Eleven commercial rice cultivars with the pedigree and type; Giza 177 (Giza 171/Yomji No.1/PiNo.4- Japonica), Giza 178 (Giza 175/Milyang 49 - Indica/Japonica), Giza 181 (IR23/IR22- Indica), Egyptian Hybrid 1 (IR69625A/Giza 178 R- Indica/Japonica), Giza 182 (Giza181/IR39422-161-1-3//Giza 181- Indica), Giza 183 (Giza 178/SKC23893- Indica/Japonica), Egyptian Yasmine (IR262/KDML-105- Indica), Sakha 101 (Giza 176/Milyang 79- Japonica), Sakha 104 (GZ 4096-8-1/GZ 4100-9-1- Japonica), Sakha 108 (Sakha 101/HR5824/Sakha 101- Japonica) and Sakha super 300 (PTGMS38/China2- Indica/Japonica) was used as experimental plant materials throughout this study. Seeds were kindly provided by the Rice Research Department, Field Crops Research Institute (FCRI), Agricultural Research Center (ARC), Egypt. Moreover, seeds of 12 common rice-associated weeds ( Table 1 ) were obtained from the Weed Research Central Laboratory (WRCL), ARC, Egypt. Likewise, seeds/grains of 31 economic crops ( Table 2 ) were generously provided by the Department of Food Legumes Research, FCRI-ARC, Egypt. All seeds were healthy, uniform, and homologous in size and color.

All experiments were conducted at the Rice Pathology Department, Rice Research and Training Center (RRTC), ARC, Egypt. Seeds were initially sterilized for 3-4 minutes using sodium hypochlorite (NaClO) solution (1%) and then washed twice with sterile water, then planted in plastic pots (30 cm inner diameter and 45 cm in depth) filled with sterilized clay soils. All pots were maintained under greenhouse conditions at 27 ± 2°C, >75% RH, and 8D:16L light cycle. Plants were irrigated daily, or earlier if needed, and fertilized with macro- and micronutrients according to the recommendations of the Egyptian Ministry of Agriculture and Land Reclamation for these cultivars/species.

All in vitro experiments were performed in a completely randomized design with five biological replicates and two technical replicates. Likewise, all in vivo experiments were performed in a completely randomized design, unless otherwise stated, with three replicates, each replicate had four pots, and all experiment was repeated twice. All data were statistically analyzed according to the analysis of variance technique (ANOVA), followed by Tukey’s Honestly Significant Difference (HSD) Test as a post hoc analysis. On the other hand, the experiment of evaluation of rice genotypes against R. solani infection was laid out using a split-plot design comprising R. solani infection in the main plots (infection) and eleven rice genotypes in subplots (genotypes). Data were statistically analyzed using ANOVA, followed by the HSD Test as a post hoc analysis based on the p-value of infection (p _infection< 0.05), genotypes (p _genotypes< 0.05), and their interaction (p _{infection × genotypes}< 0.05). Principal component analysis (PCA) was performed and its associated scatter and loading plots were generated using the response of the 11 tested rice genotypes to the 9 isolates of R. solani as expressed by relative lesion height (RLH; %). Moreover, two-way Hierarchical Cluster Analysis (HCA) was performed using the average of each RLH in each treatment. Distance and linkage were done using the Ward method (Ward Jr, 1963) and RLH similarities were presented as a heat map.

Nine isolates (named SHBP 1- 9) were isolated from diseased rice cultivars showing typical symptoms of sheath blight disease (four isolates from Sakha 108, three isolates from Sakha super 300, and one isolate from Giza 178 and Sakha 104 each) collected from three Egyptian governorates included Beheira (Itaielbarood, Abohomos, Elebrahimyia), Dakahlia (Dekerns, Talkha, Mansoura), and Kafrelsheikh (Sakha, Misaar, Kellan) ( Table 3 ). Isolates SHBP 1-9 showed typical morphological characteristics, colony texture, and abundance of asexual reproductive structures (mycelium and sclerotia) with R. solani when grown on a PDA medium ( Figure 1A ). The mycelium growth showed two types: moderate speed with flat shape in five isolates (SHBP1, 3, 4, 7, and 9) and rapid with flat/arial in four isolates (SHBP2, 5, 6, and 8) ( Figure 1A ; Table 6 ).

