Biochemical and Physiological Traits of Pinto Bean (Phaseolus vulgaris) Lines Affected by Drought Stress: A Comprehensive Analysis
Subject Areas : Plant Physiology
Zeinab Sadat Hashemi
1
,
Heshmat Omidi
2
,
Amir Bostani
3
,
Hamidreza Dorri
4
1 -
2 -
3 -
4 -
Keywords: Antioxidant activity, Proline content, Seed yield, Total chlorophyll, Water-limited.,
Abstract :
Determining the influential physiological and biochemical traits affecting seed yield under drought stress conditions is crucial for optimizing crop performance. A study conducted during 2022 and 2023 at the Bean Research Center in Markazi, Iran, utilized a split-plot design within a randomized complete block design with three replications to assess these traits in various Phaseolus vulgaris pinto bean lines (13 lines plus the ‘Kusha’ variety as a check) under drought stress. The results demonstrated that drought stress significantly reduced chlorophyll content, relative water content, and seed yield while increasing the activities of antioxidant enzymes, as well as proline and flavonoid content. Under non-stress conditions, lines 7 and 10 exhibited notably high total chlorophyll content of 3.55 and 3.46 mg. g⁻¹ FW, respectively, surpassing the control cultivar by 1.40 and 1.37 times. Line 13 displayed the highest activities of catalase, peroxidase, polyphenol oxidase, and ascorbate peroxidase under drought conditions. Regarding seed yield under drought stress, lines 3, 7, and 11 performed the best, being 1.79, 1.73, and 1.74 times higher than the control cultivar, respectively. Overall, the study highlighted that total chlorophyll content, proline content, polyphenol oxidase activity, and relative water content collectively explained 95.85% of the variations in seed yield under drought stress. Antioxidant enzyme activities, proline levels, and relative water content are key traits influencing seed yield under drought stress. Lines 3, 11, 12, and 13 are promising candidates for cultivation in water-limited regions based on these traits.
Anaya, F., R. Fghire, S. Wahbi and K. Loutfi. 2017. Antioxidant enzymes and physiological traits of Vicia faba L. as affected by salicylic acid under salt stress. J Mater Environ Sci, 8, (7) 2549-2563.
Azizi, S., N. Zare, P. Sheikhzadeh, J. Azizi Mobser and R. Karimizadeh. 2024. Effects of Drought Stress and Re-Irrigation at the Flowering Stage on the Physiological and Biochemical Responses and Yield in Promising Lentil lines. Iranian Journal of Field Crop Science, 55, (1) 123-137.
Bates, L. S., R. Waldren and I. Teare. 1973. Rapid determination of free proline for water-stress studies. Plant and soil, 39, 205-207.
Chance, J. and S. Machely. 1995. Assay of Catalase and peroxidase. Meth. Enzymo
Chauhan, J., P. Singh, P. Choyal, U. N. Mishra, D. Saha, R. Kumar, H. Anuragi, S. Pandey, B. Bose and B. Mehta. 2023. Plant photosynthesis under abiotic stresses: Damages, adaptive, and signaling mechanisms. Plant Stress, 100296.
Da Silva, E. C., R. Nogueira, M. A. Da Silva and M. B. De Albuquerque. 2011. Drought stress and plant nutrition. Plant stress, 5, (1) 32-41.
Desoky, E.-S. M., E. Mansour, E.-S. E. El-Sobky, M. I. Abdul-Hamid, T. F. Taha, H. A. Elakkad, S. M. Arnaout, R. S. Eid, K. A. El-Tarabily and M. A. Yasin. 2021. Physio-biochemical and agronomic responses of faba beans to exogenously applied nano-silicon under drought stress conditions. Frontiers in plant science, 12, 637783.
Dumanović, J., E. Nepovimova, M. Natić, K. Kuča and V. Jaćević. 2021. The significance of reactive oxygen species and antioxidant defense system in plants: A concise overview. Frontiers in plant science, 11, 552969.
Farzamisepehr, M., M. Ghorbanli and Z. Tadji. 2021. Effect of drought stress on some growth parameters and several biochemical aspects in two pumpkin species. Iranian Journal of Plant Physiology, 11, (3) 3731-3740.
Franks, P. J., T. W. Doheny‐Adams, Z. J. Britton‐Harper and J. E. Gray. 2015. Increasing water‐use efficiency directly through genetic manipulation of stomatal density. New Phytologist, 207, (1) 188-195.
Geleta, R. J., A. G. Roro and M. T. Terfa. 2024. Phenotypic and yield responses of common bean (Phaseolus vulgaris l.) varieties to different soil moisture levels. BMC Plant Biology, 24, (1) 242.
Ghanem, H. E. and M. Al-Farouk. 2024. Wheat Drought Tolerance: Morpho-Physiological Criteria, Stress Indexes, and Yield Responses in Newly Sand Soils. Journal of Plant Growth Regulation, 1-17.
Giannopolitis, C. N. and S. K. Ries. 1977. Superoxide dismutases: I. Occurrence in higher plants. Plant physiology, 59, (2) 309-314.
Goharivahid, A. A. and M. Yousefirad. 2024. 'Effects of mycorrhiza and humic acid on the quantitative and qualitative characters of red bean, Derakhshan cultivar'. Iranian Journal of Plant Physiology, 14 (1): 4825-4832.
Islam, N. S. and S. Dhaubhadel. 2023. Proanthocyanidin biosynthesis and postharvest seed coat darkening in pinto bean. Phytochemistry Reviews, 1-17.
Kar, M. and D. Mishra. 1976. Catalase, peroxidase, and polyphenoloxidase activities during rice leaf senescence. Plant physiology, 57, (2) 315-319.
