Morphological and Pathogenic Characterization of Genetically Diverse Sclerotinia Isolates from European Red Clover Crops (Trifolium Pratense L.)

Clover rot, an important disease in European red clover crops, is caused by Sclerotinia trifoliorum or Sclerotinia sclerotiorum. Until today, little is known about the variation in aggressiveness among Sclerotinia isolates from red clover. Aggressiveness has never been correlated with morphological characteristics. Rapidly growing isolates may be more aggressive, but this was never investigated in S. trifoliorum before. Also nothing is known about the link between sclerotia production and aggressiveness. Oxalic acid is an important pathogenicity factor in Sclerotinia species, but its effect on aggressiveness is unknown in S. trifoliorum isolates. For this study, we selected 30 Sclerotinia isolates from 25 locations Europe: 26 S. trifoliorum isolates and 4 S. sclerotiorum isolates from two locations in France (Fr.A and Fr.B). For each isolate, the in vitro growth speed, sclerotia production, oxalate production and aggressiveness were analysed and correlations were estimated between aggressiveness and the other characteristics. Aggressiveness was assessed in vitro on detached leaves and in a greenhouse on young plants. Our isolates differed significantly in growth speed, sclerotia production, oxalate production and aggressiveness. The infections on detached leaves and young plants revealed interaction between isolates and plant genotypes and between isolates and cultivars, but there was no indication that pathotypes exist. In vitro growth speed and in vitro aggressiveness on detached leaves were positively correlated with aggressiveness on young plants, while sclerotia production was negatively correlated with aggressiveness on young plants. These factors can be used as predictors of aggressiveness of Sclerotinia isolates from red clover crops.     

pH dependency of sclerotial development and pathogenicity revealed by using genetically defined oxalate‐minus mutants of Sclerotinia sclerotiorum

The devastating plant pathogen Sclerotinia sclerotiorum produces copious (up to 50 mM) amounts of oxalic acid, which, for over a quarter century, has been claimed as the pathogenicity determinant based on UV‐induced mutants that concomitantly lost oxalate production and pathogenicity. Such a claim was made without fulfilling the molecular Koch's postulates because the UV mutants are genetically undefined and harbour a developmental defect in sclerotial production. Here, we generated oxalate‐minus mutants of S. sclerotiorum using two independent mutagenesis techniques, and tested the resulting mutants for growth at different pHs and for pathogenicity on four host plants. The oxalate‐minus mutants accumulated fumaric acid, produced functional sclerotia and have reduced ability to acidify the environment. The oxalate‐minus mutants retained pathogenicity on plants, but their virulence varied depending on the pH and buffering capacity of host tissue. Acidifying the host tissue enhanced virulence of the oxalate‐minus mutants, whereas supplementing with oxalate did not. These results suggest that it is low pH, not oxalic acid itself, that establishes the optimum conditions for growth, reproduction, pathogenicity and virulence expression of S. sclerotiorum. Exonerating oxalic acid as the primary pathogenicity determinant will stimulate research into identifying additional candidates as pathogenicity factors towards better understanding and managing Sclerotinia diseases.     

Isolation of Oxalic acid tolerating fungi and decipherization of its potential to control Sclerotinia sclerotiorum through oxalate oxidase like protein

Oxalic acid plays major role in the pathogenesis by Sclerotinia sclerotiorum; it lowers the pH of nearby environment and creates the favorable condition for the infection. In this study we examined the degradation of oxalic acid through oxalate oxidase and biocontrol of Sclerotinia sclerotiorum. A survey was conducted to collect the rhizospheric soil samples from Indo-Gangetic Plains of India to isolate the efficient fungal strains able to tolerate oxalic acid. A total of 120 fungal strains were isolated from root adhering soils of different vegetable crops. Out of 120 strains a total of 80 isolates were able to grow at 10?mM of oxalic acid whereas only 15 isolates were grow at 50?mM of oxalic acid concentration. Then we examined the antagonistic activity of the 15 isolates against Sclerotinia sclerotiorum. These strains potentially inhibit the growth of the test pathogen. A total of three potential strains and two standard cultures of fungi were tested for the oxalate oxidase activity. Strains S7 showed the maximum degradation of oxalic acid (23?%) after 60?min of incubation with fungal extract having oxalate oxidase activity. Microscopic observation and ITS (internally transcribed spacers) sequencing categorized the potential fungal strains into the Aspergillus, Fusarium and Trichoderma. Trichoderma sp. are well studied biocontrol agent and interestingly we also found the oxalate oxidase type activity in these strains which further strengthens the potentiality of these biocontrol agents.     

