Conformational properties of heterogeneous arabinoxylan protein gums from corn bran and distillers grains in comparison with gum arabic

Abstract

The molecular structure and conformation of arabinoxylan-protein gum, commonly referred as corn fiber gum (CFG) were analyzed by high-performance size-exclusion chromatography (HPSEC) coupled with RI, UV, light scattering and viscometer detectors. CFG had a heterogeneous structure. The detailed conformation of CFG at different molecular weights was compared with that of hemicellulose fiber gum (HFG) from dried distiller's grains with solubles and gum arabic. The CFG molecules mainly had random coil conformation; only 10 % of them exhibited rigid rod conformation. Approximately 80 % of the CFG had a molecular weight between 105 and 105.4 Da, while the other 20 % of molecules were between 105.4 and 1.5 × 107.7 Da. The overall conformational properties of CFG and HFG were closer but differed from that of gum arabic. The intrinsic viscosity and radius of gyration of both CFG and HFG were greater than those of gum arabic although the average molecular weight of CFG and HFG was lower. The protein and carbohydrate were covalently linked in CFG molecules as shown by the HPSEC-multiple detectors combined with partial acid hydrolysis. Based on the detailed conformation of CFG and the methylation analysis, 1D and 2D NMR spectroscopy results, the molecular structure of CFG was proposed.