Kirkham, M. B. 2023. Principles of soil and plant water relations. Elsevier
Kleine, S. and C. Müller. 2014. Drought stress and leaf herbivory affect root terpenoid concentrations and growth of Tanacetum vulgare. Journal of Chemical Ecology, 40, 1115-1125.
Lichtenthaler, H. K. and C. Buschmann. 2001. Chlorophylls and carotenoids: Measurement and characterization by UV‐VIS spectroscopy. Current protocols in food analytical chemistry, 1, (1) F4. 3.1-F4. 3.8.
Lizana, C., M. Wentworth, J. P. Martinez, D. Villegas, R. Meneses, E. H. Murchie, C. Pastenes, B. Lercari, P. Vernieri and P. Horton. 2006. Differential adaptation of two varieties of common bean to abiotic stress: I. Effects of drought on yield and photosynthesis. Journal of Experimental botany, 57, (3) 685-697.
Mehrasa, H., A. Farnia, M. J. Kenarsari and S. Nakhjavan. 2022. Endophytic bacteria and SA application improve growth, biochemical properties, and nutrient uptake in white beans under drought stress. Journal of Soil Science and Plant Nutrition, 22, (3) 3268-3279.
Mladenov, P., S. Aziz, E. Topalova, J. Renaut, S. Planchon, A. Raina and N. Tomlekova. 2023. Physiological responses of common bean genotypes to drought stress. Agronomy, 13, (4) 1022.
Mutari, B., J. Sibiya, P. M. Matova, E. Gasura and K. Simango. 2023. Drought stress impact on agronomic, shoot, physiological, canning and nutritional quality traits of navy beans (Phaseolus vulgaris L.) under field conditions in Zimbabwe. Field Crops Research, 292, 108826.
Nakano, Y. and K. Asada. 1981. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts. Plant and cell physiology, 22, (5) 867-880.
Ogbole, O. O., O. D. Akin-Ajani, T. O. Ajala, Q. A. Ogunniyi, J. Fettke and O. A. Odeku. 2023. Nutritional and pharmacological potentials of orphan legumes: Subfamily faboideae. Heliyon, 9, (4)
Pejić, B., L. Maksimović, S. Milić, D. Simić and B. Miletaški. 2010. Effect of readily available water deficit in soil on maize yield and evapotranspiration. Ratarstvo i povrtarstvo/Field and Vegetable Crops Research, 47, (1) 115-121.
Pierre, E., Y. N. Fabiola, N. D. Vanessa, E. B. Tobias, T. Marie-Claire, Y. Y. Diane, G. T. Gilbert, N. W. Louise and F. B. Fabrice. 2023. The co-occurrence of drought and Fusarium solani f. sp. Phaseoli Fs4 infection exacerbates the Fusarium root rot symptoms in common bean (Phaseolus vulgaris L.). Physiological and Molecular Plant Pathology, 127, 102108.
Raza, A., M. S. Mubarik, R. Sharif, M. Habib, W. Jabeen, C. Zhang, H. Chen, Z. H. Chen, K. H. Siddique and W. Zhuang. 2023. Developing drought‐smart, ready‐to‐grow future crops. The Plant Genome, 16, (1) e20279.
Rosales, M. A., E. Ocampo, R. Rodríguez-Valentín, Y. Olvera-Carrillo, J. Acosta-Gallegos and A. A. Covarrubias. 2012. Physiological analysis of common bean (Phaseolus vulgaris L.) cultivars uncovers characteristics related to terminal drought resistance. Plant physiology and biochemistry, 56, 24-34.
Savita. 2023. Production Technology of Underutilized Vegetables of Leguminosae Family. In Production Technology of Underutilized Vegetable Crops:25-99: Springer. Number of 25-99 pp.
Shams Peykani, L., and M. Farzamisepehr 2018. Effect of chitosan on antioxidant enzyme activity, proline, and malondialdehyde content in Triticum aestivum L. and Zea maize L. under salt stress condition. Iranian Journal of Plant Physiology, 5: 2661-2670.
Singh, D., C. K. Singh, J. Taunk, V. Jadon, M. Pal and K. Gaikwad. 2019. Genome wide transcriptome analysis reveals vital role of heat responsive genes in regulatory mechanisms of lentil (Lens culinaris Medikus). Scientific reports, 9, (1) 12976.
Sinha, R., A. K. Pal and A. K. Singh. 2018. Physiological, biochemical and molecular responses of lentil (Lens culinaris Medik.) genotypes under drought stress. Indian Journal of Plant Physiology, 23, (4) 772-784.
Smart, R. E. and G. E. Bingham. 1974. Rapid estimates of relative water content. Plant physiology, 53, (2) 258-260.
Soureshjani, H. K., A. Nezami, M. Kafi and M. Tadayon. 2019. Responses of two common bean (Phaseolus vulgaris L.) genotypes to deficit irrigation. Agricultural Water Management, 213, 270-279.
Ullah, A., A. Tariq, F. Zeng, M. A. Asghar, J. Sardans, C. Graciano, I. Ali and J. Peñuelas. 2024. Drought priming improves tolerance of Alhagi sparsifolia to subsequent drought: A coordinated interplay of phytohormones, osmolytes, and antioxidant potential. Plant Stress, 12, 100469.
Yahaya, M. A. and H. Shimelis. 2022. Drought stress in sorghum: Mitigation strategies, breeding methods and technologies—A review. Journal of Agronomy and Crop Science, 208, (2) 127-142.
Zahra, N., M. B. Hafeez, A. Kausar, M. Al Zeidi, S. Asekova, K. H. Siddique and M. Farooq. 2023. Plant photosynthetic responses under drought stress: Effects and management. Journal of Agronomy and Crop Science, 209, (5) 651-672.
