The actions of altered osmolarity on guinea-pig detrusor smooth muscle contractility and intracellular calcium

The study measured the effects in vitro of changing extracellular osmolarity on the contractility of detrusor smooth muscle strips. The data were interpreted in the context of separate measurements from isolated cells of alterations to the intracellular [Ca2+], [Ca2+]i. Increased osmolarity (300-700 mosmol l-1) reduced phasic contractions but increased resting tension regardless of whether sucrose, LiCl or NaCl were used as osmolytes. [Ca2+]i was decreased slightly only when NaCl increased osmolarity, otherwise it was unchanged. The contractile effects may be explained by tissue shrinkage and reduction of detrusor excitability. Lowered osmolarity (300-64 mosmol l-1) decreased phasic contractions but increased resting tension and [Ca2+]i. The raised resting tension was due solely to low osmolarity and was independent of changes to [Na], [Cl] or ionic strength. The rise of [Ca2+]i was due partly to Ca2+ influx through Na(+)-Ca2+ exchange but a fraction was independent of extracellular Ca, unaffected by Gd3+, and persisted in the presence of caffeine. By contrast, reduction of phasic tension was due mainly to the reduced ionic strength, not osmolarity. The results do not support the presence of functional stretch-activated channels and suggest only a minor role for Na(+)-Ca2+ exchange under these conditions. However, they do suggest an intracellular source of Ca2+, which is independent of the sarcoplasmic reticulum.     

Transport of magnesium by two isoforms of the Na+-Ca2+ exchanger expressed in CCL39 fibroblasts

Cytoplasmic concentrations of Ca2+ ([Ca2+]i) and Mg2+ ([Mg2+]i) were measured with fluorescent indicators in CCL39 cells, a cell line established from Chinese hamster lung fibroblasts, transfected with complementary deoxyribonucleic acid (cDNA) of the Na+-Ca2+ exchanger isolated either from canine heart (NCX1) or from rat brain (NCX3). Raising extracellular [Mg2+] to 10 mM increased Mg2+ influx and the resultant change in [Mg2+]i (delta[Mg2+]i) was monitored with furaptra under Ca2+-free conditions. In control (vector-transfected) cells, delta[Mg2+]i at 45 min was similar with or without extracellular Na+ (130 mM or 0 mM) and when [Na+]i was raised by 1 mM ouabain treatment. delta[Mg2+]i in NCX1-transfected cells was attenuated significantly in the presence of 130 mM Na+, but became comparable to (or slightly larger than) that in control cells on either removal of extracellular Na+ or treatment with 1 mM ouabain. Cells expressing NCX3 showed an intermediate dependence of delta[Mg2+]i on Na+, probably reflecting a lower degree of expression of the exchanger protein. Extracellular Na+-dependent changes in [Ca2+]i (measured with fura-2 in the presence of extracellular Ca2+ and 10 microM ionomycin, a Ca2+ ionophore) were minimal in control cells, marked in the NCX1-transfected cells and intermediate in the NCX3-transfected cells. These results suggest that the Na+-Ca2+ exchanger (either NCX1 or NCX3) can transport Mg2+ and may play a role in the extrusion of magnesium from cells.     

Mechanisms involved in contraction of smooth muscles of the rat portal vein as induced by sodium depletion

Responses to external Na depletion were investigated in the rat portal vein, using a microelectrode and an isometric force transducer. Mechanical response to Na depletion was characterized by a large tonic contraction with phasic contractions in a choline solution, and by phasic contractions without a tonic contraction in a Li solution. An identical depolarization of the membrane occurred in either choline or Li solution. After the tonic contraction was established in the Na-free choline-solution, the vein all but completely relaxed with partial re-admission of Na, while maintaining constant the concentration of choline. The Na-free choline-solution at 13 degrees C did not induce the tonic contraction. In nominal Ca-free solution, no contraction occurred with a depletion of Na. A tonic contraction was also induced by Na depletion in the presence of Mn but not Ca. It is concluded that with depletion of both external and internal Na, Ca and Mn may enter the cell through channels usually occupied by Na.     

