Abstract
Resistance to three rust pathogens (leaf rust, stripe rust and stem rust) is related to different resistance genes. Leaf-rust resistance gene Lr19 , transferred to hexaploid wheat from Agropyron elongatum , appears to be a promising gene not only through the resistance to rust conferred by this gene, also because of yield increases produced in different backgrounds when alien chromatin carrying Lr19 is introgressed in wheat. It was reported that Lr19 was associated with increases in grain yield. Aerial biomass was also increased when Lr19 was introgressed, although differences were not associated with improved light interception (indirectly measured) or radiation use efficiency (RUE). The physiological basis of the increased biomass and the mechanisms causing increased number of grains per spike, in terms of dynamic of floret development, are not completely understood.
The objective of this study was to determine the performance of a near-isogenic line (cv. Bourlaug) differing in Lr19 in relation to: (i) the differences in grains per spike, by analysing the dynamics of floret primordia; and (ii) the dynamics of biomass partitioning between the spike and the rest of the vegetative organs pre- and post-anthesis.
Two field experiments were carried out during the 2001 and 2003 growing seasons; one near-isogenic line (cv. Bourlaug) was grown under potential conditions (i.e., without water and nutritional limitations). Also a check without Lr19 was grown.
The results showed that Lr19 was associated with increases in yield and a higher number of grains per unit area than the check. An increase in biomass was only observed in the 2003 growing season. Nonsignificant differences were observed in cumulative radiation intercepted between lines. Although RUE differed between growing seasons (i.e., 1.53 and 2.07 g MJ-1), there was no significant difference between the Lr19 and check genotype. In both years Lr19 allocated more assimilates and nitrogen to the spike (14% and 50% more biomass and nitrogen, respectively), and this phenomenon was associated with more fertile florets per spike.
Summarizing the data, it can be concluded that the Lr19 gene promotes the partitioning of assimilates to the reproductive organs and the nitrogen partitioning to the spike. This resulted in an increased number of fertile florets per spike and number of grains per unit area, without effecting number of spikes per unit area and crop development. Increases in biomass were not always evident.
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References
Abbate, P.E., Andrade, F.H. and Culot, J.P., 1995. The effects of radiation and nitrogen on number of grains in wheat. Journal of Agricultural Science, 124 (3), 351-360.
Fischer, R.A., 1985. Number of kernels in wheat crops and the influence of solar radiation and temperature. Journal of Agricultural Science, 105 (2), 447-461.
Fischer, R.A. and Stockman, Y.M., 1980. Kernel number per spike in wheat (Triticum aestivum L.): responses to preanthesis shading. Australian Journal of Plant Physiology, 7 (2), 169-180.
González, F.G., Slafer, G.A. and Miralles, D.J., 2003a. Floret development and spike growth as affected by photoperiod during stem elongation in wheat. Field Crops Research, 81 (1), 29-38.
González, F.G., Slafer, G.A. and Miralles, D.J., 2003b. Grain and floret number in response to photoperiod during stem elongation in fully and slightly vernalized wheats. Field Crops Research, 81 (1), 17-27.
Miralles, D.J., Katz, S.D., Colloca, A., et al., 1998. Floret development in near isogenic wheat lines differing in plant height. Field Crops Research, 59 (1), 21-30.
Miralles, D.J., Richards, R.A. and Slafer, G.A., 2000. Duration of the stem elongation period influences the number of fertile florets in wheat and barley. Australian Journal of Plant Physiology, 27 (10), 931-940.
Reynolds, M.P., Calderini, D.F., Condon, A.G., et al., 2001. Physiological basis of yield gains in wheat associated with the LR19 translocation from Agropyron elongatum . Euphytica, 119 (1/2), 137-141.
Reynolds, M.P., Pellegrineschi, A. and Skovmand, B., 2005. Sink-limitation to yield and biomass: a summary of some investigations in spring wheat. Annals of Applied Biology, 146 (1), 39-49.
Sharma, D. and Knott, D.R., 1966. The transfer of leaf-rust resistance from Agropyron to Triticum by irradiation. Canadian Journal of Genetics and Cytology, 8 (1), 137-143.
Singh, R.P., Huerta-Espino, J., Rajaram, S., et al., 1998. Agronomic effects from chromosome translocations 7DL.7Ag and 1BL.1RS in spring wheat. Crop Science, 38 (1), 27-33.
Slafer, G.A., Abeledo, L.G., Miralles, D.J., et al., 2001. Photoperiod sensitivity during stem elongation as an avenue to raise potential yield in wheat. Euphytica, 119 (1/2), 191-197.
Slafer, G.A., Araus, J.L., Royo, C., et al., 2005. Promising eco-physiological traits for genetic improvement of cereal yields in Mediterranean environments. Annals of Applied Biology, 146 (1), 61-70.
Waddington, S.R., Cartwright, P.M. and Wall, P.C., 1983. A quantitative scale of spike initial and pistil development in barley and wheat. Annals of Botany, 51 (1), 119-130.
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Miralles, D., Resnicoff, E., Carretero, R. (2007). Yield Improvement Associated with Lr19 Translocation in Wheat. In: Spiertz, J., Struik, P., Laar, H.V. (eds) Scale and Complexity in Plant Systems Research. Wageningen UR Frontis Series, vol 21. Springer, Dordrecht. https://doi.org/10.1007/1-4020-5906-X_14
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DOI: https://doi.org/10.1007/1-4020-5906-X_14
Publisher Name: Springer, Dordrecht
Print ISBN: 978-1-4020-5904-9
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