北方棉区棉花黄萎病菌落叶型菌系鉴定

 采用RAPD扩增与温室致病性测定2种方法,以黄萎病菌Verticillium dahliae的5个落叶型、7个非落叶型菌系和V.albo-atrum的2个菌系为对照,对采自北方棉区6省(自治区)的34个棉花黄萎病菌菌系进行致病型鉴定。94.1%的菌系在2种鉴定结果中表现一致,与对照菌系相比较,确定其中26个菌系为落叶型菌系,6个菌系为非落叶型菌系。从而证实了黄萎病菌落叶型菌系在北方棉区河北、河南、山东3省的存在,并发现所确定的26个北方落叶型菌系中的22个与来自美国的对照落叶型菌系T₉、V₄₄的关系比与来自江苏的对照落叶型菌系V_B、V₉₉₁的关系更近。本实验还初步筛选到2条用于鉴别V.dahliae落叶型与非落叶型菌系的RAPD特异条带OPB-19₉₆₆和OPM-20₁₆₉₁,将它们用于对34个北方菌系的RAPD扩增鉴定,则与温室致病性测定结果的一致性分别为88.2%和94.1%,证明这2条特异条带在鉴定棉花黄萎病菌落叶型菌系上具有一定的实用价值,并为进一步制作特异探针以形成一套简便、准确、规范化的鉴定技术奠定了基础。     

新疆棉花黄萎病的发生现状及其病原菌的分子鉴定与ISSR分析

为掌握新疆主要植棉区棉花黄萎病的发生现状及其病原菌大丽轮枝菌Verticillium dahliae的落叶型菌系分布以及遗传变异情况,于2015年对26个新疆主要植棉区棉花黄萎病的发生情况进行了随机调查,统计新疆大丽轮枝菌的培养性状,利用大丽轮枝菌落叶型特异引物D1/D2、INTD2F/INTD2R与非落叶型特异性引物ND1/ND2、INTNDF/INTNDR对新疆大丽轮枝菌菌系进行互补鉴定,并对部分菌系的遗传变异进行简单序列重复区间(inter simple sequence repeat,ISSR)分析。结果表明:2015年新疆棉花黄萎病发病田比例为54.0%,其中病情指数在10.0以上的发病田与2013年持平,而病情指数在20.0以上的严重发病田比例为10.8%,比2013年增加3.8个百分点;新疆大丽轮枝菌的培养性状以菌核型为主,比例为70.1%,菌丝型与中间型比例分别为13.4%和16.5%;新疆大丽轮枝菌落叶型菌系比例为53.2%,26株菌株的来源地全部检出落叶型菌系;聚类分析结果显示,当遗传相似系数为0.66时,新疆大丽轮枝菌落叶型与非落叶型菌系聚为2个谱系,菌系地理来源、培养性状与大丽轮枝菌的遗传分化无明显相关性。     

Development of a robust,VdNEP gene-based molecular marker to differentiate between pathotypes of Verticillium dahliae

Verticillium dahliae is a soilborne fungus that causes Verticillium wilt disease in a plethora of crops. Based on symptoms that develop on cotton, olive and okra, V. dahliae isolates are categorized into two pathotypes, namely defoliating and nondefoliating, with the former showing increased virulence and causing severe defoliation. Reliable differentiation between V. dahliae pathotypes is crucial for the management of Verticillium wilt in cotton and olive. In the present study, a polymorphism was detected among isolates of defoliating and nondefoliating pathotypes in Southern blots using the VdNEP gene as a probe. The regions flanking this gene were isolated by inverse PCR and sequence differences in the 3′ untranslated region (3′-UTR) of the VdNEP gene were detected between the two pathotypes. Based on these sequences, primers were designed and assessed to develop a multiplex PCR detection assay. Using this assay, a collection of cotton and olive V. dahliae isolates from Greece and Cyprus was screened, revealing that the defoliating pathotype is present in several regional units of Greece. Thus, this work presents a new, sensitive molecular marker for the differentiation between V. dahliae pathotypes based on the VdNEP gene. Because the 3′-UTR is involved in the phenotypes displayed by the pathotypes, an expression experiment was conducted under conditions simulating the xylem of a host plant. Expression of the VdNEP gene was elevated at all time points in the defoliating compared to the nondefoliating strain, suggesting a possible involvement of VdNEP expression in the defoliation process.     