Furthermore, we noticed four color patterns: cream (two isolates), light, and dark brown (three isolates each), and a unique isolate, SHBP3, with a black-brown color ( Figure 1A ). Furthermore, the sclerotia appeared in two shapes: peripheral in four isolates (SHBP1, 2, 3, and 4) and scattered in four isolates (SHBP5, 7, 8, and 9); meanwhile, SHBP6 showed a central peripheral shape. In addition, SHBP 1, 2, 5, 6, and 7 recorded the least number of days to produce sclerotia (5 days), and SHBP4 and 9 recorded the greatest number of days to produce sclerotia (9 days) ( Figure 1A and Table 6 ).

In situ microscopic observation revealed that the mycelium is generally dark or hyaline, its cells are lengthy, and its branch septa typically branch off from the main hyphae. Normal right angles were typically seen at the hyphal constrictions at the point of branching ( Figure 1B ). The mycelium was made up of hyphae that have been divided into separate cells by dolipore septa, which have extensive taxonomic characteristics.

Although the nine isolates were pathogenic and produced typical symptoms of sheath blight disease on the susceptible rice cultivar (Sakha 101) under greenhouse conditions, SHBP 9 was the most aggressive one and resulted in the highest relative lesion height % (63.98± 1.45%) on infected rice plants ( Figure 1C ). On the other hand, SHBP8 showed the lowest performance (26.36± 1.23%) compared with all the isolates.

The identification of the nine R. solani isolates (SHBP1 to 9) was further confirmed based on the sequencing of the Internal transcribed spacer (ITS) region. Briefly, nine PCR products ranged from 481 to 686 bp. The ITS sequence of each isolate was aligned on NCBI for molecular identification, and then each sequence was submitted to the GenBank sequence database of the National Center for Biotechnology Information (NCBI; https://www.ncbi.nlm.nih.gov/). Finally, the isolates accession numbers were as fellow; PP445281, PP426068, PP426196, PP426588, PP445282, PP426616, PP445324, PP429228 and PP445325, for SHBP1 to 9 respectively. The phylogenetic analysis between the nine R. solani isolates showed high similarity (about 99%) between isolates except R. solani AG1 IA isolate SHBP3 (PP426196.1; 79%) which was clustered separately at the bottom of the dendrogram ( Figure 1D ). it is worth noting that the most aggressive isolate SHBP9 (PP445325.1) was more similar to R. solani AG1 IA isolate SHBP4 (PP426588.1) than other isolates.

Moreover, to better understand the relationship between the R. solani AG1 IA and other anastomosis groups (AGs), the evolutionary analysis of R. solani AG1 IA (isolates SHBP 1-9) in comparison with other 40 R. solani strains/isolates from different anastomosis groups (AGs) ( Figure 1E ). Interestingly, eight of the nine R. solani isolates (except SHBP3) showed high similarity with the Japanese isolate of R. solani AG-1 1A isolate F190 (GenBank accession No. FJ492099.3, 644 bp) isolated from sugar beet. Moreover, the same eight isolates were also clustered with the Turkish isolate AG-1 IB isolate Rs-16 (GenBank accession No. MT568768.1, 692 bp) isolated from Brassica oleracea and the Japanese one AG-1 1C isolate F192 (GenBank accession No. FJ492101.3, 636 bp) isolated from sugar beet ( Figure 1E ). On the other hand, R. solani AG1 IA isolate SHBP3 was clustered separately from other isolates and shared similar evolutionary behavior with two Canadian isolates including R. solani AG-H isolate 534-2 (GenBank accession No. MT177264.1; 458 bp) isolated from Triticum sp. and R. solani AG-I isolate 390.Rs.16-70 (GenBank accession No. MT177265.1; 665 bp) from Glycine max ( Figure 1E ).

The nine isolates showed a wide response for the cell wall degradation enzymes (CWDE) production when cultured on a minimal inductive medium supplemented with plant-derived polysaccharides (e.g., pectin, starch, or carboxymethyl cellulose [CMC]) ( Figure 2A ). It is well known that fungal linear growth rates on CWDE-inductive media are correlated with enzyme production. Faster growth on inductive media indicates robust CWDE production. The fungal linear growth of R. solani isolates on pectin-containing medium ranged from 3.2 to 7.0 cm ( Figure 2B ), whereas it ranged from 5.5 to 8.9 cm on starch-containing medium ( Figure 2C ) and ranged from 3.9-6.13 cm on CMC-containing medium ( Figure 2D ). R. solani AG1 IA isolate SHBP9 recorded the highest linear growth on pectin-, starch-, and CMC- containing media (7.00 ± 0.20, 8.90 ± 0.20, and 6.13 ± 0.13 cm, respectively).