Analyses of genetic and pathogenic variability among Botrytis cinerea isolates

Seventy nine isolates of Botrytis cinerea were collected from different host plants and different locations of India and Nepal. All the isolates were identified as B. cinerea based on morphological features and were confirmed using B. cinerea specific primers. Differentiation among the isolates was assessed using morphological, genetic and biochemical approaches. To analyze morphological variability, differences in conidial size, presence or absence of sclerotia and their arrangement were observed. Genetic variability was characterized using RAPD analysis, presence or absence of transposons and mating type genes. Cluster analysis based on RAPD markers was used for defining groups on the basis of geographical region and host. The biochemical approach included determining differences in concentration of oxalic acid and activity of lytic enzymes. All the isolates were categorized into different pathogenic groups on the basis their variable reaction towards chickpea plants. Isolates with higher concentration of oxalic acid and greater activity of lytic enzymes were generally more pathogenic. Pathogenicity was also correlated to transposons. Isolates containing transposa group showed some degree of correlation with pathogenic behavior. However, isolates could not be grouped on the basis of a single approach which provides evidence of their wide diversity and high evolution potential. Sensitivity of sampled isolates was also tested against five botryticides. Most of the isolates from same region were inhibited by a particular fungicide. This feature provided interesting cues and would assist in devising novel and more effective measures for managing the disease.     

Aspergillus spp. eliminate Sclerotinia sclerotiorum by imbalancing the ambient oxalic acid concentration and parasitizing its sclerotia

Sclerotinia sclerotiorum, a pathogen of more than 600 host plants, secretes oxalic acid to regulate the ambient acidity and provide conducive environment for pathogenicity and reproduction. Few Aspergillus spp. were previously proposed as potential biocontrol agents for S. sclerotiorum as they deteriorate sclerotia and prevent pathogen's overwintering and initial infections. We studied the nature of physical and biochemical interactions between Aspergillus and Sclerotinia. Aspergillus species inhibited sclerotial germination as they colonized its rind layer. However, Aspergillus-infested sclerotia remain solid and viable for vegetative and carpogenic germination, indicating that Aspergillus infestation is superficial. Aspergillus spp. of section Nigri (Aspergillus japonicus and Aspergillus niger) were also capable of suppressing sclerotial formation by S. sclerotiorum on agar plates. Their culture filtrate contained high levels of oxalic, citric and glutaric acids comparing to the other Aspergillus spp. tested. Exogenous supplementation of oxalic acid altered growth and reproduction of S. sclerotiorum at low concentrations. Inhibitory concentrations of oxalic acid displayed lower pH values comparing to their parallel concentrations of other organic acids. Thus, S. sclerotiorum growth and reproduction are sensitive to the ambient oxalic acid fluctuations and the environmental acidity. Together, Aspergillus species parasitize colonies of Sclerotinia and prevent sclerotial formation through their acidic secretions.     

Assessing in vitro efficacy of certain fungicides to control Sclerotinia sclerotiorum in peanut

The fungal pathogen Sclerotinia sclerotiorum is responsible for Sclerotinia blight in several crops around the world, including peanut. This study was conducted under laboratory conditions to determine the effects of four registered fungicides, Propulse?, Fontelis^®, Omega^® and Endura^® on mycelial growth and pigmentation, as well as sclerotia and oxalic acid production on a growth medium modified with a fungicide and on the pathogenicity of S. sclerotiorum on leaflets detached from Valencia peanut. Propulse, Omega and Fontelis inhibited mycelial growth of S. sclerotiorum, while, mycelial growth on a modified support with Endura was similar to the control treatment. All fungicides, except Endura, inhibited the production of oxalic acid. Pigmentation of the mycelium was observed in both the control and endura treatments. Sclerotia production was observed only in the control treatment. With the exception of Endura, all fungicides were effective in controlling the development of lesions on Valencia peanut leaflets.     

