一种冬虫夏草全基因组DNA的提取方法

冬虫夏草是真菌与昆虫形成的复合生物体,本研究建立了一种可同时提取冬虫夏草真菌子座和虫体全部基因组DNA的方法。该方法稳定高效,简便易行,提取纯度高,适用于冬虫夏草多重PCR、Realtime-PCR和DNA指纹图谱等分子水平的研究。     

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。     

实验动物皮肤病原真菌DNA快速少量提取法

PCR技术应用于实验动物皮肤病原真菌检测,方法简单、省时。但是,真菌的DNA提取较为困难。本文推荐一种既简单又经济快速的提取皮肤真菌DNA的方法,并能成功用于实验动物皮肤病原真菌质量检测研究。     

FTA-DNA直接提取法在病原真菌分子鉴定中的应用

目的建立并评价FTA-DNA直接提取法在病原真菌分子鉴定中的应用。方法采用whatman FTA-DNA直接提取法从25个不同种属的45株培养的菌株和6例临床标本中提取病原真菌DNA,用于病原真菌的测序鉴定。配制不同浓度的孢子悬液探索该方法的检测限和安全性。结果 45株菌株扩增后均能得到1条清晰的DNA扩增片段,并成功测序。应用该方法亦成功从腹水、胸水、口腔拭子、宫颈拭子来源的临床标本中直接提取DNA并成功鉴定病原真菌。该DNA提取方法联合降落PCR能检测到1.0×103个cell/mL的孢子悬液,1.0×104个cell/mL及以下浓度的孢子悬液可以被FTA卡完全灭活。结论 FTA-DNA直接提取法可快速有效地从培养的菌株及部分临床标本中提取并保存病原真菌DNA,用于病原真菌的测序鉴定。     

一种简单有效且适于土壤微生物多样性分析的DNA提取方法

参照Zhou[11]的方法进行了改进,获得了一种简单、有效的DNA提取方法.此方法操作简单、从大量样品改为小量样品的提取,利用高浓度的PEG沉淀,不作回收纯化,所提DNA片段较大,在23 kb以上,每克土的DNA提取量从3.74～15.28 μg,OD260/OD230比值在0.89～1.21范围内,用真菌和细菌核糖体特异性引物进行PCR扩增,均获得较好的结果,DGGE图谱显示丰富性较高,可用于细菌多样性和真菌多样性的分析.此方法能够从4种不同性质土壤中提取出DNA,但提取盐渍土壤和碱性土壤的效果更好一些,为土壤微生物群落结构的多样性分析奠定良好的基础.     

氯化苄法提取染色体DNA

本文介绍了一种简便、快速提取细菌和真菌的基因组DNA的方法一氯化苄法。使用氯化苄法抽提基因组DNA,不仅具有快迅、简便、耗资少的优点;而且得到的基因组DNA纯度高,质量好,可直接用于酶切、杂交和PCR扩增等用途。该法可用于多种细菌和真菌基因组DNA的提取。     

一种实用可靠的古代 DNA 获取方法

古代DNA序列信息能够为物种演化研究提供最直接的分子证据,但获取古代DNA的技术仍存在诸多瓶颈,尤其是扩增中存在受损伤DNA模板的干扰、获取成本高和实验周期长等问题．改进了异丙醇沉淀提取法,并采用了尿嘧啶糖苷酶(UNG)去除受损伤DNA模板后进行扩增的方法,最终可以高效地获取真实的古代DNA序列．实验利用距今4 300～3 900年前的猪牙样本,将改进的古 DNA 获取方法与常规方法进行比较研究,结果表明,改进的异丙醇沉淀法提取结合UNG处理后进行PCR扩增的方法,可以在保证古代DNA获取成功率并提高获得的DNA序列可靠性的前提下,将经费投入和实验周期都各减少至常规方法的50%以下．这可以为开展大规模古代样本检测提供一种切实可行的 DNA 获取方法．     

一种从鸟类剥制标本提取DNA的改进方法

应用非损伤性取样的方法,收集鸟类剥制标本的皮肤组织和羽毛,用无水乙醇、浸泡液预处理的方法抽提DNA,结果两者都可提取DNA供PCR扩增。将PCR产物经序列测定和比对分析,证明提取的DNA为目的DNA,表明本试验方法可行。鸟类剥制标本的皮肤组织和羽毛可以作为研究种群遗传学的资源。     

利用氯化苄提取适于分子生物学分析的真菌 DNA

随着生物技术的飞速发展,更加需要简便、快速地提取高质量的DNA。以往报导的提取真菌DNA的方法大都采用液氮研磨或酶解破坏细胞壁和膜的方式,从而导致繁琐、复杂和费时的提取过程。根据氯化苄在弱碱条件下与多糖上的羟基反应形成醚从而使多糖长链断裂的事实,我们发展了一种全新的真菌DNA提取方法,该方法使氯化苄在pH9.0时与细胞壁多糖作用,破坏细胞壁,基因组DNA因而得以从细胞中释放出来。新方法具有简便、快速、价廉的优点,得到的DNA蛋白质污染少、质量较高、产量稳定。对该法提取的DNA作进一步的分子生物学分析,如限制性内切酶酶解、RFLP分析、RAPD扩增,都取得了令人满意的结果。利用氯化苄提取真菌DNA的研究,迄今在国际、国内均尚未见报道。     

