Now showing 1 - 6 of 6
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    Understanding the facets of extreme land plant adaptation from transcriptome analysis
    (2023-10-18)
    Srivastava, Richa
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    Marik, Debankona
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    Meher, Subham
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    Sahoo, Lingaraj
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    Extremophile land plants have evolved convergently to become tough survivors in harsh soil and climatic conditions, such as extremes of soil pH, temperature, drought, high salinity, heavy metals, high light intensity, and UV radiation. Thus, the extremophile plants hold the potential key to improving stress-resilience in crop plants in the face of global climate change and desertification. Moreover, extremophile plants also exhibit industrial importance, being the source of active pharmaceuticals, new fuels, and essential chemicals. Transcriptome analysis of extremophiles is a common approach towards discovering genes and molecular mechanisms for adaptation to stress apart from identifying the pathways responsible for the biosynthesis of commercially essential metabolites. Again, the current scenario in extremophile research ranges from the study of extremophile plant models, e.g., Arabidopsis lyrata, to various plants of economic and ecological significance. The genetic signatures obtained from the transcriptome libraries of these extremophiles are utilized towards their conservation by employing the genome-editing approaches apart from extending their applicability towards the introgression of abiotic tolerance traits into agronomically important crop plants. This chapter aims to summarize the recent transcriptome analyses of extremophile species from the Indian Thar desert and other extreme eco-regions of the world.
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    How do plants remember drought?
    (2022-07-01) ;
    Prasad, Shiva Sai
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    Mitra, Jayeeta
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    Siddiqui, Nadeem
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    Sahoo, Lingaraj
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    Kobayashi, Yuriko
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    Koyama, Hiroyuki
    Main conclusion: Plants develop both short-term and transgenerational memory of drought stress through epigenetic regulation of transcription for a better response to subsequent exposure. Abstract: Recurrent spells of droughts are more common than a single drought, with intermittent moist recovery intervals. While the detrimental effects of the first drought on plant structure and physiology are unavoidable, if survived, plants can memorize the first drought to present a more robust response to the following droughts. This includes a partial stomatal opening in the watered recovery interval, higher levels of osmoprotectants and ABA, and attenuation of photosynthesis in the subsequent exposure. Short-term drought memory is regulated by ABA and other phytohormone signaling with transcriptional memory behavior in various genes. High levels of methylated histones are deposited at the drought-tolerance genes. During the recovery interval, the RNA polymerase is stalled to be activated by a pause-breaking factor in the subsequent drought. Drought leads to DNA demethylation near drought-response genes, with genetic control of the process. Progenies of the drought-exposed plants can better adapt to drought owing to the inheritance of particular methylation patterns. However, a prolonged watered recovery interval leads to loss of drought memory, mediated by certain demethylases and chromatin accessibility factors. Small RNAs act as critical regulators of drought memory by altering transcript levels of drought-responsive target genes. Further studies in the future will throw more light on the genetic control of drought memory and the interplay of genetic and epigenetic factors in its inheritance. Plants from extreme environments can give queues to understanding robust memory responses at the ecosystem level.
    Scopus© Citations 24
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    Identification of differentially expressed mungbean miRNAs and their targets in response to drought stress by small RNA deep sequencing
    (2022-06-01)
    Kumar, Sanjeev
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    Das, Mahesh
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    Sahoo, Lingaraj
    MicroRNAs (miRNAs) are small, non-coding RNAs, 18–25 nt in length, that play a crucial role in regulating genes associated with the physiological processes and responses to various biotic and abiotic stresses. Different conserved and species-specific microRNAs and their functions have been identified, primarily in plants such as rice and Arabidopsis with sequenced genomes. Our present study identifies drought-responsive miRNAs and their potential targets from mungbean under three days of drought stress induced by PEG-6000. We constructed small RNA libraries from both control and drought-treated tolerant and susceptible mungbean genotypes and identified various miRNAs involved in drought stress regulation. Analysis of differentially expressed genes (DEGs) revealed 79 up-regulated and 158 down-regulated novel miRNAs and two up-and down-regulated known miRNAs under drought. Annotation of the miRNAs followed by target prediction and expression analysis revealed five miRNAs, Vra-miR160, Vra-miR164, Vra-miR167, Vra-miR394, and Vra-miR398, were potentially involved in the regulation of drought-responsive genes. Their predicted target genes were an Auxin response factor (ARF), a NAC (for petunia NAM and Arabidopsis ATAF1, ATAF2, and CUC2) transcription factor, Serine acetyltransferase 1, and Multicopper oxidase LPR2-like. The expression of drought-responsive miRNAs and their targets were validated by real-time PCR. Our data suggest that various known and novel microRNAs activated transcription factors, enzyme kinases, and hormone signaling pathways alleviate drought stress in the tolerant K-851 genotype of mungbean.
    Scopus© Citations 8
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    Enhanced osmotic adjustment, antioxidant defense, and photosynthesis efficiency under drought and heat stress of transgenic cowpea overexpressing an engineered DREB transcription factor
    (2022-12-15)
    Kumar, Sanjeev
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    Muthuvel, J.
