Browsing by Author "Chung, Sang-Min"
Now showing 1 - 3 of 3
Results Per Page
Sort Options
Item Genome-wide analysis of the pleiotropic drug resistance (PDR) gene family and putative PDR specific miRNAs: deciphering their functions in development processes and varied stresses in Triticum aestivum L.(Springer Nature, 2026-01-13) Kesawat, Mahipal Singh; Kherawat, Bhagwat Singh; Reager, Madan Lal; Lenka, Sangram K.; Chung, Sang-Min; Masika, Fred BwayoBackground The pleiotropic drug resistance (PDR) transporter stands out as one of the largest subfamilies within ABC transporters. These transporters play crucial roles in a multitude of biological processes, including detoxification, phytohormone transportation, stomatal movement, the translocation of various secondary metabolites, tolerance to heavy metal and adaptation to the diverse stress conditions. However, the structural and functional characterization of PDR gene family members in wheat has yet to be fully elucidated. Results In this investigation, we identified 66 TaPDR genes in the genome of wheat. The subsequent phylogenetic tree revealed that the genes clustered into four subfamilies. Chromosomal mapping unveiled the dispersal of 66 TaPDR genes across 17 wheat chromosomes. The twenty-two pairs of duplicated gene were identified in the PDR family. Ka/Ks ratio revealed that 22 duplicated TaPDR genes went through purifying selection. It was noted that the TaPDR genes displayed significant diversity in their gene structures. In addition, the presence of numerous cis-regulatory elements in the promoter regions of the TaPDR genes were identified. Differential expression patterns were observed among TaPDR family members across various tissues and in response to multiple stress conditions. Moreover, this investigation explored the miRNAs targeting TaPDR genes and their expression profiles in various tissues. Conclusion Thus, the results of this study establish a strong basis for further investigation of the functions of TaPDR genes across different tissues, developmental stages, phytohormone responses, and diverse stress in wheat.Item Genome-wide survey and expression analysis of peptides containing tyrosine sulfation (PSY) gene family in Cicer arietinum L.(Springer Nature, 2026-02-21) Kesawat, Mahipal Singh; Kumar, Vinay; Manohar, Swati; Sohail, Aqib; Rani, Manjusha; Chung, Sang-Min; Kumar, Deepak; Lenka, Sangram K.; Masika, Fred BwayoBackground Plant growth and developmental processes are tightly regulated by small secreted peptides, however, the functions and mechanisms of Tyrosine Sulfation-containing Peptides (PSY) remain unclear. In chickpea, knowledge of PSY genes family is limited. Results This study employed comprehensive bioinformatics approaches to identify and characterize seven CaPSY genes in the chickpea genome. The analyses encompass chromosomal localization, evolutionary relationships, gene structure, conserved motif identification, promoter architecture, prediction of PSY-targeting miRNAs, and expression profiling. Chromosomal mapping revealed that CaPSY genes are confined to four specific chromosomes rather than being evenly distributed across the genome. Phylogenetic analysis resolved nine distinct groups, each further subdivided into subgroups. Additionally, CaPSY genes were found to contain one to two introns. Amino acid sequence comparisons demonstrated that each CaPSY gene consistently harbors a PSY domain in its C-terminal end. Promoter analysis of CaPSY genes revealed the presence of multiple hormone-responsive elements, including ABRE, SARE, AuxRE, and MeJARE, as well as stress-related elements such as the drought-responsive MBS, suggesting potential regulatory roles in development and stress adaptation. Further, the expression patterns of CaPSY were evaluated in multiple tissues as well as in response to abiotic stresses. The results indicated differential expression of CaPSY genes among tissues and under multiple abiotic stress conditions. We further detected several miRNAs likely to target CaPSY genes and assessed how they are expressed in different tissues. Conclusion Thus, these findings serve as a crucial resource for basic and applied research, enabling advancements in chickpea productivity and stress tolerance via precise genome editing and innovative breeding methods.Item Nanoparticles in plant system: A comprehensive review on their role in diverse stress management and phytohormone signaling(Elsevier, 2025-08-19) Kumar, Vinay; Naik, Islavath Suresh; Das, Bimal; Singh, Anupama; Nayak, Prayasi; Mohapatra, Chinmayee; Debnath, Debanjana; Tripathy, Maitreyee; Behera, Kumareswar; Masika, Fred Bwayo; Manohar, Swati; Chung, Sang-Min; Kherawat, Bhagwat Singh; Hemalatha, Mamidi; Kesawat, Mahipal SinghClimate variability has led to significant environmental shifts in recent years, placing growing strain on agricultural systems worldwide. These environmental fluctuations have magnified the effects of abiotic and biotic stresses on plants, substantially hampering their growth and lowering crop productivity. To tackle these challenges, there is an urgent need for innovative and effective strategies that promote sustainable agricultural practices. Among emerging technologies, nanotechnology has attracted significant interest for its transformative potential in agriculture. The application of nanoscale materials including nanopesticides, nanofungicides, nanofertilizers, and nanoherbicides offers promising avenues for enhancing crop protection and boost productivity. Nanoparticles (NPs) exhibit unique physicochemical properties that allow for precise and targeted delivery of nutrients and protective agents, thereby improving both the quality and yield of crops under diverse stress conditions. Phytohormone signaling pathways comprise intricate biochemical networks that enable plant hormones to regulate growth, development, and stress responses by transmitting and amplifying precise molecular signals. Recent studies suggest that NPs can alleviate stress-induced damage in plants by modulating phytohormone signaling pathways. However, the complex mechanisms underlying the interactions between NPs and phytohormone biosynthesis remain largely unexplored. This review offers a comprehensive overview of nanoparticle synthesis methods, types, and characterization techniques, with particular emphasis on their potential for mitigating both abiotic and biotic stresses. In addition, the article explores the role of NPs in plant pathology, particularly in disease detection and management. It also highlights emerging evidence on the impact of NPs on phytohormone signaling pathways, which are crucial for improving plant resilience and productivity in stress-prone environments. Thus, nanotechnology holds considerable promise for alleviating stress-related challenges and improving crop yields. A deeper understanding of NP–phytohormone interactions is crucial for developing safe and effective nanotechnological strategies to advance sustainable agriculture