Effects of ouabain on intracellular ion activities of sensory neurons of the leech central nervous system.

1. The intracellular K+, Na+, and Ca2+ of mechanosensory neurons in the central nervous system of the leech Hirudo medicinalis was measured using double-barreled ion-sensitive microelectrodes. 2. After inhibition of the Na(+)-K+ pump with 5 x 10(-4) M ouabain, the intracellular K+ activity (aKi) decreased, while the intracellular Na+ activity (aNai) increased. The input resistance decreased in the presence of ouabain. The intracellular Ca2+ increased more than one order of magnitude after ouabain addition. All changes in intracellular ion activities and membrane resistance were fully reversible. 3. When extracellular Na+ concentration ([Na+]o) was removed [replaced by tris(hydroxymethyl)aminomethane (Tris)], aNai decreased. In the absence of [Na+]o, aKi and aNai remained unchanged after inhibition of the Na(+)-K+ pump by reducing the extracellular K+ concentration ([K+]o) to 0.2 mM. The membrane resistance increased under these conditions. 4. The intracellular Ca2+ decreased or remained constant after removal of [Na+]o. Addition of ouabain in the absence of [Na+]o did not change intracellular Ca2+, which only increased after readdition of [Na+]o. 5. The relative K+ permeability (PK) measured as membrane potential change during a brief increase of the [K+]o from 4 to 10 mM, increased manyfold after addition of ouabain but only little if [Na+]o had been removed before adding ouabain. 6. The results suggest that the intracellular Na+ increase after inhibition of the Na(+)-K+ pump affects the intracellular Ca2+ level by stimulating a Nai(+)-Ca2+ exchange mechanism. The subsequent intracellular Ca2+ activity (aCai) rise may result in an increase of the membrane permeability to K+ ions.     

Ca2+ clearance at growth cones produced by crayfish motor axons in an explant culture

Intracellular free Ca2+ concentration ([Ca2+]i) plays an important role in the regulation of growth cone (GC) motility; however, the mechanisms responsible for clearing Ca2+ from GCs have not been examined. We studied the Ca2+-clearance mechanisms in GCs produced by crayfish tonic and phasic motor axons by measuring the decay of [Ca2+]i after a high [K+] depolarizing pulse using fura-2AM. Tonic motor axons regenerating in explant cultures develop GCs with more rapid Ca2+ clearance than GCs from phasic axons. When Na/Ca exchange was blocked by replacing external Na+ with N-methyl-d-glucamine (NMG), [Ca2+]i decay was delayed in both tonic and phasic GCs. Tonic GCs appear to have higher Na/Ca exchange activity than phasic ones since reversal of Na/Ca exchange by lowering external Na+ caused a greater increase in [Ca2+]i for tonic than phasic GCs. Application of the mitochondrial inhibitors, Antimycin A1 (1 microM) and CCCP (10 microM), demonstrated that mitochondrial Ca2+ uptake/release was more prominent in phasic than tonic GCs. When both Na/Ca exchange and mitochondria were inhibited, the plasma membrane Ca2+ ATPase was effective in extruding Ca2+ from tonic, but not phasic GCs. We conclude that Na/Ca exchange plays a prominent role in extruding large Ca2+ loads from both tonic and phasic GCs. High Na/Ca exchange activity in tonic GCs contributes to the rapid decay of [Ca2+]i in these GCs; low rates of Ca2+ extrusion plus the release of Ca2+ from mitochondria prolongs the decay of [Ca2+]i in the phasic GCs.     

