Tom Song

Insulin reduces contraction and intracellular calcium concentration in vascular smooth muscle.

Resistance to insulin-induced glucose disposal is associated with hypertension, in accord with recent reports that insulin-induced vasodilation is impaired in men with resistance to insulin-induced glucose disposal. Nevertheless, the mechanism of insulin-induced vasodilation is not known. We wished to determine whether a physiological concentration of insulin inhibits agonist-induced contraction at the level of the individual vascular smooth muscle cell, and if so, how. Dispersed vascular smooth muscle cells from dog femoral artery were grown on collagen gels for 4 to 8 days. Contraction and intracellular Ca2+ concentration of individual cells were measured by photomicroscopy and fura 2 epifluorescence microscopy, respectively. Serotonin and angiotensin II contracted cells in a dose-dependent manner. Preincubation of cells for 20 minutes (short-term) or 7 days (long-term) with insulin (40 microU/mL) inhibited serotonin- and angiotensin II-induced contractions by approximately 50%. Insulin (10 microU/mL) acutely inhibited serotonin-induced contraction by 34%. The maximal effect of high extracellular K(+)-induced contraction was not affected by short-term insulin exposure, but the ED50 for extracellular K(+)-induced contraction was increased from 7.6 +/- 2.5 to 16.0 +/- 3.9 mmol/L (P < .05). Short-term insulin exposure also attenuated the peak rise of the serotonin-induced intracellular Ca2+ transient and increased the rate constant for intracellular Ca2+ decline. Verapamil and ouabain completely blocked the attenuation of agonist-induced contraction by short-term insulin exposure, indicating the importance of voltage-operated Ca2+ channels and the Na(+)-K+ pump for this effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin Acutely Inhibits Cultured Vascular Smooth Muscle Cell Contraction by a Nitric Oxide Synthase–Dependent Pathway

Insulin acutely decreases contractile agonist-induced Ca2+ influx and contraction in endothelium-free cultured vascular smooth muscle (VSM) cells, but the mechanism is not known. Since it has been reported that insulin-induced vasodilation in humans is linked to nitric oxide synthase activity, we wished to determine whether insulin inhibits Ca2+ influx and contraction of cultured vascular smooth muscle cells by a nitric oxide synthase-dependent pathway. Primary cultures of endothelial cell-free VSM cells from canine femoral artery were preincubated with and without 1 nmol/L insulin for 30 minutes, and the 5-minute production of cGMP was measured. Insulin alone did not affect cGMP production, but in the presence of 10(-5) mol/L serotonin insulin stimulated cGMP production by 60%. N(G)-monomethyl-L-arginine (0.1 mmol/L), an inhibitor of nitric oxide synthase, inhibited the conversion of arginine to citrulline by these cells, blocked insulin-stimulated cGMP production, and blocked the inhibition by insulin of 5-hydroxytryptamine (5-HT)-stimulated Mn+2 (a Ca2+ surrogate) influx and contraction. Insulin did not affect contraction of VSM cells grown under conditions designed to deplete the cells of tetrahydrobiopterin, an essential cofactor of nitric oxide synthase. These studies demonstrate that insulin acutely inhibits 5-HT-stimulated Ca2+ influx and contraction of endothelium-free cultured VSM cells by a nitric oxide synthase-dependent mechanism.

Insulin-Stimulated Glucose Transport Inhibits Ca2+ Influx and Contraction in Vascular Smooth Muscle