Region-wide analysis of genetic diversity in Verticillium dahliae populations infecting olive in southern Spain and agricultural factors influencing the distribution and prevalence of vegetative compatibility groups and pathotypes

Severity of Verticillium wilt in olive trees in Andalusia, southern Spain is associated with the spread of a highly virulent, defoliating (D) Verticillium dahliae pathotype of vegetative compatibility group 1A (VCG1A) but the extent of this spread and the diversity of the pathogen population have never been documented. VCG typing of 637 V. dahliae isolates from 433 trees in 65 orchards from five olive-growing provinces in Andalusia indicated that 78.1% were of VCG1A, 19.8% of VCG2A, 0.6% of VCG2B, 1.4% of VCG4B, and one isolate was heterokaryon self-incompatible. A single VCG prevailed among isolates within most orchards but two and three VCGs were identified in 12 and 3 orchards, respectively, with VCG1A+VCG2A occurring in 10 orchards. VCG1A was the predominant VCG in the three most important olive-growing provinces, and was almost as prevalent as VCG2A in another one. Molecular pathotyping of the 637 isolates using specific polymerase chain reaction assays indicated that VCG1A isolates were of the D pathotype whereas isolates of VCG2A, -2B, and -4B were of the less virulent nondefoliating (ND) pathotype. The pathotype of isolates correlated with the disease syndrome affecting sampled trees. Only three (seq1, seq2, and seq4) of the seven known sequences of the V. dahliae-specific 539- or 523-bp amplicon were identified among the 637 isolates. Distribution and prevalence of VCGs and seq sequences among orchards indicated that genetic diversity within olive V. dahliae in Andalusia is higher in provinces where VCG1A is not prevalent. Log-linear analysis revealed that irrigation management, source of irrigation water, source of planting stock, and cropping history of soil were significantly associated with the prevalence of VCG1A compared with that of VCG2A. Multivariate analyses using a selected set of agricultural factors as variables allowed development of a discriminant model for predicting the occurrence of D and ND pathotypes in the area of the study. Blind tests using this model correctly indentified the V. dahliae pathotype occurring in an orchard. The widespread occurrence and high prevalence of VCG1A/D pathotype in Andalusia have strong implications for the management of the disease.     

应用聚合酶链式反应鉴定新疆棉花落叶型黄萎病菌

用一对棉花落叶型黄萎病菌的特异性引物D1和D2进行PCR扩增,对于落叶型黄萎病菌,该对引物可特异性地扩增产生一段550bp的产物,而非落叶型黄萎病菌则不能被扩增.供试的35个新疆黄萎菌系中,有3个菌系扩增出550bp大小的落叶型黄萎病菌特异性片段,表明目前新疆已存在落叶型黄萎病菌,用此技术可快速、准确地检疫和鉴定落叶型黄萎病菌.     

Hyaline mutants from Verticillium dahliae, an example of selection and characterization of strains for host–parasite interaction studies

The objective of the present work was to select stable well-characterized strains of Verticillium dahliae that could be used as biological tools in genetic and plant–microbe interaction studies. Hyaline mutants, known for their stability in pathogenicity were chosen for the study. Diversity in pathogenicity was found among hyaline subclones obtained from a defoliating wild-type clone, but not within those from nondefoliating ones. Most subclones from the defoliating clone had parental pathotypes, but one (V7-2) exhibited weak pathogenicity. This subclone (V7-2), together with a highly virulent one (V7-7) deriving from the same defoliating parent clone (7), were selected for further characterization, because of their differences in pathogenicity. When studied on the basis of their growth requirements, the two subclones expressed marked differences. V7-7 grew better than V7-2 over a wider range of temperature conditions. Both subclones grew similarly in media supplemented with NH₄ as nitrogen source, but in those with NO₃, V7-7 grew more vigorously than V7-2 and only the former could grow when NO₂ was used. In spite of these differences, the two subclones were found to belong to the same vegetative compatibility group, confirming their genetic proximity. These results highlight the physiological and genetic complexity inherent in V. dahliae . In view of their characteristics, the clones obtained in this study should prove to be valuable tools in furthering the understanding of genetic and host– V. dahliae interactions.     

