Endothelin 1 enhances myofilament Ca2+ responsiveness in aequorin-loaded ferret myocardium

The influence of endothelin 1 on intracellular Ca2+ transients and isometric contractions was investigated in ferret papillary muscles loaded with the Ca(2+)-regulated bioluminescent indicator aequorin. In concentrations of 3 x 10(-9) to 1 x 10(-7) M, endothelin produced dose-dependent increases in the amplitudes of both aequorin light signals (maximum, 31 +/- 12%) and developed tension (maximum, 64 +/- 13%). The peak aequorin light [( Ca2+]i)-peak tension curve generated by increasing endothelin concentrations was steeper and shifted to the left of the curve generated by varying [Ca2+]o; however, the maximum developed tension produced by endothelin did not exceed that produced by 6 mM [Ca2+]o. The effect of endothelin on the amplitude of the aequorin light signal was less than the effect of [Ca2+]o for similar levels of tension development. Moreover, 1 x 10(-7) M endothelin caused an upward shift in the peak aequorin light-peak tension curve generated by varying [Ca2+]o and increased the maximum twitch force by about 12%. The contractions were prolonged, whereas the time course of the Ca2+ transient was not changed in the presence of endothelin. When the function of the sarcoplasmic reticulum was inhibited by 6 microM ryanodine, 10(-7) M endothelin still increased the force generation without increasing the intracellular peak Ca2+, either during isometric twitches or during tetani.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endocardial endothelium modulates myofilament Ca2+ responsiveness in aequorin-loaded ferret myocardium.

The influence of selective removal of the endocardial endothelium (by a 1-second exposure to the detergent Triton X-100, 0.5%) on myofilament Ca2+ responsiveness and intracellular Ca2+ transients was studied in ferret papillary muscles loaded with the Ca(2+)-regulated bioluminescent indicator aequorin. The removal of endocardial endothelium produced three major effects: 1) a decrease in peak developed tension and an early onset in isometric relaxation without corresponding changes in the intracellular Ca2+ transient; 2) a rightward shift in the peak [Ca2+]i-peak tension relation with no change in maximum Ca(2+)-activated twitch tension; and 3) a decrease in steady-state tetanic force with a slight increase in the steady-state [Ca2+]i (at 4 mM [Ca2+]o) and an unchanged steady-state tetanic force with a clear increase in the steady-state [Ca2+]i (at 10 mM [Ca2+]o). These results suggest that intact endocardium may enhance performance of the heart by increasing the myofilament Ca2+ responsiveness through endothelium-derived compounds such as endothelin. This hypothesis is supported by our observations that endothelin 1) induced a leftward shift in peak [Ca2+]i-peak tension curve and 2) could reverse the characteristic changes produced by the removal of endocardium.     

Protein kinase D selectively targets cardiac troponin I and regulates myofilament Ca2+ sensitivity in ventricular myocytes

Protein kinase D (PKD) is a serine/threonine kinase with emerging myocardial functions; in skinned adult rat ventricular myocytes (ARVMs), recombinant PKD catalytic domain phosphorylates cardiac troponin I at Ser22/Ser23 and reduces myofilament Ca(2+) sensitivity. We used adenoviral gene transfer to determine the effects of full-length PKD on protein phosphorylation, sarcomere shortening and [Ca(2+)](i) transients in intact ARVMs. In myocytes transduced to express wild-type PKD, the heterologously expressed enzyme was activated by endothelin 1 (ET1) (5 nmol/L), as reflected by PKD phosphorylation at Ser744/Ser748 (PKC phosphorylation sites) and Ser916 (autophosphorylation site). The ET1-induced increase in cellular PKD activity was accompanied by increased cardiac troponin I phosphorylation at Ser22/Ser23; this measured approximately 60% of that induced by isoproterenol (10 nmol/L), which activates cAMP-dependent protein kinase (PKA) but not PKD. Phosphorylation of other PKA targets, such as phospholamban at Ser16, phospholemman at Ser68 and cardiac myosin-binding protein C at Ser282, was unaltered. Furthermore, heterologous PKD expression had no effect on isoproterenol-induced phosphorylation of these proteins, or on isoproterenol-induced increases in sarcomere shortening and relaxation rate and [Ca(2+)](i) transient amplitude. In contrast, heterologous PKD expression suppressed the positive inotropic effect of ET1 seen in control cells, without altering ET1-induced increases in relaxation rate and [Ca(2+)](i) transient amplitude. Complementary experiments in "skinned" myocytes confirmed reduced myofilament Ca(2+) sensitivity by ET1-induced activation of heterologously expressed PKD. We conclude that increased myocardial PKD activity induces cardiac troponin I phosphorylation at Ser22/Ser23 and reduces myofilament Ca(2+) sensitivity, suggesting that altered PKD activity in disease may impact on contractile function.     

