Hypoxia inhibits gene expression of voltage-gated K+ channel alpha subunits in pulmonary artery smooth muscle cells.

Activity of voltage-gated K+ channels (KV) in pulmonary arterial smooth muscle cells (PASMC) is pivotal in controlling membrane potential, cytoplasmic free Ca2+ concentration ([Ca2+]cyt, and pulmonary vasomotor tone. Acute hypoxia selectively inhibits KV channels, depolarizes PASMC, raises [Ca2+]cyt, and causes pulmonary vasoconstriction and vascular remodeling. Prolonged hypoxia (24-60 h) decreased significantly the mRNA levels of KV channel alpha subunits, KV1.2 and KV1.5. Consistently, the protein levels of KV1.2 and KV1.5 were also decreased significantly by hypoxia (48-72 h). Nevertheless, hypoxia affected negligibly the mRNA levels of KV channel beta subunits (KVbeta1, KVbeta2, and KVbeta3). The native K+ channels are composed of pore-forming alpha and auxiliary beta subunits. Assembly of KV beta subunits with alpha subunits confers rapid inactivation on the slowly or non-inactivating delayed rectifier KV channels. KV beta subunits also function as an open-channel blocker of KV channels. Thus, the diminished transcription and expression of KV alpha subunits may reduce the number of KV channels and decrease KC currents. Unchanged transcription of KV beta subunits may increase the fraction of the KV channel alpha subunits that are associated with beta subunits and further reduce the total KV currents. These data demonstrate a novel mechanism by which chronic hypoxia may cause pulmonary vasoconstriction and hypertension.

Na/Ca exchanger and PMCA localization in neurons and astrocytes: functional implications.

Immunocytochemistry reveals that the Na/Ca exchanger (NCX) in neuronal somata and astrocytes is confined to plasma membrane (PM) microdomains that overlie sub-PM (junctional) endoplasmic reticulum (jER). By contrast, the PM Ca(2+) pump (PMCA) is more uniformly distributed in the PM. At presynaptic nerve terminals, the NCX distribution is consistent with that observed in the neuronal somata, but the PMCA is clustered at the active zones. Thus, the PMCA, with high affinity for Ca(2+) (K(d) congruent with 100 nM), may keep active zone Ca(2+) very low and thereby "reprime" the vesicular release mechanism following activity. NCX, with lower affinity for Ca(2+) (K(d) congruent with 1,000 nM), on the other hand, may extrude Ca(2+) that has diffused away from the active zones and been temporarily sequestered in the endoplasmic reticulum. The PL microdomains that contain the NCX also contain Na(+) pump high ouabain affinity alpha2 (astrocytes) or alpha 3 (neurons) subunit isoforms (IC(50) congruent with 5-50 nM ouabain). In contrast, the alpha1 isoform (low ouabain affinity in rodents; IC(50) >10,000 nM), like the PMCA, is more uniformly distributed in these cells. The sub-PM endoplasmic reticulum in neurons (and probably glia and other cell types as well) and the adjacent PM form junctions that resemble cardiac muscle dyads. We suggest that the PM microdomains containing NCX and alpha 2/alpha 3 Na(+) pumps, the underlying jER, and the intervening tiny volume of cytosol (<10(-18) l) form functional units (PLasmERosomes); diffusion of Na(+) and Ca(2+) between these cytosolic compartments and "bulk" cytosol may be markedly restricted. The activity of the Na(+) pumps with alpha 2/alpha 3 subunits may thus regulate NCX activity and jER Ca(2+) content. This view is supported by studies in mice with genetically reduced (by congruent with 50%) alpha 2 Na(+) pumps: evoked Ca(2+) transients were augmented in these cells despite normal cytosolic Na(+) and resting Ca(2+) concentrations ([Na(+)](CYT) and [Ca(2+)](CYT)). We conclude that alpha 2/alpha 3 Na(+) pumps control PLasmERosome (local) [Na(+)](CYT). This, in turn, via NCX, modulates local [Ca(2+)](CYT), jER Ca(2+) storage, Ca(2+) signaling, and cell responses.

Na(+)-Ca2+ exchange in the rat brain during ontogeny.

A rise of Na(+)-Ca2+ exchange during ontogenic development was found in the rat brain which parallels brain maturation. Nerve endings are the main structure which contributes to the rise of the exchange activity.

Na+-Ca2+ exchanger in the soluble fraction of crayfish striated muscle.

