Department Of Botany

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Drought priming evokes essential regulation of Hsp gene families, Hsfs and their related miRNAs and induces heat stress tolerance in chickpea
(Elsevier B.V., 2023-07-26T00:00:00) Juneja, Sumandeep; Saini, Rashmi; Adhikary, Arindam; Yadav, Renu; Khan, Shahied Ahmed; Nayyar, Harsh; Kumar, Sanjeev
Optimum temperature is crucial for plant's survival. During high temperature stress, heat shock proteins (Hsps) are expressed many folds essentially controlled by explicit heat shock factors (Hsfs).We have narrowed key HSPs, related HSFs and miRNAs regulated after priming with drought stress and consequent heat stress in chickpea. Firstly, we identified Hsf and Hsp gene families in desi and kabuli chickpea using Genome-wide analysis. Thereafter, selected Hsfs, Hsps and related miRNAs were analyzed using qRT-PCR in contrasting chickpea varieties (PBG1 and PBG5) after drought priming and exposing at 32 �C 24 hrs, 35 �C 12 hrs, and 38 �C 6 hrs. An interaction network between Hsfs and Hsps was generated. 18 & 17 Hsfs and 42 & 34 Hsps were identified in the desi and kabuli, respectively. The gene structure and motif composition of the genes were found to be conserved in all subfamilies. A total of 32 heat shock genes were found to have undergone duplication. Most of the CaHsf and CaHsp genes were differentially expressed on exposure to a combination of drought priming and heat stress in both in-silico and qPCR analysis. Targeted miRNAs expression was coordinated with the respective genes. miR156, miR166, miR319, miR171, and miR5213 were identified to be targets of sHsps, Hsfs, and Hsps. The protein-protein interaction revealed that CaHsp18.2 and CaHsp70 might be controlled by CaHsfsA1. Drought priming strongly correlated with less membrane damage and better leaf water content. Higher harvest index and root shoot ratio significantly indicated effectiveness of priming and essential role of Hsf and Hsp and related miRNAs in heat stress tolerance. � 2023
Drought priming evokes essential regulation of Hsp gene families, Hsfs and their related miRNAs and induces heat stress tolerance in chickpea
(Elsevier B.V., 2023-07-26T00:00:00) Juneja, Sumandeep; Saini, Rashmi; Adhikary, Arindam; Yadav, Renu; Khan, Shahied Ahmed; Nayyar, Harsh; Kumar, Sanjeev
Optimum temperature is crucial for plant's survival. During high temperature stress, heat shock proteins (Hsps) are expressed many folds essentially controlled by explicit heat shock factors (Hsfs).We have narrowed key HSPs, related HSFs and miRNAs regulated after priming with drought stress and consequent heat stress in chickpea. Firstly, we identified Hsf and Hsp gene families in desi and kabuli chickpea using Genome-wide analysis. Thereafter, selected Hsfs, Hsps and related miRNAs were analyzed using qRT-PCR in contrasting chickpea varieties (PBG1 and PBG5) after drought priming and exposing at 32 �C 24 hrs, 35 �C 12 hrs, and 38 �C 6 hrs. An interaction network between Hsfs and Hsps was generated. 18 & 17 Hsfs and 42 & 34 Hsps were identified in the desi and kabuli, respectively. The gene structure and motif composition of the genes were found to be conserved in all subfamilies. A total of 32 heat shock genes were found to have undergone duplication. Most of the CaHsf and CaHsp genes were differentially expressed on exposure to a combination of drought priming and heat stress in both in-silico and qPCR analysis. Targeted miRNAs expression was coordinated with the respective genes. miR156, miR166, miR319, miR171, and miR5213 were identified to be targets of sHsps, Hsfs, and Hsps. The protein-protein interaction revealed that CaHsp18.2 and CaHsp70 might be controlled by CaHsfsA1. Drought priming strongly correlated with less membrane damage and better leaf water content. Higher harvest index and root shoot ratio significantly indicated effectiveness of priming and essential role of Hsf and Hsp and related miRNAs in heat stress tolerance. � 2023
Drought priming induced thermotolerance in wheat (Triticum aestivum L.) during reproductive stage; a multifaceted tolerance approach against terminal heat stress