Characterization and Comparison of Clavibacter michiganensis subsp. nebraskensis Strains Recovered from Epiphytic and Symptomatic Infections of Maize in Iowa

Clavibacter michiganensis subsp. nebraskensis (Cmn), the causal organism of Goss’s wilt and leaf blight of maize, can be detected in the phyllosphere of its host prior to disease development. We compared the morphology and pathogenicity of 37 putative isolates of Cmn recovered from asymptomatic and symptomatic maize leaves. Thirty-three of the isolates produced mucoid orange colonies, irrespective of the source of isolation and all but four of these isolates were pathogenic on maize. The remaining 4 isolates recovered from asymptomatic leaves had large fluidal yellow colonies, and were non-pathogenic on maize. Isolates varied in their aggressiveness on a susceptible hybrid of maize but no significant differences in aggressiveness were detected between epiphytic isolates and those recovered from diseased maize tissues. The genomics of Cmn is poorly understood; therefore as a first step to determining what genes may play a role in virulence, we compared 33 putative virulence gene sequences from 6 pathogenic and a non-pathogenic isolate recovered from the phyllosphere. Sequence polymorphisms were detected in 5 genes, cellulase A, two endoglucanases, xylanase B and a pectate lyase but there was no relationship with pathogenicity. Further research is needed to determine what genes play a role in virulence of Cmn. Our data show however, that the virulence factors in Cmn likely differ from those reported for the closely related subspecies michiganensis and sepedonicus.     

Transformation of LTP gene into Brassica napus to enhance its resistance to Sclerotinia sclerotiorum

Rapeseed (Brassica napus L.) is one of the most important economic crops worldwide, and Sclerotinia sclerotiorum is the most dangerous disease that affects its yield greatly. Lipid transfer protein (LTP) has broad-spectrum anti-bacterial and fungal activities. In this study, B. napus was transformed using Agrobacterium tumefaciens harboring the plasmid-containing LTP gene to study its possible capability of increasing plant’s resistance. First, we optimized the petiole genetic transformation system by adjusting the days of explants, bacterial concentrations, ratio of hormones, and cultivating condition. Second, we obtained 8 positive plants by PGR analysis of T0 generation. The PGR results of T₁ generation were positive, indicating that the LTP gene had been integrated into B. napus. Third, T₁ transgenic plants inoculated by detached leaves with mycelia of S. sclerotiorum showed better disease resistance than non-transformants. Oxalic acid belongs to secondary metabolites of S. sclerotiorum, and several studies have demonstrated that the resistance of rapeseed to oxalic acid is significantly consistent with its resistance to S. sclerotiorum. The result from the seed germination assay showed that when T₁ seeds were exposed to oxalic acid stress, their germination rate was evidently higher than that of non-transformant seeds. In addition, we measured some physiological changes in T₁ plants and control plants under oxalic acid stress. The results showed that T₁ transgenic plants had lower malondialdehyde (MDA) content, higher super oxide dismutase (SOD), and peroxidase (POD) activities than non-transformants, whereas disease resistance was related to low MDA content and high SOD and POD activities.     

Colletotrichum species associated with sugarcane red rot in Brazil

Sugarcane is a widely cultivated crop in Brazil and in many parts of the world. However, the red rot causes huge losses due to the reduction of sucrose and deterioration of the juice. The aim of this study was to identify Colletotrichum species associated with the red rot through polyphasic approaches; which included phylogenetic, morpho-cultural analyzes and pathogenicity tests. Nine isolates from the states of Alagoas and two from São Paulo, Brazil, were preliminary analyzed with the glyceraldehyde-3 phosphate dehydrogenase gene (GAPDH), as an initial measure for species diversity. Later on, the representative isolates of each species were sequenced with the β-tubulin (TUB2) gene, calmodulin (CAL), DNA lyase (APN2/MAT IGS) and the ITS-rDNA region. Morphocultural characterization was performed by evaluating the mycelial growth rate (MGR), colony appearance and the shape and size of 50 conidia and appressoria. For the pathogenicity test asymptomatic leaves and stalks of sugarcane were tested with and without injuries. Phylogenetic analysis associated with morphocultural characteristics and the pathogenicity test of the eleven isolates revealed three Colletotrichum species: Colletotrichum falcatum (8 isolates), Colletotrichum siamense (1 isolate) and Colletotrichum plurivorum (2 isolates) causing the red rot disease in sugar cane. All species were pathogenic in wounded leaves and stalks, being C. falcatum the one causing the largest lesions (1.12 cm) in leaves and C. plurivorum in stalks (0.67 cm). Therefore, this study confirms the association of C. falcatum as a sugarcane pathogen and records for the first time worldwide the occurrence of C. siamense and C. plurivorum associated with this host.     

