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Use of Triticum tauschii to improve yield of wheat in low-yielding environments

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Abstract

Triticum tauschii (Coss.) Schmal. is an ancestor of bread wheat (T. aestivum). This species has been widely used as a source ofsimply-inherited traits, but there are few reports of yield increases due tointrogression of genes from this species. Selections from F2-derivedlines of backcross derivatives of synthetic hexaploid wheats (T.turgidum / T. tauschii) were evaluated for grain yield in diverseenvironments in southern Australia. Re-selections were made in theF6 generation and evaluated for grain yield, yield componentsincluding grain weight, and grain growth characters in diverse environmentsin southern Australia and north-western Mexico. Re-selection was effectivein identifying lines which were higher yielding than the recurrent parent,except in full-irrigation environments. Grain yields of the selectedderivatives were highest relative to the recurrent parent in thelowest-yielding environments, which experienced terminal moisture deficitand heat stress during grain filling. The yield advantage of the derivativesin these environments was not due to a change in anthesis date orgrain-filling duration, but was manifest as increased rates of grain-filling andlarger grains, indicating that T. tauschii has outstanding potential forimproving wheat for low-yielding, drought-stressed environments.

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References

  • Bramel-Cox, P.J., D.J. Andrews & K.J. Frey, 1989. Exotic germplasm for improving grain yield and growth rate in pearl millet. Crop Sci 26: 687–690.

    Google Scholar 

  • Cantrell, R.G. & L.R. Joppa, 1991. Genetic analysis of quantitative traits in wild emmer (Triticum turgidum L. var. dicoccoides). Crop Sci 31: 645–649.

    Google Scholar 

  • Ceccarelli, S., 1996. Adaptation to low/high input cultivation. Euphytica 92: 203–214.

    Google Scholar 

  • Connor, D.J., 1993. Managing wheat within the crop-livestock system of rainfed agriculture in southeast Australia. In: D.R. Buxton, R. Shibles, R.A. Forsberg, B.L. Blad, K.H. Asay, G.M. Paulsen & R.F. Wilson (Eds.), International Crop Science I, pp. 171–178. Crop Science Society of America, Inc. Madison, Wisconsin, USA.

    Google Scholar 

  • Cook, R. & R. Evans, 1987. Resistance and tolerance. In: Brown, R.H. & B.R. Kerry (Eds.), Principles and Practice of Nematode Control in Crops, pp. 179–231. Academic Press Australia, Marrickville, NSW, Australia.

    Google Scholar 

  • Cox, T.S., L.R. House & K.J. Frey, 1984. Potential of wild germplasm for increasing yield of grain sorghum. Euphytica 33: 673–684.

    Google Scholar 

  • Cox, T.S., R.G. Sears & R.K. Bequette, 1995a. Use of winter wheat ×Triticum tauschii backcross populations for germplasm evaluation. Theor Appl Genet 90: 571–577.

    Google Scholar 

  • Cox, T.S., R.G. Sears, R.K. Bequette & T.J. Martin, 1995b. Germplasm enhancement in winter wheat ×Triticum tauschii backcross populations. Crop Sci 35: 913–919.

    Google Scholar 

  • Darroch, B.A. & R.J. Baker, 1990. Grain filling in three spring wheat genotypes: statistical analysis. Crop Sci 30: 525–529.

    Google Scholar 

  • 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.

    Google Scholar 

  • Eastwood, R.F., 1996. Using Triticum tauschii for wheat improvement. In: R.A. Richards, C.W. Wrigley, H.M. Rawson, G.J. Rebetzke, J.L. Davidson & R.I.S. Brettell (Eds.), 8th Assembly of Wheat Breed. Soc. of Australia, pp. 189–193. Canberra, Australia.

  • Eastwood, R.F., Lagudah, E.S., Appels, R., Hanna, M. & Kollmorgen, J.F. 1991. Triticum tauschii: a novel source of resistance to cereal cyst nematode (Heterodera avenae). Aust J Agric Res 42: 69–77.

    Google Scholar 

  • Frey, K.J., 1976. Plant breeding in the seventies: Useful genes from wild plant species. Egypt J Genet Cytol 5: 460–482.