(Elsevier Masson s.r.l., 2023-06-23T00:00:00) Kumar, Rashpal; Adhikary, Arindam; Saini, Rashmi; Khan, Shahied Ahmed; Yadav, Manisha; Kumar, Sanjeev
In wheat (Triticum aestivum L.), terminal heat stress obstructs reproductive functioning eventually leading to yield loss. Drought priming during the vegetative stage can trigger a quicker and effective defense response against impending high temperature stress and improve crop production. In the present study, two contrasting wheat cultivars (PBW670 and C306) were subjected to moderate drought stress of 50�55% ?eld capacity for eight days during the jointing stage to generate drought priming (DP) response. Fifteen days after anthesis heat stress (36 �C) was imposed for three days and physiological response of primed, and non-primed plants was assessed by analyzing membrane damage, water status and antioxidative enzymes. Heat shock transcription factors (14 TaHSFs), calmodulin (TaCaM5), antioxidative genes (TaSOD, TaPOX), polyamine biosynthesis genes and glutathione biosynthesis genes were analyzed. GC-MS based untargeted metabolite profiling was carried out to underpin the associated metabolic changes. Yield related parameters were recorded at maturity to finally assess the priming response. Heat stress response was visible from day one of exposure in terms of membrane damage and elevated antioxidative enzymes activity. DP reduced the impact of heat stress by lowering the membrane damage (ELI, MDA & LOX) and enhancing antioxidative enzyme activity except APX in both the cultivars. Drought priming upregulated the expression of HSFs, calmodulin, antioxidative genes, polyamines, and the glutathione biosynthesis genes. Drought priming altered key amino acids, carbohydrate, and fatty acid metabolism in PBW670 but also promoted thermotolerance in C306. Overall, DP provided a multifaceted approach against heat stress and positive association with yield. � 2023 Elsevier Masson SAS
Drought priming induced thermotolerance in wheat (Triticum aestivum L.) during reproductive stage; a multifaceted tolerance approach against terminal heat stress
(Elsevier Masson s.r.l., 2023-06-23T00:00:00) Kumar, Rashpal; Adhikary, Arindam; Saini, Rashmi; Khan, Shahied Ahmed; Yadav, Manisha; Kumar, Sanjeev
In wheat (Triticum aestivum L.), terminal heat stress obstructs reproductive functioning eventually leading to yield loss. Drought priming during the vegetative stage can trigger a quicker and effective defense response against impending high temperature stress and improve crop production. In the present study, two contrasting wheat cultivars (PBW670 and C306) were subjected to moderate drought stress of 50�55% ?eld capacity for eight days during the jointing stage to generate drought priming (DP) response. Fifteen days after anthesis heat stress (36 �C) was imposed for three days and physiological response of primed, and non-primed plants was assessed by analyzing membrane damage, water status and antioxidative enzymes. Heat shock transcription factors (14 TaHSFs), calmodulin (TaCaM5), antioxidative genes (TaSOD, TaPOX), polyamine biosynthesis genes and glutathione biosynthesis genes were analyzed. GC-MS based untargeted metabolite profiling was carried out to underpin the associated metabolic changes. Yield related parameters were recorded at maturity to finally assess the priming response. Heat stress response was visible from day one of exposure in terms of membrane damage and elevated antioxidative enzymes activity. DP reduced the impact of heat stress by lowering the membrane damage (ELI, MDA & LOX) and enhancing antioxidative enzyme activity except APX in both the cultivars. Drought priming upregulated the expression of HSFs, calmodulin, antioxidative genes, polyamines, and the glutathione biosynthesis genes. Drought priming altered key amino acids, carbohydrate, and fatty acid metabolism in PBW670 but also promoted thermotolerance in C306. Overall, DP provided a multifaceted approach against heat stress and positive association with yield. � 2023 Elsevier Masson SAS
Drought priming induces chilling tolerance and improves reproductive functioning in chickpea (Cicer arietinum L.)