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    Kobayashi, Yuriko
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    Koyama, Hiroyuki
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    Sahoo, Lingaraj
    Cowpea is sensitive to drought and heat stress, particularly at the reproductive stages of development. Both stresses limit growth and yield, and their effect is more devastating when occurring concurrently. Dehydration-responsive element-binding protein 2A (DREB2A) is an important signaling hub integrating information about two different abiotic stresses, drought and heat. We identified VuDREB2A as a canonical DREB ortholog in cowpea, activating downstream stress-responsive genes by binding to DREs in their promoter. Post-translational modification of a negative regulatory domain (NRD) within the VuDREB2A protein prevents its degradation. Targeted deletion of the NRD produces a stable and constitutively active form VuDREB2A-CA. However, there is very little evidence of its practical utility under field conditions. This study overexpressed the VuDREB2A-CA in a popular cowpea variety and conducted drought- and heat-tolerance experiments across various stress regimes. Transgenic cowpea exhibited significant tolerance with consistently higher yield when exposed to over 30-d drought stress and 3-d exposure to high temperature (28 °C˗52 °C) without any pleiotropic alterations. The transgenic lines showed higher photosynthetic efficiency, osmotic adjustment, antioxidant defense, thermotolerance, and significantly higher survival and increased biomass than the wild type. Late embryogenesis abundant 5, heat shock protein 70, dehydrin, mitogen-activated protein kinase 2/4, isoflavonoid reductase, and myoinositol phosphate synthase were upregulated in transgenic lines under drought and heat stress. Through transcriptome analysis of the transgenic lines, we found significant up-regulation of various stress-responsive cowpea genes, having DRE in their promoter. Our results suggest that overexpression of VuDREB2A could improve cowpea production under drought and high temperatures.
    Scopus© Citations 2
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    Isolation and Characterization of Stress-Tolerant Priestia Species from Cowpea Rhizosphere Under Drought and Nutrient Deficit Conditions
    (2023-05-01)
    Abiala, Moses
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    Sahoo, Lingaraj
    This study aimed to isolate stress-tolerant phytobeneficial bacteria as bio-inoculants for cowpea's sustainable growth under drought and nutrient deficiency conditions. However, the application successful of phytobeneficial bacteria is subject to effective in vitro screening under different physiological conditions. We isolated several Priestia species from cowpea rhizosphere that tolerates polyethylene glycol (PEG6000)-induced drought and nutrient deficiency. Of them, C8 (Priestia filamentosa; basonym: Bacillus filamentosus), followed by C29 (Priestia aryabhattai; basonym: Bacillus aryabhattai), tolerated up to 20% PEG in a low-nutrient medium. In the presence of PEG, Priestia filamentosa and Bacillus aryabhattai exhibited optimal growth in different temperatures and pH but failed to survive at extreme temperatures of 45 °C and pH 11. Priestia filamentosa preferred L-proline and L-glutamate, while L-tryptophan and L-tyrosine were the least utilized. Interestingly, Priestia filamentosa and Bacillus aryabhattai used more complex nitrogen sources, peptone, and yeast extract, than inorganic nitrogen for growth. Most importantly, under drought and nutrient deficiency, Priestia filamentosa exhibited multiple plant growth-promoting traits and more amylase and protease production than C29. Our results indicate that Priestia filamentosa is a potential bacterium to enhance the growth of cowpea plants under stressful conditions.
    Scopus© Citations 1
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    Rhizosphere Priestia species altered cowpea root transcriptome and enhanced growth under drought and nutrient deficiency
    (2023-01-01)
    Abiala, Moses
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    Muthuvel, Jothi
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    Shekhawat, Rajveer Singh
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    Sahoo, Lingaraj
    Main Conclusion: Priestia species isolated from the cowpea rhizosphere altered the transcriptome of cowpea roots by colonization and enhanced nutrient uptake, antioxidant mechanisms, and photosynthesis, protecting cowpea from drought and nutrient deficiency. Abstract: Cowpea is a significant grain legume crop primarily grown in sub-Saharan Africa, Asia, and South America. Drought and nutrient deficiency affect the growth and yield of cowpea. To address this challenge, we studied the phyto-beneficial effects of stress-tolerant rhizobacteria on the biomass yield of cowpea under water- and nutrient-deficit conditions. Among the bacteria isolated, two rhizobacillus genotypes, C8 (Priestia filamentosa; basonym: Bacillus filamentosus) and C29 (Priestia aryabhattai; basonym: Bacillus aryabhattai) were evaluated for the improvement of seed germination and growth of cowpea under stress. Our study revealed that C8 protected cowpea from stress by facilitating phosphorus and potassium uptake, protecting it from oxidative damage, reducing transpiration, and enhancing CO2 assimilation. A 17% increase in root biomass upon C8 inoculation was concomitant with the induction of stress tolerance genes in cowpea roots predominantly involved in growth and metabolic processes, cell wall organization, ion homeostasis, and cellular responses to phosphate starvation. Our results indicate a metabolic alteration in cowpea root triggered by P. filamentosa, leading to efficient nutrient reallocation in the host plant. We propose inoculation with P. filamentosa as an effective strategy for improving the yield of cowpea in low-input agriculture, where chemical fertilization and irrigation are less accessible to resource-poor farmers.
    Scopus© Citations 4