Production and stability of 3-hydroxypropionaldehyde in Lactobacillus reuteri.

3-Hydroxypropionaldehyde (3-HPA) is considered as a potent antimicrobial substance. Exploration of its application as a food preservative or as a therapeutic auxiliary agent has been documented in the literature. In the present work, factors that may impact on 3-HPA accumulation by Lactobacillus reuteri and on the stability of 3-HPA were investigated. Three media - H(2)O, milk and MRS broth - were chosen as test systems. Data indicated that 3-HPA accumulation in resting cells of L. reuteri in a two-step fermentation is greatly affected by temperature, pH, cell age and biomass as well as components in the test system. Within 2 h of incubation, 170 mM 3-HPA could be produced with a cell dry weight of 30 g/l, representing 85% of the glycerol supplied (200 mM) in H(2)O. The presence of glycerol during cell growth increased the productivity of 3-HPA by resting cells. In general, 3-HPA is much more stable in H(2)O than in milk and MRS. Factors that enhanced accumulation of 3-HPA did not simply show the same positive impact on the stability of 3-HPA. Thus, for defined applications, factors affecting production and stability of 3-HPA should be evaluated separately.

Effect of glucose on glycerol bioconversion by Lactobacillus reuteri.

The impact of glucose on glycerol metabolism, especially on 3-hydroxypropionaldehyde (3-HPA) accumulation by resting cells of Lactobacillus reuteri has been investigated. Two systems were used in the study: MRS(-) (modified MRS - omitting glucose, acetate and Tween 80) and distilled water (H(2)O). In MRS(-), addition of glucose enhanced glycerol metabolism in resting cells of L. reuteri, consequently increasing the accumulation of 3-HPA by regulating the NAD/NADH ratio. Enhanced glycerol metabolism correlated positively with the concentration of glucose. NADH produced during glucose metabolism was preferentially reoxidized to NAD by the reduction of 3-HPA to 1,3-propanediol; an adequate supply of glycerol therefore outweighed the repression of glucose on the accumulation of 3-HPA. At a molar ratio of glucose to glycerol no greater than 0.33, accumulation of 3-HPA was favored. In non-growing medium (H(2)O), addition of glucose seemed to be counter-productive with respect to 3-HPA accumulation. Lactate had a positive impact on glycerol metabolism, presumably by altering the redox flux, resulting in enhanced 3-HPA accumulation in both MRS(-) and H(2)O systems.

Proteolytic activities of suparen and rennilase on buffalo, cow, and goat whole casein and beta-casein.

The proteolytic specificity and activity of Mucor miehei protease (Rennilase) and Endothia parasitica protease (Suparen) on buffalo, cow, and goat whole casein and beta-casein (CN) were studied by analyzing the degradation products. The results suggest that Rennilase hydrolyzes casein of the three species in a manner similar to that of chymosin, resulting in the formation of alpha(s1)-I and beta-I, -II, -III as initial degradation fragments of alpha(s1)- and beta-CN. alpha(s1)-I was also the initial breakdown product of alpha(s1)-CN by Suparen. Contrary to Rennilase, Suparen showed a higher affinity toward beta-CN and hydrolyzes beta-CN, giving rise to degradation products characterized by mobility lower than that of beta-CN. Increasing NaCl concentration (>3%) reduced the proteolysis of beta-CN of the three species by Rennilase but not by Suparen. The hydrolysis of alpha(s1)-CN and alpha(s1)-I by the two enzymes was enhanced in the presence of NaCl.

Large spectral changes accompany the conformational transition of human pancreatic lipase induced by acylation with the inhibitor tetrahydrolipstatin.

Human pancreatic lipase (HPL) loses more than 80% of its activity when incubated with tetrahydrolipstatin in a buffer containing bile salts. During the inactivation process, large changes are observed in intrinsic tryptophan fluorescence and in the near-ultraviolet circular dichroism. The rate of chemical inactivation is highly comparable to that determined from the time dependence of the spectral changes. It is concluded that HPL undergoes a conformational transition upon inhibitor binding, resulting in a change in the microenvironment of tryptophan residues. Bile salts are needed in this system for effective inactivation of the enzyme by tetrahydrolipstatin, and a large increase in the inactivation rate takes place at about the critical micellar concentration (CMC) of bile salts. The inhibited enzyme can be reactivated by reducing the bile salt concentration to below the CMC, and the changes in tryptophan fluorescence induced by acylation with tetrahydrolipstatin are thereby reversed. This suggests that bile salts above their CMC stabilize the acyl-enzyme complex.

Identification of the active-site serine in human pancreatic lipase by chemical modification with tetrahydrolipstatin.

A chemical modification approach was used in this study to identify the active site serine residue of human pancreatic lipase. Purified human pancreatic lipase was covalently modified by incubation with [3H], [14C] tetrahydrolipstatin (THL), a potent inhibitor of pancreatic lipase. The radiolabeled lipase was digested with thermolysin, and the peptides were separated by HPLC. A single THL-peptide-adduct was obtained which was identical to that obtained earlier from porcine pancreatic lipase. This pentapeptide with the sequence VIGHS is covalently bound to a THL molecule via the side chain hydroxyl group of the serine unit corresponding to Ser-152 of the lipase. The selective cleavage of the THL-serine bond by mild acid treatment resulted in the formation of the delta-lactone Ro 40-4441 in high yield and clearly proves that THL is attached via an ester bond and with retention of stereochemistry at all chiral centers to the side chain hydroxyl group of Ser-152 of the lipase. The results obtained for human pancreatic lipase corroborate the inhibition mechanism of THL found on the porcine enzyme, and are in full agreement with the identification of the Ser-152 ... His-263 ... Asp-176 catalytic triad in the X-ray structure of human pancreatic lipase.