RFLP analysis of the PCR-amplified 28S rDNA inRhizoctonia solani

RFLP analyses of a portion of the 28S rDNA gene region were conducted by using four restriction endonucleases for 57 isolates of 13 intraspecific groups (ISGs) representing 7 anastomosis groups (AGs) ofRhizoctonia solani. Variations in the PCR-amplified rDNA products and the polymorphisms on digestion with restriction enzymes (BamHI,HaeIII,HhaI andHpaII) were observed among three AGs, AG 1, 2 and 4. These differences were also conserved among some ISGs of AG 1 and AG 2. Among ISGs of AG 1, the pattern of rDNA fragments of AG 1-IA obtained by digestion withHpaII was significantly different from those of AG 1-IB and IC. Such difference in the fragment pattern was also observed among AG 2-1, 2-2 IIIB and 2-2 IV by the digestion withHhaI andHpaII. A dendrogram derived from the restriction enzyme data showed that ISGs from AG 1 and AG 2 can each be subdivided into distinct groups, those are distantly related to the majority isolates of the other AGs.     

Analysis of whole cellular fatty acids and anastomosis relationships of binucleate Rhizoctonia spp. associated with Ceratobasidium cornigerum

Previous research has demonstrated that whole cellular fatty acids analysis is a useful tool for identifying and establishing taxonomic relationships between anastomosis groups (AGs) and related Rhizoctonia isolates. In this experiment, the composition of fatty acid of 28 isolates of teleomorph genus Ceratobasidium cornigerum, consisting of binucleate Rhizoctonia, AG-A, AG-B(o), AG-C, AG-P, and AG-Q, was evaluated using gas chromatography. Eleven fatty acids identified, i.e., myristic, pentadecanoic, palmitic, 2-hydroxypalmitic, palmitoleic, heptadecanoic, 9-heptadecenoic, stearic, oleic, linoleic, and linolenic acids, were present in isolates of AG-A, AG-B(o), AG-C, AG-P, and AG-Q. The major fatty acids, palmitic, oleic, and linoleic acids, were common in all isolates, constituting 87.1% to 94.7% of the whole cellular fatty acids identified. Isolates within the same AG were closely clustered, whereas isolates from different AGs were clearly and distinctly clustered based on average linkage cluster analysis of whole cellular fatty acids. Principal-component analysis generated from all fatty acids also confirmed the divergent separation of the 5 AGs of binucleate Rhizoctonia.     

Development of specific PCR primers for the detection of Rhizoctonia solani AG 2-2 LP from the leaf sheaths exhibiting large-patch symptom on zoysia grass

Detection of Rhizoctonia solani AG 2-2 LP isolates causing large-patch disease on zoysia grass was done using polymerase chain reaction (PCR). Specific primers were designed based on an amplified region using random amplified polymorphic DNA (RAPD)-PCR. Fifteen primers and three cultural types of R. solani AG 2-2 (types IIIB, IV and LP) were used for RAPD-PCR. The banding patterns by RAPD-PCR showed that the three cultural types were clearly distinguishable. A dendrogram constructed from the results of RAPD-PCR showed that the three cultural types of AG 2-2 clustered separately. The sequence of one PCR-amplified region which appeared only in LP isolates using primer A09 was selected for designing specific primers. Primer pair A091-F/R gave a single product from pure fungal DNA of LP isolates but not from those of the other two types (IIIB and IV), R. solani AG 1, 2-1, 2-3, 2-tulip, 3-10 and BI isolates and other turfgrass fungal pathogens. Primer pair A091-F/R also gave a single product from diseased leaf sheaths and this product was in accordance with those of pure fungal DNA of LP isolates. Primer pair A091-F/R did not yield PCR product from healthy leaf sheaths. The frequencies of detection of LP isolates from leaf sheaths of zoysia grass using PCR with primer pair A091-F/R were higher than those of the conventional isolation technique. These results showed that the PCR-based technique using specific primers A091-F/R is useful for the rapid detection of LP isolates from leaf sheaths of zoysia grass exhibiting large-patch symptoms.     

