Browsing by Author "Surendra Pratap Singh"

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Development of Allium cepa potential intron polymorphism markers for molecular breeding of Alliums
(Elsevier B.V., 2024) Kuldip Jayaswall; R. Sagar; Deepanshu Jayaswal; Akash Kumar; Surendra Pratap Singh; Romit Seth; Himanshu Sharma; Deepesh Kumar; Vijay Mahajan; Sanjay Kumar; Major Singh
Allium cepa is a widely grown crop for its spice and culinary properties. For molecular breeding of Allium cepa, mining and utilization of various sequence-based markers have been widely reported. Unfortunately, none has reported its molecular breeding using potential intron polymorphism (PIP) markers. Due to advantage of intron positioning prediction and practical utility, the PIP markers used for screening the possible polymorphism and cross-transferability in the Alliums. Screening results showed that among 500 Allium cepa potential intron polymorphism (AcPIP) markers, 275 are cross-transferable and polymorphic. Among the 275 AcPIP, 111 polymorphic markers were physically mapped on to 1st to 8th chromosomes of the Allium cepa. Out of the 275 AcPIP containing functionally significant markers, 118 were mapped in onion with Arabidopsis proteome. A set of 10 Alliums were utilized to interpret the polymorphic possibilities of the 500 AcPIP markers. In totality, 55 % AcPIP markers were polymorphic and cross-transferable among the Alliums. The polymorphic information content (PIC) of AcPIP markers ranged from 0.03 to 0.47 and heterozygosity index (H) varied between 0.16 and 0.80. The constructed phylogenetic tree based on the AcPIP markers of 10 Alliums revealed different clusters due to differences in their taxonomic positions. Out of 275 AcPIP markers, 10 AcPIP markers genotyping based Jaccard dissimilarity-based NJ tree of 96 individuals of Allium cepa showed two distinct groups (high total soluble solid; HTSS and low total soluble solid; LTSS). NJ tree and dissimilarity matrix reveal that group I genotypes are distinct, and dissimilar from group II and III genotypes hence it seems that group II and III genotype evolve from group I genotypes. Further we identified nine diverse Allium cepa subsample among which, genotype number 74 has HTSS and could be used for identification and introgression of HTSS coding genes in elite cultivars. Further DNA fingerprint of Alliums with 20 AcPIP markers suggested geographical reach of the released onion varieties. Hence results suggest that 275 AcPIP markers may be useful for accelerating the breeding programme of the Alliums and other species. © 2023 SAAB
Dicarboxylate transporters of Azospirillum brasilense Sp7 play an important role in the colonization of finger millet (Eleusine coracana) roots
(American Phytopathological Society, 2019) Vijay Shankar Singh; Prajna Tripathi; Parul Pandey; Durgesh Narain Singh; Basant Kumar Dubey; Chhaya Singh; Surendra Pratap Singh; Rachana Pandey; Anil Kumar Tripathi
Azospirillum brasilense is a plant growth-promoting bacterium that colonizes the roots of a large number of plants, including C3 and C4 grasses. Malate has been used as a preferred source of carbon for the enrichment and isolation Azospirillum spp., but the genes involved in their transport and utilization are not yet characterized. In this study, we investigated the role of the two types of dicarboxylate transporters (DctP and DctA) of A. brasilense in their ability to colonize and promote growth of the roots of a C4 grass. We found that DctP protein was distinctly upregulated in A. brasilense grown with malate as sole carbon source. Inactivation of dctP in A. brasilense led to a drastic reduction in its ability to grow on dicarboxylates and form cell aggregates. Inactivation of dctA, however, showed a marginal reduction in growth and flocculation. The growth and nitrogen fixation of a dctP and dctA double mutant of A. brasilense were severely compromised. We have shown here that DctPQM and DctA transporters play a major and a minor role in the transport of C4-dicarboxylates in A. brasilense, respectively. Studies on inoculation of the seedlings of a C4 grass, Eleusine corcana, with A. brasilense and its dicarboxylate transport mutants revealed that dicarboxylate transporters are required by A. brasilense for an efficient colonization of plant roots and their growth. © 2019 The American Phytopathological Society.
Engineering D-glucose utilization in Azospirillum brasilense Sp7 promotes rice root colonization
(Springer Science and Business Media Deutschland GmbH, 2022) Vijay Shankar Singh; Basant Kumar Dubey; Sushant Rai; Surendra Pratap Singh; Anil Kumar Tripathi
Abstract: Bacteria of the genus Azospirillum include several plant associated bacteria which often promote the growth of their host plants. Although the host range of Azospirillum brasilense Sp7 is much wider than its close relative Azospirillum lipoferum 4B, it lacks the ability to efficiently utilize D-glucose for its growth. By comparing the genomes of both the species, the genes of A. lipoferum 4B responsible for conferring D-glucose utilization ability in A. brasilese Sp7 were identified by cloning individual or a combination of genes in a broad host range expression vector, mobilizing them in A. brasilense Sp7 and examining the ability of exconjugants to use D-glucose as sole carbon source for growth. These genes also included the homologs of genes involved in N-acetyl glucosamine utilization in Pseudomonas aeruginosa PAO1. A transcriptional fusion of the 5 genes encoding glucose-6-phosphate dehydrogenase and 4 components of glucose phosphotransferase system were able to improve D-glucose utilization ability in A. brasilense Sp7. The A. brasilense Sp7 strain engineered with D-glucose utilization ability showed significantly improved root colonization of rice seedling. The improvement in the ability of A. brasilense Sp7 to colonize rice roots is expected to bring benefits to rice by promoting its growth. Key points: • Genes required for glucose utilization in Azospirillum lipoferum were identified. • A gene cassette encoding glucose utilization was constructed. • Transfer of gene cassette in A. brasilense improves glucose utilization and rice root colonization. © 2022, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.
