稻瘟病菌变异菌株的AFLP分析*

利用94对AFLP引物对3个起始菌株和9个致病性变异菌株进行分析,其中49对引物可以区别出不同菌株类型,辨别变异菌株与其起始菌株的关系,以及起始菌株间的亲缘关系。9个变异菌株中5个菌株的条带数减少1~3条,4个菌株条带数没有明显变化。结果还表明,致病性及其他特征变异似乎与条带数缺失多少相关联。     

稻瘟病菌变异菌株的AFLP分析

利用94对AFLP引物对3个起始菌株和9个致病性变异菌株进行分析,其中49对引物可以区别出不同菌株类型,辨别变异菌株与其始菌株的关系,以及超始菌株间的亲缘关系。9个变异菌株中5个菌株的条带数减少1-3条,4个菌株条带数没有明显变化。结果还表明,致病性及其他特征变异似乎与条带数缺失多少相关联。     

应用ISSR技术分析不同分离方法获得的冬虫夏草菌株的遗传多样性

从60个引物中筛选出7个扩增条带清晰且多态性好的ISSR引物,并摸索合适的PCR反应条件,用于40株冬虫夏草的无性型——中国被毛孢菌株的PCR反应,共得到62条带,其中多态性条带38条,多态性百分率仅为61.29%,遗传相似系数范围在0.78¹.00之间。非加权配对算术平均法(UPGMA)聚类分析的结果表明:40株中冬虫夏草无性型菌株并没有完全按照不同的分离方法聚为3个类型;单子囊孢子分离法获得的菌株,明显区别于其他菌株而单独聚为一类,其他菌株则混合聚类。     

微卫星(TATG)n基序在香菇菌种中的验证

以（TATG）4重复序列为引物对香菇属的3个种13个菌株的微卫星区DNA进行PCR扩增,15%的琼脂糖凝胶电泳,获得了25个条带,并且在供试菌株上表现出多态性,可以实现遗传分类研究。为了验证微卫星分子标记实验准确性,又用RAPD技术对13个供试菌株进行了实验。7个引物在13个菌株上共获得了102条多态性条带。通过聚类分析,RAPD获得的分类结果与微卫星分子标记获得的结果一致。此外,为了证明微卫星分子标记获得的条带不是假阳性,在实验中回收了No.10菌株的PCR扩增产物,进行克隆测序。测序结果显示有（TATG）n基序存在,并且达到了微卫星基序重复数量的最低限度。通过本实验可知,香菇中是存在微卫星（TATG）n基序的, 且基序的多态性可以用于香菇的遗传分类研究。     

SSR标记在毛木耳种质资源遗传多样性研究中的应用

本研究利用基于毛木耳全基因组开发的SSR标记对27份毛木耳菌株（野生14株、栽培13株）的遗传多样性进行分析。首先随机选取3个菌株（2个野生菌株、1个栽培菌株）的DNA为模板,从144对SSR引物中筛选出扩增条带清晰、稳定性强、多态性丰富的引物24对。24对SSR引物共检测到116个多态性SSR片段,每对引物的多态性片段有3-7个,引物平均检测效率为4.83个,Shannon’s遗传多样性指数范围是0.866-1.885,多态性位点比率100%。供试菌株遗传相似系数范围是0.618-0.971,说明毛木耳种质资源具有丰富的遗传多样性。野生菌株与栽培菌株间平均遗传相似系数分别为0.746、0.779,说明毛木耳野生菌株遗传多样性更为丰富。经聚类分析,在遗传相似系数为0.680时,可将供试菌株分为无色（白色）类群Ⅰ和有色（浅黄色到红褐色）类群Ⅱ。遗传相似系数为0.704时,可将供试菌株中栽培菌株和野生菌株明显区分（14株野生菌株均在类群Ⅱ-2中,13株栽培菌株分别在类群Ⅰ和Ⅱ-1中）。本研究表明基于全基因组的SSR标记能从分子水平上揭示各菌株间的遗传差异,丰富毛木耳遗传多样性的研究手段,并为进一步进行毛木耳的品种选育、遗传学研究等提供有力手段。     