棉花黄萎病菌致病型的AFLP分析

 选用41个棉花黄萎病菌(Verticillium dahliae)代表菌系,在温室条件下,对4个棉花品种鄂荆1号(感)、中棉所12(耐)、文-5(抗)和唐棉2号(抗)进行致病性测定,结果可将供试菌系分为落叶型与非落叶型2类。选取8对AFLP引物PCR扩增的结果中,统计带型稳定、清晰且有多态性的条带,共169条作系统聚类分析,将上述菌系分为2大类,第一类为非落叶型菌系,包括10个非落叶型菌系和1个过渡菌系;第二类为30个落叶型菌系。根据聚类分析建立树状图,发现菌系与地理来源存在一定的相关性,而依据菌系致病力强弱分类则相关关系不大。选用25对EcoRⅠ和MseⅠ引物组合,对供试的41个V.dahliae进行AFLP扩增,筛选到2对引物E64(GACTGCGTACCAATTCGAC)、M53(GATGAGTCCTGAGTAACCG)和E49(GACTGCGTACCAATTCCAG)、M65(GAT-GAGTCCTGAGTAAGAG),能分别扩增出433bp和110bp2条仅为V.dahliae非落叶型菌系独有的特异片段,可将落叶型与非落叶型菌系分开,这2条特异片段被命名为EM₄₃₃和EM₁₁₀。     

Spatiotemporal analysis of spread of infections by Verticillium dahliae pathotypes within a high tree density olive orchard in southern Spain

The development of Verticillium wilt epidemics in olive cv. Arbequina was studied from November 1999 to May 2003 in a drip-irrigated, nontillage orchard established in a soil without a history of the disease at Córdoba, southern Spain. Disease incidence measured at 1-month-intervals increased from 0.2 to 7.8% during this period. Verticillium dahliae infecting the trees was characterized as defoliating (D) or nondefoliating (ND) pathotypes by a specific, multiplex-polymerase chain reaction (PCR) assay. Of the symptomatic trees, 87.2 and 12.8% were infected by the D or ND pathotypes, respectively. Dynamics of disease incidence were described by a generalized logistic model with a multiple sigmoid pattern. In the fitted model, the infection rate was highest in the winter to spring period and decreased to minimum values in the summer to fall period. Binary data of disease incidence was analyzed for point pattern and spatial correlation, either directly or after parsing them in contiguous quadrats. Overall, ordinary runs analysis indicated a departure from randomness of disease within rows. The binomial index of dispersion, interclass correlation, and Taylor's power law for various quadrat sizes suggested aggregation of diseased trees within the quadrat sizes tested. Spatial analysis by distance indices showed a nonrandom arrangement of quadrats containing infected trees. Spatial pattern was characterized by the occurrence of several clusters of infected trees. Increasing clustering over time was generally suggested by stronger values of clustering index over time and by the increase in the size of patch clusters. Significant spatial association was found in the clustering of diseased trees over time across cropping seasons; however, clustering was significant only for infections by D V. dahliae, indicating that infections by the D pathotype were aggregated around initial infections. The number and size of clusters of D V. dahliae-infected trees increased over time. Microsatellite-primed PCR assays of a representative number of V. dahliae isolates from diseased trees indicated that the majority of infecting D isolates shared the fingerprinting profile with D V. dahliae isolated from soil of a naturally infested cotton field in close proximity to the orchard, suggesting that short distance dispersal of the pathogen from this soil to the olive orchard may have occurred.     