Rate-sensitive contractile responses of lymphatic vessels to circumferential stretch

Phasic contractile activity in rat portal vein is more sensitive to the rate of change in length than to absolute length and this response is widely assumed to be a general characteristic of myogenic behaviour for vascular smooth muscle. Previously, we found that rat lymphatic vessels exhibit phasic contractile behaviour similar to that of portal vein. In the present study, we hypothesized that lymphatic muscle would exhibit rate-sensitive contractile responses to stretch. The hypothesis was tested on rat mesenteric lymphatics (90–220 μm, i.d.) using servo-controlled wire- and pressure-myograph systems to enable ramp increases in force or pressure at different rates. Under isometric conditions in wire-myograph preparations, both the amplitude and the frequency of phasic activity were enhanced at more optimal preloads, but superimposed upon this effect were bursts of contractions that occurred only during fast preload ramps. In such cases, the ratio of contraction frequency during the ramp to that at the subsequent plateau (at optimal preload) was > 1. Further, the frequency ratio increased as a function of the preload ramp speed, consistent with a rate-sensitive mechanism. In contrast, the amplitude ratio was < 1 and declined further with higher ramp speeds. Downward preload ramps produced corresponding rate-sensitive inhibition of contraction frequency but not amplitude. Similar findings were obtained in pressurized lymphatics in response to pressure ramps and steps. Our results suggest that lymphatics are sensitive to the rate of change in preload/pressure in a way that is different from portal vein, possibly because the pacemaker for generating electrical activity is rate sensitive but lymphatic muscle is not. The behaviour may be widely present in collecting lymphatic vessels and is probably an important mechanism for rapid adaptation of the lymphatic pump to local vascular occlusion.     

Contractile effects of polycations in permeabilized smooth muscle

The polycations spermine, neomycin and polylysine potentiated Ca2+-activated force in β-escin permeabilized guinea-pig ileum strips. The effect was inhibited by the calmodulin antagonists trifluoperazine, mastoparan and W13. Potentiation was slow or absent in α-toxin permeabilized strips, indicating dependence on penetration of the polycations into cells. The effects of spermine and neomycin were maintained after extensive permeabilization by β-escin, which eliminated the contractile effect of GTPγS. Replacement of ATP by CTP, which is not a substrate for myosin light chain kinase, inhibited contractile potentiation. Potentiation of Ca2+-activated contractions was associated with increased phosphorylation of the myosin regulatory light chains (LC20). A contractile effect of polylysine and neomycin was also seen in Ca2+-free medium and after partial LC20 thiophosphorylation, indicating that phosphorylation-independent processes may contribute to the response. Although spermine does not cause contraction in Ca2+-free medium at physiological [MgATP], it did so when [MgATP] was lowered to 40μm. Similar to high-[Mg2+], the rate of contraction on addition of ATP to strips incubated with microcystin-LR to inhibit phosphatase activity was increased by the polycations, but only at [Ca2+]<0.3μm. The results suggest that polycations increase Ca2+-activated force by inhibiting myosin phosphatase activity, thereby increasing myosin LC20 phosphorylation. However, additional activation mechanisms, evident at low [Ca2+] and at low [ATP] and possibly involving direct activation of myosin, contribute to their effect. This revised version was published online in July 2006 with corrections to the Cover Date.     

The polycationic compound gentamicin inhibits the calcium paradox in guinea-pig hearts.

The polycationic drug gentamicin and two calcium antagonists were studied with respect to their protecting action against the calcium paradox in perfused guinea-pig hearts. Besides the mechanograms the release of creatine kinase was recorded; in parallel experiments the Na(+)-content of the hearts was measured before and at the end of the Ca(2+)-lack period, and during re-exposure to normal [Ca2+]0. The calcium paradox was induced by perfusion, for 50 s, with Ca(2+)-free solution containing EGTA (3 x 10(-4) M). Nifedipine and verapamil in concentrations which reduced the equilibrium contractile force by 50%, only mitigated the extent of the calcium paradox, whereas gentamicin applied in a concentration also reducing the contractile amplitude by 50% was able to suppress the calcium paradox completely. The dose-response curves for nifedipine, with respect to the reduction of contractile force and contracture, were identical. In contrast, gentamicin was more effective in attenuating the contracture of the paradox than in reducing the equilibrium contractile force. The large gain of Na+ during the Ca(2+)-lack period was diminished by both nifedipine and gentamicin. The partial protection of calcium antagonists can be related to their interference with the uptake of Na+ through L-type Ca(2+)-channels during the Ca(2+)-lack period, whereas gentamicin seems to act by an additional inhibition of the Na/Ca exchange during the re-exposure to normal [Ca2+]0.     