白黄侧耳Pleurotus cornucopiae微卫星间区(ISSR)分析

本试验对我国1982年至2004年22年间栽培的白黄侧耳Pleurotus cornucopiae 30个菌株进行了锚定ISSR分析,试验表明,引物P4和P5都能对白黄侧耳P.cornucopiae进行多态性扩增,P4将供试菌株扩增出45个条带,大小在200～20000bp,P5将供试菌株扩增出39个条带,大小在500～15000bp,扩增出的条带100%具多态性。聚类分析在遗传相似性61%的水平下将30个供试菌株划分为15个类群,即15个具一定遗传差异的菌株;具有相同ISSR图谱、遗传相似性程度100%的可能为同一菌株,属于同物异名。试验表明我国的食用蕈菌野生环境面临人工栽培种质的污染,采自河北、山东、云南自然环境下的白黄侧耳P.cornucopiae与此前大量栽培的一些商业品种具完全相同的ISSR指纹图谱,聚类分析相似性系数100%。     

致病性维罗纳气单胞菌检测方法的建立

发掘维罗纳气单胞菌特异性更强的检测靶点和毒力相关基因靶点,建立能够检测致病性维罗纳气单胞菌的PCR检测方法.通过序列比对分析气单胞菌的16S rRNA基因序列,筛选对维罗纳气单胞菌特异的引物,用于检测种特异性,利用气单胞菌气溶素基因保守引物,检测菌株的致病性,并进行反应条件和反应体系的优化,灵敏度试验和特异性试验.发掘并设计的维罗纳气单胞菌16S rRNA特异性引物结合气单胞菌气溶素基因保守引物建立的检测方法,对12株气单胞菌和10株非气单胞菌的检测结果显示,所有致病性维罗纳气单胞菌都能扩增到大小分别为343 bp和232 bp的特异性条带,而非维罗纳气单胞菌的致病性气单胞菌只能扩增到232 bp的气溶素基因特异性条带,其它菌株都不能扩增到目的条带.灵敏度试验表明,该反应体系的检测灵敏度为1.35×10-3 mg/L.我们建立的致病性维罗纳气单胞菌检测方法能特异地检测致病性维罗纳气单胞菌,并具有高度灵敏性.     

利用SRAP标记研究四川高原青稞育成品种的遗传多样性

利用SRAP(Sequence-related Amplified Polymorphism)分子标记技术, 对25份来自四川高原的青稞育成品种进行了遗传多样性研究。结果表明: 64对引物组合共检测出999条清晰条带, 62对可以获得多态性条带, 多态性引物组合占96.9%, 共产生225条多态性条带, 占总条带数的22.5%。64对引物组合共扩增出333种等位变异, 平均每个引物组合检测到5.20种等位变异。遗传多样性在0(me9/em14, me9/em15)~0.8928(me6/em18)之间, 平均为0.5126。聚类分析结果表明, 25份材料可分成A、B、C 3大类, 材料聚类与其来源地有明显的相关性。25份材料间的平均遗传距离较小(0.3240), 平均遗传多样性较低(0.5126), 遗传基础较为狭窄。     

白黄侧耳Pleurotus cornucopiae微卫星间区(ISSR)分析1

本试验对我国1982年至2004年22年间栽培的白黄侧耳Pleurotus cornucopiae 30个菌株进行了锚定ISSR分析,试验表明,引物P₄和P₅都能对白黄侧耳P.cornucopiae进行多态性扩增,P₄将供试菌株扩增出45个条带,大小在200～20000bp,P₅将供试菌株扩增出39个条带,大小在500～15000bp,扩增出的条带100%具多态性。聚类分析在遗传相似性61%的水平下将30个供试菌株划分为15个类群,即15个具一定遗传差异的菌株;具有相同ISSR图谱、遗传相似性程度100%的可能为同一菌株,属于同物异名。试验表明我国的食用蕈菌野生环境面临人工栽培种质的污染,采自河北、山东、云南自然环境下的白黄侧耳P.cornucopiae与此前大量栽培的一些商业品种具完全相同的ISSR指纹图谱,聚类分析相似性系数100%。     

