植物病原丝状真菌G蛋白偶联受体的研究进展

通过对丝状真菌G蛋白偶联受体(GPCR)的结构、分类以及功能方面进行综述,以期明确丝状真菌与其他模式生物GPCR之间的关系。基于已报道的模式生物及丝状真菌等不同生物中的GPCR,通过SMART保守结构域分析,以及利用Clustal X、MEGA等软件对上述GPCR进行遗传关系分析。明确丝状真菌典型GPCR具有七跨膜结构域,新型GPCR则含有PIPK、RGS等保守结构域,明确不同学者对于GPCR的分类情况,以及新型GPCR所具有的特殊功能,明确模式生物GPCR、丝状真菌GPCR分别各自聚类。丝状真菌中GPCR的数量较模式生物少,不同分类单元中真菌之间GPCR的数量也不尽相同,同时,丝状真菌GPCR除具有典型的七跨膜结构域外,还含有一些其他保守的结构域,上述研究为进一步开展其功能研究提供重要的理论基础。     

丝状真菌胞吐体的研究进展

胞吐体(Exocyst)是真核生物细胞内由8个亚基组成的复合体,在后高尔基体产生的分泌囊泡与细胞膜特定位置的定向与拴系过程中发挥重要作用。一些小G蛋白通过直接与胞吐体的亚基相互作用,对极性胞外分泌进行精确的时空调节。丝状真菌的生长是通过菌丝顶端的极性生长来完成的,并且具有极强的分泌蛋白质能力,是研究胞吐体的理想系统。胞吐体对丝状真菌的形态发生和致病性都有极大的影响。本文综述了当前在丝状真菌中胞吐体的研究进展,包括它的组成、亚基定位、相关功能和调控。     

真菌G蛋白信号调控蛋白的功能研究进展

G蛋白信号途径是真菌细胞信号转导网络的枢纽,在细胞的各种生物学调控过程中具有重要作用。G蛋白信号调控蛋白(Rgulators of G protein signaling,RGS)是一类重要的G蛋白信号调控因子,能通过促进G蛋白α亚基(Gα)偶联的GTP水解,使Gα和Gβγ亚基发生聚合,导致G蛋白失活,从而迅速关闭与G蛋白偶联的信号途径。自从第一个RGS蛋白在酿酒酵母中被鉴定以来,目前已经有30多个RGS蛋白在重要的模式真菌中被报道,包括构巢曲霉、绿僵菌、稻瘟病菌、玉米赤霉菌、轮枝镰孢菌、新型隐球菌和白色念珠菌等。RGS蛋白在真菌的营养菌丝生长、产孢、毒素和色素生产、致病性和有性生殖等过程中发挥着重要作用。本文对真菌中已报道RGS蛋白的功能进行了总结,对真菌RGS蛋白的结构特征和调控机制进行了评述。     

G蛋白及其偶联信号传导途径的研究进展

G蛋白偶联信号传导系统是一类重要的细胞跨膜信号传导途径之一。在有关生化及药理的医学研究中发现许多药剂都是通过G蛋白偶联信号传导途径对动物起作用的。对G蛋白结构与功能的系统研究是新型药剂研制与开发的基础。G蛋白在物种进化过程中具有高度保守性,植物和昆虫中的G蛋白及其偶联组份研究将有助于明确作物抗病虫机理以及昆虫毒理。     

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。     

G蛋白偶联受体介导的神经信号跨膜转导

Ｇ蛋白偶联受体介导的神经信号跨膜转导郭君,周安武,杜雨苍（中国科学院上海生物化学研究所,上海２０００３１）关键词Ｇ蛋白偶联受体,神经信号跨膜转导受体是细胞膜或细胞内的一些首先能与生物活性物质相互作用的分子,它们能够识别配基并与其结合,然后将受体与配基...     

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。     

细菌蛋白分泌途径的研究进展

蛋白质分泌对于细菌的生长和繁殖具有至关重要的作用.在革兰氏阴性菌中,蛋白质分泌包括两步和一步分泌途径,主要涉及Sec、SRP和Tat途径.近年来发现I-Ⅳ型途径也参与胞内蛋白质转运.主要介绍革兰氏阴性茵蛋白分泌的机制及生理意义.对于细菌蛋白分泌机制的深入研究将为细茵蛋白质分泌工程和病原微生物的防治带来有益启示.     

