Abstract
Three near isogenic lines of spring wheat grown to determine whether Rht dwarfing alleles alter radiation interception. A field study (involving two sowing dates in two growing seasons) with lines containing different allelic dosage of Rht1 and Rht2 (i.e. dwarf, DD; semi-dwarf, SD and tall SH), was conducted without water and nutritional deficiencies. Dwarfing genes did not modify the timing of occurrence of phenological events. Above-ground biomass at anthesis was reduced by 22% in the DD line in relation of the rest of the lines. However, at maturity accumulated biomass of the DD and SH lines were not significant different. Dwarfing genes increased the light attenuation coefficient (k, with values of 0.48, 0.62 and 0.78 for the SH, SD and the DD line respectively). A similar trend was followed to the leaf thickness (estimated by the specific leaf weight, SLW). Despite the differences observed among the lines, both in k and SLW values, they did not differ significantly in the proportion of incoming radiation intercepted by the canopy, nor in the cumulative intercepted radiation during the pre and post-anthesis periods. Radiation use efficiency (RUE) differed significantly among the lines. While RUE during pre-anthesis was the lowest in the DD line, from anthesis to maturity the lines with Rht alleles showed higher RUE values than the SH line. The low pre-anthesis RUE in the DD lines could be associated with (i) poor canopy architecture due to reductions in leaf sheath and internode lengths and/or (ii) reduced canopy CO2 exchange rate. Post-anthesis RUE was lower than that recorded pre-anthesis in all lines. But the magnitude of the reduction was inversely related to the doses of the Rht alleles. Post-anthesis RUE appeared to be closely and positively associated with the number of grains set per unit biomass at anthesis. This relationship suggests a regulatory effect of the sink size on the efficiency of the crop to convert radiation into biomass during this period.
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References
Allan, R.E., 1983. Harvest indexes of backcross derived wheat lines differing in culm height. Crop Sci 23: 1029–1032.
Allan, R.E., 1986. Agronomic comparison among wheat lines nearly isogenic for three reduced-height genes. Crop Sci 26: 707–710.
Allan, R.E., 1989. Agronomic comparison between Rht1 and rht2 semidwarf gene in winter wheat. Crop Sci 29: 1103–1108.
Austin, R.B., J. Bingham, R.D. Blackwell, L.T. Evans, M.A. Ford, C.L. Morgan & M. Taylor, 1980. Genetic improvement in winter wheat yield since 1900 and associated physiological changes. J Agric Sci, Camb, 94: 675–689.
Austin, R.B., 1989. Genetic variation in photosynthesis. J Agric Sci, Camb, 112: 287–294.
Brooking, I.R. & E.J.M. Kirby, 1981. Interrelationships between stem and ear development in winter wheat: the effects of a Norin 10 dwarfing gene, Gai/Rht2, J Agric Sci, Camb, 97: 373–381.
Bush, M.G. & L.T. Evans, 1988. Growth and development in tall and dwarf isogenic lines of spring wheat. Field Crops Res 18: 243–270.
Calderini, D.F., M.F. Dreccer & G.A. Slafer, 1996a. Consequences of breeding on biomass, radiation interception and radiation use efficiency in wheat. Field Crops Res (in press).
Calderini, D.F., D.J. Miralles & V.O. Sadras, 1996b. Appearance and growth of individual leaves as affected by semidwarfism in isogenic lines of wheat. Annals Bot 77: 583–589.
Gale, M.D. & S. Youssefian, 1985. Dwarfing genes of wheat. In: G.E. Russell (Ed.), Progress in Plant Breeding, pp. 1–35. Butterworth, London.
Garcia, R., E.T. Kanemasu, B.L. Blad, A. Bauer, J.L. Hatfield, D.J. Major, R.J. Reginato & K.G. Hubbard, 1988. Interception and use efficiency of light in winter wheat under different nitrogen regimes. Agric Forest Meteorology 44: 175–186.
Gardner, J.S., W.M. Hess & E.J. Trione, 1985. Development of the young wheat spike: a SEM study of Chinese spring wheat. Am J Bot 72: 548–559.
