Simulations and practical problems of applying multiple marker assisted selection and doubled haploids to wheat breeding programs

• Published in: Euphytica Vol. 100; no. 1-3; pp. 225 - 230
• Main Authors: Howes, N.K. (Agriculture and Agri-Food Canada, Winnipeg, Man. (Canada). Cereal Research Centre), Woods, S.M, Townley-Smith, T.F
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Nature B.V 01.01.1998
• Subjects: Cereals; Gene loci; Gene mapping; GENETIC MARKERS; Genetics; HAPLOIDIA; HAPLOIDIE; HAPLOIDY; MARCADORES GENETICOS; MARQUEUR GENETIQUE; Plant breeding; Quantitative trait loci; SELECCION; SELECTION; Spring wheat; TRITICUM; Triticum aestivum
• ISSN: 0014-2336; 1573-5060
• DOI: 10.1023/a:1018308307403

Marker assisted selection (MAS) and wheat doubled haploids (DH) are relatively new technologies, recently applied to wheat breeding programs. Simulations demonstrate that DHs increase the efficiency of MAS, and offer faster strategies for combining large numbers of genes with a minimum number of marker tests. When small numbers of marked loci (1-3) are selected simultaneously, selection of DH progeny is 5-6 times more efficient than selecting F sub(4) derived families. Combining 4-8 marked loci, screening of F sub(2) plants and using only those plants homozygous or segregating for all of the marked loci as parents for DH production (10-31% of F sub(2) plants) is 3-10 times as efficient as using F sub(1) plants. A number of protocols have been proposed involving sib-matings and selection to fix some genes, with further selection in the second generation to improve the proportion of useful DH lines. In one scheme (recombinant F sub(2) selection) all F sub(2) plants, either homozygous or heterozygous for the marked alleles, are intercrossed at random and the recurrent F sub(1) plants still having these alleles are used for DH production. An alternative strategy (recurrent DH selection) is to select from an initial DH population and intercross those lines having most favourable marked loci with a second cycle of DHs to fix all favourable marked loci. Combining more than 12 marked gene loci does not seem feasible, due to the very large numbers of F sub(2)s (>2000) required. This has implications when using MAS for quantitative trait loci, where many minor gene loci would have to be combined. Direct selection for some multi-genic quantitative traits amongst the DH lines may be more efficient than using MAS where recurrent selection is used. At the Cereal Research Centre, the practical problems of using these protocols as part of the spring wheat breeding program are being evaluated.