Proteins with Na+-Ca2+ exchange activity from the soluble fraction of crayfish striated muscle were inserted into asolectin proteoliposomes. A pH dependent calcium uptake with an optimum at the alkaline side and inhibition in the presence of sodium or strontium ions in the external medium was observed. When expressed per tissue wet weight the capacity for Na+-Ca2+ exchange of proteoliposomes with inserted soluble proteins was by one half higher than that of the membrane fraction and more than twice higher in comparison with the reconstituted membrane bound exchanger. Using polyacrylamide gel electrophoresis two most prominent proteins with Mr over 200 and 43 kDa could be detected in proteoliposomes with the highest Na+-Ca2+ exchange. It is assumed that protein(s) with Mr 43 kDa could represent the soluble Na+-Ca2+ exchanger in crayfish striated muscle soluble fraction.

T-system membranes in microsomal fractions of crayfish muscles: identification and differences in protein composition.

Specific binding of 3H-ouabain and ruthenium red (RR) to membranes of T-tubules in crayfish muscles was used to identify the subfraction containing vesicles originating from the T-system. The microsomal fraction was prepared by differential centrifugation, and subfractions were separated in continuous or discontinuous sucrose density gradients. 3H-ouabain binding was estimated by scintillation counting; RR binding was examined by electron microscopy. The light subfraction was identified using both methods as that containing vesicles of T-tubules. Protein separation by SDS-electrophoresis revealed marked differences between the subfraction containing vesicles of T-tubules and other subfractions, the most distinctive feature being the presence of a protein of Mr 46,000 predominantly in the light subfraction.

Na(+)-Ca2+ exchange in locust striated muscles.

High Na+ + Ca2+ exchange rates comparable with those reported for crayfish striated muscle, rat heart and rat brain, were observed in locust striated muscle homogenates and membrane preparations. The Na(+)-Ca2+ exchange followed the 1st order kinetics with a Km value of 18 mumol.l-1 for Ca, the pH optimum was at 8, the temperature optimum at 30 degrees C, and the exchange was inhibited in the presence of sodium in the incubation medium, with a KiNa of approx. 25 mmol.l-1. The present results suggest a high Na(+)-Ca2+ exchange in locust striated muscles which operate on the calcium electrogenesis principle.

Na+-Ca2+ exchange in plasma membranes of crayfish striated muscle.

Na+-Ca2+ exchange rates and some physico-chemical properties of the exchanger were studied in crayfish striated muscle membranes enriched in plasma membranes prepared by differential centrifugation of muscle microsomal fraction on discontinuous sucrose density gradient. The lightest subfraction with the highest Na+, K+-ATPase and Mg2+-ATPase activities also showed the highest Na+-Ca2+ exchange rates. A number of physico-chemical characteristics of the Na+-Ca2+ exchanger found in the present experiments were similar to those reported for excitable membranes of mammals, except for the temperature optimum (20 degrees C for the crayfish).

Na+ pump low and high ouabain affinity alpha subunit isoforms are differently distributed in cells.

Three isoforms (alpha1, alpha2, and alpha3) of the catalytic (alpha) subunit of the plasma membrane (PM) Na+ pump have been identified in the tissues of birds and mammals. These isoforms differ in their affinities for ions and for the Na+ pump inhibitor, ouabain. In the rat, alpha1 has an unusually low affinity for ouabain. The PM of most rat cells contains both low (alpha1) and high (alpha2 or alpha3) ouabain affinity isoforms, but precise localization of specific isoforms, and their functional significance, are unknown. We employed high resolution immunocytochemical techniques to localize alpha subunit isoforms in primary cultured rat astrocytes, neurons, and arterial myocytes. Isoform alpha1 was ubiquitously distributed over the surfaces of these cells. In contrast, high ouabain affinity isoforms (alpha2 in astrocytes, alpha3 in neurons and myocytes) were confined to a reticular distribution within the PM that paralleled underlying endoplasmic or sarcoplasmic reticulum. This distribution is identical to that of the PM Na/Ca exchanger. This raises the possibility that alpha1 may regulate bulk cytosolic Na+, whereas alpha2 and alpha3 may regulate Na+ and, indirectly, Ca2+ in a restricted cytosolic space between the PM and reticulum. The high ouabain affinity Na+ pumps may thereby modulate reticulum Ca2+ content and Ca2+ signaling.

Antisense inhibition of Na+/Ca2+ exchange in primary cultured arterial myocytes.

