中国东北地区玉米纹枯病菌的融合群鉴定

自东北三省采集玉米纹枯病标本300余份,分离获得286个丝核菌菌株。融合群测定及5.8S rDNA-ITS区序列分析结果表明,这些菌株分别属于多核丝核菌的AG1-IA、AG1-IB、AG1-IC、AG4-HG-I、AG4-HG-III、AG-5、WAG-Z群及双核丝核菌的AG-Ba群。其中AG1-IA是优势致病群,占分离菌株总数的38.46%,其次是WAG-Z和AG-5群,分别占26.92%及24.83%。AG4-HG-III群菌株是国内首次从罹病玉米植株上分离得到。自各融合群中选取代表性的菌株进行5.8     

中国北方棉花主产区立枯丝核菌的融合群鉴定

从山东、河北、河南三省采集棉花立枯病样品和土壤200余份,经分离获得198个丝核菌Rhizoctonia solani分离物。菌丝融合测定及5.8S rDNA-ITS区序列分析结果表明,这些分离物分别属于多核丝核菌的AG4-HG-I和AG4-HG-III融合群以及双核丝核菌的AG-A、AG-F、AG-Fb融合群。其中AG4-HG-I是优势融合类群,占分离物总数的88.38%,其次是AG4-HG-III,占10.10%,AG-A、AG-F、AG-Fb各仅有1株。其中双核丝核菌AG-A、AG-F和AG-Fb融     

黄淮海地区夏玉米纹枯病菌的融合群鉴定

One hundred and seventy-six isolates were obtained from corn sheath blight samples in Huanghuai Plain and Haihe Plain (including Shandong, Henan, Hebei Provinces and Northern regions of Jiangsu Province) of China. Anastomosis group identification and 5.8S rDNA-internal transcribed spacer (ITS) sequence analysis showed that the isolates belonged to multinucleate Rhizoctonia AG1-IA, AG1-IB, AG4-HG-I, AG-5 and WAG-Z and binucleate Rhizoctonia AG-A and AG-Ba. Of these, AG-1-IA was the major anastomosis group(AG)（64.20% of total isolates), followed by AG-Ba (12.50%), WAG-Z (10.23%), AG1-IB (5.11%), AG4-HG-I (3.98%), AG-5 (2.27%) and AG-A (1.70%). AG-Ba was isolated for the first time from maize in China. 5.8S rDNA-ITS sequence analysis showed that the isolates could be distinctly separated based on their AG types. The isolates belonging to the same AG (or sub-AG) showed 97%-100% sequence identity.     

湖北省玉米纹枯病病原丝核菌的种类和致病性

从湖北省9个主要玉米产区采集玉米纹枯病标样,分离得到55个丝核菌菌株,融合群和致病性测定表明,这些分离菌分别属于AG1-IA、AG4、AG5、AGA、AGB(0)、AGE和WAG-Z等7个丝核菌融合群,其中AG1-IA是优势融合群,占分离菌株总数的61.82%,分布范围也最广。在致病性方面,除AGA不致病外,其它6群均致病,其中AG4致病力最强,AG1-IA次之,AG5最弱。研究同时表明,同一融合群内不同菌株致病性有差异,并且同一菌株对不同玉米自交系的致病力的强弱表现不完全一致。     

湖北省玉米纹枯病病原丝核菌的种类和致病性*

从湖北省9个主要玉米产区采集玉米纹枯病标样,分离得到55个丝核菌菌株。融合群和致病性测定表明,这些分离菌分别属于AG1—IA、AG4、AG5、AGA、AGB(0)、AGE和WAG-Z等7个丝核菌融合群,其中AG1-IA是优势融合群,占分离菌株总数的61.82%,分布范围也最广。在致病性方面,除AGA不致病外,其它6群均致病,其中AG4致病力最强,AG1-IA次之,AG5最弱。研究同时表明,同一融合群内不同菌株致病性有差异,并且同一菌株对不同玉米自交系的致病力的强弱表现不完全一致。     

山东省玉米纹枯菌融合群类型及遗传多样性

从山东省14个县市区采集的玉米纹枯病标本上分离获得103个玉米纹枯菌菌株。核荧光染色确定菌丝细胞核的数目,以及利用配对培养法确定不同菌株细胞是否融合。结果表明这些菌株分别属于多核丝核菌的AG-1-IA、AG-1-IB、AG-1-IC、AG-3、AG-4-HG-I、AG-5和WAG-Z融合群和双核丝核菌的AG-Ba融合群,其中AG-1-IA类型菌株数量占菌株总数的60.19%,为优势融合群。通过inter-simple sequence repeats（ISSR）标记技术进行菌株的遗传多样性分析,获得45个ISSR分子标记,其中91.1%的片段具有多态性,表明种群间存在丰富的遗传多样性。UPGMA聚类分析将103个菌株分成6个遗传聚类群,遗传聚类群的菌株组成说明遗传群组的划分与菌株的地理来源和菌株融合群类型均存在一定的相关性。     

