Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P50583 (asymmetrical)
 12,197 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have explored evidence that suggests that lateral intercellular spaces is the mammalian proximal nephron do not serve as a hypertonic "central compartment" driving volume absorption. A primary consideration is the very low transepithelial resistance of this tissue as demonstrated by several laboratories. By making the reasonable assumption that passive ion permeation occurs via a paracellular route, we have concluded that the diffusion resistance of the spaces in insufficient to allow the development of a significant compositional difference between the spaces and the peritubular medium. This conclusion led us to look for potential osmotic gradients existing between the luminal and peritubular solutions. From the perfusion rate dependence of osmotic volume flow in the absence of active transport in isolated convoluted and straight proximal tubules, we calculated that both segments have very high hydraulic conductances, on the order of 3,000-5,000 micron/sec. Consequently, slight differences in the effective osmolality of the external solutions are sufficient to explain net volume absorption both in vivo and in vitro. We have provided evidence for two such driving forces. First, the development of asymmetrical anion concentration differences along the length of the proximal nephron due to preferential reabsorption of HCO-3 provides a driving force if the reflection coefficient for HCO-3 exceeds that for Cl-. Second, slight luminal hypotonicity may develop as a consequence of active solute absorption. Although both mechanisms probably occur simultaneously in vivo, we consider the former to be quantitatively the most important.
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PMID:External solution driving forces for isotonic fluid absorption in proximal tubules. 76 48

The effect of oncotic pressure changes on fluid (Jv) and net bicarbonate transport (JHCO-3) and the transepithelial bicarbonate permeability (PHCO-3) were measured by an improved luminal and capillary microperfusion method that allows paired experiments on the same tubule. Rat proximal tubules were pump-perfused and Jv and [HCO-3] measured with [14C]inulin and a pH glass electrode. Raising peritubular protein (0-8-15 g/100 ml bovine serum albumin) stimulated Jv and HCO-3 reabsorption. The response to oncotic pressure changes was asymmetrical since changes of the luminal protein concentration had no significant effects. Whereas transepithelial solvent drag effects on HCO-3 must be minimal, peritubular protein most likely stimulates translocation of fluid and bicarbonate from intercellular spaces into peritubular capillaries. PHCO-3 was measured from HCO-3 net flux along a lumen-to-capillary-directed electrochemical potential gradient. In these experiments active H+ transport and Jv were minimized by 10(-4) M acetazolamide and luminal raffinose. PHCO-3 was 1.77 X 10(-5) cm X s-1 and was unaffected by increasing luminal flow rate from 10 to 45 nl X min-1. Since bicarbonate backflux is only a small fraction of physiological rates of JHCO-3, net transport alterations at varying [HCO-3] in the lumen must be due to changes in active HCO-3 (H+) transport. Thus, active H+ ion secretion across the luminal membrane of the proximal tubule is gradient dependent.
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PMID:Passive driving forces of proximal tubular fluid and bicarbonate transport: gradient dependence of H+ secretion. 663 82

We examined whether protein kinase C (PKC) modulates the transport systems involved in bicarbonate movements across the plasma membranes of rat jejunum. Results of enzymatic assays provide evidence that under basal conditions conventional PKC (cPKC) is present in both basolateral membranes (BLMs) and apical (brush border) membranes (BBMs) of the enterocyte. In BLMs the basal expression of the kinase is low compared to expression in BBMs; however, treatment with Ca(2+) and phorbol 12-myristate 13-acetate (PMA) causes a significant increase, thus suggesting an asymmetrical kinase translocation. To explore the effect of PKC activation on membrane-bound transport mechanisms, 'in vitro' phosphorylated membrane vesicles were used to perform uptake studies. Results suggest that PKC activation exerts an inhibitory effect on the basolateral Cl(-)-HCO(3)(-) antiporter, whereas the basolateral HCO(3)(-) conductive pathway seems to be stimulated and Cl(-) conductance unaffected. The apical, but not basolateral, Na(+)-H(+) exchanger is inhibited by PKC activation. The specificity of the response to PKC was confirmed by using the kinase inhibitor staurosporine or the inactive phorbol ester 4-alpha-PMA. The inhibition of both apical Na(+)-H(+) and basolateral Cl(-)-HCO(3)(-) exchange activities suggests that the overall action of PKC causes a reduction of transepithelial bicarbonate transport.
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PMID:Protein kinase C regulation of rat jejunal transport systems: mechanisms involved in bicarbonate absorption. 1208 97