BACKGROUND Insulin attenuates serotonin-induced Ca2+ influx, the intracellular Ca2+ transient, and contraction of cultured vascular smooth muscle cells from dog femoral artery. These studies were designed to test whether insulin-induced glucose transport was an early event leading to the inhibitory effects of insulin on Ca2+ influx, intracellular Ca2+ concentration, and contraction in these cells. METHODS AND RESULTS Insulin 1 nmol/L stimulated the 30-minute uptake of [3H]2-deoxyglucose in these cells via a phloridzin-inhibitable mechanism. Contraction of individual cells was measured by photomicroscopy, intracellular Ca2+ concentration was monitored by measuring fura 2 fluorescence by use of Ca(2+)-sensitive excitation wavelengths, and Ca2+ influx was estimated by the rate of Mn2+ quenching of intracellular fura 2 fluorescence when excited at a Ca(2+)-insensitive wave-length. In the presence of 5 mmol/L glucose, preincubation of cells for 30 minutes with 1 nmol/L insulin inhibited 10(-5) mol/L serotonin-induced contraction of individual cells by 62% (P < .01) and decreased the serotonin-stimulated component of Mn2+ influx by 78% (P < .05). Removing glucose from the preincubation medium or adding 1 mmol/L phloridzin completely eliminated these effects of insulin. Insulin lowered the serotonin-induced intracellular Ca2+ peak by 37% (P < .05), and phloridzin blocked this effect of insulin. When glucose uptake was increased to the insulin-stimulated level by preincubation of the cells for 30 minutes with 25 mmol/L glucose in the absence of insulin, serotonin failed to stimulate Mn2+ influx, the serotonin-induced Ca2+ peak was decreased by 46% (P < .05), serotonin-induced contraction was inhibited by 60% (P < .01), and addition of insulin did not further inhibit contraction. CONCLUSIONS Since the effects of insulin on serotonin-stimulated Ca2+ transport, intracellular Ca2+ concentration, and contraction were dependent on glucose transport and were duplicated when glucose transport was stimulated by high extracellular glucose concentration rather than insulin per se, it is concluded that insulin-stimulated glucose transport is an early event that leads to decreased Ca2+ influx and contraction in vascular smooth muscle.

Insulin inhibits serotonin-induced Ca2+ influx in vascular smooth muscle.

Insulin in physiological concentrations attenuates the agonist-induced intracellular Ca2+ ([Ca2+]i) transient and inhibits contraction in individual nonproliferated cultured canine femoral artery vascular smooth muscle cells (VSMCs). In the present study, we wished to define the effects of insulin on individual components of Ca2+ transport in vascular smooth muscle. Methods and ResultsInsulin (40 μU/mL) attenuated the 5-hydroxytryptamine (5-HT, serotonin; 10−5 mol/L)-induced [Ca2+]i transient (measured by fura 2 fluorescence) in primary confluent canine femoral artery VSMCs in the presence of extracellular Ca2+. In Ca2+ -free media, the 5-HT-induced [Ca2+ transient was reduced by 42% and was not affected by insulin. This finding suggested that insulin inhibits 5-HTinduced Ca2+ influx but does not affect sarcolemmal Call efflux or Ca2+ release from intracellular stores. In support of those conclusions, we found that insulin inhibited the 5-HT-induced component of Mn2+ (a Ca2+ surrogate) influx (measured by fura 2 fluorescence quenching at the Ca2+ isosbestic excitation wavelength). In addition, 5-HT stimulated the rates of 45Ca2+ efflux from intact cells (a measure of sarcolemmal Ca2+ efflux) and from saponin-permeabilized cells (a measure of Ca2+ release from intracellular stores), but insulin did not affect these rates of 45Ca2+ efflux. ConclusionsWe conclude that a physiological insulin concentration attenuates the 5-HT- induced [Ca2+]i transient in confluent primary cultured canine femoral artery VSMCs by inhibiting the 5 -HT-induced component of Ca2+ influx but not by affecting sarcolemmal Ca2+ efflux or Ca2+ release from intracellular stores.

Insulin inhibits vascular smooth muscle contraction at a site distal to intracellular Ca2+concentration

