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。     

丝状真菌高效表达异源蛋白的研究进展

丝状真菌是一种具有高效分泌蛋白质潜力的真核表达系统,在工业生产中常被用于生产多种生物酶和有机酸。本文综述了当前国内外对于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。     

米曲霉外源表达系统研究进展

丝状真菌米曲霉是发酵工业的重要菌种,具有强大的蛋白分泌能力和较高的食品安全性,可作为表达外源蛋白的细胞工厂。近年来,米曲霉全基因组序列的测序完成和基于表达序列标签的基因组学研究,为深入研究米曲霉外源表达系统提供了条件。从基因组学进展、遗传转化体系等方面综述了米曲霉作为外源蛋白表达宿主的研究进展。针对米曲霉在外源蛋白表达中存在的瓶颈,提出构建蛋白酶缺陷株、使用强启动子、融合表达等策略,以提高外源蛋白的表达和产量。最后介绍了米曲霉表达系统的应用,利用米曲霉代谢工程菌生产工业用酶和次级代谢产品具有良好的前景。     

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。     

代谢工程中基因修饰与基因表达的工具

代谢工程利用重组DNA技术导入定向改造的基因 ,以改进微生物细胞的某些代谢特性 ,已经发展成为一个工业微生物育种和优化发酵过程的强有力工具。基因的修饰与表达是代谢工程的重要组成部分。本文介绍了近年来代谢工程中基因修饰与表达所用的工具方面的进展。     

反义RNA技术在丝状真菌代谢工程中的应用

丝状真菌作为一种重要的工业微生物,采用各种表达调控技术对其代谢途径进行改造以便适应生产需求成为当前的研究热点之一。反义RNA技术是代谢工程中调控基因表达的一种重要手段,且由于其操作简单避免了基因敲除技术的复杂性,在丝状真菌体系中有着良好的应用前景。本综述中,从反义RNA的作用机理、真菌体系的基因工程技术以及目前反义RNA技术的应用等方面,对反义RNA技术在丝状真菌代谢工程中的应用进行了概述。     

米曲霉异源蛋白表达系统研究进展及展望

米曲霉作为一种重要的工业微生物,在异源蛋白表达方面已有广泛应用,受限于被表达蛋白的修饰及分泌过程,目前实际生产使用的基因供体主要局限于其他真菌,尤其是丝状真菌。当外源基因来源于植物、昆虫和哺乳动物时,米曲霉所生产的异源蛋白产量及生物活性往往不尽如人意。本文综述了米曲霉作为宿主表达异源蛋白的研究进展,包括其现有的遗传操作手段及异源表达方面的应用及探索,重点介绍了应用过程中面临的挑战和解决策略,另外,对米曲霉表达异源蛋白的应用前景及发展方向进行了展望。     

丝状真菌蛋白质组学研究进展

丝状真菌不仅是致病菌,而且在异源表达工业酶、化学制品以及药物活性物质中发挥着越来越重要的作用。随着人类基因组计划的实施和推进,生命科学研究已进入了功能基因组时代,特别是蛋白质组学,在蛋白质水平对丝状真菌细胞生命过程中蛋白质功能和蛋白质之间的相互作用以及特殊条件下的变化机制进行研究,对生命的复杂活动进行深入而又全面的认识也为丝状真菌工业酶制剂和重组药物的开发提供广阔的创新空间。本文综述了蛋白质组学的研究内容和方法,总结了其在丝状真菌致病菌、抗生素产生菌和纤维素酶产生菌中的应用现状。不同层次的功能基因组学分析可以从各个角度掌握生物体的代谢网络和调控机制,本文还对蛋白质组学以及功能基因组学各部分内容的整合运用进行了展望。     

乳酸乳球菌NZ9000基因组规模代谢网络模型的构建与验证

随着后基因组时代的到来,工业微生物的代谢工程改造在工业生产上发挥着越来越重要的作用。而基因组规模代谢网络模型(Genome-scalemetabolicmodel,GSMM)将生物体体内所有已知代谢信息进行整合,为全局理解生物体的代谢状态、理性指导代谢工程改造提供了最佳的平台。乳酸乳球菌NZ9000(Lactococcuslactis NZ9000)作为工业发酵领域的重要菌株之一,由于其遗传背景清晰且几乎不分泌蛋白,是基因工程改造和外源蛋白表达的理想模式菌株。文中基于基因组功能注释和比较基因组学构建了L.lactisNZ9000的首个基因组规模代谢网络模型iWK557,包含557个基因、668个代谢物、840个反应,并进一步在定性和定量两个层次验证了iWK557的准确性,以期为理性指导L. lactis NZ9000代谢工程改造提供良好工具。     

Culturable Fungi of Stored ‘Golden Delicious’ Apple Fruits: A One-Season Comparison Study of Organic and Integrated Production Systems in Switzerland

