丝状真菌蛋白表达系统研究进展*

丝状真菌以其优秀的表达分泌能力和良好的环境适应能力,使得其在蛋白质表达领域应用越来越广泛。近几十年来,通过诱变、培养优化及遗传改造等手段,使得包含曲霉属、木霉属、青霉属等在内的丝状真菌被开发成高效表达宿主。为促进丝状真菌蛋白表达系统的开发,结合作者的研究工作,对工业上丝状真菌表达宿主、蛋白质表达元件及其改造策略进行综述,并探讨了当前丝状真菌表达系统开发过程中的不足之处,为新型丝状真菌表达系统的研究提供参考和启示。     

丝状真菌新型全局性调控因子LaeA

全局调控在丝状真菌次级代谢调控及其生长发育过程中有着重要的作用。LaeA是2004年首次在构巢曲霉中被发现的第一个丝状真菌全局性调控因子,继而在烟曲霉、黄曲霉、产黄青霉、橘青霉中相继被报道。LaeA能够全局性调控抗生素和真菌毒素等次级代谢产物的合成,影响真菌形态分化,另外还通过影响沉默基因的表达从而调控未知代谢产物的产生,因而能为真菌中天然产物的开发提供新的重要途径。本文就其在丝状真菌中的发现、功能、作用机制及其应用等方面进行综述。     

Characterization of the α-mannosidase gene family in filamentous fungi: N-glycan remodelling for the development of eukaryotic expression systems

Although filamentous fungi are used extensively for protein expression, their use for the production of heterologous glycoproteins is constrained by the types of N-glycan structures produced by filamentous fungi as compared to those naturally found on the glycoproteins. Attempts are underway to engineer the N-glycan synthetic pathways in filamentous fungi in order to produce fungal expression strains which can produce heterologous glycoproteins carrying specific N-glycan structures. To fully realize this goal, a detailed understanding of the genetic components of this pathway in filamentous fungi is required. In this review, we discuss the characterization of the α-mannosidase gene family in filamentous fungi and its implications for the elucidation of the N-glycan synthetic pathway.     

丝状真菌高效表达异源蛋白研究进展

丝状真菌是具有高效分泌蛋白质潜力的真核表达系统, 能对蛋白质进行翻译后修饰, 如蛋白质糖基化等; 并且比植物、昆虫和哺乳动物细胞具有更快的生长速率。近年来, 随着真菌分子遗传技术和菌种改良策略的进步, 尤其是真菌基因组学的发展, 利用丝状真菌生产异源蛋白越来越受到关注。综述了丝状真菌作为细胞工厂生产异源蛋白的最新探索与进展, 其中包括功能基因组学在蛋白表达与分泌研究中的应用, 同时探讨了异源蛋白表达和生产的改进策略。     

丝状真菌高效表达异源蛋白研究进展

丝状真菌是具有高效分泌蛋白质潜力的真核表达系统, 能对蛋白质进行翻译后修饰, 如蛋白质糖基化等; 并且比植物、昆虫和哺乳动物细胞具有更快的生长速率。近年来, 随着真菌分子遗传技术和菌种改良策略的进步, 尤其是真菌基因组学的发展, 利用丝状真菌生产异源蛋白越来越受到关注。综述了丝状真菌作为细胞工厂生产异源蛋白的最新探索与进展, 其中包括功能基因组学在蛋白表达与分泌研究中的应用, 同时探讨了异源蛋白表达和生产的改进策略。     

丝状真菌次级代谢产物生物合成的表观遗传调控

丝状真菌产生的次级代谢产物是新药的重要来源之一,其生物合成过程受到众多因素的调控。最近的研究表明,表观遗传对多种丝状真菌次级代谢产物的生物合成具有调控作用。DNA和组蛋白的甲基化与乙酰化修饰是目前所知的丝状真菌主要的表观遗传调控形式。通过过表达或缺失相关表观修饰基因和利用小分子表观遗传试剂改变丝状真菌染色体的修饰形式,不仅可以提高多种已知次级代谢产物产量,而且可以通过激活沉默的生物合成基因簇诱导丝状真菌产生新的未知代谢产物。丝状真菌表观遗传学正逐渐成为真菌菌株改良的新策略以及挖掘真菌次级代谢产物合成潜力的强有力手段。     