中国北方马铃薯黑痣病立枯丝核菌的融合群鉴定

从山东、甘肃、青海、内蒙古、河北和黑龙江6省采集马铃薯黑痣病标本300余份,分离获得251个立枯丝核菌Rhizoctonia solani菌株。融合群测定结果表明,这些菌株分别属于多核的丝核菌AG‐3、AG1‐IB、AG4‐HG‐Ⅰ、AG4‐HG‐Ⅱ、AG4‐HG‐Ⅲ、AG‐5和AG‐11融合群。其中AG‐3是优势致病群,占分离菌株总数的71.31%;其次是AG4‐HG‐Ⅰ,占15.14%;AG‐11融合群菌株是国内首次从罹病马铃薯植株上分离得到。从各融合群中选取代表性的菌株进行5.8S rDNA‐ITS区序列分析,结果表明,隶属不同融合群或亚群菌株的5.8S rDNA‐ITS区序列存在较大的差异,而相同融合群(亚群)不同菌株的序列具有较高一致性。     

利用同功酶分析丝核菌菌丝融合1群lA亚群(Rhizoctonia solani AG1-lA)的遗传多样性

利用系统聚类分析方法,通过对丝核菌菌丝融合一群Rhizoctonia solani (AG-1)的23个菌株在七个同功酶电泳所显示的50个表现型进行了遗传分析。结果显示,23个丝核菌菌株可聚类为三大类,他们分别代表了丝核菌菌丝融合一群中的三个亚群AG-I A,AG-IB,AG—IC;其中第一聚类又可进一步分为四个亚类。同功酶的分析证实了丝核菌菌丝融合1群中的三个亚群的分类概念是具有遗传背景的,并可作为丝核菌菌丝融合群之间及群内分类的重要手段。     

新疆北疆棉田立枯丝核菌菌丝融合群及其营养亲和群研究

从新疆北疆棉区采集了典型的棉花立枯病病苗及棉田土标样686份,按常规分离方法分离得到399个分离物,从中鉴定出272个纯化的立枯丝核菌(Rhizotonia solaniKühn)菌株,经玻片吉姆萨氏染剂(Gimsa′sstain)染色程序观察细胞核数目,全部测试菌株均属于多核。用标准菌株,通过载玻片菌丝融合实验测定,将纯化的272个菌株划归为3个菌丝融合群:AG-2、AG-4和AG-5,分别占总菌株的6.24%、84.2%和1.1%。另有23个菌株不与任何标准菌株融合,占8.46%,说明新疆北疆棉田立枯丝核菌的优势菌系是多核丝核菌的AG-4融合群。通过从10种不同配方的培养基中筛选的效果好的麦芽蛋白胨(MPDA)配方培养基(Ⅱ)进行对峙培养,以建立标准菌株,将纯化获得的272个丝核菌菌株,划分为6个不同的营养亲和群,研究说明新疆北疆地区棉田立枯丝核菌各菌丝融合群内确有不同程度的分化。     

立枯丝核菌第一融合群的遗传分化*

利用12个随机引物对来自云南省不同地理环境的立枯丝核菌RhizoctoniasolaniKühn第一融合群(AG-1)的13个菌株进行遗传分化关系的研究。结果表明受试菌株被标记的DNA谱带多态性检测率为100%,即受试菌株间几乎无同质的DNA谱带。利用UPGMA法构建分子系统树分析发现,遗传距离0.5将其划分为9个遗传聚类组,遗传距离0.86将其划分为6个遗传聚类组,而遗传距离0.95可将其划分为3个遗传聚类组。结果表明受试AG1融合群的13个菌株具明显的遗传分化。     

Cropping Systems and Cultural Practices Determine the Rhizoctonia Anastomosis Groups Associated with Brassica spp. in Vietnam

Ninety seven Rhizoctonia isolates were collected from different Brassica species with typical Rhizoctonia symptoms in different provinces of Vietnam. The isolates were identified using staining of nuclei and sequencing of the rDNA-ITS barcoding gene. The majority of the isolates were multinucleate R. solani and four isolates were binucleate Rhizoctonia belonging to anastomosis groups (AGs) AG-A and a new subgroup of A-F that we introduce here as AG-Fc on the basis of differences in rDNA-ITS sequence. The most prevalent multinucleate AG was AG 1-IA (45.4% of isolates), followed by AG 1-ID (17.5%), AG 1-IB (13.4%), AG 4-HGI (12.4%), AG 2-2 (5.2%), AG 7 (1.0%) and an unknown AG related to AG 1-IA and AG 1-IE that we introduce here as AG 1-IG (1.0%) on the basis of differences in rDNA-ITS sequence. AG 1-IA and AG 1-ID have not been reported before on Brassica spp. Pathogenicity tests revealed that isolates from all AGs, except AG-A, induced symptoms on detached leaves of several cabbage species. In in vitro tests on white cabbage and Chinese cabbage, both hosts were severely infected by AG 1-IB, AG 2-2, AG 4-HGI, AG 1-IG and AG-Fc isolates, while under greenhouse conditions, only AG 4-HGI, AG 2-2 and AG-Fc isolates could cause severe disease symptoms. The occurrence of the different AGs seems to be correlated with the cropping systems and cultural practices in different sampling areas suggesting that agricultural practices determine the AGs associated with Brassica plants in Vietnam.     

