EXPLORING THE RELATIONSHIP BETWEEN PLANT HEIGHT AND YIELD-CONTRIBUTING ATTRIBUTES OF WHEAT IN DROUGHT CONDITIONS
DOI:
https://doi.org/10.54112/bcsrj.v2024i1.854Keywords:
plant height, yield contributing traits, Wheat, Drought conditions, associationAbstract
Plant height is the most dynamic yield-affecting trait which has strong genetic and phenological associations with yield performance in wheat. The objective of the study was to explore the effect of plant height on spike yield by investigating the interrelationship between height and yield components of ninety wheat genotypes under a drought environment. Different statistical procedures including correlation, regression, path coefficient, principle component, biplot, and cluster analysis were performed to dissect the associative role of height and yield components in setting the yield potential of wheat plants. High positive correlation and direct effects are seen for spike yield from seed weight (r = 0.73) and seed number (r = 0.60) with a participatory contribution of 58% and 40%, respectively. But plant height is negatively associated with thousand seed weight (-0.22*) and spike yield (-0.15) in such a way that each additional unit (1cm) of height reduces 0.11 g thousand seed weight and 0.06 g spike yield due to negative regression. PC1 and PC2 associate height and yield components respectively and both types of traits moderately oppose each other for simultaneous improvement. Highly tall and short plants were observed with low yield potential under water-limited resources due to strong negative effects either on seed weight or number. An increase in height favors seed number but reduces enough seed weight to cause comparative losses. Intelligent allocation of plant resources to height or spike defines the plant yield potential. Plants with moderate height ranging from 74-83 cm were seen with the best yield potential among five different classes of height. Genotypes HM729, HM829, and HM644 belonged to this class and their better yield potential was due to the balance ratio of seed weight and number. This work would help direct our breeding programs for the improvement of the height-oriented yield potential of wheat.
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Ahmad, M., Akram, Z., Munir, M., & Rauf, M. (2006). Physio-morphic response of wheat genotypes under rainfed conditions. Pak. J. Bot 38, 1697-1702.
Asadi, A., Kelestanie, A. A., Mirfakhraii, S. G., & Abasi, A. R. (2013). Genetic variation of the 20 bread wheat cultivars under chilling stress by using GGE biplot analysis.
Asif, M., & Kamran, A. (2011). Plant breeding for water-limited environments. Crop science 51, 2911.
Berry, P., & Berry, S. (2015). Understanding the genetic control of lodging-associated plant characters in winter wheat (Triticum aestivum L.). Euphytica 205, 671-689.
Blum, A., & Sullivan, C. (1997). The effect of plant size on wheat response to agents of drought stress. I. Root drying. Functional Plant Biology 24, 35-41.
Chen, L., Hao, L., Condon, A. G., & Hu, Y.-G. (2014). Exogenous GA3 application can compensate the morphogenetic effects of the GA-responsive dwarfing gene Rht12 in bread wheat. Plos one 9, e86431.
Chen, L., Phillips, A. L., Condon, A. G., Parry, M. A., & Hu, Y.-G. (2013). GA-responsive dwarfing gene Rht12 affects the developmental and agronomic traits in common bread wheat. Plos one 8, e62285.
Daoura, B. G., Chen, L., & Hu, Y.-G. (2013). Agronomic traits affected by dwarfing gene'Rht-5'in common wheat ('Triticum aestivum'L.). Australian Journal of Crop Science 7, 1270-1276.
Day, A., & Intalap, S. (1970). Some effects of soil moisture stress on the growth of wheat (Triticum aestivum L. em Thell.) 1. Agronomy Journal 62, 27-29.
Dewey, D. R., & Lu, K. (1959). A correlation and path‐coefficient analysis of components of crested wheatgrass seed production 1. Agronomy Journal 51, 515-518.
Edae, E. A. (2013). Association mapping for yield, yield components and drought tolerance-related traits in spring wheat grown under rainfed and irrigated conditions Colorado State University].
Everitt, B., & Dunn, G. (2001). Applied multivariate data analysis (Vol. 2). Wiley Online Library.