The effects of organic and integrated production systems on the culturable fungal microflora of stored apple fruits from five matched pairs of certified organic and integrated ‘Golden Delicious’ farms were studied at five representative production sites in Switzerland. Isolated fungi were identified morphologically. Colonization frequency (percentage of apples colonized), abundance (colony numbers), and diversity (taxon richness) were assessed for each orchard. The standard quality of the stored fruits was comparable for both organic and integrated apples and complied with national food hygiene standards. Yeasts (six taxa) and the yeast-like fungus Aureobasidium pullulans were the dominant epiphytes, filamentous fungi (21 taxa) the dominant endophytes. The most common fungi occurred at all sites and belonged to the “white” and “pink” yeasts, yeast-like A. pullulans, filamentous fungi Cladosporium spp., Alternaria spp., and sterile filamentous fungi. Canonical correspondence analysis of the total fungal community revealed a clear differentiation among production systems and sites. Compared to integrated apples, organic apples had significantly higher frequencies of filamentous fungi, abundance of total fungi, and taxon diversity. The effects of the production system on the fungal microflora are most likely due to the different plant protection strategies. The incidence of potential mycotoxin producers such as Penicillium and Alternaria species was not different between production systems. We suggest that higher fungal diversity may generally be associated with organic production and may increase the level of beneficial and antagonistically acting species known for their potential to suppress apple pathogens, which may be an advantage to organic apples, e.g., in respect to natural disease control.     

Growth-rate-independent production of recombinant glucoamylase by Fusarium venenatum JeRS 325

Most recombinant proteins generated in filamentous fungi are produced in fed-batch cultures, in which specific growth rate normally decreases progressively with time. Because of this, such cultures are more suited to the production of products that are produced efficiently at low-growth rates (e.g., penicillin) than to products which are produced more efficiently at high-growth rates (e. g., glucoamylase). Fusarium venenatum A3/5 has been transformed (JeRS 325) to produce Aspergillus niger glucoamylase (GAM) under the control of the Fusarium oxysporum trypsin-like protease promoter. No glucoamylase was detected in the culture supernatant during exponential growth of F. venenatum JeRS 325 in batch culture. In glucose-limited chemostat cultures, GAM concentration increased with decrease in dilution rate, but the specific production rate of GAM (g GAM [g biomass](-1) h(-1)) remained approximately constant over the dilution-rate range 0.05 h to 0.19 h(-1), i.e., the recombinant protein was produced in a growth-rate-independent manner. The specific production rate decreased at dilution rates of 0.04 h(-1) and below. Specific production rates of 5.8 mg and 4.0 mg GAM [g biomass](-1) h(-1) were observed in glucose-limited chemostat cultures in the presence and absence of 1 g mycological peptone L(-1). Compared to production in batch culture, and for the same final volume of medium, there was no increase in glucoamylase production when cultures were grown in fed-batch culture. The results suggested that a chemostat operated at a slow dilution rate would be the most productive culture system for enzyme production under this trypsin-like promoter.     

Rapid detection of lytic antimicrobial activity against yeast and filamentous fungi.

A rapid method for assessing the lytic activity of antimicrobial agents against yeast and fungi has been developed. The assay is based on the release of the intracellular enzyme, maltase (alpha-glucosidase). The released maltase activity was measured colorimetrically by the production of p-nitrophenol from p-nitrophenyl-alpha-D-glucopyranoside (PNPG). The lytic activity of different antimicrobial compounds was measured against yeast cells or germinating spores of filamentous fungi. Lytic anti-yeast activity could be detected within 20 min incubation at 30 degrees C against Saccharomyces cerevisiae, Candida albicans, and Cryptococcus neoformans. Lytic anti-fungal activity appeared after 2 h of incubation at 30 degrees C against germinating spores of Aspergillus niger and Botrytis cinerea. Whole cells of either yeast or fungi did not hydrolyze sufficient PNPG within 3 h at 30 degrees C to yield a detectable color change. Lytic activity of enzymes (e.g., Lyticase), antibiotics (e.g., Amphotericin B), and an antibiotic-producing strain of bacteria were detected using the assay. The anti-yeast assay has been adapted to a 96-well microtiter format. Both assays provided a rapid, sensitive, and reproducible detection of lytic anti-yeast and anti-fungal activity.     

Comparison of morphogenetic networks of filamentous fungi and yeast.

