Abstract
Polymorphism of the high molecular weight glutenin subunits was studied in 456 accessions of the wild wheat Triticum turgidum var. dicoccoides (2n=4x=28; genomes AABB), originating from 21 populations in Israel. A total of 50 different SDS PAGE migration patterns were observed, resulting from the combinations of 15 subunit patterns of the A genome and 24 subunit patterns of the B genome. Most migration patterns consisted of five subunits, varying between three and six. The migration patterns of the A genome had zero to three subunits—two being most common. The apparent molecular weights (MWs) of the slowest migrating subunit (114,000 to 103,500) and of the next in rate of migration (106,000 to 96,000) were highly correlated (r = 0·97). Also, both subunits were either present (in most accessions) or absent. In 82.3 per cent of the accessions, the third subunit (MW 76,000 to 71,500) was absent, while in 16.9 per cent of the accessions all three subunits of the A genome were absent. The migration patterns of the B genome had one to three subunits—three being most common. The slowest migrating subunit (99,500 to 93,000) was present in almost all cases (99·3 per cent). The MWs of the next two subunits (90,500 to 82,000 and 86,000 to 78,000, respectively) were highly correlated (r = 0·95). Also, either both subunits were present, as in most cases (94·4 per cent), or absent (5·6 per cent). A nomenclature for the genes encoding for the HMW glutenins is proposed based on the following model: The three subunit groups controlled by each genome are encoded by two genes. In genome A, one gene (Glu-A1–1), with 12 alleles, encodes for the two correlated subunit groups 1Ax and 1Ax'; the other gene (Glu-A1–2), with 3 alleles, encodes for the fast-migrating subunit group (1Ay). In genome B, one gene (Glu-B1-1), with 8 alleles, encodes for the slow-migrating subunit group (1Bx), and the other gene (Glu-B1–2), with 10 alleles, encodes for the two correlated subunit groups, 1By and 1By'. The polymorphism of the HMW glutenin genes found in var. dicoccoides is much higher than that of cultivated wheats as well as of genes coding for enzymes in var. dicoccoides.
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Levy, A., Galili, G. & Feldman, M. Polymorphism and genetic control of high molecular weight glutenin subunits in wild tetraploid wheat Triticum turgidum var. dicoccoides. Heredity 61, 63–72 (1988). https://doi.org/10.1038/hdy.1988.91
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DOI: https://doi.org/10.1038/hdy.1988.91
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