Genetic Diversity Among Iranian Isolates of Rhizoctonia solani Kühn Anastomosis Group1 Subgroups Based on Isozyme Analysis and Total Soluble Protein Pattern

Rhizoctonia solani is a destructive fungal pathogen with a wide host range. The R. solani complex species includes several divergent groups delimited by affinities for hyphal anastomosis. In this study, genetic variation among 20 isolates of R. solani anastomosis group 1 (AG1) subgroups (AG1‐IA and AG1‐IB) collected from Mâzandaran province, Iran, and standard isolates of these subgroups, was determined by isozyme analysis and total soluble protein profile. Mycelial protein pattern and isozyme analysis were studied using denaturing and non‐denaturing polyacrylamide gel electrophoresis, respectively. A total of 15 enzyme systems were tested, among which six enzymes including esterase, alkaline phosphatase, superoxide dismutase, octanol dehydrogenase, lactate dehydrogenase and mannitol dehydrogenase generated distinct and reproducible results. The soluble protein patterns were similar among the R. solani isolates examined; however, minor differences in banding pattern were observed between the two subgroups. In isozyme analysis, a total of 64 electrophoretic phenotypes were detected for all six enzymes used. Based on cluster analysis and similarity matrix, the fungal isolates were divided into two genetically distinct groups of I and II consistent with the previously reported AG1‐IA and AG1‐IB subgroups in AG1. Group I represented all isolates belonging to AG1‐IA subgroup, whereas group II represented all isolates belonging to AG1‐IB subgroup. Results from isozyme analysis suggest that the subgrouping concept within AGs is genetically based.     

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     

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.     

Rapid detection ofRhizoctonia species, causal agents of rice sheath diseases, by PCR-RFLP analysis using an alkaline DNA extraction method

Restriction fragment length polymorphism (RFLP) analysis for DNA products amplified by the polymerase chain reaction (PCR) was used for the direct detection ofRhizoctonia solani AG 1 IA and AG 2-2 IIIB,R. oryzae, R. oryzae-sativae andR. fumigata from the diseased rice sheaths. A rapid DNA extraction method with a solution of sodium hydroxide was conducted to extract parasite DNA from diseased rice sheaths. 28S ribosomal DNA (rDNA) derived from fungal genomic DNA extracted by the alkaline method was specifically PCR-amplified. The results of PCR-RFLP analysis for DNA samples from artificially inoculated rice sheath tissues with eachRhizoctonia spp. and the corresponding culture on the medium using two restriction enzymes.HhaI andMspI, showed identical polymorphisms. PCR-RFLP analysis using DNA samples from naturally infected rice sheath tissues also revealed the possibility of direct diagnosis ofR. solani AG 1 IA,R. oryzae andR. oryzae-sativae.     

Chemotaxonomy of fungi in the Rhizoctonia solani species complex performing GC/MS metabolite profiling

Hyphal anastomosis testing and molecular methods have been the primary criteria employed to understand the evolutionary and taxonomic relationships of the soil-borne fungal plant pathogen Rhizoctonia solani species complex. In this study, a metabolomics-based approach for characterizing and identifying isolates of R. solani using gas chromatography/mass spectrometry (GC/MS) metabolite profiling and footprinting was developed. Multivariate and hierarchical cluster analyses of GC/MS data provided resolution of isolates belonging to anastomosis groups (AGs) 1–6, 9, and 10 of R. solani. Clustering of R. solani AG-3 isolates, based on host origin, was also observed and attributed to metabolite-biomarkers belonging to amino, carboxylic and fatty acids. The chemotaxonomic approach using metabolomics is a high-throughput methodology that complements existing molecular approaches for the taxonomic investigation of Rhizoctonia isolates and monitoring of fungal metabolism.