Caffeine-induced contraction of rat portal vein and effects of K-depolarization, Na-removal and low temperature.

Contribution of Ca influx from extracellular pool and Ca-release from store sites in caffeine-induced contraction of rat portal vein longitudinal muscle were examined. At 37 degrees C caffeine induced a phasic contraction and the contraction was inhibited by verapamil or in the absence of Ca. Under low temperature, it was not decreased remarkably by verapamil or by the removal of extracellular Ca. Na-removal potentiated caffeine-induced contraction in the absence of Ca. Caffeine-induced contraction was also potentiated by high-K-depolarization. These contractions were at both temperature inhibited greatly by ryanodine. Caffeine induced the burst of the action potential at 37 degrees C but it was not remarkable at 17 degrees C. These results indicate that both extracellular Ca influx and release of stored Ca are involved in the caffeine-induced contraction. However, dependence of the contraction on Ca sources are influenced by temperature, extracellular Na and membrane potential.     

Effect of felodipine on the myogenic response to dynamic stretch in vascular smooth muscle

In the present experiments we examined the effect of felodipine, a vasoselective dihydropyridine calcium antagonist, on contractile responses to dynamic and static stretch of the isolated portal vein of the rat. Dynamic stretch was applied to the vascular smooth muscle at graded rates (from 0.5-1.5% muscle length s-1). Earlier observations (Johansson & Mellander 1975) of a rate-dependent excitation of the vascular smooth muscle by dynamic stretch were confirmed. Addition of felodipine, 3 nM, reduced the spontaneous activity at static lengths to about 50% but resulted in much stronger inhibition of the dynamic stretch responses. Particularly the rate-dependent increase in active force was no longer evident since the response at high rates of passive lengthening was most clearly reduced by felodipine. By contrast, lowering of the extracellular Ca2+ concentration resulted in a comparable attenuation of the spontaneous contractile activity and of the dynamic stretch responses which still showed the typical rate dependence. Therefore, the pronounced inhibition by felodipine of the dynamic myogenic reactivity of the rat portal vein appeared to be a specific effect and not simply related to the overall reduction in contractile activity. We suggest that felodipine, in addition to its inhibition of action potentials and excitation-contraction coupling may exert a special negative influence on the mechano-electrical coupling, i.e. the process that couples dynamic stretch of the vascular smooth muscle to membrane excitation.     

Characteristics of contractile response of isolated portal veins from chronic portal hypertensive rats under altered levels of external K+, Ca2+, and norepinephrine concentrations: a comparison with normal Wistar rats

We studied contractile properties of portal veins isolated from chronic portal hypertensive rats (PHR) resulting from liver cirrhosis, a model obtained by repeated subcutaneous injections of CCl4 (2 mg/kg) twice weekly for over 45 weeks. Portal venous pressure in vivo was significantly higher in PHR (167.0 +/- 38.7 mmH2O) than in the control normal Wistar rats (NWR) (102.0 +/- 25.5 mmH2O). A pair of portal veins from PHR and NWR were mounted longitudinally in an organ bath and perfused with Tyrode's solution with different K+, Ca2+, and norepinephrine concentrations. The isometric tension was measured by a strain-gauge. Under control conditions, spontaneous phasic contractile force, corrected by cross-sectional area, was greater, and the frequency was lower in PHR than in NWR preparations. The averaged peak contractile force measured at different [K]o (5.4-86.4 mM) was also greater in PHR than in NWR. Force of the tonic contraction measured at different [Ca]o (0.45-5.4 mM), under conditions of 86.4 mM [K]o was significantly larger in PHR than in NWR preparations. However, the Ca2+ sensitivity of both preparations was the same. D-600 (greater than or equal to 0.1 microM) inhibited the tonic contraction in both preparations with an identical sensitivity to the drug. In the presence of norepinephrine (10 microM), the Ca2+ sensitivity of the tonic contraction increased both in PHR and NWR preparations. The increase was more pronounced in PHR and was completely reversed in the presence of the alpha 1-adrenoceptor blocker, prazosin (0.1 microM). The alpha 1-adrenoceptor sensitivity to norepinephrine was not altered in PHR preparations. The rate of Ca2+ release and uptake of intracellular Ca2+ seemed identical in both preparations. Thus, in the absence of norepinephrine, the phasic and tonic contractile forces of portal veins from PHR are larger than that of NWR, probably due to increased membrane Ca2+ permeability. The PHR preparations have a higher affinity for external Ca2+ in the presence of norepinephrine, an additional factor contributing to elevation of portal blood pressure in the presence of chronic liver cirrhosis.     

