Summary
Diverse landraces of wheat, collected from the semi-arid (150 to 250 mm of total annual rainfall) Northern Negev desert in Israel were considered as a potential genetic resource of drought resistance for wheat breeding. These materials were therefore evaluated for their reponses to drought stress in agronomical and physiological terms. Up to 68 landraces, comprising of Triticum durum, T. aestivum, and T. compactum were tested in two field drought environments, in one favourable field environment, under post-anthesis chemical plant desiccation which revealed the capacity for grain filling from mobilized stem reserves, under a controlled drought stress in a rainout shelter and in the growth chamber under polyethylene glycol (PEG)-induced water stress. Biomass, grain yield and its components, harvest index, plant phenology, canopy temperatures, kernel weight loss by chemical plant desiccation, growth reduction by PEG-induced drought stress and osmotic adjustment were evaluated in the various experiments.
Landraces varied significantly for all parameters of drought response as measured in the different experiments, which was in accordance to their documented large morphological diversity. Variation in grain yield among landraces under an increasing drought stress after tillering was largely affected by spike number per unit area. Kernel weight contributed very little to yield variation among landraces under stress, probably because these tall (average of 131 cm) landraces generally excelled in their capacity to support kernel growth by stem reserve mobilization under stress. Yield under stress was reduced with a longer growth duration of landraces only under early planting but not under late planting. Landraces were generally late flowering but they were still considered well adapted phenologically to their native region where they were always planted late.
Landraces differed significantly in canopy temperature under drought stress. Canopy temperature under stress in the rainout shelter was negatively correlated across landraces with grain yield (r=0.67**) and biomass (r=0.64**) under stress. Canopy temperature under stress in the rainout shelter was also positively correlated across landraces (r=0.50**) with canopy temperature in one stress field environment. Osmotic adjustment in PEG-stressed plants was negatively correlated (r=−0.60**) with percent growth reduction by PEG-induced water stress. It was not correlated with yield under stress in any of the experiments. In terms of yield under stress, canopy temperatures and stem reserve utilization for grain filling, the most drought resistant landrace was the ‘Juljuli’ population of T.durum.
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References
Bidinger F.R., V. Mahalakshmi & G.D.P. Rao, 1987. Assessment of drought resistance in pearl millet (Pennisetum americanum L.) Leeke. I. Factors affecting yields under stress. Aust. J. Agric. Res. 38: 37–48.
Blum A., B. Sinmena & O. Ziv, 1980. An evaluation of seed and seedling drought tolerance screening tests in wheat. Euphytica 29: 727–736.
Blum A., J. Mayer and G. Gozlan, 1982. Infrared thermal sensing of plant canopies as a screening technique for dehydration avoidance in wheat. Field Crops Res. 5: 137–146.
Blum A., H. Poiakova, G. Golan & J. Mayer, 1983a. Chemical desiccation of wheat plants as a simulator of post-anthesis stress. I. Effects on translocation and kernel growth. Field Crops Res. 6: 51–58.
Blum A., J. Mayer & G. Golan, 1983b. Chemical desiccation of wheat plants as a simulator of post-anthesis stress. II. Relations to drought stress. Field Crops Res. 6: 149–155.
Blum A., J. Mayer & G. Gozlan, 1983c. Associations between plant production and some physiological components of drought resistance in wheat. Plant, Cell and Environment 6: 219–225.
Blum A., B. Sinmena, G. Golan & J. Mayer, 1988. The grain quality of landraces of wheat as compared with modern cultivars. J. Plant Breed. 97: 226–233.
Donald C.M. & J. Hamblin, 1976. The biological yield and harvest index of cereals as agronomic and plant breeding criteria. Adv. Agron. 28: 361–405.
Frankel O.H. & M.E. Soulé, 1981. Conservation and Evolution. Cambridge University Press, Cambridge, p. 327.
Hadjichristodoulou A., 1985. The stability of the number of tillers of barley varieties and its relation with consistency of performance under semi-arid conditions. Euphytica 34: 641–649.
Jain S.K., C.O. Qualset, G.M. Bhatt & K.K. Wu, 1975. Geographic pattern of phenotypic diversity in a world collection of durum wheat. Crop Sci. 15: 700–704.
Johnson R.C., H.T. Nguyen & L.I. Croy, 1984. Osmotic adjustment and solute accumulation in two wheat genotypes differing in drought resistance. Crop Sci. 24: 957–962.
Kanemasu E.T., 1983. Yield and water-use relationships: some problems in relating grain yield to transpiration. p. 413–417. In: H.M. Taylor, W.R. Jordan & T.R. Sinclair (Eds.). Limitations to Efficient Water Use in Crop Production. Am. Soc. Agron., Madison.
Morgan J.M., 1984. Osmoregulation and water stress in higher plants. Ann. Rev. Plant Physiol. 35: 257–319.
Poiarkova H. & A. Blum, 1983. Land-races of wheat from the Northern Negev desert in Israel. Euphytica 32: 257–271.
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Blum, A., Golan, G., Mayer, J. et al. The drought response of landraces of wheat from the northern Negev Desert in Israel. Euphytica 43, 87–96 (1989). https://doi.org/10.1007/BF00037900
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DOI: https://doi.org/10.1007/BF00037900