Gene genealogies support Fusarium oxysporum f. sp. ciceris as a monophyletic group

Fusarium oxysporum f. sp. ciceris (Foc), the causal agent of fusarium wilt of chickpea, consists of two pathotypes (yellowing and wilting) and eight races (races 0, 1B/C, 1A and 2–6) of diverse geographical distribution. Six Foc isolates, one each of races 0, 1B/C, 1A, 4, 5 and 6, representing the two pathotypes and the geographical range of the pathogen, showed identical sequences in introns of the genes for translation elongation factor 1α ( EF1 α), β-tubulin, histone 3, actin and calmodulin. Eleven additional Foc isolates representative of all races, pathotypes and geographical range, and three isolates of F. oxysporum (Fo) nonpathogenic to chickpea were further analysed for sequence variation in the EF1 α gene. All isolates pathogenic to chickpeas shared an identical EF1 α gene sequence, which differed from that shared by the three Fo isolates nonpathogenic to chickpea. EF1 α gene sequences from the 17 Foc isolates and the three Fo isolates were compared with 24 EF1 α gene sequences in GenBank from isolates of 11 formae speciales of F. oxysporum by parsimony analysis. Foc isolates formed a grouping distinct from other formae speciales and nonpathogenic isolates. These results indicate that F. oxysporum f. sp. ciceris is monophyletic.     

The influence of verticillium wilt epidemics on cotton yield in southern Spain

Experiments were conducted in the Guadalquivir Valley of Andalucía, southern Spain, in 1986 and 1987, using field plots naturally infested with different inoculum densities of the defoliating and nondefoliating pathotypes of Verticillium dahliae to determine the influence of verticillium wilt epidemics on yield of cotton cultivar Coker 310. The total number of bolls, the number of open bolls, and seed cotton yield were related to the growth stage of plants at first appearance of foliar symptoms, and to inoculum density and virulence of the V. dahliae pathotype prevailing in the soil. For the three yield components, the greatest reduction was observed in plants showing symptoms before opening of first flowers (about 650 degree-days after sowing). Yield increased with delay in the development of foliar symptoms during the crop season, and the effect of the wilt epidemics on yield was small or nil for plants that developed symptoms after opening of the first bolls (1400–1500 degree-days after sowing). A multiple regression equation was derived that related yield reduction to the physiological time accumulated from the time of sowing until the appearance of foliar symptoms and to the rate of disease intensity increase over physiological time. This multiple point model explained about 70% of the variation in cotton yield loss due to verticillium wilt.     

Effect of temperature on conidial germination, mycelial growth and aggressiveness of the defoliating and nondefoliating pathotypes of Verticillium dahliae from cotton in China

Three defoliating (D) pathotype isolates and five nondefoliating (ND) pathotype isolates of Verticillium dahliae from cotton in central China were tested for adaptation to various temperatures in conidial germination on water agar (10?C33°C), mycelial growth on potato dextrose agar (10?C33°C) and infection of cotton seedlings (Gossypium hirsutum cvs. ??E Mian 24?? and ??Yin Rui 361??) (25?C33°C). Results showed that the D-pathotype isolates adapted better than the ND-pathotype isolates to 30°C for conidial germination and mycelial growth, although the isolates of the two pathotypes had the same optimum temperature of 25°C. Under day/night temperatures of 25/25, 27/27 and 30/25°C for 20 and 25?days, the D-pathotype isolates induced the defoliation syndrome on seedlings of the two upland cotton cultivars, whereas the ND-pathotype isolates did not induce defoliation syndrome. The values for the areas under the disease progress curve (AUDPC) and the vascular discoloration index (VDI) were higher for the D-pathotype isolates than those for the ND-pathotype isolates in each temperature treatment. Under 30/30 or 33/27°C, at least two of the three D-pathotype isolates still had higher AUDPC values and/or VDI values than all the ND-pathotype isolates on E Mian 24. Therefore, the D-pathotype isolates appear more aggressive than the ND-pathotype isolates in infection of cotton. Results also showed that the cotton cultivar Yin Rui 361 was more tolerant than the cotton cultivar E Mian 24 to infection by both pathotypes of V. dahliae. This study suggests that the D-pathotype isolates can well adapt to high temperature and heavily infect cotton under 25?C30°C, and these features might be responsible for the rapid spread of this pathotype in central China.     