(Springer Science and Business Media Deutschland GmbH, 2022-08-02T00:00:00) Saini, Rashmi; Das, Rangman; Adhikary, Arindam; Kumar, Rashpal; Singh, Inderjit; Nayyar, Harsh; Kumar, Sanjeev
Key message: Priming alleviates membrane damage, chlorophyll degradation along with cryoprotectants accumulation during chilling stress that leads to improved reproductive functioning and increased seed yield. Abstract: Chilling temperatures below 15��C have severe implications on the reproductive growth and development of chickpea. The abnormal reproductive development and subsequent reproductive failure lead to substantial yield loss. We exposed five chickpea cultivars (PBG1, GPF2, PDG3, PDG4, and PBG5) to drought stress (Priming) during the vegetative stage and analyzed for chilling tolerance during the reproductive stage. These varieties were raised in the fields in two sets: one set of plants were subjected to drought stress at the vegetative stage for 30�days (priming) and the second set of plants were irrigated regularly (non-primed). The leaf samples were harvested at the flowering, podding, and seed filling stage and analyzed for membrane damage, water status, chlorophyll content, cellular respiration, and certain cryoprotective solutes. The reproductive development was analyzed by accessing pollen viability, in vivo and in vitro germination, pollen load, and in vivo pollen tube growth. Principal component analysis (PCA) revealed that priming improved membrane damage, chlorophyll b degradation, and accumulation of cryoprotectants in GPF2, PDG3, and PBG5 at the flowering stage (< 15��C). Pearson's correlation analysis showed a negative correlation with the accumulation of proline and carbohydrates with flower, pod, and seed abortion. Only, PBG5 responded best to priming while PBG1 was worst. In PBG5, priming resulted in reduced membrane damage and lipid peroxidation, improved water content, reduced chlorophyll degradation, and enhanced cryoprotective solutes accumulation, which led to increased reproductive functioning and finally improved seed yield and harvest index. Lastly, the priming response is variable and cultivar-specific but overall improve plant tolerance. � 2022, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.
Drought priming induces chilling tolerance and improves reproductive functioning in chickpea (Cicer arietinum L.)
(Springer Science and Business Media Deutschland GmbH, 2022-08-02T00:00:00) Saini, Rashmi; Das, Rangman; Adhikary, Arindam; Kumar, Rashpal; Singh, Inderjit; Nayyar, Harsh; Kumar, Sanjeev
Key message: Priming alleviates membrane damage, chlorophyll degradation along with cryoprotectants accumulation during chilling stress that leads to improved reproductive functioning and increased seed yield. Abstract: Chilling temperatures below 15��C have severe implications on the reproductive growth and development of chickpea. The abnormal reproductive development and subsequent reproductive failure lead to substantial yield loss. We exposed five chickpea cultivars (PBG1, GPF2, PDG3, PDG4, and PBG5) to drought stress (Priming) during the vegetative stage and analyzed for chilling tolerance during the reproductive stage. These varieties were raised in the fields in two sets: one set of plants were subjected to drought stress at the vegetative stage for 30�days (priming) and the second set of plants were irrigated regularly (non-primed). The leaf samples were harvested at the flowering, podding, and seed filling stage and analyzed for membrane damage, water status, chlorophyll content, cellular respiration, and certain cryoprotective solutes. The reproductive development was analyzed by accessing pollen viability, in vivo and in vitro germination, pollen load, and in vivo pollen tube growth. Principal component analysis (PCA) revealed that priming improved membrane damage, chlorophyll b degradation, and accumulation of cryoprotectants in GPF2, PDG3, and PBG5 at the flowering stage (< 15��C). Pearson's correlation analysis showed a negative correlation with the accumulation of proline and carbohydrates with flower, pod, and seed abortion. Only, PBG5 responded best to priming while PBG1 was worst. In PBG5, priming resulted in reduced membrane damage and lipid peroxidation, improved water content, reduced chlorophyll degradation, and enhanced cryoprotective solutes accumulation, which led to increased reproductive functioning and finally improved seed yield and harvest index. Lastly, the priming response is variable and cultivar-specific but overall improve plant tolerance. � 2022, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.
