Chelex-100快速提取放线菌DNA作为PCR扩增模板

旨在建立有效扩增16S rRNA基因序列的放线菌DNA快速提取的方法。采用Chelex-100法提取放线菌DNA,使用PCR扩增16S rRNA基因序列评价提取核酸的质量。结果显示,Chelex-100法能够在10 min之内从放线菌中快速提取DNA,所提取的DNA可以直接用于PCR扩增反应,PCR扩增产物电泳条带清晰,符合理论预期结果。因此,Chelex-100法提取放线菌DNA可以作为16S rRNA基因序列PCR扩增的模板,该方法具有经济、简便、快速的特点,适合于放线菌菌株大规模地筛选和分类鉴定。     

牛肉干中牛基因组DNA提取方法的比较研究

为得到一种快速、稳定、准确、优质的牛肉干DNA的提取方法,本研究比较了SDS法、改良CTAB法、酚-氯仿抽提法以及4种试剂盒提取法的提取效果。通过比较DNA的提取质量、提取效率,并对提取的DNA进行PCR扩增分析。DNA提取结果表明,7种提取方法均能从牛肉干中提取出DNA,其中采用SDS法、酚-氯仿法、试剂盒1法和试剂盒4法所提取的DNA质量较高,A260/A280比值在1.7~1.9之间。试剂盒3法提取所花的时间最少,DNA得率最高,但DNA的纯度最低。PCR扩增结果表明,7种方法所提取的DNA均能满足后续PCR扩增实验的要求。实验室可根据具体的实际情况选择使用DNA提取方法。     

苛求芽孢杆菌基因组DNA提取方法的比较

目的:比较不同方法提取苛求芽孢杆菌基因组DNA的差异。方法:用经典CTAB提取法、改进CTAB法(溶菌酶处理结合CTAB提取法)、UniQ柱吸附提取法制备苛求芽孢杆菌基因组DNA,比较产物完整性和用于PCR扩增的有效性。结果:三种方法制备基因组DNA纯度接近,但改进CTAB法产率最高,UniQ法产率最低。经典CTAB法和UniQ法提取基因组DNA易降解。三种方法所得基因组DNA用于PCR扩增效率接近。结论:溶菌酶裂解结合CTAB提取更适合制备苛求芽孢杆菌基因组DNA。     

Chelex-100法及酚氯仿法提取阴道毛滴虫DNA的比较

目的-比较Chelex-100法和酚氯仿法提取阴道毛滴虫基因组DNA。方法-分别用Chelex-100法和酚氯仿法提取阴道毛滴虫基因组DNA,用PCR法检测DNA提取的有效性。结果两种方法提取的DNA经PCR扩增均有特定的条带。结论-两种方法均能提取阴道毛滴虫DNA。Chelex-100方法简便、省时,较适用于分子生物学研究及临床PCR扩增使用。     

利用CTAB法和子囊孢子破壁法提取冬虫夏草菌DNA

通过CTAB法从冬虫夏草菌株和天然冬虫夏草不同部位提取DNA,并用PCR扩增进行验证,证明了CTAB法适合从冬虫夏草子座、菌核和冬虫夏草菌培养物中提取DNA。首次报道1种将子囊孢子破壁直接进行PCR扩增的方法,并比较了该方法和CTAB法在提取冬虫夏草DNA方面的差异。2种方法获得的DNA用于PCR扩增均能得到较好的结果。     

三种提取柱状黄杆菌基因组DNA方法的比较

采用酚氯仿抽提法、CTAB法和SDS-蛋白酶K法分别对鱼类病原菌柱状黄杆菌提取基因组DNA。使用超微量紫外分光光度计和琼脂糖凝胶电泳检测所提取的基因组DNA的产量和质量,并用PCR扩增对DNA进行了评价。结果显示,3种方法均可提取到柱状黄杆菌的基因组DNA,并能有效扩增细菌16S rDNA序列,但CTAB法提取的DNA产量和质量最高,CTAB法可以作为柱状黄杆菌DNA提取以开展分子生物学研究的首选方法。     

RAPD分析用白花丹参叶片DNA的提取方法

本研究采用改良CTAB法和SDS法提取新鲜白花丹参叶片的基因组DNA,初步筛选RAPD扩增引物。结果表明改良CTAB法提取的DNA较SDS法质量好,随机引物p2扩增条带相对较为清晰。再利用p2随机引物对2种方法提取的DNA进行RAPD检测比较,结果显示仅改良CTAB法能扩增出有效条带,说明改良CTAB法更适合用于白花丹参基因组DNA的RAPD检测分析。本文将为白花丹参叶片DNA的提取提供方法学参考。     

三种提取冬虫夏草菌丝体基因组DNA方法的比较

采用改良氯化苄法、CTAB法、蛋白酶K裂解法这三种方法,对冬虫夏草菌丝体基因组DNA进行提取,将提取的基因组DNA经过紫外分光光度计检测纯度和计算浓度、琼脂糖凝胶电泳分析及PCR扩增,结果表明,3种方法均能提取到符合分子生物学的DNA,其中蛋白酶K裂解法纯度最高,含蛋白质少,改良氯化苄法、CTAB法次之。而浓度则是改良氯化苄法最高,CTAB法、蛋白酶K裂解法次之。3种方法所提取的DNA均能扩增出理想条带。     