Diabetes and reactivity of isolated human saphenous vein

Helical strips of saphenous veins from diabetic (n = 8) and non-diabetic (n = 18) humans were studied in vivo for their responsiveness to several vasoactive agents. Following application of passive force (approximately 20.0 mN), venous strips from non-diabetic humans often developed spontaneous phasic contractile activity (12 out of 18 patients; 2-5 contractions/min). These intrinsic changes in force were seen in venous strips from only one diabetic patient. The phasic contractions were not altered by treatment with phentolamine, whereas the calcium channel blocker, D-600, and calcium-free solution (1.0 mM EGTA) inhibited the phasic contractions. Saphenous veins from diabetic patients developed less maximal, active tension in response to norepinephrine than those from non-diabetic patients. Contractile responses to serotonin, angiotensin II, and elevated potassium concentration in saphenous veins from diabetic patients were not different from those in veins from non-diabetic patients. These observations demonstrate attenuated development of active tension in response to alpha-adrenergic receptor activation and reduced spontaneous contractile activity in venous smooth muscle from diabetic patients.     

Effects of magnesium on contractile activation of skinned cardiac cells.

1. In the presence of a slight buffering of the free [Ca2+] with 0.050 mM total EGTA cyclic contractions were induced by a Ca2+-triggered release of Ca2+ on skinned (sarcolemma-free) segments of single cardiac cells from rat ventricle. The threshold of the free [Ca2+] trigger was elevated when the free [Mg2+] was increased. 2. At a suprathreshold free [Ca2+] increasing the free [Mg2+] resulted in a decrease in frequency and in an increase in amplitude of the phasic contractions. Addition of caffeine at a specified interval after a cyclic contraction produced a larger contraction when free [Mg2+] was higher. It was concluded that an increase of free [Mg2+] increased the capacity and the rate of binding for Ca2+ by the sarcoplasmic reticulum (SR). 3. Small skinned fibres of skeletal muscle which were perfused with 10 mM caffeine yielded results similar to those obtained in skinned cardiac cells. It was concluded that the mechanism of action of free Mg2+ was similar in both preparations, but that the SR of skeletal muscle had a higher capacity and rate of binding for Ca2+ than the cardiac SR. 4. With a strong buffering of the free [Ca2+] with 4-0 mM total EGTA, a smaller tonic tension was developed for a given pCa in the presence of a higher free [Mg2+]. This result was nearly identical in skinned cells from cardiac and skeletal muscle tissue. 5. A decrease of the [MgATP2-] produced a tension in the skinned cardiac cells that were perfused in Ca2+ free media. The maximum tension was observed for [MgATP2-] 10(-5-50)M as in skinned fibres of skeletal muscle. A further decrease of [MgATP2-] resulted in a decrease of tension.     

Calcium-sodium antagonism on the frog's heart: a voltage-clamp study.