Fungi generally display either of two growth modes, yeast-like or filamentous, whereas dimorphic fungi, upon environmental stimuli, are able to switch between the yeast-like and the filamentous growth mode. Signal transduction pathways have been elucidated in the budding yeast Saccharomyces cerevisiae, establishing a morphogenetic network that links cell-cycle events with cellular morphogenesis. Recent molecular genetic studies in several filamentous fungal model systems revealed key components required for distinct steps from fungal spore germination to the maintenance of polar hyphal growth, mycelium formation, and nuclear division. This allows a mechanistic comparison of yeast-like and hyphal growth and the establishment of a core model morphogenetic network for filamentous growth including signaling via the cAMP pathway, Rho modules, and cell cycle kinases. Appreciating similarities between morphogenetic networks of the unicellular yeasts and the multicellular filamentous fungi will open new research directions, help in isolating the central network components, and ultimately pave the way to elucidate the central differences (of many) that distinguish, e.g., the growth mode of filamentous fungi from that of their yeast-like relatives, the role of cAMP signaling, and nuclear division.     

Metabolite profiling of fungi and yeast: from phenotype to metabolome by MS and informatics

Filamentous fungi and yeast from the genera Saccharomyces, Penicillium, Aspergillus, and Fusarium are well known for their impact on our life as pathogens, involved in food spoilage by degradation or toxin contamination, and also for their wide use in biotechnology for the production of beverages, chemicals, pharmaceuticals, and enzymes. The genomes of these eukaryotic micro-organisms range from about 6000 genes in yeasts (S. cerevisiae) to more than 10,000 genes in filamentous fungi (Aspergillus sp.). Yeast and filamentous fungi are expected to share much of their primary metabolism; therefore much understanding of the central metabolism and regulation in less-studied filamentous fungi can be learned from comparative metabolite profiling and metabolomics of yeast and filamentous fungi. Filamentous fungi also have a very active and diverse secondary metabolism in which many of the additional genes present in fungi, compared with yeast, are likely to be involved. Although the 'blueprint' of a given organism is represented by the genome, its behaviour is expressed as its phenotype, i.e. growth characteristics, cell differentiation, response to the environment, the production of secondary metabolites and enzymes. Therefore the profile of (secondary) metabolites--fungal chemodiversity--is important for functional genomics and in the search for new compounds that may serve as biotechnology products. Fungal chemodiversity is, however, equally efficient for identification and classification of fungi, and hence a powerful tool in fungal taxonomy. In this paper, the use of metabolite profiling is discussed for the identification and classification of yeasts and filamentous fungi, functional analysis or discovery by integration of high performance analytical methodology, efficient data handling techniques and core concepts of species, and intelligent screening. One very efficient approach is direct infusion Mass Spectrometry (diMS) integrated with automated data handling, but a full metabolic picture requires the combination of several different analytical techniques.     

Rare Invasive Fungal Infections: Epidemiology, Diagnosis and Management

Rare yeast and filamentous fungi belonging to hyalohyphomycetes (e.g., Scedosporium, Fusarium), zygomycetes and dematiaceous (e.g., Alternaria, Bipolaris) are implicated in human infections ranging from colonization and localized infections in immunocompetent individuals to fungemias and disseminated diseases in immunocompromised patients and accounting <10 % of all isolated fungal pathogens. The diagnosis of yeast, Fusarium and Scedosporium infections is based on blood cultures and of filamentous fungal infections on histopathology, direct microscopy and culture of infected tissues. The panfungal marker 1,3-b-D glucan test as well as cross reaction with antigen tests for other fungi can be used; whereas, PCR assays have been developed for direct detection of these fungi in blood and in tissues. Amphotericin B is the drug of choice for most rare yeast infections except for Trichosporon infections where voriconazole is used. The management of the other infections includes surgery combined with antifungal therapy mainly with amphotericin B for zygomycetes, voriconazole or amphotericin B for hyalohyphomycetes, and itraconazole or amphotericin B for dematiaceous fungi.     

Regulation of secondary metabolite production in filamentous ascomycetes

Fungi are renowned for their ability to produce bioactive small molecules otherwise known as secondary metabolites. These molecules have attracted much attention due to both detrimental (e.g. toxins) and beneficial (e.g. pharmaceuticals) effects on human endeavors. Once the topic only of chemical and biochemical studies, secondary metabolism research has reached a sophisticated level in the realm of genetic regulation. This review covers the latest insights into the processes regulating secondary metabolite production in filamentous fungi.     

Alkane utilisation by Cladosporium resinae: the importance of extended lag phases when assessing substrate optima

Abstract Lag phases were shown to be important when assessing substrate optima for alkane utilisation by filamentous fungi. Failure to take the progressively longer lag phase (in respect to carbon chain length) into consideration may have led previous workers, who used single point biomass measurements as an indication of growth, to underestimate the potential of fungi to grow on alkanes such as octadecane. For a variety of fungi tested, optimum substrates of somewhat longer chain-length than normally reported were found by using growth rates as indicators of best growth, e.g., octadecane for Cladosporium resinae .