Principles of Plant Genetics and Breeding. George Acquaah

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Principles of Plant Genetics and Breeding - George Acquaah


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is the subject of Chapter 25. Selection in conventional plant breeding generally relies on breeding values estimated from pedigree‐based mixed models that cannot account for Mendelian segregation, and in the absence of inbreeding, can only explain one half of the genetic variability (individual contributes only half of its alleles to the next generation as previously stated). Molecular markers have the capacity to track mendelian segregation as several positions of the genome of the organism, thereby increasing the accuracy of estimates of genetic values (and the genetic progress achievable when the predictions are used for selection in breeding). Even though marker‐assisted selection (MAS) (see Chapter 24) has achieved some success, its application to improving quantitative traits is hampered by various factors. The biparental mating designs used for detection of loci affecting quantitative traits and statistical methods used are not well‐suited to traits that are under polygenic control (MAS uses molecular markers in linkage disequilibrium with QTL).

      Genomic selection (or genome‐wide selection) is proposed as a more effective approach to improving quantitative traits. It uses all the available molecular markers across the entire genome (there are thousands of genome‐wide molecular markers) to estimate genetic or breeding values. Using high‐density marker scores in the prediction model and high throughput genotyping, genomic selection avoids biased marker effect estimates and captures more of the variation due to the small‐effect QTL. Genomic selection has advantages. It can accelerate the selection cycles and increase the selection gains per unit time.

      The subject of mapping is treated in detail in Chapter 22. Quantitative traits pose peculiar challenges to plant breeders compared to qualitative traits. They are difficult to map and breed. Over the years, researchers have developed new methodologies to address these challenges, thereby enabling breeders to achieve genetic gain more rapidly in their endeavors.

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      2 Bernardo, R. (2002). Breeding for Quantitative Traits in Plants, 369. Stemma Press.

      3 Bernardo, R. and Yu, J. (2007). Prospects for genome‐wide selection for quantitative traits in maize. Crop Science 47: 1082–1090.

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      5 Bohren, B.B., McKean, H.E., and Yamada, Y. (1961). Relative efficiencies of heritability estimates based on regression of offspring on parent. Biometrics 17: 481–491.

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      7 Crossa, J., Perez, P., de los Campos, G. et al. (2010). Genomic selection and prediction in plant breeding. In: Quantitative Genetics, Genomics, and Plant Breeding, 2e (ed. M.S. Kang), 269–288.

      8 Edwards, J.W. and Lamkey, K.R. (2002). Quantitative genetics of inbreeding in a synthetic maize population. Crop Science 42: 1094–1104.

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      10 Falconer, D.S. and Mackay, T.F.C. (1996). Introduction to Quantitative Genetic, 4e. Harlow, UK: William Longman.

      11 Gallais, A. (2003). Quantitative Genetics and Breeding Methods in Autopolyploid Plants. Paris: INRA 513p.

      12 Gardner, C.O. (1977). Quantitative genetic studies and population improvement in maize and sorghum. In: Proc. Int. Conf. Quantitative Genetics (eds. E. Pollak, O. Kempthorne and T.B. Bailey), 475–489. Ames, Iowa: Iowa State University.

      13 Glover, M.A., Willmot, D.B., Darrah, L.L. et al. (2005). Diallele analysis of agronomic traits using Chinese and US maize germplasm. Crop Science 45: 1096–1102.

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      17 Henderson, C.R. (1963). Selection index and expected genetic advance. In: Statistical Genetics and Plant Breeding (eds. W.D. Hanson and H.F. Robinson). Washington, D.C.: Nat. Acad. Sci. Nat. Res. Council Publ. No. 982.

      18 Hill, W.G. (2010). Understanding and using quantitative genetic variation. Philosophical Transactions of The Royal Society B Biological Sciences 365 (1537): 73–85.

      19 Hill, J., Becker, H.C., and Tigerstedt, P.M.A. (1998). Quantitative and Ecological Aspects of Plant Breeding. London: Chapman and Hall.

      20 Holland, J.B. (2001). Epistasis and plant breeding. In: Plant Breeding Reviews, vol. 21 (ed. J. Janick), 27–92. Wiley.

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      22 Mackay, T.F.C., Stone, E.A., and Ayroles, J.F. (2009). The genetics of quantitative traits: challenges and prospects. Nature Reviews Genetics 10: 565–577.

      23 Meuwissen, T.H.E., Hayes, B.J., and Goddard, M.E. (2001). Prediction of total genetic value using genome‐wide dense markermaps. Genetics 157: 1819–1829.

      24 Zhu, M., Yu, M., and Zhao, S. (2009). Understanding quantitative genetics in the systems biology era. International Journal of Biological Sciences 5: 161–170.

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      Part A

      Please answer the following questions true or false:

      1 Heritability is a population phenomenon.

      2 Specific combining ability of a trait depends on additive gene action.

      3 Polygenes have distinct and distinguishable effects.

      4 Quantitative variation deals with discrete phenotypic variation.

      5 Quantitative traits are also called metrical traits.

      6 Quantitative traits are more influenced by the environment than qualitative traits.

      7 Quantitative traits are controlled by polygenes.

      Part B

      Please answer the following questions:

      1 What is quantitative genetics, and how does it differ from qualitative genetics?

      2 Give two specific assumptions of quantitative genetic analysis.

      3 Describe additive gene action.

      4 What is heritability of a trait?

      5 What is the breeders' equation?

      Part C

      Please write a brief essay on each of the following topics:

      1 Discuss the role


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