     

First Report of Rhizoctonia solani AG‐7 on Cotton in Egypt

Eighty‐two isolates of Rhizoctonia solani were recorded from roots of naturally‐infected seedlings of the Egyptian cotton (Gossypium barbadense L.). Anastomosis groups (AGs) of the isolates were determined by using 13 different AGs testers. Three (3.7%) of the isolates were identified as R. solani AG7, while the remaining isolates were belonging to the AG 2‐1, AG4 and AG5. The identification of the three isolates was based on the frequency of the C2 reaction with the AG7 tester isolate. No fusion was observed between AG7 and isolates representing the other 13 AGs. Colonies of AG7 isolates grown on potato dextrose agar (PDA), malt yeast agar (MYA) and melt peptone agar (MPA) were brown to dark brown with aerial mycelium and sclerotia. The isolates had pitted sclerotial clusters and brownish exudates after 21 days of culturing on PDA, but without clear zonation. Pathogenicity test under greenhouse conditions revealed that AG7 caused the common symptoms of damping–off, which included seed rot, lesions on the hypocotyls and root rot.     

Molecular characterization of Rhizoctonia solani isolates the incitant of soybean root rot

Rhizoctonia solani isolates used in this investigation were identified as anastomosis-4 (AG-40), collected from different localities from Assiut governorate in Egypt. Pathogenicity test of seven isolates of R. solani was evaluated on soybean Giza 111 cultivar under greenhouse conditions. All tested isolates were able to infect soybean plants causing root rot with different degrees of severities, isolate No. 1, 2 and 3 showed significantly highest root rot severity, while isolate No. 5 gave the lowest percentage of root rot rating. The sodium dodecyl sulphate polyacrylamide gel electrophoresis patterns were used to compare three isolates of R. solani. There are no variations among R. solani isolates except a few exceptions according to their protein patterns. DNA markers obtained from all isolates showed genetic similarity among different isolates obtained from different geographical regions barring few exceptions. Correlation between DNA patterns of R. solani isolates and their virulence was detected, but no correlation with anastomosis groups (AG).     

Rhizoctonia spp. Causing Root and Hypocotyl Rot in Phaseolus vulgaris in Cuba

Sixty isolates of Rhizoctonia spp. were obtained from Cuban bean fields during the period 2004–2007. Isolates were characterized with different techniques, including nuclei staining, pectic zymogram, PCR–RFLP analysis of the rDNA–ITS region and sequencing of the rDNA–ITS region. The majority of the isolates were identified as multinucleate Rhizoctonia solani isolates, representing two different anastomosis groups (AGs), AG 2‐2 WB and AG 4 HGI; the remaining isolates were binucleate Rhizoctonia isolates and belonged to AG F and AG A. AG 4 HGI isolates were equally distributed in all soil types; AG 2‐2 isolates were more frequently isolated from cambisols, whereas AG F isolates were related to calcisols. Pathogenicity experiments in vitro and in the greenhouse, revealed that binucleate isolates only caused root rot, whereas R. solani isolates were able to cause root rot and hypocotyl rot. Furthermore, differences in virulence level were observed between R. solani and binucleate isolates and among different AGs. Isolates of R. solani AG 4 HGI and R. solani AG 2‐2 WB were the most aggressive, binucleate isolates of AG F were intermediate aggressive, whereas a binucleate isolate of AG A was weakly aggressive. In contrast with other reports about R. solani in bean, web blight symptoms were never observed during this study.     

Characterisation,differentiation and biochemical diversity of Fusarium solani and Fusarium proliferatum based on cellular fatty acid profiles

The biochemical relationships between Fusarium solani and Fusarium proliferatum isolates were investigated using fatty acid analysis. Cellular fatty acid composition showed that palmitic acid, stearic acid, oleic acid and linoleic acid were the most abundant fatty acids in these species and accounted for 93.88 and 94.02% of the fatty acid profiles in F. solani and F. proliferatum, respectively. The most predominant fatty acids were linoleic acid (37.44%) in F. solani and oleic acid (39.81%) in F. proliferatum. The fatty acid compositions of F. solani and F. proliferatum were significantly different (p?<?0.05) for most of the individual fatty acids. This study demonstrated that fatty acid profiles may be useful to characterise and differentiate F. solani and F. proliferatum isolates at the species level. Using fatty acid analysis, biochemical diversity was observed among isolates of these species. The dendrogramme revealed that F. solani and F. proliferatum formed two distinct clusters with a distance of 7.2. Isolates of each species were clustered with each other, having a Euclidean distance of 6 and 6.6 for F. solani and F. proliferatum, respectively.     