Higher Ca2+ sensitivity of triton-skinned guinea pig mesenteric microarteries as compared with large arteries.

Small mesenteric resistance arteries and the main branch of the mesenteric artery (outer in situ diameter 115 +/- 3 microns [n = 76] and greater than 1,000 microns, respectively) were skinned with 1% Triton X-100. Both preparations were mounted as rings for circumferential force measurement in an EGTA solution (free Ca2+, less than 10 nM; calmodulin, 0.3 microM; pH 6.7). Force-pCa curves were obtained by increasing free Ca2+ (0.05 to 30 microM). The resulting dose-dependent contractions, after normalization to maximal force development (arteries, 21.4 +/- 2.4 [n = 3]; arterioles, 15.3 +/- 2.1 mN/mm2 [n = 5]) were fitted to sigmoidal force-pCa curves. Values of ED50 and of the cooperativity factor h were 6.08 and 2.39 in arterioles and 5.64 and 1.64 in arteries. The higher Ca2+ sensitivity of arteriolar preparations remained at pH 7.0 at higher calmodulin concentrations and after inhibition of smooth muscle phosphatase with okadaic acid. Total myosin light chain kinase activity in crude arteriolar extracts (using [gamma-32P] ATP and isolated gizzard light chains as substrates) was approximately 25% of arterial kinase. Both kinase preparations had identical Ca2+ sensitivities. Likewise, total arteriolar phosphatase activity (using 32P-labeled gizzard light chains) was approximately 25% of the arterial activity; both phosphatases had an identical sensitivity toward okadaic acid. The ratio of kinase/phosphatase activities was identical in both tissues. Extracts of both tissues contained two isozymes of the myosin heavy chain as determined with sodium dodecyl sulfate-polyacrylamide gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Single amino acid substitutions define isoform-specific effects of troponin I on myofilament Ca2+ and pH sensitivity

Troponin I isoforms play a key role in determining myofilament Ca2+ sensitivity in cardiac muscle. The goal here was to identify domain clusters and residues that confer troponin I isoform-specific myofilament Ca2+ and pH sensitivities of contraction. Key domains/residues that contribute to troponin I isoform-specific Ca2+ and pH sensitivity were studied using gene transfer of a slow skeletal troponin I (ssTnI) template, with targeted cardiac troponin I (cTnI) residue substitutions. Substitutions in ssTnI with cognate cTnI residues R125Q, H132A, and V134E, studied both independently and together (ssTnIQAE), resulted in efficient stoichiometric replacement of endogenous myofilament cTnI in adult cardiac myocytes. In permeabilized myocytes, the pCa50 of tension ([Ca2+] required for half maximal force), and the acidosis-induced rightward shift of pCa50 were converted to the cTnI phenotype in myocytes expressing ssTnIQAE or ssTnIH132A, and there was no functionally additive effect of ssTnIQAE versus ssTnIH132A. Interestingly, only the acidosis-induced shift in Ca2+ sensitivity was comparable to cTnI in myocytes expressing ssTnIV134E, while ssTnIR125Q fully retained the ssTnI phenotype. An additional ssTnIN141H substitution, which lies within the same structural region of TnI as V134, produced a shift in myofilament Ca2+ sensitivity comparable to cTnI at physiological pH, while the acidic pH response was similar to the effect of wild-type ssTnI. Analysis of sarcomere shortening in intact adult cardiac myocytes was consistent with the force measurements. Targeted substitutions in the carboxyl portion of TnI produced residue-specific influences on myofilament Ca2+ and pH sensitivity of force and give new molecular insights into the TnI isoform dependence of myofilament function.     

Intraluminal flow increases vascular tone and 45Ca2+ influx in the rabbit facial vein.

