Variants of ß-casofensin, a bioactive milk peptide, differently modulate the intestinal barrier: In vivo and ex vivo studies in rats.

ß-Casofensin is a bioactive milk peptide that modulates the intestinal barrier, particularly through its action on goblet cells. ß-Casofensin corresponds to fragment (f) 94-123 of the bovine ß-casein (ß-CN) A2 variant. Fifteen genetic variants of bovine ß-CN (A1-3, B-G, H1-2, I-L) are known, of which the A2, A1, and B forms are the most common. These variants differ from each other by the substitution of one or more amino acids, some of which are localized in f94 to 123. The aim of our study was to compare the intestinal effects of ß-casofensin A2 and its 3 main variants: A1, A3, and B. For this purpose, a solution (0.1 µM; 10 µL/g of body weight, postnatal d 10-20) containing ß-casofensin A2, one of its variants (A1, A3, or B), or drinking water (control; CT) was administered to rat pups orally. After euthanasia (postnatal d 20), intestinal segments were collected for biochemical and histochemical analysis and also used to determine paracellular permeability to fluorescein isothiocyanate-labeled 4-kDa dextran in an Ussing chamber. We also studied the direct effects of ß-casofensin A2 and its A1 variant on the paracellular permeability of jejunum segments of adult rats. ß-Casofensin A2 and its B variant significantly increased the population of goblet cells compared with the CT, A1, and A3 groups. The mucin 2 mRNA level was significantly higher in the ß-casofensin A2 group than in the CT, A3, and B groups. Our results also revealed that the protein expression of zonula occludens-1 and occludin was reduced in the jejunum of rats in the A1, A3, and B groups compared with the CT group. However, the A1 variant was the only peptide to decrease jejunal permeability compared with the CT group. This variant, tested directly in the apical compartment of an Ussing chamber at a concentration of 0.1 nM, also reduced jejunal permeability. In conclusion, the substitution of a single amino acid alters the effect of ß-CN sequence f94 to 123 on goblet cells and on intestinal permeability. A genetic polymorphism of ß-CN can affect the biological activity of peptides derived from this protein. These data should be taken into account in the production of bioactive foods.

The influence of metabolic network structures and energy requirements on xanthan gum yields.

The metabolic network of Xanthomonas campestris is complex since a number of cyclic pathways are present making simple stoichiometric yield predictions difficult. The influence of certain pathway configurations and the resulting variations in flux have been examined as regards the maximum yield potential of this bacteria for xanthan gum production. These predictions have been compared with experimental results showing that the strain employed is functioning close to its theoretical maximum as regards yield criteria. The major constraint imposed on the network concerns energy availability which has a more pronounced effect on yield than carbon precursor supply. This can be attributed to the relatively high maintenance requirements determined experimentally and incorporated into the model. While some of this overall energy burden will undoubtedly be associated with incompressible metabolic requirements such as sugar uptake and xanthan efflux mechanisms, future strain improvement strategies will need to attack other non-essential energy-consuming reactions, if yields are to be further increased.