Production of recombinant proteins by filamentous fungi

The initial focus of recombinant protein production by filamentous fungi related to exploiting the extraordinary extracellular enzyme synthesis and secretion machinery of industrial strains, including Aspergillus, Trichoderma, Penicillium and Rhizopus species, was to produce single recombinant protein products. An early recognized disadvantage of filamentous fungi as hosts of recombinant proteins was their common ability to produce homologous proteases which could degrade the heterologous protein product and strategies to prevent proteolysis have met with some limited success. It was also recognized that the protein glycosylation patterns in filamentous fungi and in mammals were quite different, such that filamentous fungi are likely not to be the most suitable microbial hosts for production of recombinant human glycoproteins for therapeutic use. By combining the experience gained from production of single recombinant proteins with new scientific information being generated through genomics and proteomics research, biotechnologists are now poised to extend the biomanufacturing capabilities of recombinant filamentous fungi by enabling them to express genes encoding multiple proteins, including, for example, new biosynthetic pathways for production of new primary or secondary metabolites. It is recognized that filamentous fungi, most species of which have not yet been isolated, represent an enormously diverse source of novel biosynthetic pathways, and that the natural fungal host harboring a valuable biosynthesis pathway may often not be the most suitable organism for biomanufacture purposes. Hence it is expected that substantial effort will be directed to transforming other fungal hosts, non-fungal microbial hosts and indeed non microbial hosts to express some of these novel biosynthetic pathways. But future applications of recombinant expression of proteins will not be confined to biomanufacturing. Opportunities to exploit recombinant technology to unravel the causes of the deleterious impacts of fungi, for example as human, mammalian and plant pathogens, and then to bring forward solutions, is expected to represent a very important future focus of fungal recombinant protein technology.     

丝状真菌异源蛋白表达系统研究进展

丝状真菌,俗称霉菌,在食品工业中被用于生产多种生物酶和有机酸。近年来,人们发现丝状真菌具有分泌量大、表达的蛋白有天然活性等特点,非常适合作为同源和异源重组蛋白的表达宿主,因此被广泛研究和探讨。简要综述了以黑曲霉为代表的几种常被用作蛋白表达宿主的丝状真菌的特点、应用中的主要问题和基本解决方案,以及近年关于丝状真菌表达系统的最佳培养条件和发酵条件的研究进展。     

丝状真菌纤维素酶合成诱导及转录调控

利用廉价可再生木质纤维素资源水解产生的可发酵糖生产生物能源和生物基化学品是近年来国内外研究的热点。纤维素酶酶解是木质纤维素原料生物降解的重要手段,但目前纤维素酶生产成本过高,限制了纤维素生物转化和生物炼制的工业化应用。对丝状真菌纤维素酶基因表达和调控进行研究,有利于进一步选育纤维素酶高产菌株,降低纤维素酶生产成本。随着高通量测序及丝状真菌遗传操作等技术的进步,对丝状真菌纤维素酶诱导和基因表达调控机理有了更深入的认识。本文综述了近年来丝状真菌纤维素酶诱导和纤维素酶基因表达调控的最新进展,重点论述糖转运蛋白、转录因子和染色质重塑对纤维素酶表达调控的影响,并对利用人工锌指蛋白进行丝状真菌纤维素酶诱导调控研究进行了展望。     

Recombinant DNA in filamentous fungi: progress and prospects

Recombinant DNA technology enables the creation of well-defined alterations in the genetic material of an organism. Methods to manipulate recombinant DNA in the filamentous fungi (a group of microorganisms that includes species of academic as well as commercial interest) have recently been developed. This has been the result of adaptation of procedures successfully employed in the manipulation of other microorganisms. There are a number of similarities in the behavior of recombinant DNA in different fungi, but a number of differences have also been observed between the filamentous and the nonfilamentous fungi. Such differences include the ability to identify DNA replication origins and the host range of expression of fungal genes.     