Likewise, the gene expression of pectate lyase B (RsPLB, Figure 2E ), putative pectate lyase C (RsPLC, Figure 2F ), and polysaccharide lyase family 1 protein (RsPSL, Figure 2G ) supported the enzymatic activity analysis. The studied genes were upregulated in all R. solani isolates when grown on a pectin-containing medium compared with those grown on a pectin-free medium. For instance, R. solani AG1 IA isolate SHBP9 had the highest transcript levels of RsPLB (up to 7.20-folds), RsPLC (8.73-folds), and RsPSL (8.33-folds). On the other hand, R. solani AG1 IA isolate SHBP8 had the lowest transcript levels of RsPLB, RsPLC, and RsPSL (4.00-, 3.53-, and 3.37-folds, respectively) when grown on pectin-containing medium compared with those grown on pectin-free medium ( Figures 2E–G ).

All nine isolates were pathogenic and produced typical symptoms of sheath blight disease on 11 different Egyptian rice genotypes under greenhouse conditions. The percentage of relative lesion height ranged from 10.93% (isolate SHBP4 on Egyptian Yasmine) to 68.70% (Isolate SHBP9 on Sakha 104) ( Figure 3A ). Moreover, two-way Hierarchical Cluster Analysis (HCA) and its associated heatmap were performed using the individual response (RLH) of each genotype to different R. solani isolates ( Figure 3A ). Interestingly, the HCA-associated dendrogram among rice genotypes showed that all tested genotypes were clustered into three distinct clusters. Cluster “I” included three resistant genotypes (Egyptian Hybrid 1, Giza 182, and Egyptian Yasmine), Cluster “II” included four moderately resistant genotypes (Giza 177, Giza 178, Giza 183, and Giza 181), whereas Cluster “II” included four susceptible genotypes (Sakha 101, Sakha 104, Sakha 108, and Sakha Super-300) ( Figure 3A ). It is worth noting that while Egyptian Yasmine showed the highest resistance to all isolates, Sakha 104 had almost the lowest resistance to all isolates. On the other hand, the HCA-associated dendrogram among R. solani isolates clustered both SHBP8 and SHBP9 separately from other isolates. R. solani AG1 IA isolate SHBP9 was the most aggressive isolate and caused the highest relative lesion height percentage on Sakha 104 (68.70 ± 1.22%), Sakha 101 (64.32 ± 1.14%), Sakha Super 300 (62.53 ± 1.04%), and Sakha-108 (59.40 ± 0.95%) ( Figure 3A ). On the other hand, Egyptian Yasmine was the lowest susceptible rice genotype and recorded the lowest relative lesion height percentage when infected with isolates SHPB4 (10.93 ± 0.51%), SHPB8 (11.02 ± 0.51%), SHPB1 (11.14 ± 0.42%), and SHPB5 (11.30 ± 0.72%) ( Figure 3A ).

Likewise, principal component analysis (PCA) revealed the differences between rice genotypes as well as R. solani isolates ( Figures 3B–E ). Briefly, The PCA-associated scatter plot showed a clear separation among all studied rice genotypes concerning the total variation of PC1 (91.47%) and PC2 (2.85%) ( Figures 3A, B ). in agreement with HCA, Egyptian Hybrid 1, Giza 182, and Egyptian Yasmine were clustered together at the left side of the scatter plot and separately from other genotypes. Moderately resistant genotypes (Giza 177, Giza 178, Giza 183, and Giza 181) were grouped in the center of the scatter plot, whereas susceptible rice genotypes (Sakha 101, Sakha 104, Sakha 108, and Sakha Super-300) were grouped into the right side of the scatter plot ( Figure 3B ). Moreover, the PCA-associated loading plot showed that all R. solani isolates were positively correlated with the susceptible rice genotypes ( Figure 3C ).