白黄侧耳Pleurotus cornucopiae微卫星间区(ISSR)分析1

本试验对我国1982年至2004年22年间栽培的白黄侧耳Pleurotus cornucopiae 30个菌株进行了锚定ISSR分析,试验表明,引物P₄和P₅都能对白黄侧耳P.cornucopiae进行多态性扩增,P₄将供试菌株扩增出45个条带,大小在200～20000bp,P₅将供试菌株扩增出39个条带,大小在500～15000bp,扩增出的条带100%具多态性。聚类分析在遗传相似性61%的水平下将30个供试菌株划分为15个类群,即15个具一定遗传差异的菌株;具有相同ISSR图谱、遗传相似性程度100%的可能为同一菌株,属于同物异名。试验表明我国的食用蕈菌野生环境面临人工栽培种质的污染,采自河北、山东、云南自然环境下的白黄侧耳P.cornucopiae与此前大量栽培的一些商业品种具完全相同的ISSR指纹图谱,聚类分析相似性系数100%。     

Analysis of Genetic Diversity of Fusarium oxysporum f. sp. phaseoli Isolates, Pathogenic and Non-pathogenic to Common Bean (Phaseolus vulgaris L.)

Twenty isolates of Fusarium oxysporum from Brazil, pathogenic and non‐pathogenic to common bean, were analysed using random amplified polymorphic DNA (RAPDs) to study the genetic diversity. RAPD analysis using 23 oligonucleotides resulted in the amplification of 229 polymorphic and 7 monomorphic DNA fragments ranging from 234 to 2590 bp. High genetic variability was observed among the isolates, with the distances varying between 8% and 76% among pathogenic, 2% and 63% among the non‐pathogenic and 45% and 76% between pathogenic and non‐pathogenic isolates. The analysis of genetic distance data showed that the pathogenic isolates tended to group in one group and the non‐pathogenic in another. The genetic distance values of 30% among the pathogenic isolates in cluster A are compatible with the genetic distance values observed within the physiological races, but the distance values among the pathogenic isolates in clusters B and G are not compatible with the distance values observed within the race. Although our results are preliminary, it was not possible to exclude the existence of more than one race of this fungus in Brazil.     

Microsatellite analysis of genetic diversity among clinical and nonclinical Saccharomyces cerevisiae isolates suggests heterozygote advantage in clinical environments

The genetic structure of a global sample of 170 clinical and nonclinical Saccharomyces cerevisiae isolates was analysed using 12 microsatellite markers. High levels of genetic diversity were revealed both among the clinical and among the nonclinical S. cerevisiae isolates without significant differentiation between these two groups of isolates, rendering a single origin of pathogenic isolates unlikely. This suggests that S. cerevisiae is a true opportunistic pathogen, with a diversity of unrelated genetic backgrounds able to cause infections in humans, and that the ability of S. cerevisiae isolates to cause infections is likely due to a combination of their phenotypic plasticity and the immune system status of the exposed individuals. As was previously reported for bread, beer and wine strains and for environmental S. cerevisiae isolates, the microsatellite genotypes indicated ploidy level variation, from possibly haploid up to tetraploid, among clinical S. cerevisiae isolates. However, rather than haploid, sporulation proficiency and spore viability data indicated that most S. cerevisiae isolates that were mono-allelic at all examined microsatellite loci were likely homothallic and self-diploidized. Interestingly, the proportion of heterozygous clinical isolates was found to be significantly higher than the proportion of heterozygous nonclinical isolates, suggesting a selective advantage of heterozygous S. cerevisiae yeasts in clinical environments.     

