonii) were compared on the basis of 16S rRNA gene phylogeny and cross-species DNA-DNA hybridization to a whole-genome C. saccharolyticus oligonucleotide microarray, revealing that C. saccharolyticus was the most divergent within this group. Growth physiology of the seven Caldicellulosiruptor species on a range of carbohydrates showed that, while all could be cultivated on acid-pretreated switchgrass, only C. saccharolyticus, C. bescii, C. kronotskyensis, and C. lactoaceticus were capable of hydrolyzing Whatman no. 1 filter paper. Two-dimensional gel electrophoresis of the secretomes from cells grown on microcrystalline cellulose revealed that the cellulolytic species also had diverse secretome fingerprints. The C. saccharolyticus secretome contained a prominent S-layer protein that appears in the cellulolytic Caldicellulosiruptor species, suggesting a possible role in cell-substrate interactions. Growth physiology also correlated with glycoside hydrolase (GH) and carbohydrate-binding module (CBM) inventories for the seven bacteria, as deduced from draft genome sequence information. These inventories indicated that the absence of a single GH and CBM family was responsible for diminished cellulolytic capacity. Overall, the genus Caldicellulosiruptor appears to contain more genomic and physiological diversity than previously reported, and this argues for continued efforts to isolate new members from high-temperature terrestrial biotopes.     

Discrete and Structurally Unique Proteins (Tāpirins) Mediate Attachment of Extremely Thermophilic Caldicellulosiruptor Species to Cellulose

A variety of catalytic and noncatalytic protein domains are deployed by select microorganisms to deconstruct lignocellulose. These extracellular proteins are used to attach to, modify, and hydrolyze the complex polysaccharides present in plant cell walls. Cellulolytic enzymes, often containing carbohydrate-binding modules, are key to this process; however, these enzymes are not solely responsible for attachment. Few mechanisms of attachment have been discovered among bacteria that do not form large polypeptide structures, called cellulosomes, to deconstruct biomass. In this study, bioinformatics and proteomics analyses identified unique, discrete, hypothetical proteins (“tāpirins,” origin from Māori: to join), not directly associated with cellulases, that mediate attachment to cellulose by species in the noncellulosomal, extremely thermophilic bacterial genus Caldicellulosiruptor. Two tāpirin genes are located directly downstream of a type IV pilus operon in strongly cellulolytic members of the genus, whereas homologs are absent from the weakly cellulolytic Caldicellulosiruptor species. Based on their amino acid sequence, tāpirins are specific to these extreme thermophiles. Tāpirins are also unusual in that they share no detectable protein domain signatures with known polysaccharide-binding proteins. Adsorption isotherm and trans vivo analyses demonstrated the carbohydrate-binding module-like affinity of the tāpirins for cellulose. Crystallization of a cellulose-binding truncation from one tāpirin indicated that these proteins form a long β-helix core with a shielded hydrophobic face. Furthermore, they are structurally unique and define a new class of polysaccharide adhesins. Strongly cellulolytic Caldicellulosiruptor species employ tāpirins to complement substrate-binding proteins from the ATP-binding cassette transporters and multidomain extracellular and S-layer-associated glycoside hydrolases to process the carbohydrate content of lignocellulose.     

Heterologous co-expression of two β-glucanases and a cellobiose phosphorylase resulted in a significant increase in the cellulolytic activity of the Caldicellulosiruptor bescii exoproteome

Journal of Industrial Microbiology & Biotechnology - The ability to deconstruct plant biomass without conventional pretreatment has made members of the genus Caldicellulosiruptor the target of...     

Caldicellulosiruptor core and pangenomes reveal determinants for noncellulosomal thermophilic deconstruction of plant biomass

Extremely thermophilic bacteria of the genus Caldicellulosiruptor utilize carbohydrate components of plant cell walls, including cellulose and hemicellulose, facilitated by a diverse set of glycoside hydrolases (GHs). From a biofuel perspective, this capability is crucial for deconstruction of plant biomass into fermentable sugars. While all species from the genus grow on xylan and acid-pretreated switchgrass, growth on crystalline cellulose is variable. The basis for this variability was examined using microbiological, genomic, and proteomic analyses of eight globally diverse Caldicellulosiruptor species. The open Caldicellulosiruptor pangenome (4,009 open reading frames [ORFs]) encodes 106 GHs, representing 43 GH families, but only 26 GHs from 17 families are included in the core (noncellulosic) genome (1,543 ORFs). Differentiating the strongly cellulolytic Caldicellulosiruptor species from the others is a specific genomic locus that encodes multidomain cellulases from GH families 9 and 48, which are associated with cellulose-binding modules. This locus also encodes a novel adhesin associated with type IV pili, which was identified in the exoproteome bound to crystalline cellulose. Taking into account the core genomes, pangenomes, and individual genomes, the ancestral Caldicellulosiruptor was likely cellulolytic and evolved, in some cases, into species that lost the ability to degrade crystalline cellulose while maintaining the capacity to hydrolyze amorphous cellulose and hemicellulose.