The buccal segment of the rabbit facial vein exhibits a high level of myogenic tone in vitro that develops only in stretched vessel segments between 33 degrees and 44 degrees C. The infusion of physiological salt solution into the lumen of 2-mm-long rabbit facial vein segments induced a flow rate-dependent increase in wall tone, both in the presence (37 degrees C) and absence (30 degrees C) of myogenic tone. In calcium-free physiological solution with EGTA, neither flow nor stretch-induced tone was observed. This flow-induced contraction was associated with an increase in 45Ca2+ unidirectional influx and net uptake. These measurements correlated positively with the level of the associated constrictor responses, both in the presence or absence of myogenic tone. The mean contractile responses to flow (10 and 40 microliters/min), stretch, and histamine (1 microM) were 13%, 28%, 24%, and 33% of the tissue maximal response, respectively. When 45Ca2+ influx was expressed in relation to the force development (45Ca2+ influx per milligram), the amount of calcium entry was dependent on the stimulus. Values for 45Ca2+ influx per milligram in response to flow (10 and 40 microliters/min) and to histamine (1 microM) were not significantly different. The value was significantly lower for the response to stretch. On the other hand, 45Ca2+ net uptake, when expressed per unit force, was similar in response to flow (10 and 40 microliters/min), histamine (1 microM), and stretch.(ABSTRACT TRUNCATED AT 250 WORDS)     

Local Ca2+ entry through L-type Ca2+ channels activates Ca2+-dependent K+ channels in rabbit coronary myocytes.

Large-conductance Ca2+-dependent K+ channels (KCa), which are abundant on the sarcolemma of vascular myocytes, provide negative feedback via membrane hyperpolarization that limits Ca2+ entry through L-type Ca2+ channels (ICaL). We hypothesize that local accumulation of subsarcolemmal Ca2+ during ICaL openings amplifies this feedback. Our goal was to demonstrate that Ca2+ entry through voltage-gated ICaL channels can stimulate adjacent KCa channels by a localized interaction in enzymatically isolated rabbit coronary arterial myocytes voltage clamped in whole-cell or in cell-attached patch clamp mode. During slow-voltage-ramp protocols, we identified an outward KCa current that is activated by a subsarcolemmal Ca2+ pool dissociated from bulk cytosolic Ca2+ pool (measured with indo 1) and is dependent on L-type Ca2+ channel activity. Transient activation of unitary KCa channels in cell-attached patches could be detected during long step depolarizations to +40 mV (holding potential, -40 mV; 219 pS in near-symmetrical K+). This local interaction between the channels required the presence of Ca2+ in the pipette solution, was enhanced by the ICaL agonist Bay K 8644, and persisted after impairment of the sarcoplasmic reticulum by incubation with 10 micromol/L ryanodine and 30 micromol/L cyclopiazonic acid for at least 60 minutes. Furthermore, we provide the first direct evidence of simultaneous openings of single KCa (67 pS) and ICaL (3.9 pS) channels in near-physiological conditions, near resting membrane potential. Our data imply a novel sensitive mechanism for regulating resting membrane potential and tone in vascular smooth muscle.     

Increased myofilament Ca2+ sensitivity and diastolic dysfunction as early consequences of Mybpc3 mutation in heterozygous knock-in mice

Hypertrophic cardiomyopathy (HCM) is frequently caused by mutations in MYBPC3 encoding cardiac myosin-binding protein C (cMyBP-C). The mechanisms leading from gene mutations to the HCM phenotype remain incompletely understood, partially because current mouse models of HCM do not faithfully reflect the human situation and early hypertrophy confounds the interpretation of functional alterations. The goal of this study was to evaluate whether myofilament Ca(2+) sensitization and diastolic dysfunction are associated or precede the development of left ventricular hypertrophy (LVH) in HCM. We evaluated the function of skinned and intact cardiac myocytes, as well as the intact heart in a recently developed Mybpc3-targeted knock-in mouse model carrying a point mutation frequently associated with HCM. Compared to wild-type, 10-week old homozygous knock-in mice exhibited i) higher myofilament Ca(2+) sensitivity in skinned ventricular trabeculae, ii) lower diastolic sarcomere length, and faster Ca(2+) transient decay in intact myocytes, and iii) LVH, reduced fractional shortening, lower E/A and E'/A', and higher E/E' ratios by echocardiography and Doppler analysis, suggesting systolic and diastolic dysfunction. In contrast, heterozygous knock-in mice, which mimic the human HCM situation, did not exhibit LVH or systolic dysfunction, but exhibited higher myofilament Ca(2+) sensitivity, faster Ca(2+) transient decay, and diastolic dysfunction. These data demonstrate that myofilament Ca(2+) sensitization and diastolic dysfunction are early phenotypic consequences of Mybpc3 mutations independent of LVH. The accelerated Ca(2+) transients point to compensatory mechanisms directed towards normalization of relaxation. We propose that HCM is a model for diastolic heart failure and this mouse model could be valuable in studying mechanisms and treatment modalities.     

