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

Prostaglandin E1 potentiation of the spontaneous phasic contraction of rat isolated portal vein by a cyclopiazonic acid-sensitive mechanism

1. The effect of prostaglandin E1 (PGE1) on the spontaneous phasic contraction of the rat isolated portal vein was studied. 2. The isolated portal vein exhibited spontaneous phasic contractions. Removal of Ca2+ from Krebs-Ringer solution or application of nifedipine abolished the spontaneous contraction, indicating that the contraction depends exclusively on Ca2+ influx through L-type Ca2+ channels. On the other hand, cyclopiazonic acid (CPA), a specific inhibitor of Ca(2+)-ATPase of sarcoplasmic reticulum (SR) increased the amplitude of the contractions, suggesting that the SR regulates the spontaneous contractions negatively by sequestration of Ca2+ entering through L-type Ca2+ channels and buffering the rise in cytosolic Ca2+. 3. PGE1 increased the amplitude of the spontaneous contraction in a concentration-dependent manner without affecting the resting tension. The effect was completely abolished by nifedipine. Bay K 8644 and phenylephrine (PE) also increased the amplitude of the contraction in a concentration-dependent manner. PGE1 at a concentration of 1 microM. Bay K 8644 at 100 nM and PE at 30 nM doubled the amplitude, respectively. 4. Pretreatment with 1 microM CPA abolished the effect of PGE1, but the effects of Bay K 8644 and PE were not inhibited by pretreatment with CPA. In contrast, 10 microM ryanodine attenuated the effect of PE without affecting the contractile effect of PGE1. 5. When the SR was depleted of Ca2+ by repeated applications of caffeine in a nominally Ca(2+)-free Krebs-Ringer solution, it took about 120 s to restore the spontaneous contraction after addition of Ca2+ into the solution. In CPA-treated veins, the time taken to restore the contraction was shortened significantly. Pretreatment with 1 microM PGE1 shortened the time to the same extent as pretreatment with CPA did. 6. These results suggest that PGE1 increases the amplitude of the spontaneous phasic contraction by a different mechanism from those by which PE and Bay K 8644 increase it. Inhibition of Ca(2+)-ATPase of the SR might be involved in the vasoactive effect of PGE1.

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.

Rat renal arcade segment expresses vasopressin-regulated water channel and vasopressin V2 receptor

The arcades are long, branched renal tubules which connect deep and mid-cortical nephrons to cortical collecting ducts in the renal cortex. Because they are inaccessible by standard physiological techniques, their functions are poorly understood. In this paper, we demonstrate that the arcades are a site of expression of two proteins, aquaporin-2 (the vasopressin-regulated water channel) and the V2 vasopressin receptor, that are important to regulated water transport in the kidney. Using a peptide-derived polyclonal antibody to aquaporin-2, quantitative ELISA in microdissected segments showed that aquaporin-2 is highly expressed in arcades and that the expression is increased in response to restriction of fluid intake. Immunocytochemistry revealed abundant aquaporin-2 labeling of structures in the cortical labyrinth in a pattern similar to that of the Na(+)-Ca2+ exchanger and kallikrein, marker proteins expressed in arcades but not in cortical collecting ducts. RT-PCR experiments demonstrated substantial aquaporin-2 and V2 receptor mRNA in microdissected arcades. In situ hybridization, using 35S-labeled antisense cRNA probes for the V2 receptor demonstrated strong labeling of both arcades and cortical collecting ducts. Thus, these results indicate that the arcades contain the specific proteins associated with vasopressin-regulated water transport, and may be a heretofore unrecognized site of free water absorption.

Endogenous ouabain: role in the pathogenesis of hypertension

Substantial evidence implicates impaired renal excretion of sodium as the major culprit in the pathogenesis of hypertension. The key question is: How does the impairment of Na+ excretion lead to increased peripheral vascular resistance and elevation of the blood pressure? Here we describe the evidence that elevated levels of a recently-discovered adrenal cortical hormone, endogenous ouabain, plays a central role in this process. This hormone inhibits the Na+ pump and raises intracellular Na+. Then, as a result of Na/Ca exchange, cytosolic Ca2+ and, more importantly, intracellular stores of Ca2+, are increased in vascular smooth muscle (VSM), vasomotor neurons, and endothelial cells, as well as in many other types of cells. Consequently, these cells become hyper-responsive because the cytosolic Ca2+ transients induced by cell activation are enhanced. The synergy of augmented sympathetic neuron transmitter release and augmented VSM cell responsiveness may account for the increased arterial tone and peripheral vascular resistance that is the hallmark of hypertension.