    Google Scholar 

  • Gill, B.S., H.C. Sharma, W.J. Raupp, L.E. Browder, J.H. Hatchett, T.L. Harvey, J.G. Moseman & J.G. Waines. 1985. Evaluation of Aegilops species for resistance to wheat powdery mildew, wheat leaf rust, hessian fly and greenbug. Plant Dis 69: 314–316.

    Google Scholar 

  • Kushnir, U. & G.M. Halloran, 1984. Transfer of high kernel weight and high protein from wild tetraploid wheat (Triticum turgidum dicoccoides) to bread wheat (T. aestivum) using homologous and homoeologous recombination. Euphytica 33: 249–255.

    Google Scholar 

  • Ladizinsky, G., 1985. Founder effect in crop-plant evolution. Eco Bot 39: 191–199.

    Google Scholar 

  • Levy, A.A. & M. Feldman, 1989. Genetics of morphological traits in wild wheat. Triticum turgidum var. dicoccoides. Euphytica 40: 275–281.

    Google Scholar 

  • Lupton, F.G.H. & R.N.H. Whitehouse, 1957. Studies on the breeding of self-pollinated cereals. I. Selection methods for breeding for yield. Euphytica 6: 169–184.

    Google Scholar 

  • McCormick, K.M., J.F. Panozzo & H.A. Eagles, 1995. Starch pasting properties and genetic relationships of wheat cultivars important to Victorian wheat breeding. Aust J Agric Res 46: 861–871.

    Google Scholar 

  • Panozzo, J.F. & H.A. Eagles, 1999. Rate and duration of grain filling and nitrogen accumulation of wheat cultivars grown in different environments. Aust J Agric Res 50: 1007–1015.

    Google Scholar 

  • Payne, R.W., P.W. Lane, D.B. Baird, S.A. Harding, K.E. Bicknell, G.W. Morgan, D.A. Murray, R. Thompson, A.D. Todd, G. Tunnicliffe Wilson, R. Webster, S.J. Welham & R.P. White, 1995. GENSTAT 5 Release 3.2 Reference Manual. Clarendon Press, Oxford, UK.

    Google Scholar 

  • Reddy, N., G.M. Halloran & M.E. Nicolas, 1996. Agronomic assessment of lines derived from a direct cross of wheat with T. tauschii L. In: R.A. Richards, C.W. Wrigley, H.M. Rawson, G.J. Rebetzke, J.L. Davidson & R.I.S. Brettell (Eds.), Proc 8th Assembly of Wheat Breed. Soc. of Australia, pp. 24–26. Canberra, Australia.

  • Takeda, K. & K.J. Frey, 1976. Contributions of vegetative growth rate and harvest index to grain yield of progenies from Avena sativa X A. sterilis crosses. Crop Sci 16: 817–821.

    Google Scholar 

  • Villareal, R.L., S. Rajaram, A. Mujeeb-Kazi, E.D. Toro & E. Del-Toro, 1991. The effect of chromosome 1B/1R translocation on the yield potential of certain spring wheats (Triticum aestivum L.). Plant Breed 106: 77–81.

    Google Scholar 

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Authors and Affiliations

  1. Joint Centre for Crop Improvement, Institute of Land and Food Resources, The University of Melbourne, Private Bag 260, Horsham, Vic, 3401

    N.N. Gororo, H.A. Eagles & M.E. Nicolas

  2. Victorian Institute for Dryland Agriculture, Private Bag 260, Horsham, Vic, 3401

    H.A. Eagles, R.F. Eastwood & R.G. Flood

  3. CRC for Molecular Plant Breeding, Victorian Institute for Dryland Agriculture, Private Bag 260, Horsham, Vic, 3401

    N.N. Gororo & H.A. Eagles

Authors
  1. N.N. Gororo
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  2. H.A. Eagles
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  3. R.F. Eastwood
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  4. M.E. Nicolas
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  5. R.G. Flood
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Gororo, N., Eagles, H., Eastwood, R. et al. Use of Triticum tauschii to improve yield of wheat in low-yielding environments. Euphytica 123, 241–254 (2002). https://doi.org/10.1023/A:1014910000128

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