1. In double sucrose-gap voltage-clamped frog atrial fibres the influence of [Ca]o and [Na]o on membrane current and contraction was investigated. 2. The slow (secondary) inward current varied with [Ca]o but was almost insensitive to changes in [Na]o. In contrast, the phasic (transient) contraction initiated by the slow inward current was affected by both [Ca]o and [Na]o. 3. With moderate changes of [Ca]o and [Na]o from normal, the strength of phasic contraction at a given depolarization followed the [Ca]o/[Na]2o ratio approximately. This was best seen at membrane potentials near zero level. 4. Under the same conditions, tonic (sustained) contractions associated with prolonged depolarizations were strictly correlated to the [Ca]o/[Na]2o ratio at any potential. No interrelation between tonic tension and steady-state current was found. 5. With extensive changes in [Ca]o and [Na]o, the sensitivity of both phasic and tonic tension to the [Ca]o/[Na]2o ratio declined, the negative effect of [Na]o becoming smaller than was expected from this ratio. 6. In Na-free choline-Ringer, a strong contracture developed followed by a spontaneous relaxation. Starting from the relaxed state, application of depolarizing clamps gave rise to phasic contractions with a very slow relaxation while tonic contractions were apparently lacking. 7. The results are interpreted in terms of an energy-dependent carrier mechanism exchanging one Ca for two Na ions across the cell membrane. The model implies a strong asymmetry in the rate constants governing the chemical reactions on both sides of the membrane. The system is thought to operate close to equilibrium at any potential, thereby determining the steady level of myoplasmic Ca. The equilibrium itself is considered to shift upon depolarization. Assuming that [Na]i is constant, the steady level of [Ca]i is expected to be proportional to the [Ca]o/[Na]2o ratio, the scale factor being a function of membrane potential. 8. The carrier model suggests the occurrence of a depolarization-induced inward transfer of Ca which might be involved in the generation of tonic contractions. 9. The apparent lack of tonic contractions in the absence of external Na ions may be explained by a suppression of carrier-mediated Ca influx normally occurring upon depolarization. 10. The antagonistic effects of [Ca]o and [Na]o on phasic contraction are understood as being due to alterations of the Ca pumping system rather than changes in slow inward current.     

Isometric and isotonic relaxation in venous smooth muscle.

The time course of relaxation under isometric and isotonic conditions was studied in preparations of rat portal vein which maintained regular phasic contractions in solutions with increased [K-+] and [Ca-2+]. It was found that the smooth muscle during isotonic lengthening was able to carry the afterload for a period of time which was longer than expected from the control isometric response. The difference was largest for afterloads corresponding to about half the isometric peak force. The terminal decline in force was identical in afterloaded and purely isometric responses. Inhibitory influences of isotonic shortening causing increased rates of relaxation, as reported for striated muscles, were not observed. The differences in the course of relaxation between isotonic and isometric responses of portal vein could not be attributed to variations in membrane excitation. It also appears that the differences are not due to changes in release or uptake of activator calcium, or to presence of viscous elements in the tissue. It is suggested that the ability of the smooth muscle to carry load over a relatively long period during isotonic relaxation may be attributed to the characteristics of the instantaneous force-velocity relations in the force range above Po.     

Electrical basis of contractions in the muscle layers of the pig colon

Simultaneous in vitro measurements of electrical and mechanical activities were performed, using suction electrodes and force transducers, respectively, on longitudinal and circular muscle layers of the pig proximal colon. In addition, circular muscle strips were studied with the sucrose gap technique. Spontaneous activity was present in both preparations. In the circular muscle, slow waves with superimposed spikes occurred at a variable frequency, accompanied by phasic contractions. Longitudinal muscle preparations showed a different behavior. Regular appearance of distinct slow waves as described for the circular muscle did not occur. Instead, periods of membrane potential oscillations at a frequency of 41 cycles/min and a duration of approximately 12 s were observed in this layer. Most oscillations had superimposed spikes, and each period of oscillations was associated with a contraction. Spontaneous activity in the circular layer was myogenic in nature but susceptible to innervation and stretch. In contrast, an excitatory stimulus (acetylcholine or stretch) was a prerequisite for activity in the longitudinal layer. Cholinomimetics increased and adrenergic agents decreased the frequency of the slow waves and spiking activity and frequency and force of contractions in the circular muscle. Cholinergic agents increased the activity in the longitudinal muscle into continuous electrical oscillations with spiking activity and concomitant tonic contractile activity, whereas adrenergic agents abolished electrical and mechanical activity. Spontaneous release of acetylcholine occurred, partly due to regenerative activity of myenteric cholinergic nerves. In addition, tonic activity in the noncholinergic nonadrenergic inhibitory neurons decreased circular muscle tone.     