土壤中棉花黄萎病菌快速检测技术研究

 Verticillium wilt,caused by Verticillium dahliae,is the most important disease of cotton.In this work,the previously developed defoliating(D) and nondefoliating(ND) V.dahliae-specific primers were adopted for detection of pathotypes of V.dahliae in soil by using nested PCR.The results showed that the detection assay was efficient when used in infested soil and was an useful technique for rapid and accurate assessment of soil contamination by V.dahliae.     

Specific Detection of Tomato Pathotype of Verticillium dahliae by PCR Assays

Verticillium dahliae Klebahn is the causal agent of tomato wilt disease. Isolates of V. dahliae can be classified based on pathogenicity to tomato, but the pathotypes are indistinguishable in morphology. We designed PCR primers for specific detection of isolates pathogenic to tomato (tomato pathotype) from the sequences of a pathotype-specific gene, vdt1. With the primer pair Tg5/Tc3, a PCR product (approximately 3.2 kb) specific to tomato pathotype was amplified from the genomic DNA of isolates. Using the primer pair, a tomato pathotype isolate was specifically detected from hypocotyls of inoculated tomato and eggplant. On the other hand, no amplification was observed from non-tomato pathotype isolates of V. dahliae, some other wilt pathogens of tomato and a healthy host plant. Therefore, the primer pair can be useful for pathotype-specific detection of V. dahliae as well as for diagnosis of wilt disease of tomato plant. Received 7 September 2001/ Accepted in revised form 3 December 2001     

Differentiation of Cotton-defoliating and Nondefoliating Pathotypes of Verticillium dahliae by RAPD and Specific PCR Analyses

Severe Verticillium wilt of cotton in southern Spain is associated with the spread of a highly virulent, defoliating (D) pathotype of Verticillium dahliae. Eleven of the D and 15 of a mildly virulent, nondefoliating (ND) pathotype were analyzed by random amplified polymorphic DNA (RAPD) using the polymerase chain reaction (PCR). Six of 21 primers tested generated pathotype-associated RAPD bands. Another 21 V. dahliae isolates were compared in blind trials both by RAPD-PCR using the six selected primers and pathogenicity tests on cotton cultivars. There was a 100% correlation between pathotype characterization by each method. Unweighted paired group method with arithmetic averages cluster analysis was used to divide the 47 V. dahliae isolates into two clusters that correlated with the D or ND pathotypes. There was more diversity among ND isolates than among D isolates, these latter isolates being almost identical. ND- and D-associated RAPD bands of 2.0 and 1.0kb, respectively, were cloned, sequenced, and used to design specific primers for the D and ND pathotypes. These pathotype-associated RAPD bands were present only in the genome of the pathotype from which they were amplified, as shown by Southern hybridization. The specific primers amplified only one DNA band of the expected size, and in the correct pathotype, when used for PCR with high annealing temperature. These specific primers successfully characterized V. dahliae cotton isolates from China and California as to D or ND pathotypes, thus demonstrating the validity and wide applicability of the results.     

Genetic and Virulence Diversity in Verticillium dahliae Populations Infecting Artichoke in Eastern-Central Spain

