Dietary starch with an increased content of resistant starch (RS) has the potential to reduce the prevalence of diabetes, obesity, and cardiovascular diseases. Here, an efficient glycogen branching enzyme, CcGBE, from Corallococcus sp. strain EGB was identified, and its relevant properties, including potential application in the preparation of modified starch, were evaluated. The purified CcGBE exhibited a maximal specific activity of approximately 20,000 U/mg using cassava starch as the optimal substrate. The content of α-1,6-glucosidic bonds in CcGBE-modified cassava starch increased from 2.9 to 13.2%. Meanwhile, both the average chain length (CL) of CcGBE-modified starch and the blue value of the color complex formed by starch and iodine initially increased and then decreased, indicating that a new CL transfer mode was reported. Perforated small starch granules were released after CcGBE treatment, and a time-dependent decrease in the retrogradation enthalpy (ΔHr) of cassava starch indicated that CcGBE inhibited the long-term retrogradation of starch. Moreover, the RS content and cold water solubility (CWS) of CcGBE-modified starch increased from 3.3 to 12.8% and from 23.1 to 93.8%, respectively. These findings indicate the application potential of CcGBE for the preparation of modified starch with increased RS and CWS.
Keywords: cassava starch; chain length distribution; glycogen branching enzyme; resistant starch; retrogradation.