利用氯化苄提取适于分子生物学分析的真菌DNA

随着生物技术的飞速发展,更加需要简便、快速地提取高质量的DNA。以往报导的提取真菌DNA的方法大都采用液氮研磨或酶解破坏细胞壁和膜的方式,从而导致繁琐、复杂和费时的提取过程。根据氯化苄在弱碱条件下与多糖上的羟基反应形成醚从而使多糖长链断裂的事实,我们发展了一种全新的真菌DNA提取方法,该方法使氯化苄在pH9.0时与细胞壁多糖作用,破坏细胞壁,基因组DNA因而得以从细胞中释放出来。新方法具有简便、快速、价廉的优点,得到的DNA蛋白质污染少、质量较高、产量稳定。对该法提取的DNA作进一步的分子生物学分析,如限制性内切酶酶解、RFLP分析、RAPD扩增,都取得了令人满意的结果。利用氯化苄提取真菌DNA的研究,迄今在国际、国内均尚未见报道。     

DNA序列分析用于常见致病真菌鉴定和分型

随着真菌感染的增多,仅用表型方法鉴定环境中或临床上的致病真菌不足以快速准确地诊断真菌感染疾病,近年来,分子生物学方法因快速、准确而逐步得到应用,其中DNA序列分析已成为鉴定致病真菌到种水平的重要方法。现就DNA序列分析在常见致病真菌分类鉴定及基因分型的应用加以综述。     

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。     

向日葵黑茎病菌的快速分子检测

从新疆采集的向日葵黑茎病罹病植株的茎秆、叶片和花盘共分离获得20个真菌分离物。经致病性测定,证明分离物XJ011和XJ111是引起该病害的病原物。采用ITS通用引物ITS1/ITS4对XJ011和XJ111菌株的rDNA-ITS区进行PCR扩增和测序,并结合形态学特征,将该菌鉴定为麦氏茎点霉Phoma macdonaldii。同时,在rDNA-ITS的多态性丰富区域设计了一对特异性引物320FOR/320REV,建立了P. macdonaldii病菌的快速分子检测体系,能特异性检测出向日葵黑茎病菌,灵敏度     

一种快速提取丝状真菌染色体DNA的方法

介绍了一种适用于丝状真菌染色体DNA大片段的快速提取方法,该方法以(100mM Tris,100mM NaGl,50mM EDTA-Na2 2%SDS,pH值9.0)为提取液,经石英砂研磨破壁.应用该方法成功地提取了粗糙脉胞菌(Neurospora crassa)、米曲霉(Aspergillus oryzae)、产黄青霉(Penicillium chrysogenum)和头孢霉菌(Cep- halosporium sp.)等4种不同丝状真菌的染色体DNA大片段,且所提DNA片段均大于20kb,可直接用于限制性酶切、PCR等分子生物学研究.     

Optimal extraction methods for the simultaneous analysis of DNA from diverse organisms and sample types

Using environmental DNA (eDNA) to assess the distribution of micro‐ and macroorganisms is becoming increasingly popular. However, the comparability and reliability of these studies is not well understood as we lack evidence on how different DNA extraction methods affect the detection of different organisms, and how this varies among sample types. Our aim was to quantify biases associated with six DNA extraction methods and identify one which is optimal for eDNA research targeting multiple organisms and sample types. We assessed each methods’ ability to simultaneously extract bacterial, fungal, plant, animal and fish DNA from soil, leaf litter, stream water, stream sediment, stream biofilm and kick‐net samples, as well as from mock communities. Method choice affected alpha‐diversity for several combinations of taxon and sample type, with the majority of the differences occurring in the bacterial communities. While a single method performed optimally for the extraction of DNA from bacterial, fungal and plant mock communities, different methods performed best for invertebrate and fish mock communities. The consistency of methods, as measured by the similarity of community compositions resulting from replicate extractions, varied and was lowest for the animal communities. Collectively, these data provide the first comprehensive assessment of the biases associated with DNA extraction for both different sample types and taxa types, allowing us to identify DNeasy PowerSoil as a universal DNA extraction method. The adoption of standardized approaches for eDNA extraction will ensure that results can be more reliably compared, and biases quantified, thereby advancing eDNA as an ecological research tool.     