Intraspecific variation of <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> AG 3 isolates recovered from potato fields in Central Iran and South Australia

Pectic zymogram, RFLP and PCR analyses were used to characterize Rhizoctonia solani AG 3 isolates collected from diseased potatoes in South Australia. The pectic zymogram data were compared with those obtained for isolates collected from central Iran. Analyses of bands corresponding to pectin esterase and polygalacturonase revealed three zymogram subgroups (ZG) in AG 3. In addition to the previously reported ZG7 (here renamed ZG7-1), two new zymogram subgroups, ZG7-2 and ZG7-3, were identified. Of the 446 isolates tested, 50% of the South Australian and 46% of the Iranian isolates were ZG7-1. The majority of the isolates originating from stem and root cankers were ZG7-1, whereas most of the isolates designated ZG7-2 and ZG7-3 originated from tuber-borne sclerotia. Pathogenicity tests revealed that ZG7-1 generally produced fewer sclerotia and more severe cankers of underground parts of the potato plants than the other two ZGs. Two random DNA clones, one originating from an AG 3 isolate and the other from an AG 4 isolate, were used as probes for RFLP analyses of Australian isolates. The AG 3 probe, previously identified to be specific to this group, detected a high level of genetic diversity, with 11 genotypes identified amongst 50 isolates analysed. The low-copy AG 4 probe resolved three genotypes amongst 24 isolates. For 23 isolates analysed with both markers, the combined data distinguished a total of six genotypes and similarity analysis resolved the isolates into two main groups with 50% homology. PCR, using primers for the plant intron splice junction region (R1), also revealed variation. No obvious relationship among pectic zymogram groups, RFLP and PCR genotypes was observed.     

Genetic variation and pathogenicity of anastomosis group 2 isolates of Rhizoctonia solani in Australia

A collection of isolates of Rhizoctonia solani anastomosis group (AG) 2 was examined for genetic diversity and pathogenicity. Anastomosis reactions classified the majority of isolates into the known subgroups of AG 2-1 and AG 2-2 but the classification of several isolates was ambiguous. Morphological characters were consistent with the species, with no discriminating characters existing between subgroups. Vertical PAGE of pectic enzymes enabled the separation of zymogram group (ZG) 5 and 6 within AG 2-1, but not the separation of ZG 4 and 10 within AG 2-2. PCR analysis using inter-simple sequence repeats (ISSR) and the intron-splice junction (ISJ) region supported the separation of ZG 5 and 6, while the AG 2-2 isolates were separated by geographic region. A comparison of distance matrices produced by the zymogram analysis and PCR indicated a strong correlation between the marker types. Pathogenicity studies suggested canola (Brassica napus) cultivars were most severely affected by AG 2-1, while cultivars of two species of medic (Medicago truncatula cv. Caliph and M. littoralis cv. Herald) were susceptible to both AG 2-1 and 2-2. The results indicate that AG 2 is a polyphyletic group in which the classification of subtypes is sometimes difficult. Further investigation of the population structure within Australia is required to determine the extent and origin of the observed diversity.     

