|Prasad, B -|
|Babar, M -|
|Xu, X -|
|Klatt, A -|
Submitted to: Crop and Pasture Science
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: October 17, 2008
Publication Date: January 10, 2009
Citation: Prasad, B., Babar, M.A., Xu, X.Y., Bai, G., Klatt, A.R. 2009. Genetic Diversity in the U.S. Hard Red Winter Wheat Cultivars as Revealed by Microsatellite Markers. Crop and Pasture Science. 60:16-24. Interpretive Summary: Knowledge of the genetic diversity existing in previously released US hard red winter wheat (HRWW) cultivars from the Great Plains is essential for effective use of these genetic resources in breeding programs. This study evaluated 60 cultivars historically released from 1900 to 2005 using 62 molecular markers. We found that genetic diversity gradually increased in cultivars released after the 1970s. Cultivars released in the 1990s had the highest genetic diversity. Molecular marker data separated 60 cultivars into eight groups and the grouping closely matches with their pedigrees and regional distribution. Our results indicate that genetic diversity of HRWW cultivars from the Great Plains has increased in the past century, and the trend is continuing.
Technical Abstract: Knowledge of the genetic diversity existing in previously released hard red winter wheat (HRWW, Triticum aestivum L.) cultivars in the Great Plains region, United States, is essential for effective utilization of these genetic resources in the various HRWW breeding programs. To ascertain a measure of the genetic diversity of the existing US HRWW, 60 cultivars were analyzed with 62 microsatellite markers distributed throughout the wheat genome. Marker data were subjected to distance-based analysis and analysis of molecular variances. In total, 341 polymorphic alleles were scored with a range of 2—12 alleles per locus. Genetic diversity gradually increased in cultivars released after the 1970s. Cultivars released in the 1990s had the highest allelic richness (4.79), gene diversity (0.60), and polymorphic information content (0.56). Levels of genetic diversity were similar between the major HRWW breeding programs. Cluster analysis resulted in eight clusters. Cluster grouping gave close matches with pedigrees and with regional distribution of the cultivars. Using decadal information, cultivars released from 1900—1969 were grouped into one cluster, cultivars from 1990—2005 were grouped into a separate cluster, whereas cultivars from the 1980s did not group with any other decades. Analysis of molecular variance revealed a significant variation among the clusters, signifying that a true genetic variation existed among the clusters. The higher proportion of genetic variation explained by cultivars within clusters compared with among clusters indicates greater genetic diversity among cultivars within clusters. Our results indicate that genetic diversity of Great Plains HRWW cultivars has increased in the past century, and the trend is continuing.