The widespread occurrence of the enterohemolysin gene ehlyA among environmental strains of Escherichia coli

The putative virulence factor enterohemolysin, encoded by the ehlyA gene, has been closely associated with the pathogenic enterohemorrhagic Escherichia coli (EHEC) group. Escherichia coli isolates from effluents from seven geographically dispersed municipal wastewater treatment plants were screened for the presence of enterohemolysin. A total of 338 E. coli isolates were found to express the ehlyA gene. However, none of the isolates contained the toxin-encoding genes (stxA or stxB) associated with EHEC. Two of the 338 isolates possessed the virulence factor intimin, encoded by the eae gene. These findings suggest that the ehlyA gene may be widely distributed among non-EHEC isolates in the environment.     

Strain variation and geographic endemism in Streptococcus iniae

Twenty-six Israeli isolates of Streptococcus iniae from both marine and fresh/brackish water sources were compared with each other and with 9 foreign isolates. All the isolates were tentatively identified according to their biochemical profile. Direct sequencing of approximately 600 bp PCR products of the 16S rDNA confirmed their identification as S. iniae at the molecular level and revealed a new (one-nucleotide) variant among Israeli isolates, in addition to 2 variants that had been previously reported. Strain variation was further examined by subjecting the isolates to randomly amplified polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP) analyses. The RAPD method allowed separation of the isolates into only 2 groups, one including 5 Israeli fresh/brackish water isolates and one including all the other isolates. The AFLP method grouped the Israeli marine isolates into one homogeneous cluster, although they had been obtained in different years (1995 to 2001) from different species of fish, and from wild (Red Sea) as well as cultured (both Mediterranean and Red Sea) sources. The Israeli fresh/brackish water isolates and foreign isolates separated into distinct entities that clustered at generally high degrees of similarity. The distance between the clusters of the Israeli marine and fresh/brackish water isolates indicates that the S. iniae streptococcosis that has been afflicting the aquaculture industries in the 2 environments in recent years was caused by distinct strains. AFLP showed superior discriminative properties over RAPD in detecting intraspecific variation and proved to be an important tool for the characterization of S. iniae. A correlation between strain variation and geographic endemism was established.     

Genetic Relationship of Pyrenophora graminea, P. teres f. maculata and P. teres f. teres Assessed by RAPD Analysis

Barley‐pathogenic Pyrenophora isolates are P. graminea (PG), P. teres f. maculata (PTM) and P. teres f. teres (PTT), which cause foliar leaf stripe, spot blotch and net blotch lesions, respectively. However, the species are often indistinguishable by morphological and cultural characteristics. Random amplified polymorphic DNA (RAPD) analysis has been used to study the genetic relationship amongst 11 PG, 9 PTM and 23 PTT isolates from distant geographical locations. Using seven primers, 55 (52.38%) polymorphic DNA bands were detected out of 105 different fragments amplified in the three pathogens. Genotypic diversity was high as all but two PTT strains had distinct multilocus RAPD fingerprints. Unweighted pair‐group method with arithmetic average (UPGMA) clustering separated the isolates into three main clusters, corresponding to the three pathogens studied. No clear geographical substructuring was found. Nei's gene diversity analysis detected only small differences (max. 6.6%) in band frequencies but considerable levels of differentiation were observed among the pathogen species/forms. However, the variability among the Pyrenophora species/forms (max. 42.0%) was less than within species/forms (max. 58%). Nei's unbiased genetic distance values were in agreement with UPGMA clustering and gene diversity analysis: the two forms of P. teres showed higher divergence from one another (D = 0.132) than the distance found between PG and PTM (D = 0.094). The results suggest that the present taxonomical classification of these morphological taxa may not correspond to their phylogenetic relationship and that there is a very close genetic relationship amongst barley‐pathogenic Pyrenophora species, but genetic exchanges between them could be infrequent.     