Advances in molecular interactions on the Rhizoctonia solani-sugar beet pathosystem

Rhizoctonia solani is a soilborne pathogen with a broad host range. An anastomosis group (AG) system based on hyphal fusions has been established to distinguish between different R. solani subgroups in this species complex. Members of the AG2-2IIIB subgroup can cause serious problems in sugar beet production, resulting in Rhizoctonia root and crown rot. In this review, we summarize the current molecular advances in the R. solani sugar beet pathosystem. The draft genome of R. solani AG2-2IIIB has an estimated size of 56.02 Mb, larger than any of the R. solani AGs sequenced to date. The genome of AG2-2IIIB has been predicted to harbor 11,897 protein-encoding genes, including a high number of carbohydrate-active enzymes (CAZymes). The highest number of CAZymes was observed for polysaccharide lyase family 1 (PL-1), glycoside hydrolase family 43 (GH-43), and carbohydrate esterase family 12 (CE-12). Eleven single-effector candidates were predicted based on AG2-2IIIB genome data. The RsLysM, RsRlpA, and RsCRP1 genes were highly induced upon early-stage infection of sugar beet seedlings, and heterologous expression in Cercospora beticola and model plant species demonstrated their involvement in virulence. However, despite the progress achieved thus far on the molecular interactions in this pathosystem, many aspects remain to be elucidated, including the development of efficient transformation systems, important for functional studies, and the silencing of undesirable traits in the sugar beet crop.     

Characterization of Rhizoctonia solani Isolates from Tobacco Fields Related to Anastomosis Groups 2-1 and BI (AG 2-1 and AG BI)

Tobacco has been reported to be infected by Rhizoctonia solani isolates belonging to anastomosis groups 1 through to 5. Ten pathogenic isolates of the fungus were collected from tobacco fields in Italy and France that anastomosed in high frequencies with AG BI tester isolates and in low frequencies with tester isolates of all described subgroups of AG2, although morphology and thiamine requirement of the isolates were similar to AG 2-1. Biomolecular evaluations by means of electrophoresis of polygalacturonase isozymes and RFLPs of ribosomal DNA internal transcribed spacers were carried out. The isolates shared a common pectic zymogram, distinct from those of AG BI and AG 2-subgroups, while RFLPs of rDNA-ITS evidenced a limited genetic variation within the homogeneous group and a closer similarity to AG 2-1. As far as priority is due to the anastomosis behaviour, the isolates should be ascribed to AG BI. However, tobacco isolates differ from tester strains of the known AG BI in their morphology, thiamine requirement, pathogenicity and biomolecular features. In addition they do not anastomose with both AG 3 and AG 6. Therefore they may represent a new subgroup.     

Variability in the Sensitivity of Rhizoctonia solani Anastomosis Groups to Fungicides

Tolclofos-methyl, iprodione and cyproconazole, among the eleven fungicides tested in vitro, gave consistently strong inhibition against all ten anastomosis groups (AGs) of Rhizoctonia solani. Carboxin, furmecyclox, thiabendazole, fenpropimorph and vinclozolin also inhibited all AGs but with wide variations in toxicity levels (EC90 values). Pencycuron showed strong activity against four AGs but was ineffective against the other six AGs. Generally, R. solani AGs were insensitive to fenarimol and imazalil. Tolclofos-methyl strongly inhibited 23 AG2-1 and 20 AG4 rapeseed/canola R. solani isolates from different locations in Saskatchewan, Alberta and Manitoba. The same isolates were also sensitive to iprodione, cyproconazole and carboxin. All AG4 canola isolates were insensitive to pencycuron (EC90 > 500 mg/l) while AG2-1 isolates showed highly variable levels of sensitivity with EC90s ranging from 0.5 to 220 mg/l. Tolclofos-methyl, applied to Brassica napus (canola) cv. Westar seed at 1 g a.i./kg, provided 75—100 % control of seedling damping-off in pots infested with AG2-1 or AG4 isolates. In parallel experiments, pencycuron (1 g a.i./kg seed) failed to control damping-off by AG4 canola isolates and gave variable disease control against AG2-1 isolates.     