A method to construct cDNA library of the entomopathogenic fungus, <Emphasis Type="Italic">Metarhizium anisopliae</Emphasis>, in the hemolymph of the infected locust

A method was developed to construct cDNA library of pathogenic fungus in the blood of the infected insect for cloning the fungal genes expressed in the host. This method is designed to take advantage of the obvious difference between the cell structures and components of the pathogen cells and that of the host cells. The host blood cells only have cell membrane, which can be disrupted by using SDS/proteinase K (PK). The fungal cells grown in the animal blood have cell wall, which can protect the fungal cell from the disruption of SDS/proteinase K (PK). By this method, the blood cells were disrupted by SDS/proteinase K (PK) and then the released animal RNA and DNA were digested completely with RNase and DNase. Therefore, the fungi grown in the blood were harvested without any contamination of host RNA and DNA. The pure fungi harvested from the infected blood can be used for mRNA extraction and cDNA library construction. The purity of the fungal mRNA was confirmed by PCR and RT-PCR with specific primer pairs for the host and specific primer pairs for the fungus, respectively, and the clones of cDNA library constructed by using the fungal mRNA was also analyzed. The results showed that there was no detectable contaminated insect DNA or RNA existing in the fungal mRNA. Randomly selected cDNA clones from cDNA library were sequenced and analyzed against GenBank using Blastx; no selected sequences had significant similarity with insects’ genes in comparison with the data of GenBank. The results further confirmed that the method to purify the pathogenic fungus from the host animal is reliable and the mRNA extracted from the fungus is eligible for cDNA library construction, and other molecular analysis including RT-PCR. This method may be applied to other pathogenic fungi and their host animals.     

Molecular detection of Puccinia horiana Henn. the causal agent of Chrysanthemum white rust

Chrysanthemum white rust is one of the most important foliar diseases of pot chrysanthemum and is a quarantine pathogen in many countries. Under conducive environmental conditions, it has the potential to completely destroy susceptible cultivars. This is mainly avoided through frequent preventive fungicide applications. As part of a research program to develop a disease warning system, a molecular detection method was developed. To determine the nucleotide sequence of the nuclear rDNA-ITS (internal transcribed spacer) region of P. horiana, 56 isolates were collected between 2003 and 2006 from diseased commercial chrysanthemum plants from different national and international geographical areas. DNA was isolated from the basidiospores or teliospores from several isolates and the rDNA-ITS region was cloned and sequenced. Based on the limited variability in rDNA-ITS sequence between these isolates, several primer pairs were designed and tested for detection through conventional and real-time PCR. Specificity of detection was cross-checked against a variety of other fungi (saprophytes and other rusts) that may occur in the same environment, and against DNA of healthy chrysanthemum leaves. Using the best primers, the PCR-based methods successfully detected all the P. horiana isolates tested, while no signal was observed with other rust species up to 1 ng non target genomic DNA template. The limit of detection of P. horiana DNA in conventional, nested and real-time PCR was 10 pg, 10 fg and 10 fg, respectively. The DNA extraction method and PCR template concentration were optimized to maximize the recoverability of the pathogen from infected plant tissue. Using the optimized real-time PCR method, the pathogen could be detected in washed plant tissue, 9 hours after inoculation. Hence, this method allows detection of the P. horiana in any part of its latent stage and will also serve as a tool for studying the biology and epidemiology of the pathogen.     

Simultaneous monitoring of two fungal genotypes on plant roots by single nucleotide polymorphism quantification with an innovative KASPar quantitative PCR

An innovative quantitative PCR-based method derived from the Kompetitive Allele Specific PCR Assay Reagent (KASPar) system was developed to quantify the genomic DNA from two coexisting genotypes on the same tissues of a host-plant. For this purpose, the classical end-point KASPar method was evolved to a real-time method thanks to the addition of an adapted measurement step after each PCR cycle. It was applied to the quantification of the two genotypes G1 and G2 of the Gaeumannomyces graminis var. tritici (Ggt) soilborne fungus, pathogenic on wheat roots. Specific primers targeting a single nucleotide polymorphism from the ITS sequence were used allowing simultaneous quantification of both genotypes in the same reaction. The assays were applied to quantify fungal DNA of each genotype, aside or mixed together, after DNA extraction from fungal pure cultures and from single or co-inoculated roots in artificial medium or in soil. The detection and quantification lower limits for the two genotypes were 1.25 pg and 5 pg for DNA from fungal pure cultures, and 1.8 pg and 7 pg for DNA from fungal inoculated roots. The advantages of this cost-effective method are the high levels of specificity, sensitivity and reproducibility. Moreover, the accuracy of the method is independent of the copy numbers of the target sequences. The method is the first one to adapt the non-quantitative genotyping KASPar system to a quantitative application of two known genotypes of a species simultaneously and is suitable for simultaneous genotype-specific quantification of any other organisms (fungi, bacteria, plants).     

The influence of genotypic variation on metabolite diversity in populations of two endophytic fungal species

The relationship between metabolite production and genotypic diversity in two endophytic fungi was investigated. We selected populations of Cylindrocarpon destructans and Heliscus lugdunensis from the roots of a single tree. A total of 49 isolates of both species were selected and classified by simple genotypic tests (random amplified polymorphic DNA analysis and rDNA-ITS sequencing). In a blind test, the ability of these fungi to produce natural products was tested by ethyl acetate extraction of hyphae and culture filtrates, followed by high-performance liquid chromatography analysis (HPLC). A positive relationship was found between genotype classification and the pattern of natural products produced by a given isolate. To test the robustness of this correlation, a discriminate selection procedure was carried out by collecting fungal isolates from a second site and selecting a sub-set of the population, on the basis of genotypic variability. This sub-set of fungal isolates produced greater numbers of unique metabolites than those selected indiscriminately.