Development of a specific PCR assay for the detection of Rhizoctonia solani AG 1-IB using SCAR primers

AIMS: The aim of this study was to develop a specific and sensitive identification method for Rhizoctonia solani AG 1-IB isolates based on phylogenetic relationships of R. solani AG-1 subgroups using rDNA-internal transcribed spacer (rDNA-ITS) sequence analysis. METHODS AND RESULTS: A neighbour-joining tree analysis of 40 rDNA-ITS sequences demonstrated that R. solani AG-1 isolates cluster separately in six subgroups IA, IB, IC, ID, IE and IF. A molecular marker was generated from a random amplified polymorphic DNA fragment (RAPD). After conversion into a sequence-characterized amplified region (SCAR), a specific primer set for identification of subgroup AG 1-IB was designed for use in a polymerase chain reaction (PCR). The primer pair amplified a single DNA product of 324 bp. CONCLUSIONS: R. solani AG-1 subgroups were discriminated by sequence analysis of the ITS region. The designed SCAR primer pair allowed an unequivocal and rapid detection of R. solani AG 1-IB in plant and soil samples. SIGNIFICANCE AND IMPACT OF THE STUDY: Sequence analysis of the rDNA-ITS region can be used for differentiation of subgroups within AG-1. The use of the developed SCAR primer set allowed a reliable and fast identification of R. solani AG 1-IB and provides a powerful tool for disease diagnosis.     

Trials of direct detection and identification of Rhizoctonia solani AG 1 and AG 2 subgroups using specifically primed PCR analysis

Specifically primed polymerase chain reaction (PCR) analysis was used for direct detection and identification of Rhizoctonia solani isolates belonging to AG 1 subgroups (IA, IB, and IC) and AG 2 subgroups (2-1 and 2-2). A rapid DNA extraction method with a solution of sodium hydroxide was conducted to extract PCR templates. PCRspecific primer sets for each group were designed from sequences in the regions of the 28S ribosomal DNA of this fungus. The results of specifically primed PCR analysis showed that AG 1-IA, AG 1-IB, AG 1-IC, AG 2-1, and AG 2-2 primers sets contributed detection from the same AG isolates and could escape detection from different AG isolates at a high level of frequency. In this experiment, we suggested that our synthesized primer sets might provide a method for the direct detection and identification of AGs of R. solani.     

Trials of direct detection and identification of <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> AG 1 and AG 2 subgroups using specifically primed PCR analysis

Specifically primed polymerase chain reaction (PCR) analysis was used for direct detection and identification of Rhizoctonia solani isolates belonging to AG 1 subgroups (IA, IB, and IC) and AG 2 subgroups (2-1 and 2-2). A rapid DNA extraction method with a solution of sodium hydroxide was conducted to extract PCR templates. PCR-specific primer sets for each group were designed from sequences in the regions of the 28S ribosomal DNA of this fungus. The results of specifically primed PCR analysis showed that AG 1-IA, AG 1-IB, AG 1-IC, AG 2-1, and AG 2-2 primers sets contributed detection from the same AG isolates and could escape detection from different AG isolates at a high level of frequency. In this experiment, we suggested that our synthesized primer sets might provide a method for the direct detection and identification of AGs of R. solani. Received: June 28, 2001 / Accepted: November 14, 2001     

Identification and pathogenicity of Rhizoctonia species isolated from bean and soybean plants in Samsun,Turkey

A total of 434 isolates of Rhizoctonia belonging to 10 anastomosis groups were obtained from the roots and rhizosphere soils of bean and soybean plants grown in Samsun, Turkey. AG-4 was found to be the most common group on bean and soybean plants and AG-5, AG-6, binucleate AG-A, AG-B and R. zeae were other groups isolated from the both plant species. AG-1, AG-7 and AG-K from bean and AG-E from soybean were other groups obtained in the study. The pathogenicity tests on bean and soybean seedlings showed that the highest disease severities were caused by AG-4 isolates, whereas AG-1 and AG-6 isolates were moderately pathogenic. Binucleate Rhizoctonia AG-B isolates were also moderately pathogenic, while other binucleate Rhizoctonia were found to be weakly pathogenic. Rhizoctonia zeae isolates caused moderate disease symptoms on bean, but soybean plants were slightly affected by this group of isolates. This is the first reported observation of R. solani AG-6 and AG-7 and binucleate Rhizoctonia AG-B on bean, and R. solani AG-5 and AG-6 and binucleate Rhizoctonia AG-A, AG-B and AG-E on soybean, in Turkey.