ABSTRACT Severe Verticillium dahliae attacks have occurred in artichoke crops in the Comunidad Valenciana region of eastern-central Spain since the late 1990s. Knowledge of genetic and virulence diversity in the pathogen population is a key factor for the management of the disease through disease risk assessment as well as development and use of resistant cultivars. V. dahliae isolates from artichoke (109 isolates) and cotton (three isolates) in that region were characterized by vegetative compatibility grouping (VCG), and specific polymerase chain reaction assays using three sets of primer pairs that differentiate the cotton-defoliating (D) and -nondefoliating (ND) V. dahliae pathotypes. In all, 35 and 39 V. dahliae isolates representative of the identified VCGs and geographic origins were tested for virulence to artichoke cvs. Nun 6374 and Nun 9444, and cotton cv. Acala SJ-2, respectively. Four VCGs were identified among 107 artichoke isolates, and 2 isolates were heterokaryon self-incompatible: VCG1A (one isolate), VCG2A (31 isolates), VCG2B (72 isolates), and VCG4B (three isolates). The three cotton isolates were VCG1A. Isolates in VCG2B were distributed across the region and were the most prevalent isolates in the northern part. Conversely, 83.9% of isolates in VCG2A were recovered from the southern part of the region. Two subgroups of isolates were identified in VCG2B based on heterokaryon compatibility with either international or local tester isolates, which further showed diversity in the amplification of 334- and 824-bp DNA fragments which are markers of the D and ND pathotypes, respectively. Virulence of isolates to artichoke and cotton correlated with VCG but the pattern of correlation varied with the host. VCG1A isolates from artichoke and cotton induced defoliation in cotton but not in artichoke. Collectively, isolates of VCG2B and VCG4B were the most virulent and isolates of VCG1A or HSI were the least virulent to artichoke; but isolates of VCG1A were more virulent to cotton than those of any other VCG. Also, molecular subgrouping in VCG2B determined by amplification of the 334- and 824-bp markers correlated with virulence of isolates to the two hosts tested.     

Verticillium wilt of olive in Turkey: a survey on disease importance,pathogen diversity and susceptibility of relevant olive cultivars

A comprehensive survey on the prevalence and incidence of Verticillium wilt of olive in Turkey has been conducted over 6 years (2003–2008). Vegetative compatibility group (VCG) assessment and PCR-based molecular pathotyping were used to evaluate the distribution of the defoliating (D) and nondefoliating (ND) pathotypes of Verticillium dahliae in surveyed areas. Pathogen prevalence was 35% of all olive orchards inspected and incidence of the disease reached 3.1%. VCG1A was predominant (29.3%) and infected all major cultivars grown in Turkey. The other two VCGs detected (2A and 4B) were of minor relevance (4.9% and 0.9%, respectively). Disease incidence caused by VCG1A infections was higher (ranging from 1.1% to 6.9%) than that caused by VCG2A and VCG4B in 10 provinces (Manisa, Aydin, Kahramanmaras, Izmir, Mugla, Kilis, Denizli, Gaziantep, Mardin and Balikesir). However, VCG2A and 4B were more prevalent (and responsible for higher disease incidence) than VCG1A in three provinces (Hatay, Osmaniye and Bursa). Finally, VCG1A isolates were found in all provinces except Canakkale, and simultaneous presence of the three VCGs was only verified in Hatay province. An artificial inoculation bioassay (19 representative V. dahliae isolates included) revealed that VCG1A (13) isolates as a group were more aggressive and caused defoliation, whereas VCG2A (5) and VCG4B (1) isolates induced milder symptoms. Within a VCG group, virulence varied among isolates infecting the same olive cultivar and this virulence was also related to the differential susceptibility of the cultivars (‘Manzanilla’, ‘Ayvalik’ and ‘Gemlik’) tested. Molecular pathotyping allowed the identification of D (VCG1A) and ND (VCG2A/4B) pathotypes, which correlated with results from pathogenicity tests. Remarkably, the V. dahliae VCG1A/D pathotype population infecting olive in Turkey was molecularly different from that one previously identified in Spain.     

Vegetative Compatibility Groupings of Verticillium dahliae from Cotton in Mainland China

One hundred and fourteen isolates of Verticillium dahliae obtained from cotton and eggplant in mainland China were successfully assigned to two vegetative compatibility groups (VCGs) except for one self-incompatible isolate. Eleven isolates were strongly compatible with T9, the tester strain of the cotton defoliating pathotype, forming a linear growth of wild type with abundant microsclerotia and dense mycelia between compatible nitrate-nonutilizing mutants. The remaining 102 isolates were grouped into the non-defoliating VCG2, although the strength of the reaction varied; some isolates were strongly compatible with the tester strain while others were only slightly compatible. All VCG1 isolates including T9 showed the same defoliating symptom in greenhouse inoculation tests. This study confirmed the presence of the defoliating pathotype (VCG1) of V. dahliae in mainland China.     

