Rabbit NHE2 and NHE3 are two epithelial isoform Na+/H+ exchangers (NHE), the messages for which are found predominantly and entirely, respectively, in renal, intestinal, and gastric mucosa. The current studies used Western analysis and immunohistochemistry to identify and characterize the apical vs. basolateral membrane distribution of NHE2 and NHE3 in intestinal epithelial cells. Based on Western analysis, NHE2 and NHE3 both are present in brush-border but not basolateral membranes of small intestine. Both NHE2 and NHE3 are 85-kDa proteins. Consistent with Western analysis, NHE2 and NHE3 are immunolocalired to the brush-border but not basolateral membranes of villus epithelial cells, but not goblet cells, in human jejunum and ileum and in surface epithelial cells in the ascending and descending colon and rectum. In addition, NHE2 and NHE3 are present in small amounts in the crypt cell brush border of human jejunum, ileum, ascending and descending colon, and rectum. In rabbit jejunum, ileum, and ascending colon, NHE2 and NHE3 are present in the brush border of epithelial and not goblet cells, again much more in the villus (small intestine)/ surface cells (colon) than the crypt. NHE2 but not NHE3 is present in the brush border of rabbit descending colon surface cells and in small amounts in crypt cells. NHE2 and NHE3 are both human and rabbit small intestinal and colonic epithelial cell brush-border Na+/H+ exchanger isoforms that colocalize in all intestinal segments except rabbit descending colon, which lacks NHE3.
Resistance to insulin-mediated glucose disposal has been postulated to predispose individuals to a cluster of associated abnormalities (Syndrome X) known to increase risk of cardiovascular disease (CVD). Although several abnormalities subsumed under the rubric of Syndrome X have been shown to predict CVD, there has been no prospective study evaluating the power of insulin resistance, the putative fundamental defect in the syndrome, in this context. Therefore, this study was initiated to evaluate the hypothesis that resistance to insulin-mediated glucose disposal would predict the development of CVD in healthy volunteers. To accomplish this goal, 147 normal, healthy, nonobese, volunteers were evaluated [4.7 +/- 0.1 yr (mean +/- SEM)] after baseline measurements of steady state plasma glucose concentration (an estimate of insulin-mediated glucose disposal), as well as other CVD risk factors. Clinical end points developed in 13 subjects during the follow-up period; hypertension in 5, coronary artery disease in 4, cerebrovascular accident in 3, and peripheral vascular disease in 1. There was a significant univariate relationship between SSPG and CVD (P < 0.002), with the majority of the events taking place in the tertile of subjects with the highest SSPG concentration, i.e. the greatest degree of insulin resistance. In contrast, no CVD events were observed in the tertile with the lowest SSPG concentrations; the most insulin sensitive. SSPG was also related significantly to diastolic blood pressure, triglyceride, and low-density lipoprotein and high-density lipoprotein cholesterol concentrations, and the glucose and insulin responses to oral glucose. All of these relationships were independent of age, gender, body mass index, estimates of physical activity, and smoking history. When SSPG was paired with each of the other variables in a series of multiple regression models, only SSPG, or insulin response, were independent predictors of CVD events. In conclusion, approximately one of every five healthy, nonobese subjects in the most insulin-resistant tertile, followed for approximately 5 yr, had a serious clinical event. These data highlight the importance of insulin resistance as a predictor of CVD.
NHE3, a cloned intestinal and renal brush border Na+/H+ exchanger, has previously been shown to be both stimulated and inhibited by different protein kinases/growth factors. For instance, NHE3 is stimulated by serum and fibroblast growth factor (FGF) and inhibited by protein kinase C. In the present study, we used a series of NHE3 C terminus truncation mutants to identify separate regions of the C-terminal cytoplasmic tail responsible for stimulation and inhibition by protein kinases/growth factors. Five NHE3 C terminus truncation mutant stable cell lines were generated by stably transfecting NHE3 deletion cDNAs into PS120 fibroblasts, which lack any endogenous Na+/H+ exchanger. Using fluorometric techniques, the effects of the calcium/calmodulin (CaM) inhibitor W13, calcium/CaM kinase inhibitor KN-62, phorbol myristate acetate, okadaic acid, FGF, and fetal bovine serum on Na+/H+ exchange were studied in these transfected cells. Inhibition of basal activity of full-length NHE3 is mediated by CaM at a site C-terminal to amino acid 756; this CaM effect occurs through both kinase dependent and independent mechanisms. There is another independent inhibitory domain for protein kinase C between amino acids 585 and 689. In addition, there are at least three stimulatory regions in the C-terminal domain of NHE3, corresponding to amino acids 509-543 for okadaic acid, 475-509 for FGF, and a region N-terminal to amino acid 475 for fetal bovine serum. We conclude that separate regions of the C terminus of NHE3 are involved with stimulation or inhibition of Na+/H+ exchange activity, with both stimulatory and inhibitory domains having several discrete subdomains. A conservative model to explain the way these multiple domains in the C terminus of NHE3 regulate Na+/H+ exchange is via an effect on associated regulatory proteins.
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