Abstract
Water stress is one of the major constraints to the grain yield of sorghum in tropical and sub-tropical areas of the world. Osmotic adjustment has been widely proposed as a plant attribute that confers adaptation to water stress. The inheritance of osmotic adjustment to water stress was investigated in a series of generations derived from the three possible bi-parental crosses between two inbred sorghum lines with a high capacity for osmotic adjustment (Tx2813 and TAM422; high-OA lines) and one with a low capacity (QL27; low-OA line). Broad-sense heritability on a single-plant basis was generally found to be high. Analysis of segregation ratios by the mixture method of clustering identified two independent major genes for high osmotic adjustment. The line Tx2813 possessed a recessive gene which is given the symbol oa1; the line TAM422 possessed an additive gene which is given the symbol OA2. There was some evidence that there may be other minor genes which influence the expression of osmotic adjustment in these crosses as two putative transgressive segregants, with higher osmotic adjustment than the parents, were identified from the cross between Tx2813 and TAM422. Populations of recombinant inbred lines were developed and characterised for osmotic adjustment for two of the crosses (QL27 x TAM422, low-OA x high-OA; Tx2813 x TAM422, high-oal x high-OA2). These will be used to conduct experiments which test hypotheses about the contribution of the high-osmotic-adjustment genes to the grain yield of sorghum under a range of water-stress conditions.
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References
Ackerson RC, Krieg DR, Sung FJM (1980) Leaf conductance and osmoregulation of field-grown sorghum genotypes. Crop Sci 20:10–14
Basford KE, McLachlan GJ (1985) The mixture of clustering applied to three-way data. J Classification 2:109–125
Basnayake J, Ludlow MM, Cooper M, Henzell RG (1993) Genotypic variation of osmotic adjustment and desiccation tolerance in contrasting sorghum inbred lines. Field Crops Res 35:51–62
Basnayake J, Cooper M, Ludlow MM, Henzell RG (1994) Combining ability variation for osmotic adjustment among a selected range of grain sorghum (Sorghum bicolor L. Moench) lines. Field Crops Res 38:147–155
Blum A (1988) Plant Breeding for Stress Environments. CRC Press, Inc, Boca Raton, Florida, USA
Blum A (1989) Osmotic adjustment and growth of barley genotypes under drought stress. Crop Sci 20:230–233
Cavalli LL (1952) An analysis of linkage in quantitative inheritance. In: Rieve ECR, Waddington CH (eds) Quantitative inheritance. HMSO, London, pp 135–144
Galiba G, Simon-Sarkodi L, Kocsy G, Salgo A, Sutka J (1992) Possible chromosomal location of genes determining the osmoregulation of wheat. Theor Appl Genet 85:415–418
Grumet R, Hanson AD (1986) Genetic evidence for an osmoregulatory function of glycinebetaine accumulation in barley. Aust J Plant Physiol 13:353–364
Hanson WD, Weber CR (1960) Resolution of genetic variability in self-pollinated species with an application to the soybean. Genetics 46:1425–1434
Ludlow MM, Muchow RC (1990) A critical evaluation of traits for improving crop yield in water-limited environments. Adv Agron 43:107–153
Ludlow MM, Muchow RC (1992) Physiology of yield and adaptation of dryland grain sorghum. In: Foale MA, Henzell RG, Vance PV (eds) Proc 2nd Austr Sorghum Conf, Gatton. Australian Institute of Agricultural Science, Melbourne, Occasional Publication No. 68, pp 49–69
Ludlow MM, Santamaria JM, Fukai S (1990) Contribution of osmotic adjustment to grain yield of Sorghum bicolor (L.) Moench under water-limited conditions. II. Post-anthesis water stress. Aust J Agric Res 41:67–78
Mather K, Jinks JL (1982) Biometrical genetics, 3rd edn. Chapman and Hall, London
McLachlan GJ, Basford KE (1988) Mixture models: inference and applications to clustering. Statistics: textbooks and monographs, vol 84. Marcel Dekker Inc., New York
Morgan JM (1980) Osmotic adjustment in the spikelet and leaves of wheat. J Exp Bot 31:655–665
Morgan JM (1983) Osmoregulation as a selection criterion for drought tolerance in wheat. Aust J Agric Res 34:607–614
Morgan JM (1991) A gene controlling differences in osmoregulation in wheat. Aust J Plant Physiol 18:249–257
Munns R (1988) Why measure osmotic adjustment? Aust J Plant Physiol 15:717–726
Nyquist WE (1991) Estimation of heritability and prediction of selection response in plant populations. Crit Rev Plant Sci 10:235–322
Santamaria JM, Ludlow MM, Fukai S (1990) Contribution of osmotic adjustment to grain yield in Sorghum bicolor (L.) Moench under water-limited conditions. I. Water stress before anthesis. Aust J Agric Res 41:51–65
Rowe KE, Alexander WL (1980) Computations for estimating the genetic parameters in a joint-scaling test. Crop Sci 20:109–110
Tangpremsri T, Fukai S, Fischer KS, Henzell RG (1991) Genotypic variation in osmotic adjustment in grain sorghum. 1. Development of variation in osmotic adjustment under moisture-limited conditions. Aust J Agric Res 42:747–757
Warner JN (1952) A method for estimating heritability. Agron J 44:427
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Basnayake, J., Cooper, M., Ludlow, M.M. et al. Inheritance of osmotic adjustment to water stress in three grain sorghum crosses. Theoret. Appl. Genetics 90, 675–682 (1995). https://doi.org/10.1007/BF00222133
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DOI: https://doi.org/10.1007/BF00222133