Several hypertensive states are associated with resistance to insulin-induced glucose disposal and insulin-induced vasodilation. Insulin can inhibit vascular smooth muscle (VSM) contraction at the level of the VSM cell, and resistance to insulins inhibition of VSM cell contraction may be of pathophysiological importance. To understand the VSM cellular mechanisms by which insulin resistance leads to increased VSM contraction, we sought to determine how insulin inhibits contraction of normal VSM. It has been shown that insulin lowers the contractile agonist-stimulated intracellular Ca2+([Formula: see text]) transient in VSM cells. In this study, our goal was to see whether insulin inhibits VSM cell contraction at steps distal to [Formula: see text] and, if so, to determine whether the mechanism is dependent on nitric oxide synthase (NOS) and cGMP. Primary cultured VSM cells from canine femoral artery were bathed in a physiological concentration of extracellular Ca2+ and permeabilized to Ca2+ with a Ca2+ ionophore, either ionomycin or A-23187. The resultant increase in[Formula: see text] contracted individual cells, as measured by photomicroscopy. Preincubating cells with 1 nM insulin for 30 min did not affect basal [Formula: see text] or the ionomycin-induced increase in [Formula: see text], as determined by fura 2 fluorescence measurements, but it did inhibit ionomycin- and A-23187-induced contractions by 47 and 51%, respectively (both P < 0.05). In the presence of 1.0 μM ionized Ca2+, ionomycin-induced contractions were inhibited by insulin in a dose-dependent manner. In the presence of ionomycin, insulin increased cGMP production by 43% ( P < 0.05). 1 H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (10 μM), a selective inhibitor of guanylate cyclase that blocked cGMP production in these cells, completely blocked the inhibition by insulin of ionomycin-induced contraction. It was found that the cells expressed the inducible isoform of NOS. N G-monomethyl-l-arginine or N G-nitro-l-arginine methyl ester (0.1 mM), inhibitors of NOS, did not affect ionomycin-induced contraction but prevented insulin from inhibiting contraction. We conclude that insulin stimulates cGMP production and inhibits VSM contraction in the presence of elevated[Formula: see text]. This inhibition by insulin of VSM contraction at sites where [Formula: see text] could not be rate limiting is dependent on NOS and cGMP.

Protein kinase C mediates insulin-inhibited Ca2+ transport and contraction of vascular smooth muscle.

Insulin acutely inhibits contraction of primary cultured vascular smooth muscle (VSM) cells from canine femoral artery by inhibiting contractile agonist-induced Ca2+ influx. Insulin also inhibits contraction at step(s) distal to intracellular Ca2+ concentration (Ca2+i) by stimulating cyclic guanosine monophosphate (GMP) production. We wished to see whether these effects of insulin are mediated by protein kinase C (PKC). Ca2+ influx was assessed by measuring the rate of fluorescence quenching of intracellular fura 2 by extracellular Mn2+. We found that 10 micromol/L serotonin (5-HT) stimulated Mn2+ influx 3-fold, and 1 nmol/L insulin inhibited the 5-HT-stimulated component of Mn2+ influx by 63% (P < .05), but insulin had no effect in the presence of 1 micromol/L staurosporine, an inhibitor of PKC. In the absence of insulin, preincubating cells with 0.1 micromol/L phorbol 12-myristate 13-acetate (PMA) for 5 min inhibited the 5-HT-stimulated component of Mn2+ influx by 69% (P < .05). Insulin inhibited cell contraction induced by raising Ca2+i to supraphysiologic levels with ionomycin by 75% (P < .05). We also noted that 10(-6) mol/L calphostin C, another PKC inhibitor, or 16-h preincubation with PMA completely blocked this effect of insulin. Finally, 10-min exposure to insulin or PMA increased cyclic GMP production in ionomycin-treated cells by 50% and 64%, respectively (both P < .05). We conclude that insulin inhibits VSM cell contraction by inhibiting 5-HT-stimulated Ca2+ influx and also at step(s) distal to Ca2+i by a PKC-dependent mechanism.

Effects of Insulin on Vascular Smooth Muscle Contraction

Many studies have revealed an association between resistance to insulin-induced glucose disposal and high blood pressure. This relationship is present in patients with essential hypertension, obesity, and non-insulin-dependent diabetes mellitus (1). It has been proposed that compensatory hyperinsulinemia increases sympathetic nerve activity and renal Na reabsorption, which could contribute to the genesis ofhypertension (1). Despite the effects of hyperinsulinemia on the nervous and renal systems, chronic experimental hyperinsulinemia in dogs (2) or insulinoma in humans (3) are not associated with hypertension. This may be explicable since insulin infusion causes vasodilation in humans and dogs (2, 4). Thus, there exists a balance of insulin’s effects to raise blood pressure (stimulation of sympathetic nerve activity and renal Na+ reabsorption) versus the effect of insulin to lower blood pressure (vasodilation).