Investigating sorghum protein solubility and in vitro digestibility during seed germination.

In this work, we examined the impact of sorghum gain germination on kafirins solubility and digestibility. Two genotypes differing in their proteins and tannins contents were germinated under controlled conditions up to radicle emergence. Biochemical, physicochemical, and in vitro digestibility tests were applied on the germinated grains. Microscopic examination of grains endosperm revealed that germination resulted in pitted starch granules and protein matrix slackening. Apart cystine and the amount of free thiol groups which increased significantly, the overall amino acids composition remained rather unchanged, just as the kafirins solubility and size distribution. In contrast germination was demonstrated to improved significantly the in vitro protein digestibility, even after cooking and especially for the genotype poor in tannin. Without inducing major physicochemical changes, germination enhanced kafirins susceptibility to gastrointestinal proteases. Germination may be a way to improve the nutritional value of sorghum.

Sorghum grain germination as a route to improve kafirin digestibility: Biochemical and label free proteomics insights.

Kafirin, the sorghum grain storage protein presents lower digestibility compared to its cereals counterparts. Germination has been proposed as an adequate bioprocessing method to improve seed protein digestibility. Here, germination was rationalized so as to evenly sample germinated seeds and the dynamic changes of the proteome and several biochemical markers was connected for the first time with the in vitro protein digestibility of germinated seeds. Free sulfhydryl groups increased during germination and in vitro protein digestibility enhanced. The dynamic in abundance of several enzymes out of which 3 cysteine proteases were found to coincide with appearance of aqueous soluble peptides derived from kafirin at boot time of their degradation. The study provides deep information about the molecular events occurring during sorghum seed germination and reveals potential biomarkers of the kafirin proteolysis. It points a way to improve sorghum nutritional value through controlled germination.

Relationship between endosperm cells redox homeostasis and glutenin polymers assembly in developing durum wheat grain.

Assembly of glutenin polymers was examined for two contrasted durum wheat cultivars in connection with changes in the redox status of the endosperm cells that accompanied grain development. The evolutions of the redox state of ascorbate and glutathione, as well as the activities of antioxidant enzymes were measured. Changes in the size distribution profile and redox state of storage proteins were evaluated, with particular emphasis on protein-bound glutathione (PSSG). At the beginning of grain filling phase, the size distribution profile of proteins included an extra peak shoulder at about 40,000 g mol(-1). The shoulder was assimilated to free glutenin subunits as it disappeared concomitantly with the upturn in glutenin polymers accumulation. Irrespective of cultivars, small SDS-soluble polymers accumulated first, followed by larger and insoluble ones, attesting for a progressive polymerization. During the grain filling phase, catalase (EC 1.11.1.6) activity dropped, reaching a very low level at physiological maturity. During the same period, superoxide dismutase (EC 1.15.1.1) and glutathione reductase (EC 1.6.4.2) activities increased steadily while the equilibrium constant between GSSG and PSSG shifted from 10(-2) to unity. These results demonstrated that grain filling was accompanied by a continuous decrease in cellular redox potential. In this context, formation of protein-bound glutathione would represent a protective mechanism against irreversible thiol oxidation. Storage protein S-glutathionylation instead of limiting glutenin polymer assembly as it has been proposed might be a required intermediate step for glutenin subunits pairing.

Mechanisms of heat-mediated aggregation of wheat gluten protein upon pasta processing.

During pasta processing, structural changes of protein occur, due to changes in water content, mechanical energy input, and high temperature treatments. The present paper investigates the impact of successive and intense thermal treatments (high temperature drying, cooking, and overcooking) on aggregation of gluten protein in pasta. Protein aggregation was evaluated by the measurement of sensitivity of disulfide bonds toward reduction with dithioerythritol (DTE), at different reactions times. In addition to the loss in protein extractability in sodium dodecyl sulfate buffer, heat treatments induced a drastic change in disulfide bonds sensitivity toward DTE reduction and in size-exclusion high-performance liquid chromatography profiles of fully reduced protein. The protein solubility loss was assumed to derive from the increasing connectivity of protein upon heat treatments. The increasing degree of protein upon aggregation would be due to the formation of additional interchain disulfide bonds.

Polymerization kinetics of wheat gluten upon thermosetting. A mechanistic model.

Size exclusion high-performance liquid chromatography analysis was carried out on wheat gluten-glycerol blends subjected to different heat treatments. The elution profiles were analyzed in order to follow the solubility loss of protein fractions with specific molecular size. Owing to the known biochemical changes involved during the heat denaturation of gluten, a mechanistic mathematical model was developed, which divided the protein denaturation into two distinct reaction steps: (i) reversible change in protein conformation and (ii) protein precipitation through disulfide bonding between initially SDS-soluble and SDS-insoluble reaction partners. Activation energies of gluten unfolding, refolding, and precipitation were calculated with the Arrhenius law to 53.9 kJ x mol(-1), 29.5 kJ x mol(-1), and 172 kJ x mol(-1), respectively. The rate of protein solubility loss decreased as the cross-linking reaction proceeded, which may be attributed to the formation of a three-dimensional network progressively hindering the reaction. The enhanced susceptibility to aggregation of large molecules was assigned to a risen reaction probability due to their higher number of cysteine residues and to the increased percentage of unfolded and thereby activated proteins as complete protein refolding seemed to be an anticooperative process.