Functional coupling of the Na+/Ca2+ exchanger with Ca2+ release from intracellular stores in cultured smooth muscle cells of guinea pig ileum

The mechanism of increase in intracellular Ca2+ concentration ([Ca2+]i) by removal of extracellular Na+, which phenomena were reported previously (Japan. J. Pharmacol. 63 83-91 1993), was investigated in cultured guinea pig ileum longitudinal muscle cells loaded with a fluorescent Ca2+ indicator, fura-2, by digital ratio imaging microscopy. Isotonic substitution of choline chloride for NaCl induced a transient increase in [Ca2+]i. The pretreatment of thapsigargin (0.5 microM), but not nicardipine (10 microM), suppressed the transient increase completely. In solutions containing micromolar concentrations of free Ca2+ (nominally Ca2+-free solution), the Na+-free induced transient increase was observed, but neither the second cell exposure to the Na+-free solution nor the following application of histamine increased [Ca2+]i, indicating that removal of extracellular Na+ releases Ca2+ from intracellular stores including inositol 1,4,5-trisphosphate (IP3)-releasable pools. The Na+-free induced transient increase required the presence of more than micromolar concentrations of extracellular free Ca2+ and releasable Ca2+ within the stores, but ryanodine did not affect the transient increase. These results suggest that undetectable influx of Ca2+ by the reverse-mode action of the Na+/Ca2+ exchanger can release Ca2+ from the thapsigargin-sensitive intracellular stores including IP3-releasable pools.

Regulation of cytosolic calcium levels in vascular smooth muscle

Ca2+ plays an important role in the contraction of skeletal, cardiac, and smooth muscle, as well as in a number of important processes, such as secretion and neuronal activity. In this review, I focus on the various mechanisms by which cytosolic Ca2+ concentration is regulated in vascular smooth muscle, in the resting state and during activation. Particular attention is paid to the calcium pumps of the plasmalemma and the sarcoplasmic reticulum, to the inositol 1,4,5-trisphosphate- and ryanodine-sensitive calcium channels of the sarcoplasmic reticulum, and to voltage-dependent and voltage-independent calcium channels of the plasmalemma.

The plasma membrane calcium pump--a physiological perspective on its regulation

This review focuses on the physiological role of the plasma membrane Ca(2+)+ Mg(2+)-dependent adenosine triphosphatase (PM Ca(2+)-ATPase) in cellular signalling. Particular attention has been paid to the regulation of the PM Ca(2+)-ATPase (PM Ca2+ pump) by calmodulin, proteases, protein kinases, acidic phospholipids and oligomerization in intact cells. We also review recent work investigating the possible regulation of the PM Ca2+ pump by G proteins and agonists. The source of adenosine triphosphate (ATP) and Ca2+ in fueling and activating the Ca2+ pump is discussed, as well as the possible role of the PM Ca(2+)-ATPase in subplasma membrane Ca2+ regulation. The physiological implication of the localisation of the PM Ca2+ pump in caveolae is also considered.

Signal transduction and regulation in smooth muscle

Smooth muscle cells in the walls of many organs are vital for most bodily functions, and their abnormalities contribute to a range of diseases. Although based on a sliding-filament mechanism similar to that of striated muscles, contraction of smooth muscle is regulated by pharmacomechanical as well as by electromechanical coupling mechanisms. Recent studies have revealed previously unrecognized contractile regulatory processes, such as G-protein-coupled inhibition of myosin light-chain phosphatase, regulation of myosin light-chain kinase by other kinases, and the functional effects of smooth muscle myosin isoforms. Abnormalities of these regulatory mechanisms and isoform variations may contribute to diseases of smooth muscle, and the G-protein-coupled inhibition of protein phosphatase is also likely to be important in regulating non-muscle cell functions mediated by cytoplasmic myosin II.