Production and Degradation of Oxalic Acid by Brown Rot Fungi

Our results show that all of the brown rot fungi tested produce oxalic acid in liquid as well as in semisolid cultures. Gloeophyllum trabeum, which accumulates the lowest amount of oxalic acid during decay of pine holocellulose, showed the highest polysaccharide-depolymerizing activity. Semisolid cultures inoculated with this fungus rapidly converted ¹⁴C-labeled oxalic acid to CO₂ during cellulose depolymerization. The other brown rot fungi also oxidized ¹⁴C-labeled oxalic acid, although less rapidly. In contrast, semisolid cultures inoculated with the white rot fungus Coriolus versicolor did not significantly catabolize the acid and did not depolymerize the holocellulose during decay. Semisolid cultures of G. trabeum amended with desferrioxamine, a specific iron-chelating agent, were unable to lower the degree of polymerization of cellulose or to oxidize ¹⁴C-labeled oxalic acid to the extent or at the rate that control cultures did. These results suggest that both iron and oxalic acid are involved in cellulose depolymerization by brown rot fungi.     

Sclerotinia sclerotiorum Thioredoxin1 (SsTrx1) is required for pathogenicity and oxidative stress tolerance

Sclerotinia sclerotiorum infects host plant tissues by inducing necrosis to source nutrients needed for its establishment. Tissue necrosis results from an enhanced generation of reactive oxygen species (ROS) at the site of infection and apoptosis. Pathogens have evolved ROS scavenging mechanisms to withstand host‐induced oxidative damage. However, the genes associated with ROS scavenging pathways are yet to be fully investigated in S. sclerotiorum. We selected the S. sclerotiorum Thioredoxin1 gene (SsTrx1) for our investigations as its expression is significantly induced during S. sclerotiorum infection. RNA interference‐induced silencing of SsTrx1 in S. sclerotiorum affected the hyphal growth rate, mycelial morphology, and sclerotial development under in vitro conditions. These outcomes confirmed the involvement of SsTrx1 in promoting pathogenicity and oxidative stress tolerance of S. sclerotiorum. We next constructed an SsTrx1‐based host‐induced gene silencing (HIGS) vector and mobilized it into Arabidopsis thaliana (HIGS‐A) and Nicotiana benthamiana (HIGS‐N). The disease resistance analysis revealed significantly reduced pathogenicity and disease progression in the transformed genotypes as compared to the nontransformed and empty vector controls. The relative gene expression of SsTrx1 increased under oxidative stress. Taken together, our results show that normal expression of SsTrx1 is crucial for pathogenicity and oxidative stress tolerance of S. sclerotiorum.     

Phylogenetics and histology provide insight into damping-off infections of ‘Poblano’ pepper seedlings caused by <Emphasis Type="Italic">Fusarium</Emphasis> wilt in greenhouses

The ‘Poblano’ pepper crop is economically important in Mexico and throughout the world as it is used as a hot spice in food. The cultivated area of the ‘Poblano’ pepper crop is decreasing yearly for many reasons, among them a wilt disease commonly associated with Fusarium spp. This disease is a problem of field and greenhouse production plants. Moreover, it is not clear whether the pathogens that cause wilt in mature plants are the same as those involved in the damping-off symptoms and death of pepper seedlings in greenhouses. For this reason, the aim of the present study was to identify the causal agent of damping-off in pepper during seedling production, establish its relationship with the causal agent of wilting in mature plants, and determine whether histological damage in seedlings occurs. Isolates were recovered from the crown rot and stem base of 4-month-old infected ‘Poblano’ mature pepper plants and were identified using morphological and phylogenetic approaches. Fusarium oxysporum and F. solani were isolated from the crown rot and base stem, respectively. A pathogenicity test showed that both species caused damping-off in pepper seedlings. Histological studies with inoculated seedlings of both isolates showed several changes in the external cortex, epidermal cells, endodermis, Casparian strips, cell size, and xylem wall. Casparian strip rupture resulted in permeability loss and regulatory activity to maintain the cellular equilibrium inside the vascular bundles. Hence, according to these findings, producers should avoid seedling contamination by infected mature plants because the aggressiveness of Fusarium isolates can cause rapid seedling mortality.     