Similarly, the PCA-associated scatter plot of R. solani isolates showed a clear separation among all isolates concerning the total variation of PC1 (70.59%) and PC2 (17.48%) ( Figures 3D, E ). The most aggressive isolate, R. solani isolate AG1 IA SHBP9, and the lowest aggressive isolate, R. solani isolate AG1 IA SHBP8 were grouped far away from each other ( Figure 3D ). Furthermore, the PCA-associated loading plot showed that all rice genotypes were positively correlated with the virulence of R. solani AG1 IA isolate SHBP9 ( Figure 3E ).

The virulence of R. solani isolate AG1 IA SHBP9 was tested against 12 common rice-associated weeds ( Table 1 ), and 31 economic crops ( Table 2 ) belonging to 12 families (3 Monocotyledons and 9 Dicotyledons) to assess the host range of R. solani AG1 IA. All the Monocotyledon plants, 13 of Poaceae, 3 of Cyperaceae, and 1 of Typeaceae, were susceptible to R. solani AG1 IA isolate SHBP9 ( Figures 4 , 5 ). Meanwhile, 6 plant species belonging to Dicotyledons were resistant to the SHBP9 including chickpea (Cicer arietinum) from Fabaceae, Rocket (Eruca sativa) from Brassicaceae, and the four studied crops from Solanaceae (potato, tomato, eggplant, and pepper) ( Table 2 ). In addition, the remaining 20 Dicotyledons plant species: 3 of Cucurbitaceae, 2 of Malvaceae, 1 of Linaceae, 8 of Fabaceae, 2 of Brassicaceae, 1 of Amaranthaceae, 2 of Apiaceae, and 1 of Asteraceae, were susceptible to R. solani isolate AG1 IA isolate SHBP9 ( Figure 5 ; Table 2 ).

Eleven rice genotypes (five Japonica, three Indica-Japonica, and three Indica) were used to evaluate their resistance against the sheath blight disease caused by R. solani AG1 IA (isolate SHBP 9). Greenhouse findings showed that the typical symptoms of sheath blight disease were observed on the eleven tested rice genotypes at least 30 dpi, ( Figure 6 ). Rice genotypes differed in their susceptibility to sheath blight ( Figures 6 , 7 ). Sakha 104 recorded the highest RLH (69.63%; Figure 7A ), disease score (9; Figure 7B ), disease index (67.31%; Figure 7C ), and sheath lesion area (9.75 cm²; Figure 7D ), followed by Sakha 101, Sakha super 300, Sakha 108 and Giza 177 in terms of RLH (64.22, 62.52, 59.90 and 45.16%), disease score (7), disease index (62.08, 60.44, 57.93 and 43.65%), and lesion sheath area (7.18, 5.13, 2.96 and 1.53 cm²), respectively. Meanwhile, the lowest disease traits were observed by indica type and indica japonica; particularly Egyptian Yasmine with RLH (19.10%), disease score (1), disease index (18.4%), and Lesion sheath area (1.24 cm), followed by Egyptian hybrid 1 and Giza 182 RLH (26.99 and 28.23%), disease score (3), disease index (26.09 and 26.95%) and Lesion sheath area (1.60 and 1.77 cm, respectively). In addition, indica type, i.e., Giza 181, Giza 182, Giza 178, and Giza 183, recorded moderate disease traits ranging from 32- 44.75% for RLH and 5 for disease score ( Figures 7A, B ).

The morphological traits of healthy and R. solani-infected rice genotypes differed significantly ( Figure 8 ). Infection with R. solani significantly altered plant height (p _Infection< 0.0001; Figure 8A ), stem diameter (p _Infection = 0.0003; Figure 8C ), and flag leaf area (p _Infection = 0.0234; Figure 8D ), but not the number of tillers per plant (p _Infection = 0.1001; Figure 8B ). Mock-inoculated (healthy) Sakha Super 300 had the plant height (125.3 ± 3.00 cm), whereas R. solani-infected Sakha 108 showed the lowest plant height (85.60 ± 6.00 cm) ( Figure 8A ). Likewise, healthy Giza 182 recorded the highest number of tillers per plant (15.60 ± 0.40) which was similar to the R. solani-infected Sakha 108 (15.60 ± 0.40) with no significant differences between them ( Figure 8B ). However, Giza 177, either infected or not, had the lowest number of tillers per plant (6.90 ± 0.30). Meanwhile, healthy Sakha Super 300, healthy Egyptian Yasmine, and R. solani-infected Egyptian Yasmine had the highest stem diameter (5.67 ± 0.20 5.60 ± 0.40, and 5.58 ± 0.20 mm, respectively) without significant differences between them. Nevertheless, infected Giza 177 and Sakha 101 recorded the thinnest stem diameter (3.93 ± 0.20 and 3.92 ± 0.40 mm, respectively) without significant differences between them ( Figure 8C ). Finally, the flag leaf area did not differ significantly among most of the rice genotypes, either infected or not. However, healthy Egyptian Yasmine had the highest flag leaf area (58.30 ± 4.0 cm²), whereas R. solani-infected Sakha 104 had the lowest flag leaf area (30.04 ± 3.89 cm²) ( Figure 8D ).