Drought priming triggers diverse metabolic adjustments and induces chilling tolerance in chickpea (Cicer arietinum L.)
(Elsevier Masson s.r.l., 2022-11-30T00:00:00) Saini, Rashmi; Adhikary, Arindam; Juneja, Sumandeep; Kumar, Rashpal; Singh, Inderjit; Nayyar, Harsh; Kumar, Sanjeev
Chickpea (Cicer arietinum L.) suffers from chilling stress at the reproductive stage (<15 �C) which leads to significant yield loss. This study presents a comprehensive plant response to drought priming and its effect on chilling tolerance during the reproductive stage in two chickpea cultivars PBG1 and PBG5. Lipidome profiling (Fatty acid methyl esters analysis), metabolome profiling (GC-MS based untargeted analysis), fatty acid desaturases and antioxidative gene expression (qRT-PCR) were analyzed to monitor physiological and biochemical events after priming during flowering, podding and seed filling stages. Drought priming alleviated membrane damage and chlorophyll degradation by increasing membrane unsaturated fatty acids (18:3) along with up-regulation of various fatty acid desaturases (CaFADs) genes and antioxidative machinery during flowering and improved seed yield in PBG5. PCA, HCA, and KEGG pathway analysis of 87 identified metabolites showed that metabolites were regulated differently in both cultivars under non-primed and primed conditions. The plant response was more apparent at flowering and podding stages which coincided with chilling temperature (<15 �C). Drought priming stimulated many important genes, especially FADs, antioxidative proteins and accumulation of key metabolites (proline and TCA intermediates) required for defense especially in PBG5. This explains that plant's response to drought priming not only depends on developmental stage, and temperature regime (<15 �C) but also on the genotypic-specificity. � 2022 Elsevier Masson SAS
Drought priming triggers diverse metabolic adjustments and induces chilling tolerance in chickpea (Cicer arietinum L.)
(Elsevier Masson s.r.l., 2022-11-30T00:00:00) Saini, Rashmi; Adhikary, Arindam; Juneja, Sumandeep; Kumar, Rashpal; Singh, Inderjit; Nayyar, Harsh; Kumar, Sanjeev
Chickpea (Cicer arietinum L.) suffers from chilling stress at the reproductive stage (<15 �C) which leads to significant yield loss. This study presents a comprehensive plant response to drought priming and its effect on chilling tolerance during the reproductive stage in two chickpea cultivars PBG1 and PBG5. Lipidome profiling (Fatty acid methyl esters analysis), metabolome profiling (GC-MS based untargeted analysis), fatty acid desaturases and antioxidative gene expression (qRT-PCR) were analyzed to monitor physiological and biochemical events after priming during flowering, podding and seed filling stages. Drought priming alleviated membrane damage and chlorophyll degradation by increasing membrane unsaturated fatty acids (18:3) along with up-regulation of various fatty acid desaturases (CaFADs) genes and antioxidative machinery during flowering and improved seed yield in PBG5. PCA, HCA, and KEGG pathway analysis of 87 identified metabolites showed that metabolites were regulated differently in both cultivars under non-primed and primed conditions. The plant response was more apparent at flowering and podding stages which coincided with chilling temperature (<15 �C). Drought priming stimulated many important genes, especially FADs, antioxidative proteins and accumulation of key metabolites (proline and TCA intermediates) required for defense especially in PBG5. This explains that plant's response to drought priming not only depends on developmental stage, and temperature regime (<15 �C) but also on the genotypic-specificity. � 2022 Elsevier Masson SAS
Unravelling cross priming induced heat stress, combinatorial heat and drought stress response in contrasting chickpea varieties