鸡肠道菌群总DNA三种提取方法的比较

目的比较不同方法提取鸡肠道菌群总DNA的差异,为分子方法分析肠道菌群组成提供质量较高的DNA模板。方法采用反复冻融法、酶裂解法和试剂盒法（E.N.Z.A Stool DNA Kit）来提取鸡肠道菌群的总DNA,并根据DNA浓度及纯度、16S DNA扩增产物和ERIC-PCR产物所反映的片段多态性4个指标,对这3种方法提取的DNA质量进行比较。结果3种方法均能提取DNA,所得DNA都可以用于16S DNA的扩增,但后2种方法所得DNA的ERIC-PCR结果能反映出更高的菌群多样性。结论试剂盒法和酶裂解法所提取的DNA质量好,适合用于肠道菌群的分子生态研究。     

用于分析土壤微生物结构变化规律的变性梯度凝胶电泳条件研究

研究确定土壤微生物基因组DNA提取方法、PCR扩增条件、DGGE电泳条件,为进一步研究分析土壤中微生物结构变化规律提供理论依据。土壤微生物基因组DNA提取采用直接法和间接法进行比较; PCR扩增条件调整扩增体系、DGGE电泳条件调整变性剂范围,并对其结果进行比较分析。通过对DGGE电泳相关条件的研究,结果显示,土壤中粗基因组DNA采用直接法提取,然后进行纯化; PCR扩增体系中加入BSA,DGGE电泳系统组成中变性剂浓度范围为35%～55%。确定了土壤微生物基因组DNA提取方法、PCR扩增条件、DGGE电泳条件,为后续的相关研究提供理论依据。     

一种适用于PCR反应的酵母菌、无绿藻及丝状真菌DNA提取方法

目的 介绍一种从酵母、无绿藻及丝状真菌中提取DNA以用于PCR反应的方法。方法 所用菌种包括临床分离的未知菌株和保藏菌株共23株：未知酵母菌（5株）、真皮毛孢子菌（1株）、糠秕马拉色菌（1株）、季也蒙念珠菌（5株）、未知丝状真菌（6株）、无绿藻（1株）、烟曲霉（2株）、拟青霉菌（1株）、茎点霉（1株）。用溶细胞酶（lyticase）结合Biospin真菌基因组DNA提取试剂盒提取基因组DNA,A260／A280检测纯度并计算质量浓度,用真菌通用引物ITS1／ITS4扩增真菌核糖体基因（rDNA）内转录间区ITS基因,经PCR扩增检验所提取的DNA质量。结果 成功提取所有23株真菌基因组DNA,其纯度及质量浓度能满足PCR反应的要求。结论 用溶细胞酶结合Biospin真菌基因组DNA提取试剂盒从酵母菌、无绿藻及丝状真菌提取的DNA可用于PCR反应。     

一种用于PCR扩增的丝状真菌DNA快速提取方法

丝状真菌在工业、农业、医药以及基础生物学研究中具有重要作用。利用遗传转化技术对丝状真菌进行菌株改良和基因功能分析, 也越来越受到重视。然而, 丝状真菌DNA提取方法繁琐、费时, 难以满足利用PCR技术高通量筛选转化子的需要。本文以曲霉菌为例建立了一种快速提取丝状真菌DNA的实验方法, 微波处理置于10 × TE buffer中的菌丝即可得到DNA。RAPD试验和PCR扩增证明, 该方法提取的DNA能够达到PCR扩增的要求。研究结果为高通量快速筛选丝状真菌转化子奠定了基础。     

丝状真菌基因工程研究进展

本文评述了丝状真菌基因工程的研究进展,内容涉及已被转化成功的９０余种丝状真菌种类及其所利用的选择标记,比较了几种外源ＤＮＡ进入丝状真菌受体的方法,并较为详细地评述了丝状真菌复制型与整合型转化及其转化子的有性生殖与无性生殖的遗传稳定性,最后,展望了丝状真菌基因工程在农业、工业和医药方面的应用。表明了丝状真菌基因工程具有广阔的应用前景。     

The challenge for identifying the fungi living inside mushrooms: the case of truffle inhabiting mycelia

The Tuber ascomata (truffles) are a microhabitat for bacteria, viruses, and fungi (yeasts and filamentous fungi). In this survey, we tried to develop a method that would make it possible to define the mycobiome of the truffle-inhabiting filamentous fungi using culture independent molecular methods. The nested quantitative Real-Time PCR allowed us to demonstrate that each truffle is home to multiple species of filamentous fungi and that their DNA is present within the healthy ascoma at the ratio of 10^?6 compared to that of the truffle. Probably due to their insignificant presence, Denaturing Gradient Gel Electrophoresis of the amplification of ITS amplicons showed only those of the host. Based on the results, the possibilities of being able to detect the fungicolous fungi present in very small amounts within a fungal host are discussed.     