Infection with R. solani significantly altered all studied yield components including panicle length (p _Infection< 0.0001; Figure 9A ), panicle weight (p _Infection = 0.0019; Figure 9B ), 1000-grain weight (p _Infection< 0.0001; Figure 9C ), and number of discolored grains (p _Infection< 0.0001; Figure 9D ). Mock-inoculated Giza 181 recorded the highest panicle length (27.67 ± 0.30 cm), whereas infected Sakha Super 300 had the lowest panicle length (17.20 ± 0.20cm) (p _{Infection × Genotype}< 0.0001; Figure 9A ). Likewise, the highest performance of panicle weight was recorded by the healthy Sakha Super 300 (4.70 ± 0.20 g) while the lowest performance of panicle weight was recorded by healthy Giza 178 (1.56 ± 0.20 g) and R. solani-infected Giza 178 (1.50 ± 0.20 cm) with no significant differences between them (p _{Infection × Genotype} = 0.0473; Figure 9B ). In terms of 1000-grain weight, non-infected Sakha 101 had the highest 1000-grain weight (28.2 ± 0.20 g) whereas infected Giza 178 had the lowest value (15.00 ± 0.20 g) (p _{Infection × Genotype}< 0.0001; Figure 9C ). Finally, R. solani-infected Giza 181 recorded the highest number of discolored grains (28.00 ± 0.20) whereas Giza 177 had the lowest number (6.00 ± 0.20) (p _{Infection × Genotype}< 0.0001; Figure 9D ).

The behavior of mycelium growth on different genotypes varies due to the genetic background of each genotype ( Figures 10A–L ). Only growing mycelium was noticed on Egyptian hybrid 1, Giza 182, and Egyptian Yasmine ( Figures 10D, E, G ). The growing mycelium started to branch outside the sheath, as in Giza 177 ( Figure 10A ). The branching mycelium penetrated the stem and branched inside it as in Giza 178 and Giza 183, ( Figures 10B, F ), then the mycelium shrank as in Giza 181 and Sakha 108 and Super 300 ( Figures 10C, K, L respectively), and converted to mycelium cushion as in Sakha 101 ( Figure 10H ), finally formed sclerotia as in Sakha 104 ( Figure 10I ). So, the fungus can invade the sheath of Sakha 104 faster than the other genotypes. It was observed that there was more branching and growth density of the fungus on the Japanese types, especially the Sakha 104, where there was a significant development in the growth of the mycelium and its transformation into a cushion, as well as the formation of sclerotia on the sheath’s surface ( Figure 10J ).

Out of the 12 tested SSR markers ( Figure 11A ), 11 SSR markers were polymorphic, and among them, only three markers differentiated between the resistance and susceptible genotypes. Furthermore, these markers, RM202, RM426, and RM6971, showed a specific band (~300, ~144, and ~152bp), respectively, for the resistance genotypes (Egyptian Yasmine and Giza 182) ( Figure 11A ). The SSR—based phylogenetic tree was divided into three main clades ( Figure 11B ). Clade I contained only two resistant genotypes (Giza 182 and Egyptian Yasmine), Clade II contained four moderately resistant genotypes (Giza 181, Giza 183, Giza 178, Egyptian Hybrid 1), and Clade III contained five susceptible genotypes (Sakha Super 300, Giza 177, Sakha 101, Sakha 104, Sakha 108). Finally, these three SSR markers, RM202, RM426, and RM6971, could be used in a breeding program for sheath blight resistance. Collectively, these findings suggest the high specificity of RM202, RM426, and RM6971 markers, as well as their potential utilization in breeding programs since they uniquely differentiate between resistant and susceptible rice genotypes.