The effects of chimeric phosphorothioated antisense oligodeoxynucleotides (AS-oligos) targeted against the Na+/Ca2+ exchanger (NCX) were tested in primary cultured rat mesenteric artery myocytes. In parallel cultures, myocytes proliferated and were morphologically normal in the presence of scrambled nonsense (NS-) or AS-oligos or no oligos (controls). NCX function was examined with digital imaging, using fura 2 to estimate the cytosolic free Ca2+ concentration ([Ca2+]cyt). Resting [Ca2+]cyt was higher (145 +/- 4 nM; P < 0.05) in AS-oligo-treated cells than in controls (125 +/- 5 nM) or NS-oligo-treated cells (131 +/- 4 nM). Lowering external Na+, to promote Ca2+ entry via NCX, increased [Ca2+]cyt transiently in controls and NS-oligo-treated cells but not in AS-oligo-treated cells. Raising the cytosolic free Na+ concentration with ouabain augmented the low-Na(+)-induced rise in [Ca2+]cyt in controls and NS-oligo-treated cells, but AS-oligo-treated cells still did not respond. Nevertheless, serotonin (5-HT) increased [Ca2+]cyt in all three groups. Thus AS-oligos selectively blocked NCX activity but not the 5-HT response. To determine the effect of NCX knockdown on the modulation of stored Ca2+, the 5-HT response was tested immediately after removal of external Ca2+. Ouabain augmented the 5-HT-induced rise in [Ca2+]cyt in control and NS-oligo-treated cells but not AS-oligo-treated cells. This indicates that the NCX can modulate intracellular Ca2+ stores. We conclude that AS-oligos are useful for investigating the physiological role of NCX in vascular smooth muscle.

Regulatory processes on the cytoplasmic surface of the Na(+)/Ca(2+) exchanger from lobster exoskeletal muscle.

A partially purified preparation of the lobster muscle Na(+)/Ca(2+) exchanger was reconstituted with, presumably, random orientation in liposomes. Ca(2+) efflux from (45)Ca-loaded vesicles was studied in exchanger molecules in which the transporter cytoplasmic surface was exposed to the extravesicular (ev) medium. Extravesicular Na(+) (Na(ev))-dependent Ca(2+) efflux depended directly upon the extravesicular Ca(2+) concentration ([Ca(2+)](ev)) with a half-maximal activation at [Ca(2+)](ev) = 0.6 microm. This suggests that the lobster muscle exchanger is catalytically upregulated by cytoplasmic Ca(2+), as in most other species. In contrast, at low [Na(+)](ev), the Ca(ev)-binding site (i.e., on the cytoplasmic surface) for Ca(2+) transported via Ca(2+)/Ca(2+) exchange was half-maximally activated by about 7.5 microm Ca(2+). Mild proteolysis of the Na(+)/Ca(2+) exchanger by alpha-chymotrypsin also upregulated the Na(ev)-dependent Ca(2+) efflux. Following proteolytic digestion in Ca-free medium, the exchanger was no longer regulated by nontransported ev Ca(2+). Proteolytic digestion in the presence of 1.9 microm free ev Ca(2+), however, induced only a 1. 6-fold augmentation of Ca(2+) efflux, whereas, after digestion in nominally Ca-free medium, a 2.3-fold augmentation was observed; Ca(2+) also inhibited proteolytic degradation of the Na(+)/Ca(2+) exchanger measured by immunoblotting. These data suggest that Ca(2+), bound to a high affinity binding site, protects against the activation of the Na(+)/Ca(2+) exchanger by alpha-chymotrypsin. Additionally, we observed a 6-fold increase in the Na(+)/Ca(2+) exchange rate, on average, when the intra- and extravesicular salt concentrations were increased from 160 to 450 mm, suggesting that the lobster muscle exchanger is optimized for transport at the high salt concentration present in lobster body fluids.

The renal sodium-calcium exchanger.

The functional expression of the renal sodium-calcium exchanger has been amply documented in studies on renal cortical basolateral membranes. In perfused renal tubules, other investigators have shown sodium-calcium exchange activity in the proximal convolution of the rat and in the distal convolution, the connecting tubule, and the collecting tubule of the rabbit. In rat proximal tubules, we found that the sodium-calcium exchanger is an important determinant of cytosolic calcium homeostasis, since inhibition of sodium-dependent calcium efflux mode caused a large accumulation of tubular calcium. In membranes from rat proximal tubules sodium-calcium activity was high, and in intact proximal tubules, the tubular sodium-calcium exchanger exhibited a high affinity for cytosolic calcium and had a substantial transport capacity, which may be absolute requirements for the maintenance of stable cytosolic calcium in proximal tubules.

The cellular mechanism of action of cardiotonic steroids: a new hypothesis.

Arterial smooth muscle (ASM) contraction is triggered by agonist-evoked Ca2+ mobilization from sarcoplasmic reticulum (SR). The amount of Ca2+ released, and thus, the magnitude of the contractions, depends directly on SR Ca2+ content. Na+ pump inhibition by cardiotonic steroids (CTS) indirectly increases the Ca2+ content of the SR and, thus, contractility. This sequence of events does not, however, account for the multiple Na+ pump alpha subunit isoforms with different affinities for Na+ and for CTS, nor does it explain the cardiotonic and vasotonic effects of low doses of CTS that do not elevate cytosolic Na+ or Ca2+. We show that the Na+ pump high ouabain affinity (alpha3) isoform and the plasmalemmal (PM) Na/Ca exchanger are confined to PM domains that overlie junctional SR in ASM, while low ouabain affinity alpha1 and the PM Ca2+ pump are uniformly distributed in the PM. Thus, low doses of CTS, including an endogenous ouabain-like compound, influence cytosolic Na+ and (indirectly) Ca2+ concentrations only in the cytoplasmic clefts between the PM and junctional SR (a functional unit we call the "plasmerosome"). In turn, this modulates the Ca2+ content of the junctional SR and cell responsiveness.