Mechanisms underlying pre- and postjunctional effects of neuropeptide Y in sympathetic vascular control

The effects of porcine neuropeptide Y (NPY) regarding sympathetic vascular control were studied in vitro on isolated rat blood vessels. The 10(-9)M NPY enhanced (about two-fold) the contractile responses to transmural nerve stimulation (TNS), noradrenaline (NA) and adrenaline (about two-fold) in the femoral artery. Higher concentrations of NPY (greater than 10(-8)M) caused an adrenoceptor-resistant contraction per se. The TNS-evoked [3H]NA efflux was significantly reduced by NPY in a concentration-dependent manner (threshold 10(-9)M). The calcium antagonist, nifedipine, abolished the contractile effects of NPY and the NPY-induced enhancement of NA contractions but did not influence the prejunctional inhibition of [3H]NA release. Receptor-binding studies showed that the ratio of alpha 1-to alpha 2-adrenoceptors in the femoral artery was 30:1. The NPY did not cause any detectable change in the number of alpha 1-or alpha 2-adrenoceptor binding sites or in the affinity of alpha 2-binding sites, as revealed by prazosin- and clonidine-binding, respectively. The NPY also inhibited the TNS-evoked [3H]NA release (by 42-86%) in the superior mesenteric and basilar arteries and in femoral and portal veins. The NPY still depressed TNS-evoked [3H]NA secretion from the portal vein in the presence of phentolamine. The NPY caused a clear-cut contraction in the basilar artery, increased the contractile force of spontaneous contractions in the portal vein, while only weak responses were observed in the superior mesenteric artery and femoral vein. The NA-induced contraction was markedly enhanced by NPY in the superior mesenteric artery, only slightly enhanced in the portal vein and uninfluenced in the femoral vein. In conclusion, in all blood vessels tested, NPY depresses the TNS-evoked [3H]NA secretion via a nifedipine-resistant action. Furthermore, NPY exerts a variable, Ca2+-dependent vasoconstrictor effect and enhancement of NA and TNS contractions.     

External calcium sensitivity of low sodium contractures in the control and hypertrophied right ventricle of the ferret.

The existence of possible differences of calcium (Ca2+) fluxes through the sarcolemmal sodium-calcium (Na+/Ca2+) exchanger during hypertrophy has been tested by comparing the characteristics of the contracture--as an indicator of the intracellular Ca2+ concentration--induced by partial or total withdrawal of external sodium (Na+), in the absence of external potassium, in the right ventricular trabeculae of adult ferret hearts. Pressure-overload was induced by pulmonary artery clipping and led to an increase of the right ventricular weight of 60%. At an external Ca2+ concentration ([Ca2+]o) of 3 mM, the dependence of the contractures on extracellular sodium concentration ([Na+]o), the rate of tension development, the time course of spontaneous relaxation and the time course for the repriming of the contracture were unchanged by hypertrophy. However, the relationship between [Ca2+]o and contracture amplitude at various [Na+]o showed that the apparent affinity of the contracture for [Ca2+]o was decreased in hypertrophied preparations. Thus, in 0 mM [Na+]o, half-maximal contracture was induced at a [Ca2+]o of 0.012 +/- 0.016 mM and 0.171 +/- 0.021 mM in control (n = 11) and hypertrophy (n = 12) respectively (P less than 0.001). Although these data may be indicative of a decreased Ca2+ influx through the Na+/Ca2+ exchanger, it cannot be excluded that intracellular buffering mechanism may also be involved in this differential response to [Na+]o withdrawal.