Gent, M.P.N., 1995. Canopy light interception, gas exchange, and biomass in reduced height isolines of winter wheat. Crop Sci 35: 1636–1642.
Gifford, R.M., J.H. Thorne, W.D. Witz & R.T. Giaquinta, 1984. Crop productivity and photoassimilate partitioning. Science 225: 801–808.
Green, C.F., 1989. Genotypic differences in the growth of Triticum aestivum in relation to absorbed solar radiation. Field Crops Res 19: 285–295.
Hipps, L.E., G. Asrar & E.T. Kanemasu, 1983. Assessing the interception of photosynthetically active radiation in winter wheat. Agric Meteorology 28: 253–259.
Hoogendoorn, J., W.H. Pfeiffer, S. Rajaram & M.D. Gale, 1988. Adaptative aspects of dwarfing genes in CIMMYT germplasm. 7th Int Wheat Genet Symp, Camb, 1093–1100.
Jamieson, P.D., R.J. Martin, G.S. Francis & D.R. Wilson, 1995. Drought effects on biomass production and radiation-use efficiency in barley. Field Crops Res 43: 77–86.
King, P.W., M.D. Gale & S.A. Quarrie, 1983. The effects of Norin 10 and Tom Thumb dwarfing genes on wheat morphology, physiology and abscicic acid production. Ann Bot 51: 201–208.
McCaig, T.N. & J.A. Morgan, 1993. Root and shoot dry matter partitioning in near isogenic lines differing in height. Can J Plant Sci 73: 679–689.
Miralles, D.J. & G.A. Slafer, 1995a. Individual grain weight responses to genetic reduction in culm length in wheat as affected by source-sink manipulations. Field Crops Res 43: 55–66.
Miralles, D.J. & G.A. Slafer, 1995b. Yield, biomass and yield components in dwarf, semidwarf and tall isogenic lines of spring wheat under recommended and late sowings. Plant Breed 114: 392–396.
Morgan, J.A., D.R. LeCain & R. Wells, 1990. Semidwarfing genes concentrate photosynthetic machinery and affect leaf gas exchange of wheat. Crop Sci 30: 602–608.
Nizam Uddin, M. & D.R. Marshall, 1989. Effects of dwarfing genes on yield and yield components under irrigated and rainfed conditions in wheat (Triticum aestivum L.) Euphytica 42: 127–134.
Richards, R.A., 1992. The effect of dwarfing genes in spring wheat in dry environments. I. Agronomic characteristics. Aust J Agric Res 43: 517–523.
Slafer, G.A. & F.H. Andrade, 1989. Genetic improvement in bread wheat (Triticum aestivum) yield in Argentina. Field Crops Res 21: 289–296.
Slafer, G.A., F.H. Andrade & E.H. Satorre, 1990. Genetic-improvement effects on pre-anthesis physiological attributes related to wheat grain-yield. Field Crops Res 23: 255–263.
Takahashi, T. & K. Nakaseko, 1993. Seasonal changes in distribution of intercepted photosynthetically active radiation for layer and dry matter production in spring wheat canopy. Jap J Crop Sci 62: 313–318.
Thorne, G.N., I. Pearman, W. Day & A.D. Todd, 1988. Estimation of radiation interception by winter wheat from measurements of leaf area. J Agric Sci, Camb, 110: 101–108.
Youssefian, S., E.J.M. Kirby & M.D. Gale, 1992. Pleiotropic effects of the GA-insensitive Rht dwarfing genes in wheat. 1. Effects on developmental of the car, stem and leaves. Field Crops Res 28: 179–190.
Zadoks, J.C., T.T. Chang & C.F. Konzak, 1974. Decimal code for the growth stage of cereals. Weed Res 14: 415–421.
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Miralles, D.J., Slafer, G.A. Radiation interception and radiation use efficiency of near-isogenic wheat lines with different height. Euphytica 97, 201–208 (1997). https://doi.org/10.1023/A:1003061706059
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DOI: https://doi.org/10.1023/A:1003061706059