味觉信号的通用编码途径

味觉对于辨别甜味、苦味、酸味、咸味和鲜味 (氨基酸味 )有重要的作用。最近 ,利用遗传学、生物信息学、表达克隆等手段克隆了哺乳动物的味觉受体。甜味和鲜味是由Ｔ1Ｒ家族的三个Ｇ蛋白偶联受体介导的。苦味主要由Ｔ2Ｒ家族约 30个Ｇ蛋白偶联受体所介导。ＴＲＰＭ5是一种新近从味觉细胞中克隆的基因 ,属于ＴＲＰ钙离子通道家族。形态学研究结果表明 ,ＴＲＰＭ5与Ｔ1Ｒ或Ｔ2Ｒ受体共存 ,并且证明ＴＲＰＭ5可以被味觉受体通过磷脂酶Ｃ(ＰＬＣ)所激活。ＴＲＰＭ5或者ＰＬＣβ2基因敲除的小鼠表现出甜味、苦味和鲜味味觉缺失 ,但不影响其酸味和…     

丝状真菌的细胞凋亡

凋亡是一种程序性细胞死亡类型,为多细胞生物发育和维持生命所必需的,也普遍存在于细菌等原核生物和酵母、丝状真菌等真核生物中。丝状真菌既具有酵母和哺乳动物共有的凋亡同源蛋白,也具有酵母所不具备的哺乳动物凋亡同源蛋白,所以其凋亡机制较酵母更为复杂,而又较哺乳动物简单。凋亡在丝状真菌的发育、繁殖、衰老等过程中具有重要的作用。近年,丝状真菌作为新的凋亡研究的模式生物被广泛研究,而且进展迅速。综述丝状真菌的凋亡现象和检测方法,丝状真菌中凋亡的生物学功能,丝状真菌凋亡的诱导条件,以及丝状真菌凋亡相关基因的功能研究进展。     

丝状真菌遗传筛选系统的研究及其应用

随着基因组时代的发展,主要丝状真菌基因组测序基本完成而被广泛应用于工业、农业、医药等领域。然而丝状真菌的遗传转化效率极低,为了保证在大量非转化子背景下能筛选到目标转化子,恰当的筛选标记显得尤为重要。目前,在丝状真菌的遗传转化过程中常用的筛选标记可分为两类:药物抗性筛选标记和营养缺陷型筛选标记。但两者均具有一定的局限性,为此科研人员利用最新研究的基因组编辑技术对筛选标记加以修饰改造,以更好地用于遗传筛选。本文综述了目前常用的遗传筛选系统的分子机制及运用基因组编辑技术改造的新型筛选标记理论,为丝状真菌在各领域更广泛的应用奠定基础。     

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。     

Choline: Its role in the growth of filamentous fungi and the regulation of mycelial morphology

Abstract Choline is an essential metabolite for the growth of filamentous fungi. It occurs most notably as a component of the major membrane phospholipid, phosphatidyl choline (lecithin), and fulfills a major role in sulphate metabolism in the form of choline- o -sulphate in many species. Choline is usually synthesised endogenously, but exogenous choline can also be taken up, either to compensate for metabolic deficiencies in choline-requiring mutants such as those of Aspergillus nidulans and Neurospora crassa , or as a normal function by species such as Fusarium graminearum which do not require added choline for growth. F. graminearum has a highly specific constitutive uptake system for this purpose. Recent studies have begun to indicate that choline also plays an important role in hyphal and mycelial morphology. Over a wide range of concentrations, choline influences mycelial morphology, apparently influences mycelial morphology, apparently by controlling branch initiation. At high concentrations of added choline, branching is inhibited but specific growth rate is unaffected, leading to the production of rapidly extending, sparsely branched mycelia. Reduction of choline concentration allows a progressive increase in branching. Additionally, in choline-requiring mutants which have a very reduced content of choline, multiple tip-formation and apical branching occurs. Just prior to cessation of growth in choline-starved cultures of A. nidulans choline-requiring mutants, hyphal morphology changes due to a brief phase of unpolarised growth to produce spherical swellings called ballons, at or near hyphal apices. The precise mechanism by which choline affects fungal morphology is not yet known, although in A. nidulans it appears to be at least partially due to the influence of membrane composition on the synthesis of the hyphal wall polymer chitin. Several hypotheses for the possible mode of action of choline in affecting fungal morphology are discussed here.     