Integrated control of white rot disease on beans caused by Sclerotinia sclerotiorum using Contans® and reduced fungicides application

This study was conducted to determine the compatibility of Contans® (Coniothyrium minitans) with fungicides against Sclerotinia sclerotiorum. Results showed that both Contans® and Topsin® significantly reduced the disease incidence caused by S. sclerotiorum by 90% and 95% survival plants, respectively when they were individually applied and compared to control. While, soil application of Contans® and Sumisclex mixture was the most effective in suppressing the white rot disease incidence that produced 100% survival plants, application of C. minitans combined with the reduced doses of fungicides would be advantageous in saving labor cost, thus increasing production efficiency of bean.     

Pathogenicity variation in Fusarium verticillioides populations isolated from maize in northern Italy

One hundred and eighty one strains were selected among Fusarium verticillioides populations isolated from maize samples collected in three fields located in northern Italy. All the isolates were tested for their pathogenicity on maize seeds by assessing the seed germination percentages and the percentage infection indexes concerning seed colonization, radicle decay and coleoptile rot. Fusarium verticillioides strains did not affect seed germination even in presence of high seed colonization, but showed a variable pathogenic behavior according to the maize growth stages. Seedborne F. verticillioides population as well as strains isolated at maturity was effective in seed colonization and in inducing coleoptile rot, not causing however serious radicle decay. Only populations isolated at seedling and pre-silking stages showed high radicle decay ability. These results provide baseline information on F. verticillioides pathogenicity. They constitute an important input for further investigation of F. verticillioides biology in order to define its evolutionary potential.     

Carbendazim resistance and dimethachlone sensitivity of field isolates of Sclerotinia sclerotiorum from oilseed rape in Henan Province,China

Sclerotinia stem rot caused by Sclerotinia sclerotiorum is one of the most important diseases in oilseed rape‐growing areas of China. To determine the frequency of resistance of field isolates of S. sclerotiorum to carbendazim and dimethachlone, a total of 556 isolates from 10 different regions of Henan Province were obtained between 2015 and 2016. The frequency of isolates with a high‐resistance phenotype and a moderate‐resistance phenotype to carbendazim was 69.2% and 10.8%, respectively. However, S. sclerotiorum isolates resistant to dimethachlone were not detected. The baseline sensitivity of S. sclerotiorum to dimethachlone was distributed as a unimodal curve with a mean EC₅₀ value of 0.39 ± 0.09 μg ml^?1 for the inhibition of mycelial growth. Four dimethachlone‐resistant mutants were obtained from 20 wild‐type isolates induced by exposure to increasing concentrations of the fungicide in vitro. The mutants showed high levels of resistance to dimethachlone, with resistance factors that ranged from 179 to 323. Positive cross‐resistance occurred between dimethachlone and procymidone, iprodione, and fludioxonil; however, no cross‐resistance was observed for carbendazim and boscalid. The fitness of the dimethachlone‐resistant mutants was significantly lower than that of the wild‐type isolates, as measured by mycelial growth, hyphal dry weight, sclerotium number and dry weight, and pathogenicity. Additionally, based on osmotic tests, the inhibition of mycelial growth caused by NaCl applied at different concentrations was significantly higher for the dimethachlone‐resistant mutants than for their wild‐type parents.     

Diagnosis and management of Sclerotinia stem rot (white mould) of lentils in Greece

The paper describes the field-level symptoms, the identification and management of Sclerotinia stem rot of lentil caused by the soilborne plant pathogen Sclerotinia sclerotiorum in Greece. Regarding symptoms at a field level, initially plants before flowering turn yellow with roots and the base of the plants become brown; then rotten plants exhibit a dry stem and die. On the diseased tissue, at the base of the stem, the typical white mycelium and the resting bodies (sclerotia) were observed. According to our pathogenicity studies in vitro, on the infected plant tissues the fungus first develop a characteristic fluffy white mycelium which will give rise to large black sclerotia, the most obvious evidence of plants infected with S. sclerotiorum. Finally, concerning evaluation of fungicides, isolates of S. sclerotiorum were sensitive to thiophanate-methyl and to triazole fungicides. Thiophanate-methyl and triazole fungicides proved to be most effective in controlling the disease emerged from mycelium or sclerotia.     

