Interference of D-mannoheptulose with D-glucose phosphorylation,metabolism and functional effects: Comparison between liver,parotid cells and pancreatic islets

D-mannoheptulose is currently used as a tool to inhibit, in a competitive manner, D-glucose phosphorylation, metabolism and functional effects in the pancreatic islet B-cell. In order to better understand the mode of action of the heptose, we have explored its effect upon D-glucose phosphorylation in liver, parotid cells and islet homogenates, this allowing to characterize the interference of the heptose with glucokinase and/or hexokinase. The effect of D-mannoheptulose upon the metabolism of D-glucose was also examined in both intact parotid cells and pancreatic islets. Last, the effect of D-mannoheptulose upon glucose-stimulated insulin release was reinvestigated over large concentration ranges of both the heptose and hexose. The experimental data revealed a mixed type of D-mannoheptulose inhibitory action upon D-glucose phosphorylation, predominantly of the non-competitive and competitive type, in liver and parotid homogenates, respectively. Despite efficient inhibition of hexose phosphorylation in both parotid cell and islet homogenates, the heptose suppressed the metabolic and functional responses to D-glucose only in pancreatic islets, whilst failing to affect adversely D-glucose catabolism in parotid cells. These findings suggest that factors such as the intracellular transport and availability of the heptose may interfere with the expression of its antagonistic action upon D-glucose metabolism.     

Comparison between D-[3-3H]- and D-[5-3H]glucose and fructose utilization in pancreatic islets from control and hereditarily diabetic rats

The metabolism of D-glucose and/or D-fructose was investigated in pancreatic islets from control rats and hereditarily diabetic GK rats. In the case of both D-glucose and D-fructose metabolism, a preferential alteration of oxidative events was observed in islets from GK rats. The generation of 3HOH from D-[5-3H]glucose (or D-[5-3H]fructose) exceeded that from D-[3-3H]glucose (or D-[3-3H]fructose) in both control and GK rats. This difference, which is possibly attributable to a partial escape from glycolysis of tritiated dihydroxyacetone phosphate, was accentuated whenever the rate of glycolysis was decreased, e.g., in the absence of extracellular Ca(2+) or presence of exogenous D-glyceraldehyde. D-Mannoheptulose, which inhibited D-glucose metabolism, exerted only limited effects upon D-fructose metabolism. In the presence of both hexoses, the paired ratio between D-[U-14C]fructose oxidation and D-[3-3H]fructose or D-[5-3H]fructose utilization was considerably increased, this being probably attributable, in part at least, to a preferential stimulation by the aldohexose of mitochondrial oxidative events. Moreover, this coincided with the fact that D-mannoheptulose now severely inhibited the catabolism of D-[5-3H]fructose and D-[U-14C]fructose. The latter situation is consistent with both the knowledge that D-glucose augments D-fructose phosphorylation by glucokinase and the findings that D-mannoheptulose, which fails to affect D-fructose phosphorylation by fructokinase, inhibits the phosphorylation of D-fructose by glucokinase.     

Inhibition of glucose-induced insulin release by 3-O-methyl-D-glucose: Enzymatic,metabolic and cationic determinants

