Effect of cross-linkers on the structure and function of pig-renal sodium–glucose cotransporters after papain treatment

Kidney brush-border membranes contain two sodium-dependent glucose transporters, one with low and one with high affinity for phlorizin, the specific inhibitor of these transporters. Using Scatchard analysis of phlorizin binding and Western blotting with specific antibodies against these transporters, we demonstrate in this study that although both transporters were proteolysed by papain treatment, only the high-affinity phlorizin-binding sites were decreased. Papain treatment followed by cross-linking with homobifunctional disuccinimidyl tartarate restored only the structure of the low-affinity phlorizin-binding protein (approx. molecular mass 70 kDa) without modifying the phlorizin-binding sites. When disuccinimidyl tartarate was replaced with dithiobis(succinimidyl acetate), another homobifunctional cross-linker with a higher spacer arm, the low- and high-affinity sites were both restored, with reappearance of two phlorizin-binding proteins with approx. molecular masses of 70 and 120 kDa. We conclude that high-affinity phlorizin-binding sites depend on the presence of the heterodimeric 120 kDa protein.

Role of carboxyl and sulfhydryl residues on rabbit small intestinal brush-border membrane Na(+)-glucose cotransporter

The role of sulfhydryl (SH) and carboxylic acid residues in Na(+)-dependent glucose uptake, Na(+)-dependent phlorizin binding, and substrate exchange by the rabbit small intestinal brush-border membrane (BBM) Na(+)-glucose cotransporter was examined in sodium dodecyl sulfate-BBM vesicles. The sulfhydryl reagent p-chloromercuribenzoate (PCMB) inhibited all three measures of cotransporter function in a dithiothreitol-sensitive manner with similar K0.5 values (concn of PCMB resulting in 50% inhibition). PCMB sulfonate had no effect on Na(+)-glucose cotransporter function < 250 microM. The carboxylic acid reagent 1-ethyl-3-(4-azonia-4,4-dimethylpentyl)carbodiimide no effect on Na(+)-glucose cotransporter function. N,N'-dicyclohexylcarbodiimide (DCCD) inhibited all three measures of cotransporter function with similar K0.5 values for inhibition. Inhibition by DCCD did not require addition of a nucleophile. In contrast, PCMB-pretreated cotransporter was insensitive to DCCD in the absence of added nucleophile with respect to substrate transport (Na(+)-dependent glucose uptake) but not Na(+)-dependent phlorizin binding. These results indicate an intravesicular or lipophilic environment for both the PCMB-reactive SH residue and the DCCD-reactive carboxylic acid residues, suggesting that a SH residue may act as an endogenous nucleophile for interaction of DCCD with the Na(+)-glucose cotransporter and suggesting that different carboxylic acid residues may be involved in Na(+)-dependent glucose uptake and Na(+)-dependent phlorizin binding.

Site density of mouse intestinal glucose transporters declines with age

To evaluate the effect of age on nutrient transport, the absorption rates of D-glucose, D-fructose, L-alanine, L-aspartate, L-leucine, L-lysine, L-proline, folic acid, and nicotinamide were determined in isolated jejunal tissues of young (6.7 mo old) and aged (23.7 and 27.0 mo old) mice (COBS:SFW). D-Glucose and D-fructose uptakes per milligram tissue were approximately 20-120% higher in the proximal jejunum and 15-50% higher in the distal jejunum of young mice. Amino acid and vitamin uptakes per milligram were also higher in young mice, but differences were not statistically significant. The number of Na(+)-D-glucose transporters per milligram tissue as estimated by specific phlorizin binding decreased with age. There was no age-related change in passive L-glucose permeability, in Kd of specific phlorizin binding, in transporter turnover rate, and in the molecular weight of the Na(+)-D-glucose transporter. Thus a reduction in D-glucose transporter site density fully accounts for the age-related decline in D-glucose transport rate per milligram small intestine.

Effect of diet on glucose transporter site density along the intestinal crypt-villus axis

High-carbohydrate diets stimulate intestinal brush-border glucose uptake and increase the number of glucose-protectable phlorizin binding sites, but it has been unknown where along the crypt-villus axis these effects are expressed. We attacked this problem by three methods. First, by measuring phlorizin binding to isolated mouse enterocytes fractionated along the crypt-villus axis by the Weiser method, we identified a high-affinity binding site predominating from villus tip to midvillus and a site of possibly lower affinity predominating in the crypts. A high-carbohydrate diet increased by severalfold the density of the villus sites and probably also of the crypt sites, without changing their binding constants. Second, autoradiography revealed increased glucose-protectable phlorizin binding along the whole crypt-villus axis on a high-carbohydrate diet. Finally, a polyclonal antibody against the Na(+)-glucose cotransporter recognized a protein in the brush-border membrane of villus cells. Hence, substrate-dependent upregulation of intestinal glucose transport involves increased numbers of transporters along the crypt-villus axis.