Thermal stability of wheat gluten protein: its effect on dough properties and noodle texture

Abstract

There is a need to develop more sensitive and reliable tests to help breeders select wheat lines of appropriate quality. Gluten thermostability, measured by the viscoelasticity of heated gluten, was assessed for its usefulness in evaluating quality of wheats in breeding programs. Two sets of wheat samples were used: Set I consisting of 20 cultivars and/or breeders' lines (BL), with diverse dough strengths and allelic variations of high Mr glutenin subunits coded at the Glu-A1, Glu-B1 and Glu-D1 loci (N=20) and Set II consisting of 16 near isogenic BL of F7 generation that had been in a quality selection program for three years. Thermostability of the isolated wet gluten was determined by measuring its viscoelastic properties, and was related to noodle texture, flour protein content, protein composition, dough physical properties and other quality predicting tests. Viscoelasticity of heat-treated gluten, isolated with 2% NaCl solution, significantly correlated with most of the tests used to measure dough and/or gluten strength and Chinese white salted noodle texture. The rate of thermal denaturation of proteins depends on Mr and packing density. High ratios of monomeric proteins such as gliadins and low Mr glutenin subunits to high Mr glutenin subunits increase the thermostability of the gluten. The measurement of viscoelasticity of heat-denatured gluten can be a useful test to determine gluten quality. Our study showed that gluten viscoelasticity and most of the tests related to dough and/or gluten strength are independent of allelic variations of the high molecular weight glutenin subunits. This test has been developed for predicting white salted noodle quality.