Farooq, M., Wahid, A., Kobayashi, N., Fujita, D., & Basra, S. M. (2009). Plant drought stress: effects, mechanisms and management. Sustainable agriculture, 153-188.
Gent, M. P., & Kiyomoto, R. K. (1997). Physiological and agronomic consequences of Rht genes in wheat. Journal of crop production 1, 27-46.
Griffiths, S., Simmonds, J., Leverington, M., Wang, Y., Fish, L., Sayers, L., Alibert, L., Orford, S., Wingen, L., & Snape, J. (2012). Meta-QTL analysis of the genetic control of crop height in elite European winter wheat germplasm. Molecular Breeding 29, 159-171.
Kocheva, K., Nenova, V., Karceva, T., Petrov, P., Georgiev, G., Börner, A., & Landjeva, S. (2014). Changes in water status, membrane stability and antioxidant capacity of wheat seedlings carrying different Rht‐B1 dwarfing alleles under drought stress. Journal of Agronomy and Crop Science 200, 83-91.
Rebetzke, G., Ellis, M., Bonnett, D., Mickelson, B., Condon, A., & Richards, R. (2012). Height reduction and agronomic performance for selected gibberellin-responsive dwarfing genes in bread wheat (Triticum aestivum L.). Field Crops Research 126, 87-96.
Sayar, R., Bchini, H., Mosbahi, M., & Ezzine, M. (2010). Effects of salt and drought stresses on germination, emergence and seedling growth of durum wheat (Triticum durum Desf.). J. Agric. Res 5, 2008-2016.
Sehgal, S. A., Tahir, R. A., & Nawaz, M. (2012). Molecular characterization of wheat genotypes using SSR markers. International Journal Bioautomation 16, 119.
Selote, D. S., & Khanna‐Chopra, R. (2006). Drought acclimation confers oxidative stress tolerance by inducing co‐ordinated antioxidant defense at cellular and subcellular level in leaves of wheat seedlings. Physiologia Plantarum 127, 494-506.
Skylas, D., Mackintosh, J., Cordwell, S., Basseal, D., Walsh, B., Harry, J., Blumenthal, C., Copeland, L., Wrigley, C., & Rathmell, W. (2000). Proteome approach to the characterisation of protein composition in the developing and mature wheat-grain endosperm. Journal of Cereal Science 32, 169-188.
Spink, J., Berry, P., Wade, A., & White, E. (2004). Minimising chlormequat residues in harvested grain. Home-Grown Cereals Authority Research Project, HGCA, London 332, 44.
Steel, R. G., Torrie, J. H., & Dickey, D. A. (1997). Principles and procedures of statistics: a biometrical approach.
Tilman, D., Balzer, C., Hill, J., & Befort, B. L. (2011). Global food demand and the sustainable intensification of agriculture. Proceedings of the National Academy of Sciences 108, 20260-20264.
Velleman, P. F., & Welsch, R. E. (1981). Efficient computing of regression diagnostics. The American Statistician 35, 234-242.
Wen, W., Deng, Q., Jia, H., Wei, L., Wei, J., Wan, H., Yang, L., Cao, W., & Ma, Z. (2013). Sequence variations of the partially dominant DELLA gene Rht-B1c in wheat and their functional impacts. Journal of experimental botany 64, 3299-3312.
Wu, X., Chang, X., & Jing, R. (2012). Genetic insight into yield-associated traits of wheat grown in multiple rain-fed environments. Plos one 7, e31249.
Würschum, T., Langer, S. M., & Longin, C. F. H. (2015). Genetic control of plant height in European winter wheat cultivars. Theoretical and Applied Genetics 128, 865-874.
Zhang, B., Shi, W., Li, W., Chang, X., & Jing, R. (2013). Efficacy of pyramiding elite alleles for dynamic development of plant height in common wheat. Molecular Breeding 32, 327-338.
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Copyright (c) 2024 HM JAVED, A NAEEM, S SHAUKAT, M MAKHDOOM, I GHAFOOR, N SHAHZADI, F HUSSAIN, ALK TIPU, M IMRAN, A REHMAN, T MAJEED, AR AKBER
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