Chemotaxonomy of fungi in the <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> species complex performing GC/MS metabolite profiling

Hyphal anastomosis testing and molecular methods have been the primary criteria employed to understand the evolutionary and taxonomic relationships of the soil-borne fungal plant pathogen Rhizoctonia solani species complex. In this study, a metabolomics-based approach for characterizing and identifying isolates of R. solani using gas chromatography/mass spectrometry (GC/MS) metabolite profiling and footprinting was developed. Multivariate and hierarchical cluster analyses of GC/MS data provided resolution of isolates belonging to anastomosis groups (AGs) 1–6, 9, and 10 of R. solani. Clustering of R. solani AG-3 isolates, based on host origin, was also observed and attributed to metabolite-biomarkers belonging to amino, carboxylic and fatty acids. The chemotaxonomic approach using metabolomics is a high-throughput methodology that complements existing molecular approaches for the taxonomic investigation of Rhizoctonia isolates and monitoring of fungal metabolism.     

Induction of pathogenesis-related proteins during biocontrol of <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> with <Emphasis Type="Italic">Pseudomonas aureofaciens</Emphasis> in soybean (<Emphasis Type="Italic">Glycine max</Emphasis> L. Merr.) plants

To investigate the biocontrol effectiveness of the antibiotic producing bacterium, Pseudomonas aureofaciens 63–28 against the phytopathogen Rhizoctonia solani AG-4 on Petri plates and in soybean roots, growth response and induction of PR-proteins were estimated after inoculation with P. aureofaciens 63–28 (P), with R. solani AG-4 (R), or with P. aureofaciens 63–28 + R. solani AG-4 (P + R). P. aureofaciens 63–28 showed strong antifungal activity against R. solani AG-4 pathogens in Petri plates. Treatment with P. aureofaciens 63–28 alone increased the emergence rate, shoot fresh weight, shoot dry weight and root fresh weight at 7 days after inoculation, when compared to R. solani AG-4; P + R treatment showed similar effects. Peroxidase (POD) and β-1,3-glucanase activity of P. aureofaciens 63–28 treated roots increased by 41.1 and 49.9%, respectively, compared to control roots. POD was 26% greater in P + R treated roots than R. solani treated roots. Two POD isozymes (59 and 27 kDa) were strongly induced in P + R treated roots. The apparent molecular weight of chitinase from treated roots, as determined through SDS-PAGE separation and comparison with standards, was about 29 kDa. Five β-1,3-glucanase isozymes (80, 70, 50, 46 and 19 kDa) were observed in all treatments. These results suggest that inoculation of soybean plants with P. aureofaciens 63–28 elevates plant growth inhibition by R. solani AG-4 and activates PR-proteins, potentially through induction of systemic resistance mechanisms.     

Genetic Diversity of Thanatephorus cucumeris Infecting Tomato in Iran

The necrotrophic fungus Thanatephorus cucumeris (anamorph Rhizoctonia solani) is among the most important soil‐borne pathogens which causes tomato foot and root rot worldwide. We investigated virulence and genetic relationships among and within different taxonomic groups of R. solani from the tomato‐growing regions in the north‐east of Iran. Characterization of R. solani taxonomic groups revealed that, of 56 isolates, four were AG‐2‐1, 16 were AG‐3 PT, 21 were AG‐4 HG‐I and 15 were AG‐4 HG‐II. Because interprimer binding site (iPBS), which is based on amplification of retrotransposons, is known as novel and powerful DNA fingerprinting technology, we selected four iPBS primers, which can detect polymorphisms of tomato foot root and root rot pathogen, for investigating genotypic variability of the isolates. The iPBS analyses separated various taxonomic groups of R. solani and showed great diversity among the isolates, demonstrating that the R. solani isolates obtained from tomato were not a clonal population. Crop rotation strategies and geographic location seem to be important factors affecting genetic structure of the isolates. Pathogenicity tests on tomato cultivar ‘Mobil’ showed significant differences in the virulence of various isolates. The overall results indicated that isolates of AG‐3 and AG‐4 were more virulent than AG‐2‐1. There was no significant correlation between genetic diversity and virulence of the isolates. This is the first report of R. solani AG‐4 HG‐II, causing tomato foot and root rot. Also, our research is the first in assessment of genetic diversity in fungal populations using iPBS molecular markers.