GABA: a key player of abiotic stress regulation
(Taylor and Francis Ltd., 2023) Vipul Mishra; Priya Gahlowt; Samiksha Singh; Nawal Kishore Dubey; Surendra Pratap Singh; Durgesh Kumar Tripathi; Vijay Pratap Singh
Abiotic stress is considered as the main culprit for reduction of global food production. Recent studies have reported GABA as a major regulator of abiotic stress and thus opening new avenues in research on emerging roles of GABA in abiotic stress acclimation in plants. © 2023 The Author(s). Published with license by Taylor & Francis Group, LLC.
Immunomodulator and marker-assisted identification of Allium genotypes containing immunological memory against anthracnose
(Academic Press, 2025) Kuldip Jayaswall; Deepesh Kumar; Deepanshu Jayaswal; Ram Sagar; Sanjay Kumar; Ram Kumar Sharma; Kiran Pandurang Bhagat; Vijay M. Mahajan; Himanshu Sharma; Surendra Pratap Singh; Isha Sharma
Allium cepa (onion) suffers significant yield losses due to anthracnose disease caused by Colletotrichum gloeosporioides. Current control methods, such as biocontrol agents, have limited effectiveness, while agrochemical applications pose risks to human health and the environment. Genomics-assisted breeding can be useful in getting a diverse genetic pool of wild Allium species to improve disease resistance in cultivated varieties. In this study, we used 42 intron length polymorphic and 22 chloroplast-based SSR markers to identify wild Alliums for anthracnose resistance. Genetic analysis using the marker data showed that two wild types, 6AfistAKO-17 and 15Afistul, are very different from the cultivated types. Immunomodulator benzo-thiadiazole-7-carbothioic acid S-methyl ester evoked a long-lasting immune response in wild Alliums. Transcriptome profiling showed that 131 immune-related genes were more than twice as active in wild Alliums compared to cultivated ones. These included MAPKs (7 genes), WRKY transcription factors (10), R genes (19), MYB transcription factors (28), cytochrome P450s (46), transcriptional activators (14), and other immune-associated genes (7). The results from the anatomical analysis showed that wild Alliums have more callose in their vascular bundles, thicker wax on their leaf surfaces, and closed stomata, which were confirmed by fluorescence and scanning electron microscopy, indicating that wild Alliums have a stronger immune system than the cultivated Alliums. Our findings suggest that wild Alliums possess both immunity and immune memory-related genes. This study suggests that molecular markers could help transfer the immunity-related genes from wild Alliums to cultivated Alliums to protect them from anthracnose infestation. © 2025 Elsevier Ltd
Silencing of sterol glycosyltransferases modulates the withanolide biosynthesis and leads to compromised basal immunity of Withania somnifera
(Nature Publishing Group, 2016) Gaurav Singh; Manish Tiwari; Surendra Pratap Singh; Surendra Singh; Prabodh Kumar Trivedi; Pratibha Misra
Sterol glycosyltransferases (SGTs) catalyse transfer of glycon moiety to sterols and their related compounds to produce diverse glyco-conjugates or steryl glycosides with different biological and pharmacological activities. Functional studies of SGTs from Withania somnifera indicated their role in abiotic stresses but details about role under biotic stress are still unknown. Here, we have elucidated the function of SGTs by silencing SGTL1, SGTL2 and SGTL4 in Withania somnifera. Down-regulation of SGTs by artificial miRNAs led to the enhanced accumulation of withanolide A, withaferin A, sitosterol, stigmasterol and decreased content of withanoside V in Virus Induced Gene Silencing (VIGS) lines. This was further correlated with increased expression of WsHMGR, WsDXR, WsFPPS, WsCYP710A1, WsSTE1 and WsDWF5 genes, involved in withanolide biosynthesis. These variations of withanolide concentrations in silenced lines resulted in pathogen susceptibility as compared to control plants. The infection of Alternaria alternata causes increased salicylic acid, callose deposition, superoxide dismutase and H2 O2 in aMIR-VIGS lines. The expression of biotic stress related genes, namely, WsPR1, WsDFS, WsSPI and WsPR10 were also enhanced in aMIR-VIGS lines in time dependent manner. Taken together, our observations revealed that a positive feedback regulation of withanolide biosynthesis occurred by silencing of SGTLs which resulted in reduced biotic tolerance. © 2016, Nature Publishing Group. All rights reserved.