PIRA-PCR for detection of Fusarium graminearum genotypes with moderate resistance to carbendazim

PIRA-PCR ( p rimer- i ntroduced r estriction a nalysis PCR) was developed to detect isolates of Fusarium graminearum with moderate resistance to carbendazim, a methyl benzimidazole carbamate (MBC)-group fungicide. Two primer pairs were designed and synthesized according to the nucleotide sequence of the β ₂-tubulin gene from F. graminearum. Fragments of 164 bp were amplified by nested PCR from isolates differing in carbendazim sensitivity. A Hin dIII restriction enzyme recognition site was introduced artificially by inner primers to detect a mutation at codon 167, and Taa I ( Tsp 4CI) restriction enzyme was used to detect a mutation at codon 200. The sensitivity of isolates to carbendazim was determined by analyzing electrophoresis patterns of the resulting PCR products after simultaneous digestion with both Hin dIII and Taa I. Results from PIRA-PCR and a conventional method (mycelial growth on agar) were identical but PIRA-PCR required only 7–8 h while the conventional method required 5–7 days. This study demonstrates that PIRA-PCR not only monitors the appearance of moderately resistant isolates, but can be useful for detecting genotypes of F. graminearum with moderate resistance to carbendazim.     

Vegetative Compatibility Groups of Verticillium dahliae in Israel: Their Distribution and Association with Pathogenicity

A collection of 565 isolates of Verticillium dahliae, recovered between 1992 and 1997 from 13 host plant species and soil at 47 sites in Israel, was tested for vegetative compatibility using nitrate-nonutilizing (nit) mutants. Three vegetative compatibility groups (VCGs) were found and identified as VCG2A (28 isolates), VCG2B (158 isolates), and VCG4B (378 isolates) by using international reference strains. One isolate was heterokaryon self-incompatible. Of the VCG2B isolates, 92% were recovered from the northern part of Israel and 90% of VCG4B isolates were recovered from the south, with some overlap in the central region. Isolates of the minor group VCG2A were geographically scattered among the two major VCGs. Isolates of the same VCG resembled one another more than isolates from different VCGs based on colony and microsclerotial morphology, temperature responses, and, partially, pathogenicity. Different pathotypes were defined among 60 isolates tested, using cotton (cv. Acala SJ-2) and eggplant (cv. Black Beauty) as differentials. All isolates in VCG2A and 86% of the isolates in VCG4B, irrespective of their origin, induced weak to moderate symptoms on cotton and moderate to severe symptoms on eggplant and were similar to the previously described cotton nondefoliating patho-type. In contrast, all cotton isolates in VCG2B caused severe foliar symptoms, stunting, and often death, but little or no defoliation of inoculated cotton plants. These were defined as a cotton defoliating-like pathotype and induced only weak to moderate symptoms on eggplant. We concluded that vegetative compatibility grouping of V. dahliae in Israel is closely associated with specific pathogenicity and other phenotypic traits.     

Characterization of Verticillium dahliae Isolates from Potato on Hokkaido by Random Amplified Polymorphic DNA (RAPD) and REP-PCR Analyses

Verticillium dahliae isolates from potato on the island of Hokkaido (potato isolates) and those belonging to pathotypes A (eggplant pathotype), B (tomato pathotype) and C (sweet pepper pathotype) were divided into three distinct groups by RAPD and REP-PCR. The three DNA groups I, II, III consisted of pathotypes A and C, pathotype B and potato isolates, respectively. The potato isolates were assigned to pathotype A on the basis of pathogenicity. Another set of potato isolates was further collected from eight potato cropping regions on Hokkaido to further examine the relationships among them in detail. Only one of these isolates was identified as DNA group II, but all the others were classified as DNA group III. Isolates from daikon, eggplant, and melon on Hokkaido also belonged to DNA group III. These results suggest that V. dahliae isolates from Hokkaido are unique at the DNA level and different from other pathotype A isolates in Japan. Received 28 February 2000/ Accepted in revised form 6 November 2000