丝状真菌代谢工程研究进展

丝状真菌(Filamentous fungi)作为重要的工业发酵微生物,在有机酸、蛋白质及次级代谢产物等关键生物基产品生产方面发挥着重要作用。自20世纪90年代代谢工程理念提出以来,尤其是代谢工程使能技术的创新及发展,极大地促进了丝状真菌细胞工厂的构建及其在工业发酵领域的应用。文中将系统介绍近年来丝状真菌代谢工程技术的发展,及其在生物基化学品细胞工厂构建中的应用,最后讨论丝状真菌代谢工程中关键问题并展望其未来发展。     

带有报告基因的板栗疫病菌寄生隐赤壳分泌表达突变体库的构建及分泌缺陷突变体的筛选

丝状真菌分泌蛋白与其致病性密切相关,目前对于病原真菌的蛋白胞外分泌途径及其调控机制的报道不多。为建立一个方便高效的真菌分泌蛋白调控途径的遗传研究体系,本研究以植物病原丝状真菌——板栗疫病菌寄生隐赤壳Cryphonectria parasitica为对象,选取分泌表达量最高的两个分泌蛋白的信号肽SP1和SP2,分别构建带有GUS报告基因的分泌蛋白表达载体pCPXBle-SP1-GUS和pCPXBle-SP2-GUS并用于转化板栗疫病菌。选择高效分泌GUS蛋白的转化株SP1-9为出发菌株,利用农杆菌介导的遗传转化技术构建了T-DNA插入突变体库,从576个突变体中筛选到2株GUS分泌表达明显降低的突变体。本研究成功构建了可用于研究丝状真菌蛋白分泌的遗传研究体系,并筛选获得了分泌蛋白缺陷突变体,为深入研究丝状真菌分泌途径及其调控机制奠定了基础。     

纳木措可培养丝状真菌多样性及其与理化因子关系

微生物多样性在评估水体生态环境方面发挥着重要作用。本研究以青藏高原纳木措湖为研究对象, 开展水体可培养丝状真菌多样性及影响因子研究。通过膜过滤平置培养法、经典分类法和rRNA转录间隔区(ITS)序列分析对纳木措湖20个采样点的丝状真菌进行分离、纯化及鉴定, 测定水体理化指标, 综合分析丝状真菌空间分布格局与理化因子的相关性。菌种鉴定结果显示, 从纳木措水体样品中共分离纯化出1,412株丝状真菌, 隶属22属47种, 其中链格孢属(Alternaria)、青霉属(Penicillium)和毛霉属(Mucor)为优势属, 链格孢(Alternaria chlamydosporigena)和冻土毛霉(Mucor hiemalis)为优势种; Pearson相关性分析显示, 丝状真菌总丰度与温度、铵态氮、全磷呈显著正相关; 冗余分析显示, 铵态氮、温度、全磷、全氮、盐度及电导率是影响纳木措湖丝状真菌群落组成与分布的主要理化因子。综上所述, 纳木措水体可培养丝状真菌具有较高的物种多样性和空间异质性, 而且水体环境因子影响其分布。     

Development of ToxA and ToxB promoter-driven fluorescent protein expression vectors for use in filamentous ascomycetes

The green fluorescent protein (GFP) has been established as the premier in vivo reporter for investigations of gene expression, protein localization, and cell and organism dynamics. The fungal transformation vector pCT74, with sGFP under the control of the ToxA promoter from Pyrenophora tritici-repentis, effectively expresses GFP in a diverse group of filamentous ascomycetes. Due to the versatility of ToxA promoter-driven expression of GFP, we constructed an additional set of fluorescent protein expression vectors to expand the color palette of fluorescent markers for use in filamentous fungi. EYFP, ECFP and mRFP1 were successfully expressed from the ToxA promoter in its fungus of origin, P. tritici-repentis, and a distant relative, Verticillium dahliae. Additionally the ToxB promoter from P. tritici-repentis drove expression of sGFP in V. dahliae, suggesting a similar potential to the ToxA promoter for heterologous expression in ascomycetes. The suite of fungal transformation vectors presented here promise to be useful for a variety of fungal research applications.     

