Comparative proteomics and gene expression analyses revealed responsive proteins and mechanisms for salt tolerance in chickpea genotypes

Arefian, Mohammad; Vessal, Saeedreza; Malekzadeh-Shafaroudi, Saeid; Siddique, Kadambot H. M.; Bagheri, Abdolreza

doi:10.1186/s12870-019-1793-z

Cited by 52 publications

(37 citation statements)

References 81 publications

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“…In recent years, the evidence of an existing genetic diversity in terms of seed protein composition was exploited in cultivated pulses, including chickpeas [8,17,27,28]. Most of the information on pulse protein composition was obtained by electrophoretic separation and is relative to genetic diversity [8,29,30], while less data are available on the effect of environmental [31] or agronomic factors [32]. In our study, the interaction of genotypic factor under different crop managements (organic vs. conventional) showed a marked significant variability.…”

Section: Discussionmentioning

confidence: 60%

Influence of Organic and Conventional Farming on Grain Yield and Protein Composition of Chickpea Genotypes

et al. 2021

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Chickpea is a key crop in sustainable cropping systems and for its nutritional value. Studies on agronomic and genetic influences on chickpea protein composition are missing. In order to obtain a deep insight into the genetic response of chickpeas to management in relation to agronomic and quality traits, a two-year field trial was carried out with eight chickpea genotypes under an organic and conventional cropping system. Protein composition was assessed by SDS-PAGE in relation to the main fractions (vicilin, convicilin, legumin, lectin, 2s-albumin). Crop response was highly influenced by year and presumably also by management, with a −50% decrease in grain yield under organic farming, mainly due to a reduction in seed number per m2. No effect of crop management was observed on protein content, despite significant differences in terms of protein composition. The ratio between the major globulins, 7s vicilin and 11s legumin, showed a negative relationship with grain yield and was found to be higher under organic farming. Among genotypes, black-seed Nero Senise was characterized by the highest productivity and water-holding capacity, associated with low lectin content. These findings highlight the importance of the choice of chickpea genotypes for cultivation under organic farming in relation to both agronomic performance and technological and health quality.

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Section: Discussionmentioning

confidence: 60%

Influence of Organic and Conventional Farming on Grain Yield and Protein Composition of Chickpea Genotypes

et al. 2021

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“…The fine tuning of plant lipid profile is a key tool in crop adaption to environmental changes, but the process by which lipid contouring modulates a respond to salt stress is not clear [101,102]. Salinity causes structural changes in the lipid composition of the plasma membrane, like increasing the degree of free fatty acid saturation and enhancing concentration of free sterols, leading to a reduction in cellular membrane fluidity [103].…”

Section: Lipid Metabolismmentioning

confidence: 99%

Current Advances in Plant Growth Promoting Bacteria Alleviating Salt Stress for Sustainable Agriculture

2020

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Humanity in the modern world is confronted with diverse problems at several levels. The environmental concern is probably the most important as it threatens different ecosystems, food, and farming as well as humans, animals, and plants. More specifically, salinization of agricultural soils is a global concern because of on one side, the permanent increase of the areas affected, and on the other side, the disastrous damage caused to various plants affecting hugely crop productivity and yields. Currently, great attention is directed towards the use of Plant Growth Promoting Bacteria (PGPB). This alternative method, which is healthy, safe, and ecological, seems to be very promising in terms of simultaneous salinity alleviation and improving crop productivity. This review attempts to deal with different aspects of the current advances concerning the use of PGPBs for saline stress alleviation. The objective is to explain, discuss, and present the current progress in this area of research. We firstly discuss the implication of PGPB on soil desalinization. We present the impacts of salinity on crops. We look for the different salinity origin and its impacts on plants. We discuss the impacts of salinity on soil. Then, we review various recent progress of hemophilic PGPB for sustainable agriculture. We categorize the mechanisms of PGPB toward salinity tolerance. We discuss the use of PGPB inoculants under salinity that can reduce chemical fertilization. Finally, we present some possible directions for future investigation. It seems that PGPBs use for saline stress alleviation gain more importance, investigations, and applications. Regarding the complexity of the mechanisms implicated in this domain, various aspects remain to be elucidated.

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“…In recent years, several proteomic studies on dehydration have focused on the extracellular matrix [ 19 , 20 ], cell nuclear [ 21 – 23 ], and seed germination [ 24 ] proteomes of chickpea seedlings. Proteome changes in chickpea have been investigated under other abiotic stresses, such as heat [ 25 ], salinity [ 26 , 27 ], and abscisic acid [ 28 ]. The extracellular matrix (ECM) is a dynamic structure that includes important signaling components for front-line defense.…”

Section: Introductionmentioning

confidence: 99%

Proteomic responses to progressive dehydration stress in leaves of chickpea seedlings

2020

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Background Chickpea is an important food legume crop with high protein levels that is widely grown in rainfed areas prone to drought stress. Using an integrated approach, we describe the relative changes in some physiological parameters and the proteome of a drought-tolerant (MCC537, T) and drought-sensitive (MCC806, S) chickpea genotype. Results Under progressive dehydration stress, the T genotype relied on a higher relative leaf water content after 3 and 5 d (69.7 and 49.3%) than the S genotype (59.7 and 40.3%) to maintain photosynthetic activities and improve endurance under stress. This may have been facilitated by greater proline accumulation in the T genotype than the S genotype (14.3 and 11.1 μmol g − 1 FW at 5 d, respectively). Moreover, the T genotype had less electrolyte leakage and lower malondialdehyde contents than the S genotype under dehydration stress, indicating greater membrane stability and thus greater dehydration tolerance. The proteomic analysis further confirmed that, in response to dehydration, the T genotype activated more proteins related to photosynthesis, stress response, protein synthesis and degradation, and gene transcription and signaling than the S genotype. Of the time-point dependent proteins, the largest difference in protein abundance occurred at 5 d, with 29 spots increasing in the T genotype and 30 spots decreasing in the S genotype. Some of the identified proteins—including RuBisCo, ATP synthase, carbonic anhydrase, psbP domain-containing protein, L-ascorbate peroxidase, 6-phosphogluconate dehydrogenase, elongation factor Tu, zinc metalloprotease FTSH 2, ribonucleoproteins and auxin-binding protein—may play a functional role in drought tolerance in chickpea. Conclusions This study highlights the significance of genotype- and time-specific proteins associated with dehydration stress and identifies potential resources for molecular drought tolerance improvement in chickpea.

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Comparative proteomics and gene expression analyses revealed responsive proteins and mechanisms for salt tolerance in chickpea genotypes

Cited by 52 publications

References 81 publications

Influence of Organic and Conventional Farming on Grain Yield and Protein Composition of Chickpea Genotypes

Influence of Organic and Conventional Farming on Grain Yield and Protein Composition of Chickpea Genotypes

Current Advances in Plant Growth Promoting Bacteria Alleviating Salt Stress for Sustainable Agriculture

Proteomic responses to progressive dehydration stress in leaves of chickpea seedlings

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