The analog of D-glucose, 3-O-methyl-D-glucose, is thought to delay the equilibration of D-glucose concentration across the plasma membrane of pancreatic islet B-cells, but not to exert any marked inhibitory action upon the late phase of glucose-stimulated insulin release. In this study, however, 3-O-methyl-D-glucose, when tested in high concentrations (30-80 mM) was found to cause a rapid, sustained and not rapidly reversible inhibition of glucose-induced insulin release in rat pancreatic islets. In relative terms, the inhibitory action of 3-O-methyl-D-glucose was more marked at low than high concentrations of D-glucose. It could not be attributed to hyperosmolarity and appeared specific for the insulinotropic action of D-glucose, as distinct from non-glucidic nutrient secretagogues. Although 3-O-methyl-D-glucose and D-glucose failed to exert any reciprocal effect upon the steady-state value for the net uptake of these monosaccharides by the islets, the glucose analog inhibited D-[5-3H]glucose utilization and D-[U-14C]glucose oxidation. This coincided with increased 86Rb outflow and decreased 45Ca outflow from prelabelled islets, as well as decreased 45Ca net uptake. A preferential effect of 3-O-methyl-D-glucose upon the first phase of glucose-stimulated insulin release was judged compatible with an altered initial rate of D-glucose entry into islet B-cells. The long-term inhibitory action of the glucose analog upon the metabolic and secretory response to D-glucose, however, may be due, in part at least, to an impaired rate of D-glucose phosphorylation. The phosphorylation of the hexose by beef heart hexokinase and human B-cell glucokinase, as well as by parotid and islet homogenates, was indeed inhibited by 3-O-methyl-D-glucose. The relationship between insulin release and D-glucose utilization or oxidation in the presence of 3-O-methyl-D-glucose was not different from that otherwise observed at increasing concentrations of either D-glucose or D-mannoheptulose. It is concluded, therefore, that 3-O-methyl-D-glucose adversely affects the metabolism and insulinotropic action of D-glucose by a mechanism largely unrelated to changes in the intracellular concentration of the latter hexose.     

Glucose-induced positive cooperativity of fructose phosphorylation by human B-cell glucokinase

Human B-cell glucokinase displays sigmoidal kinetics towards D-glucose or D-mannose, but fails to do so towards D-fructose. Yet, D-glucose, D-mannose and 2-deoxy-D-glucose confer to the enzyme positive cooperativity towards D-fructose. For instance, in the presence of 5 mM D-[U-¹⁴C]fructose, its rate of phosphorylation is increased to 214.3 ± 11.0%, 134.0 ± 4.3% and 116.5 ± 3.0% of paired control value by D-glucose, D-mannose and 2-deoxy-D-glucose (each 6 mM), respectively. D-glucose and, to a lesser extent, D-mannose also display reciprocal kinetic cooperativity. D-fructose, however, fails to affect D-glucose or D-mannose phosphorylation under conditions in which positive cooperativity is otherwise observed. These findings are relevant to the reciprocal effects of distinct hexoses upon their phosphorylation by B-cell glucokinase and, as such, to the metabolic and functional response evoked in pancreatic islet B-cells by these sugars, when tested either separately or in combination. (Mol Cell Biochem 175: 263–269, 1997)     

Salivary biomass assessed by bioluminescence ATP assay related to (bacterial and somatic) cell counts

The present work aimed (1) to evaluate ATP content in saliva by the bioluminescent luciferin-luciferase method, (2) to evaluate the relationships between ATP content, bacterial count and epithelial cell numbers in saliva, (3) to study the effect of two different antiseptics (peroxidase system producing hypothiocyanite and chlorhexidine) on the salivary biomass. In 45 young adults, the salivary ATP content ranged from 8 to 1515 nM. Salivary ATP content was significantly and directly correlated to bacterial count and epithelial cell numbers (Spearman-Rank correlation, P< or =0.001). Regression analysis allowed the inference of a mean epithelial cell and bacterial ATP content of 152.7 fg and 8.3 fg per cell, respectively. The salivary ATP content decreased significantly to 38. 8+/-12.3 per cent (mean+/-SEM, N=6) of its initial value after a 30-min incubation in the presence of a peroxidase system producing hypothiocyanite (OSCN(-)). Chlorhexidine (CHX) reduced salivary ATP content to 52.0+/-16.7 per cent. OSCN(-) did not affect the transformed logarithm of bacterial count but CHX reduced it from 7. 02+/-0.26 to 0.52+/-0.33. No effect of OSCN(-) was seen on the ratio of epithelial cell viability while CHX reduced it from 46.7+/-5.1 to 3.9+/-1.1 per cent. It is concluded that the combination of the evaluations of the ATP content and cell numbers in saliva can provide reliable data about the effects of oral antiseptics on salivary biomass.