Publication no. C-2003-1110-05R |  VIEW ARTICLE

Genotypic and Environmental Modification of Asian Noodle Quality of Hard Winter Wheats (1).

R. Graybosch (2), N. Ames (3), P. S. Baenziger (4), and C. J. Peterson (5). (1) Joint contribution of the United States Department of Agriculture, Agriculture Research Service and the University of Nebraska Agriculture Research Division as Journal Series Paper No. 13973. Mention of firm names or trade products does not imply that they are endorsed or recommended by the University of Nebraska or USDA over other firms or products not mentioned. (2) USDA-ARS, 344 Keim, University of Nebraska, Lincoln, NE 68583. Corresponding author. E-mail: <rag@unlserve.unl.edu> (3) Agriculture and Agrifood Canada, Winnipeg, Manitoba. (4) Department of Agronomy & Horticulture, University of Nebraska, Lincoln, NE. (5) Department of Crop & Soil Science, Oregon State University, Corvallis, OR. Cereal Chem. 81(1):19-25. Accepted July 15, 2003. This article is in the public domain and not copyrightable. It may be freely reprinted with customary crediting of the source. American Association of Cereal Chemists, Inc., 2004.

The relative effects of environment, genotype, and their interactions on the modification of Asian noodle quality attributes were assessed using 38 winter wheat (Triticum aestivum L.) cultivars and breeding lines grown in replicated trials at three Nebraska locations in harvest year 2000. Noodle color was determined in both white salted and yellow alkaline procedures, and noodle textural features were investigated by producing white salted noodles. Significant environmental, genotypic, and genotype-by-environment variation was observed for nearly all initial and 24-hr noodle color traits in both types of noodles. Significant genotypic effects were observed for several textural traits, while significant environmental effects were observed only for noodle hardness and water uptake. However, among the noodle textural traits, the genotype-by-environment interaction was significant only for noodle firmness. High and significant phenotypic correlations were observed between color traits in the two noodle applications. Genetic correlations were of lower magnitude, indicating the possibility of breeding wheats specifically for various noodle color types. Strong negative phenotypic and genetic correlations were observed between flour protein content and noodle brightness (L*) values in both yellow alkaline and white-salted applications. Textural traits largely were independent of noodle color traits. When significant phenotypic or genetic correlations were observed between variable pairs, invariably similar correlations were observed with flour protein content. Noodle cutting force, cutting area, and final thickness showed strong phenotypic and genetic correlations with each other and with protein content. These variables largely were independent of noodle firmness and hardness, which were, in turn, more dependent on alleles at the wheat wx-A1 and wx-B1 (waxy) loci. Noodle firmness was greatest in flours from wild-type wheats; lines with a null allele only at the wx-A1 locus did not differ from wild-type. Softest noodles were produced from lines carrying null alleles at both wx-A1 and wx-B1, while lines with a null only at wx-B1 were intermediate in softness.