Na(+)-Ca2+ exchanger of rat proximal tubule: gene expression and subcellular localization.

The activity of the Na(+)-Ca2+ exchanger, a membrane transporter that mediates Ca2+ efflux, has been described in amphibian and mammalian renal proximal tubules. However, demonstration of cell-specific expression of the Na(+)-Ca2+ exchanger in proximal renal tubules has been restricted to functional assays. In this work, Na(+)-Ca2+ exchanger gene expression in rat proximal tubules was characterized by three additional criteria: functional assay of transport activity in membrane vesicles derived from proximal tubules, expression of specific Na(+)-Ca2+ exchanger protein detected on Western blots, and determination of specific mRNA encoding Na(+)-Ca2+ exchanger protein on Northern blots. A new transport activity assay showed that proximal tubule membranes contained the highest Na(+)-Ca2+ exchanger transport activity reported in renal tissues. In dog renal proximal tubules and sarcolemma, a specific protein of approximately 70 kDa was detected, whereas in rat proximal tubules and sarcolemma, the specific protein approximated 65 kDa and was localized to the basolateral membrane. On Northern blots, a single 7-kb transcript isolated from rat proximal tubules, whole kidney, and heart hybridized under high-stringency conditions with rat heart cDNA. These data indicate that Na(+)-Ca2+ exchanger protein expressed in rat proximal tubule is similar, if not identical, to the cardiac protein. We suggest that the tubular Na(+)-Ca2+ exchanger characterized herein represents the Na(+)-Ca2+ exchanger described in functional assays of renal proximal tubules.

Angiotensin I modulates Ca-transport systems in the rat heart through angiotensin II.

The objective of this study was to determine the effect of angiotensin I (Ang I) treatment in vivo on two major Ca-transport systems-the L-type voltage dependent calcium channel (L-VDCC) and the Na/Ca exchanger in rat heart. For our experiments we used four groups of rats, treated differently with saline, Ang I, the ACE inhibitor enalapril and/or combination of both for 6 days, every 24 h. We observed an increase in the activity, and also in mRNA expression of the Na/Ca exchanger, after repeated administration of Ang I in vivo. The maximal binding capacity of Ca-antagonist PN 200-110, which binds to the alpha 1 subunit of the L-VDCC was elevated from 0.8-1.85 pg/mg protein. mRNA expression of the voltage-dependent calcium channels of L-type system was also upregulated by Ang I administration, but not when enalapril was applied simultaneously with Ang I. These results demonstrate that in vivo application of the Ang I significantly modulates not only the activity, but also expression of the Na/Ca exchanger and the L-VDCC in rat hearts through angiotensin II (Ang II). Since in the in vitro experiments on the isolated cardiomyocytes, Ang II (100 nM) increased the calcium uptake after depolarization, and the AT1 receptor agonist losartan prevented this increase, we assume that this regulation might involve the AT1 receptors.

Na(+)-Ca2+ exchanger in arteries: identification by immunoblotting and immunofluorescence microscopy.

Antibodies raised against dog cardiac Na(+)-Ca2+ exchanger were employed to determine the presence and distribution of the exchanger in arterial smooth muscle (ASM) cells. The antiserum cross-reacted with protein bands of approximately 70, 120, and 150-160 kDa from the membranes of ASM cells, as well as heart sarcolemma. A cardiac Na(+)-Ca2+ exchanger cDNA probe hybridized to 7-kilobase (kb) mRNA from myocytes of the mesenteric artery. Thus ASM cells possess a "cardiac type" Na(+)-Ca2+ exchanger. The relative amounts of 7-kb mRNA and antigen detected on Northern and Western blots, respectively, however, indicate that vascular myocytes contain much less of this transporter than do cardiac myocytes. Immunofluorescence studies on cultured arterial myocytes suggest that the exchanger molecules are organized in reticular patterns over the cell surfaces. A similar pattern is observed when cells are stained for sarcoplasmic reticulum (SR) Ca(2+)-ATPase. This raises the possibility that the exchanger in the plasmalemma of arterial myocytes may be associated, perhaps functionally as well as structurally, with the underlying SR. The antiserum also cross-reacted with endothelial cell membranes, but labeling was lighter and more diffuse than in the myocytes.