Y H Liau

In vitro fatty acid acylatin of mucus glycoprotein from sublingual salivary glands

The enzyme activity which catalyzes the transfer of palmitic acid from palmitoyl-coenzyme A to sublingual gland mucus glycoprotein has been demonstrated in the detergent extracts of the microsomal fraction of rat sublingual and parotid salivary glands. The acyltransferase activity of this fraction was similar in both types of glands. Further subcellular fractionation performed on sublingual glands revealed that the enzyme is associated with the Golgi-rich membrane fraction. Optimum enzymatic activity for fatty acylation of mucus glycoprotein was obtained using 0.5% Triton X-100, 2 mM dithiothreitol, 25 mM NaF, and 10 mM MgCl2 at a pH of 7.4. Higher concentrations of NaF, MgCl2 and dithiothreitol, however, were inhibitory. The apparent Km of the sublingual glands microsomal enzyme for mucus glycoprotein was 0.55 mg/ml and for palmitoyl-CoA, 3.5 X 10(-5) M. A 15% decrease in the acyltransferase activity was obtained with the reduced and alkylated mucus glycoprotein and it showed no activity towards the proteolytically degraded glycoprotein. The 14C-labeled product of the enzyme reaction gave in CsCl density gradient a band at the density of 1.49 in which the 14C label coincided with the glycoprotein. The 14C label in this glycoprotein was susceptible to deacylation with hydroxylamine, and the released labeled material was identified as palmitate.

Lysolecithin Affects the Viscosity, Permeability, and Peptic Susceptibility of Gastric Mucin

The effect of lysolecithin and lecithin on gastric mucin viscosity, permeability to hydrogen ion, and degradation by pepsin was investigated. Preincubation with lysolecithin produced a marked decrease in the glycoprotein viscosity. This decrease was concentration-dependent and at 10 mM lysolecithin reached a value of 74%. A 25% increase in mucin viscosity was obtained with 10 mM lecithin. Permeability measurements showed that 10 mM lecithin increased the retardation ability of the glycoprotein to hydrogen ion by 11%, whereas a 12% decrease in the retardation capacity of the glycoprotein was obtained with 10 mM lysolecithin. The results of peptic activity assay indicated that whereas lecithin had no effect on the rate of mucin proteolysis, the lysolecithin exerted significant (75%) stimulatory effect. The results suggest that lysolecithin in the stomach weakens the integrity of the protective mucus layer by promoting peptic degradation, reducing the ability to resist acid penetration, and decreasing viscosity of its mucin component.

Fatty acid acylation of mucin by gastric mucosa: Effects of sofalcone and sucralfate

The effects of antiulcer drugs, sofalcone and sucralfate, on the activity of gastric mucosal mucus glycoprotein fatty acyltransferase were investigated. The acyltransferase enzyme, contained in the detergent extracts of the microsomal fraction of rat gastric mucosa, was incubated with the deacylated gastric mucin and palmitoyl-CoA substrates in the presence and absence of drugs, and the formed fatty acid acylated glycoprotein product was quantitated. In the absence of drugs, the enzymatic activity increased proportionally with increased concentrations of both substrates and of enzyme, and gave an apparent Km value of 5.6 X 10(-7) M. Introduction of sofalcone to the reaction mixtures led to an enhancement in the rate of mucus glycoprotein acylation. The rate of enhancement was proportional to sofalcone concentration up to 1.0 X 10(-5) M, with an apparent Km value of 3.7 X 10(-7) M. In contrast to sofalcone, the acyltransferase activity was inhibited by sucralfate. The rate of inhibition of mucus glycoprotein acylation by sucralfate was of the competitive type and at 1.0 X 10(-4) M reached a value of 25%. The apparent KI value calculated from the double-reciprocal plots for sucralfate was 9.1 X 10(-7) M. As the acylation of mucin with fatty acids plays an important role in the maintenance of gastric mucosal integrity, the results suggest that stimulation of the fatty acyltransferase enzyme by sofalcone may be one of the beneficial effects of this drug towards ulcer healing.

Enzymic acylation of mucus glycoprotein with palmitic acid in rat submandibular salivary gland

The enzymic activity which catalyses transfer of palmitic acid from palmitoyl coenzyme A to mucus glycoprotein was found in Triton X-100 extracts of the microsomal fraction of rat submandibular and sublingual salivary glands. The acyltransferase activity of this fraction was 1.3-1.4 times greater in submandibular gland than in sublingual gland. Further subcellular fractionation of submandibular gland showed that the enzyme activity was associated with a Golgi-rich membrane fraction. Optimum enzyme activity for fatty acylation of mucus glycoprotein was at pH 7.4 using 0.5 per cent Triton X-100, 2 mM dithiothreitol 25 mM NaF and 10 mM MgCl2; higher concentrations were inhibitory. The apparent Km of the submandibular microsomal enzyme for mucus glycoprotein was 5.9 X 10(-7) M, and for palmitoyl-CoA, 3.3 X 10(-5) M. The 14C-labelled glycoprotein product of the reaction co-migrated on CsCl equilibrium, density-gradient centrifugation with submandibular mucus glycoprotein, and contained ester-bound palmitic acid. The fatty acyltransferase showed no activity with proteolytically-degraded glycoprotein; the acceptor capacity of reduced and S-carboxymethylated glycoprotein was only about 10 per cent lower than that of the intact mucus glycoprotein. This suggests that the acylation of salivary mucus glycoprotein with fatty acids occurs at its non-glycosylated, proteolysis-susceptible regions, and that the majority of these fatty acids are linked to the glycoprotein through hydroxyl esters.