Characterization of virulent gene locus in the genome of Fusarium spp. causing wilt disease of Psidium guajava L. in India

Wilt of Psidium guajava L., incited by Fusarium oxysporum f. sp. psidii and Fusarium solani is a serious soil borne disease of guava in India. Forty-two isolates, each of F. oxysporum f. sp. psidii (Fop) and F. solani (Fs), collected from different agro climatic zones of India showing pathogenicity were subjected to estimate their virulence factor in terms of analysis using virulent gene-related microsatellite loci. The erratic spread and occurrence of guava wilt in different areas may be due to variable aggressiveness or virulence of different pathogenic isolates in the soil. Out of 10 virulent gene locus related microsatellite markers ofFusarium spp., only six marker viz. Xyl, KHS1, PelA1, PG6/7, CHS1/2 and FMK1/MAPK1 were successfully amplified. This indicates that all the tested Fusarium sp. isolates of guava are having virulence gene in their genome. Microsatellite marker for virulence factor genes of Xyl loci was amplified in both Fop and Fs isolates. Product size of 281 bps was exactly amplified with a single banding pattern in all the isolates of Fop and Fs. It has been observed that other five microsatellite marker for virulence factor genes such as KHS1, PelA1, PG6/7, CHS1/2 and FMK1/MAPK1 were amplified with specific band pattern. PG6/7, CHS1/2 and FMK1/MAPK1 were only amplified in Fop isolates with a product size of 765 bps, 1566 bps; 1010 bps and 1244 bps. PelA1 and KHS1were amplified only in Fs isolates with the product size of 586 bps; 1359 bps, respectively. The results indicate that virulence factor genes are in response to produce wilt disease like symptoms in guava plants and also having pathogenic gene-related locus.     

Evaluation of DNA polymorphisms amplified by arbitrary primers (RAPD) as genetically associated elements to differentiate virulent and non-virulent Paracoccidioides brasiliensis isolates

Randomly amplified polymorphic DNA (RAPD) analysis of 35 Paracoccidioides brasiliensis isolates was carried out to evaluate the correlation of RAPD profiles with the virulence degree or the type of the clinical manifestations of human paracoccidioidomycosis. The dendrogram presented two main groups sharing 64% genetic similarity. Group A included two isolates from patients with chronic paracoccidioidomycosis; group B comprised the following isolates showing 65% similarity: two non-virulent, six attenuated, five virulent, eight from patients with chronic paracoccidioidomycosis and two from patients with acute paracoccidioidomycosis. The virulent Pb18 isolate and six attenuated or non-virulent samples derived from it were genetically indistinguishable (100% of similarity). Thus, in our study, RAPD patterns could not discriminate among 35 P. brasiliensis isolates according to their differences either in the degree of virulence or in the type of the clinical manifestation of this fungal infection.     

RAPD analysis of Yersinia enterocolitica

A total of 87 isolates of Yersinia enterocolitica were examined with randomly amplified polymorphic DNA (RAPD) by use of three different primers. Based on the RAPD profiles, the strains could be divided into three major groups: (1) the pathogenic American serotypes, O: 8, O: 13ab, O: 20 and O: 21; (2) the pathogenic European serotypes, O: 3, O: 5,27 and O: 9; and (3) the nonpathogenic serotypes. Five tested strains of the American serotype O: 4 gave unique profiles with YCPEL, but did not give reproducible profiles with the other primers. The European serotypes could be further subdivided into a group consisting of strains of O: 3 and O: 5,27 and a group of strains of O: 9. RAPD profiling provides an easy approachable method to divide isolates of Y. enterocolitica into pathogenic and nonpathogenic strains and further to differentiate between the pathogenic isolates.     

Phylogenetic analysis of Bacillus cereus isolates from severe systemic infections using multilocus sequence typing scheme

Bacillus cereus strains from cases of severe or lethal systemic infections, including respiratory symptoms cases, were analyzed using multilocus sequence typing scheme of B. cereus MLST database. The isolates were evenly distributed between the two main clades, and 60% of them had allele profiles new to the database. Half of the collection's strains clustered in a lineage neighboring Bacillus anthracis phylogenetic origin. Strains from lethal cases with respiratory symptoms were allocated in both main clades. This is the first report of strains causing respiratory symptoms to be identified as genetically distant from B. anthracis. The phylogenetic location of the presented here strains was compared with all previously submitted to the database isolates from systemic infections, and were found to appear in the same clusters where clinical isolates from other studies had been assigned. It seems that the pathogenic strains are forming clusters on the phylogenetic tree.