一种经济快速提取丝状真菌基因组DNA的方法

以螺旋木霉(Trichoderma SpiraleXX)、小克银汉霉(Cunninghamella phaeospora MK)和卵形孢球托霉(Gongronella butleri XT)3种丝状真菌为材料,采用改进的CTAB法提取基因组DNA.方法改进后无需液氮、聚乙烯砒咯烷酮(PVP)和NaAc等试剂,过程简洁,且所需菌体量少,提取的DNA纯度较好,适用于一次微量提取多个样品的基因组DNA.此方法得到的基因组DNA可用于PCR扩增.     

Overcoming diverse homologous recombinations and single chimeric guide RNA competitive inhibition enhances Cas9-based cyclical multiple genes coediting in filamentous fungi

Deciphering the complex cellular behaviours and advancing the biotechnology applications of filamentous fungi increase the requirement for genetically manipulating a large number of target genes. The current strategies cannot cyclically coedit multiple genes simultaneously. In this study, we firstly revealed the existence of diverse homologous recombination (HR) types in marker-free editing of filamentous fungi, and then, demonstrated that sgRNA efficiency-mediated competitive inhibition resulted in the low integration of multiple genetic sites during coediting, which are the two major obstacles to limit the efficiency of cyclically coediting of multiple genes. To overcome these obstacles, we developed a biased cutting strategy by Cas9 to greatly enhance the desired HR type and applied a new selection marker labelling strategy for multiple donor DNAs, in which only the donor DNA with the lowest sgRNA efficiency was labelled. Combined with these strategies, we successfully developed a convenient method for cyclically coediting multiple genes in different filamentous fungi. In addition, diverse HRs resulted in a useful and convenient one-step approach for gene functional study combining both gene disruption and complementation. This research provided both a useful one-step approach for gene functional study and an efficient strategy for cyclically coediting multiple genes in filamentous fungi.     

Double-joint PCR: a PCR-based molecular tool for gene manipulations in filamentous fungi

Gene replacement via homologous double crossover in filamentous fungi requires relatively long (preferentially >0.5 kb) flanking regions of the target gene. For this reason, gene replacement cassettes are usually constructed through multiple cloning steps. To facilitate gene function studies in filamentous fungi avoiding tedious cloning steps, we have developed a PCR-assisted DNA assembly procedure and applied it to delete genes in filamentous fungi. While the principle of this procedure is essentially the same as other recently reported PCR-based tools, our technique has been effectively used to delete 31 genes in three fungal species. Moreover, this PCR-based method was used to fuse more than 10 genes to a controllable promoter. In this report, a detailed protocol for this easy to follow procedure and examples of genes deleted or over-expressed are presented. In conjunction with the availability of genome sequences, the application of this technique should facilitate functional characterization of genes in filamentous fungi. To stream line the analysis of the transformants a relatively simple procedure for genomic DNA or total RNA isolation achieving approximately 100 samples/person/day is also presented.     

根癌农杆菌在丝状真菌转化中的应用

原生质体转化法是丝状真菌转化的传统方法,但其过程繁琐且转化效率低。根癌农杆菌介导的转化方法原本是进行植物遗传转化的标准方法,但近年来发现该方法还可用于丝状真菌的转化。根癌农杆菌介导的丝状真菌转化具有操作简便、转化效率高、重复性好等优点,从而可以解决丝状真菌转化难的问题。在本文中,就其转化机制、特点和转化条件优化等方面的最新研究进展进行了综述。     

CRISPR/Cas9基因编辑技术在丝状真菌中的应用

随着对丝状真菌基因水平研究的不断深入,CRISPR/Cas9技术作为先进的基因编辑技术,已被广泛应用于丝状真菌的基因编辑。探究了CRISPR/Cas9系统在不同丝状真菌中的应用情况,主要从sgRNA的构建与表达、Cas9蛋白的改造与表达、不同的DNA双链断裂修复（DNA double-strand break,DSB）方式等方面进行概述,并对编辑效率、脱靶效应进行总结,旨在为今后丝状真菌中CRISPR/Cas9系统的构建及改良提供思路。     

Rapid and efficient protocol for DNA extraction and molecular identification of the basidiomycete Crinipellis perniciosa

DNA isolation from some fungal organisms is difficult because they have cell walls or capsules that are relatively unsusceptible to lysis. Beginning with a yeast Saccharomyces cerevisiae genomic DNA isolation method, we developed a 30-min DNA isolation protocol for filamentous fungi by combining cell wall digestion with cell disruption by glass beads. High-quality DNA was isolated with good yield from the hyphae of Crinipellis perniciosa, which causes witches' broom disease in cacao, from three other filamentous fungi, Lentinus edodes, Agaricus blazei, Trichoderma stromaticum, and from the yeast S. cerevisiae. Genomic DNA was suitable for PCR of specific actin primers of C. perniciosa, allowing it to be differentiated from fungal contaminants, including its natural competitor, T. stromaticum.