(Elsevier Masson s.r.l., 2022-04-01T00:00:00) Yadav, Renu; Saini, Rashmi; Adhikary, Arindam; Kumar, Sanjeev
Drought and high temperature stress affect chickpea growth and productivity. Often these stresses occur simultaneously in the field and lead to a wide range of molecular and metabolic adaptations. Two chickpea varieties; GPF2 (heat sensitive) and PDG4 variety (heat tolerant) were exposed to 35 �C for 24 h individually and along with drought stress. Five heat responsive signalling genes and 11 structural genes were analyzed using qPCR along with untargeted metabolites analysis using GC MS. Expression of antioxidant genes (CaSOD and CaGPX, CaAPX and CaCAT), transcription factors (CaHSFB2, CaHSFB2A, CaHSFB2B, CaHSP17.5 and CaHSP22.7) and signalling genes (CaCAM, CaGAD, and CaMAPK) were upregulated in GPF2 as compared to PDG4 variety. Principal component analysis (PCA), partial least-square discriminant analysis (PLS-DA), and heat map analysis were applied to the metabolomics data to identify the differential response of metabolites in two chickpea varieties. GC-MS analysis identified 107 and 83 metabolites in PDG4 and GPF2 varieties respectively. PDG4 variety accumulated more sugars, amino acids, sugar alcohols, TCA cycle intermediates which provided heat resistance. Additionally, the differential metabolic pathways involved in heat tolerance were alanine, aspartate, and glutamate metabolism, pantothenate CoA biosynthesis, fructose and mannose metabolism and pentose phosphate pathway in PDG4 variety. There was less accumulation of metabolites in the primed plants of both varieties as compared to the non-primed plants indicating less damage due to heat stress. The present study gives an overview of the molecular changes occurring in response to heat stress in sensitive and tolerant chickpea. � 2022 Elsevier Masson SAS
Unravelling cross priming induced heat stress, combinatorial heat and drought stress response in contrasting chickpea varieties
(Elsevier Masson s.r.l., 2022-04-01T00:00:00) Yadav, Renu; Saini, Rashmi; Adhikary, Arindam; Kumar, Sanjeev
Drought and high temperature stress affect chickpea growth and productivity. Often these stresses occur simultaneously in the field and lead to a wide range of molecular and metabolic adaptations. Two chickpea varieties; GPF2 (heat sensitive) and PDG4 variety (heat tolerant) were exposed to 35 �C for 24 h individually and along with drought stress. Five heat responsive signalling genes and 11 structural genes were analyzed using qPCR along with untargeted metabolites analysis using GC MS. Expression of antioxidant genes (CaSOD and CaGPX, CaAPX and CaCAT), transcription factors (CaHSFB2, CaHSFB2A, CaHSFB2B, CaHSP17.5 and CaHSP22.7) and signalling genes (CaCAM, CaGAD, and CaMAPK) were upregulated in GPF2 as compared to PDG4 variety. Principal component analysis (PCA), partial least-square discriminant analysis (PLS-DA), and heat map analysis were applied to the metabolomics data to identify the differential response of metabolites in two chickpea varieties. GC-MS analysis identified 107 and 83 metabolites in PDG4 and GPF2 varieties respectively. PDG4 variety accumulated more sugars, amino acids, sugar alcohols, TCA cycle intermediates which provided heat resistance. Additionally, the differential metabolic pathways involved in heat tolerance were alanine, aspartate, and glutamate metabolism, pantothenate CoA biosynthesis, fructose and mannose metabolism and pentose phosphate pathway in PDG4 variety. There was less accumulation of metabolites in the primed plants of both varieties as compared to the non-primed plants indicating less damage due to heat stress. The present study gives an overview of the molecular changes occurring in response to heat stress in sensitive and tolerant chickpea. � 2022 Elsevier Masson SAS