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。     

一种快速高效获取丝状真菌PCR反应模板的方法

建立一种快速高效获取丝状真菌PCR反应模板的方法,提高丝状真菌PCR鉴定效率。通过单因素法对机械破壁联合微波法进行条件优化,利用优化后的方法获取13株不同种属丝状真菌的PCR反应模板,同时与Chelex-100法、机械破壁法作对比,以试剂盒抽提法作为阳性对照,进行ITS序列扩增,琼脂糖凝胶电泳检测扩增结果。机械破壁联合微波法获取丝状真菌PCR反应模板的最佳条件为40 Hz机械破壁1 min、微波700 W高温裂解3 min,采取该法与试剂盒抽提法获得的模板均成功扩增13株不同种属丝状真菌ITS序列,且PCR鉴定结果一致;Chelex-100法获得的模板成功扩增6株丝状真菌ITS序列;机械破壁法获得的模板虽成功扩增9株丝状真菌ITS序列,但扩增效果欠佳。机械破壁联合微波法能够有效获取丝状真菌PCR反应模板,与试剂盒抽提法相比具有操作简便、快速高效的优点,提高丝状真菌PCR鉴定效率。     

根癌农杆菌介导丝状真菌遗传转化因素的研究进展

根癌农杆菌介导的丝状真菌遗传转化体系,是当前研究真菌基因组学的有力工具,广泛运用于真菌随机插入突变体库的构建和基因打靶。概述了根癌农杆菌介导的丝菌转化的大致过程,转化效率的影响因素。     

Chitinases of filamentous fungi: a large group of diverse proteins with multiple physiological functions

Chitin is the second most abundant natural biopolymer and the main structural component of invertebrate exoskeletons and cell walls of filamentous fungi. Fungal chitinases have multiple physiological functions including the degradation of exogenous chitin and cell wall remodelling during hyphal growth, but the regulation of the chitinolytic systems of filamentous fungi is not well understood. Fungi have on average between 10 and 25 different chitinases, but only the increasing number of fungal genome sequencing projects in the last few years has enabled us to assess the whole range and diversity of fungal chitinases. In this review the variety, domain architecture and subgroups of chitinases of filamentous fungi are shown, and how these data integrate with that from molecular biological studies on chitinases are discussed.     

丝状真菌次级代谢产物的研究现状与发展趋势

近年来,丝状真菌次级代谢产物的研究在国内外受到了极高的重视,同时也取得了较大的进展。本文对丝状真菌次级代谢产物的生物合成和调控机制以及隐性次级代谢产物生物合成基因簇的激活等方面进行了简述,同时对组合生物学给真菌次级代谢产物研究带来的机遇和挑战进行了讨论。     

Characterization and application of small RNAs and RNA silencing mechanisms in fungi

Although extensively cataloged and functionally diverse in plants and animals, the role and targets of small RNAs remain mostly uncharacterized in filamentous fungi. To date, much of the knowledge of small RNAs in filamentous fungi has been derived from studies of a limited group of fungi, most notably in Neurospora crassa. While most of the recently discovered classes of small RNAs appear to be unique to fungi some are commonly found in eukaryotes. It is noteworthy that the RNA silencing protein machinery involved in small RNA biogenesis has also diverged greatly, particularly within filamentous fungi, and may explain the diversity of small RNA classes. In this review, we summarize important classes of eukaryotic small RNAs and provide a current analysis of the RNA silencing machinery based on available fungal genome sequences. Finally, we discuss opportunities for exploiting knowledge of small RNAs and RNA silencing for practical application such as engineering plants resistant to fungal pathogens.