Oxalic Acid Has an Additional,Detoxifying Function in Sclerotinia sclerotiorum Pathogenesis

The mechanism of the diseases caused by the necrotroph plant pathogen Sclerotinia sclerotiorum is not well understood. To investigate the role of oxalic acid during infection high resolution, light-, scanning-, transmission electron microscopy and various histochemical staining methods were used. Our inoculation method allowed us to follow degradation of host plant tissue around single hyphae and to observe the reaction of host cells in direct contact with single invading hyphae. After penetration the outer epidermal cell wall matrix appeared degraded around subcuticular hyphae (12-24 hpi). Calcium oxalate crystals were detected in advanced (36-48 hpi) and late (72 hpi) infection stages, but not in early stages. In early infection stages, surprisingly, no toxic effect of oxalic acid eventually secreted by S. sclerotiorum was observed. As oxalic acid is a common metabolite in plants, we propose that attacked host cells are able to metabolize oxalic acid in the early infection stage and translocate it to their vacuoles where it is stored as calcium oxalate. The effects, observed on healthy tissue upon external application of oxalic acid to non-infected, living tissue and cell wall degradation of dead host cells starting at the inner side of the walls support this idea. The results indicate that oxalic acid concentrations in the early stage of infection stay below the toxic level. In plant and fungi oxalic acid/calcium oxalate plays an important role in calcium regulation. Oxalic acid likely could quench calcium ions released during cell wall breakdown to protect growing hyphae from toxic calcium concentrations in the infection area. As calcium antimonate-precipitates were found in vesicles of young hyphae, we propose that calcium is translocated to the older parts of hyphae and detoxified by building non-toxic, stable oxalate crystals. We propose an infection model where oxalic acid plays a detoxifying role in late infection stages.     

Prokaryotic expression and protein function of Brassica napus PGIP2 and its genetic transformation

Sclerotinia rot is a fungal disease caused by Sclerotinia sclerotiorum (Lib.) de Bary, which has severely reduced rapeseed production worldwide. Polygalacturonase-inhibiting proteins (PIGPs) inhibit the activity of polygalacturonases, which are secreted during fungal infection in plants. This study investigated the function of the polygalacturonase-inhibitor gene 2 (PGIP2) in sclerotinia rot resistance. The PGIP2 was successfully expressed in a prokaryotic system, and recombinant PGIP2 protein, purified after enterokinase treatment to remove tag peptide, inhibited S. sclerotiorum PG activity in vitro. PGIP2 was overexpressed in the susceptible Brassica napus cultivar 98c40 via Agrobacterium-mediated transformation. After inoculation with S. sclerotiorum mycelia, the transgenic rapeseed demonstrated greatly reduced leaf damage, as compared with their non-transgenic plants. Therefore, the PGIP2 encodes a functional protein and would be a candidate gene for enhancing Sclerotinia rot resistance.     

Biological and molecular variability of Sarocladium oryzae, the sheath rot pathogen of rice (Oryza sativa L.)

Sheath rot disease of rice caused by Sarocladium oryzae (Sawada) (=Acrocylindrium oryzae, Sawada) has become an important production constraint in all rice-growing countries. Pathogenicity, phytotoxic metabolites, and random amplified polymorphic DNA (RAPD) markers were used to assess the level of genetic variability of S. oryzae derived from rice cultivars, CR1018, IR36, and IR50, of different locations in North East and South India. Variability in pathogenicity, phytotoxic metabolite production, and DNA polymorphisms was detected among S. oryzae isolates. Results indicated that S. oryzae isolates produced both cerulenin and helvolic acid at concentrations 0.3–0.62 and 0.9–4.8 μg mL⁻¹ of culture filtrate, respectively. Isolates that produce higher concentration of helvolic acid induced a high percent incidence of sheath rot disease. Oligonucleotide primers, GF and MR, generated either a simple (up to 2 bands) or complex (up to 6 bands) RAPD pattern. According to their level of similarity, S. oryzae isolates from North East and South India were grouped separately into two major clusters and 13 genotypes. Molecular- and pathogenicity-based classifications were not correlated, but a high level of genetic variability within S. oryzae isolates was identified. The molecular variability of S. oryzae isolates will be an important consideration in breeding programs to develop durable resistance for sheath rot disease.