Regulation of longevity by regulator of G-protein signaling protein, Loco

Regulator of G-protein signaling (RGS) proteins contribute to G-protein signaling pathways as activators or repressors with GTPase-activating protein (GAP) activity. To characterize whether regulation of RGS proteins influences longevity in several species, we measured stress responses and lifespan of RGS-overexpressing and RGS-lacking mutants. Reduced expression of Loco, a RGS protein of Drosophila melanogaster, resulted in a longer lifespan for both male and female flies, also exhibiting stronger resistance to three different stressors (starvation, oxidation, and heat) and higher manganese-containing superoxide dismutase (MnSOD) activity. In addition, this reduction in Loco expression increased fat content and diminished cAMP levels. In contrast, overexpression of both genomic and cDNA loco gene significantly shortened the lifespan with weaker stress resistance and lower fat content. Deletion analysis of the Loco demonstrated that its RGS domain is required for the regulation of longevity. Consistently, when expression of RGS14, mammalian homologue of Loco, was reduced in rat fibroblast cells, the resistance to oxidative stress increased with higher MnSOD expression. The changes of yeast Rgs2 expression, which shares a conserved RGS domain with the fly Loco protein, also altered lifespan and stress resistance in Saccharomyces cerevisiae. Here, we provide the first evidence that RGS proteins with GAP activity affect both stress resistance and longevity in several species.     

Vegetative incompatibility in filamentous fungi: Podospora and Neurospora provide some clues

In filamentous fungi, vegetative cell fusion between genotypically distinct individuals leads to a cell-death reaction known as vegetative or heterokaryon incompatibility. Genes involved in this reaction have been characterised molecularly. We can now begin to get a better understanding of the mechanism and the biological significance of this intriguing phenomenon.     

Global nutritional profiling for mutant and chemical mode-of-action analysis in filamentous fungi

We describe a method for gene function discovery and chemical mode-of-action analysis via nutrient utilization using a high throughput Nutritional Profiling platform suitable for filamentous microorganisms. We have optimized the growth conditions for each fungal species to produce reproducible optical density growth measurements in microtiter plates. We validated the Nutritional Profiling platform using a nitrogen source utilization assay to analyze 21 Aspergillus nidulans strains with mutations in the master nitrogen regulatory gene, areA. Analysis of these data accurately reproduced expected results and provided new data to demonstrate that this platform is suitable for fine level phenotyping of filamentous fungi. Next, we analyzed the differential responses of two fungal species to a glutamine synthetase inhibitor, illustrating chemical mode-of-action analysis. Finally, a comparative phenotypic study was performed to characterize carbon catabolite repression in four fungal species using a carbon source utilization assay. The results demonstrate differentiation between two Aspergillus species and two diverse plant pathogens and provide a wealth of new data on fungal nutrient utilization. Thus, these assays can be used for gene function and chemical mode-of-action analysis at the whole organism level as well as interspecies comparisons in a variety of filamentous fungi. Additionally, because uniform distribution of growth within wells is maintained, comparisons between yeast and filamentous forms of a single organism can be performed.Electronic Supplementary Material Supplementary material is available in the online version of this article at The revised version of the PDF file was published online in January 2004. The figures are now in color.An erratum to this article can be found at     

真菌通用引物Its1和Its4在丝状真菌鉴定中的价值评价

目的 对真菌通用引物Its1和Its4在丝状真菌鉴定中的价值进行评价.方法 收集中山大学附属第一医院2012年1月至2012年8月间分离的丝状真菌11株,使用真菌通用引物Its1和Its4采用PCR法扩增核糖体基因,对PCR产物进行序列测定,将测序结果与GenBank中已知标准或临床菌株DNA序列比对,确定丝状真菌的菌种;同时与传统形态学鉴定方法进行比较,从而对真菌通用引物Its1和Its4在丝状真菌鉴定中的价值进行评价.结果 从DNA提取到序列测定结束,在2个工作日内即可完成.所有菌株均测序成功,测序结果与GenBank中的序列比对,烟曲霉、杂色曲霉、橘青霉、溜曲霉可以鉴定到种;黄曲霉和米曲霉、阿姆斯特丹散囊菌和冠突散囊菌由于高度同源性无法区分鉴定到种.结论 利用真菌通用引物Its1和Its4结合PCR技术和测序技术,可快速、准确将大部分丝状真菌鉴定到种.