Postresuscitation stunning: postfibrillatory myocardial dysfunction caused by reduced myofilament Ca2+ responsiveness after ventricular fibrillation-induced myocyte Ca2+ overload

INTRODUCTION: Resuscitation from ventricular fibrillation (VF), particularly from prolonged VF, frequently is complicated by postfibrillatory myocardial dysfunction (postresuscitation stunning). We tested whether this dysfunction can be caused by reduced myofilament Ca2+ responsiveness after VF-induced myocyte Ca2+ overload. We also tested whether electrical defibrillation shocks contribute to this dysfunction. METHODS AND RESULTS: Myofilament Ca2+ responsiveness was estimated as ratio of left ventricular developed pressure over myocyte Ca2+ transient amplitudes (assessed as indo-1 fluorescence) in isolated perfused rat hearts before, during, and after VF (1.5 or 10 min) comparing three modes of defibrillation (biphasic electrical shocks, lidocaine, or spontaneous). We found that, independent of these defibrillation modes, myofilament Ca2+ responsiveness was significantly reduced, particularly after prolonged VF, although hearts were not ischemic or acidotic during and after VF (unchanged coronary flow, myocardial oxygen consumption, and pH of the coronary effluent). This reduction was associated with VF-induced myocyte Ca2+ overload and increasing or decreasing Ca2+ overload during VF (using 1 microM diltiazem or 6 mM extracellular calcium) led to parallel changes of myofilament Ca2+ responsiveness. However, myofilament Ca2+ responsiveness was not associated with the defibrillation shock energy (range 0.1-15.0 J/g wet heart weight). CONCLUSION: Postfibrillatory myocardial dysfunction can be caused by reduced myofilament Ca2+ responsiveness after VF-induced myocyte Ca2+ overload. Electrical defibrillation shocks (up to 15 J/g wet heart weight), however, do not significantly contribute to this dysfunction. Our findings suggest that early additional therapy targeting intracellular Ca2+ overload may normalize myocyte Ca2+ and partially prevent postresuscitation stunning.     

ATP stimulates Ca2+ uptake and increases the free Ca2+ concentration in isolated rat liver nuclei.

Addition of ATP to a highly purified fraction of rat liver nuclei incubated with submicromolar concentrations of Ca2+ and trace amounts of 45Ca2+ resulted in the rapid accumulation of 45Ca2+ in the nuclei. This was associated with an increase in intranuclear free Ca2+ concentration as measured with the fluorescent dye 1-[2-(5-carboxyoxazol-2-yl)-6-aminobenzofuran-5-oxy]-2-(2'-a mino-5'- methylphenoxy)ethane-N,N,N',N'-tetraacetic acid (fura-2). Inhibitors of microsomal and mitochondrial Ca2+ translocases had no effect on nuclear Ca2+ sequestration, indicating that it was distinct from previously known intracellular Ca2+-transporting systems. Ca2+ uptake and the associated increase in intranuclear free Ca2+ concentration were prevented by calmidazolium, a potent calmodulin antagonist. Partial characterization of the ATP-stimulated nuclear Ca2+ uptake showed that maximal rates of Ca2+ uptake and increase in intranuclear free Ca2+ level occurred at concentrations of Ca2+ normally present in the cytosol of mammalian cells. Together, these results show that a distinct, ATP- and calmodulin-dependent Ca2+ uptake system exists in liver nuclei. This system may play an important role in the regulation of intranuclear Ca2+-dependent processes.     

Endothelin activates the dihydropyridine-sensitive, voltage-dependent Ca2+ channel in vascular smooth muscle.

Endothelin is a potent endothelium-derived vasoconstrictor peptide recently characterized from porcine and human vascular endothelial cells. Here we provide evidence that endothelin activates the dihydropyridine-sensitive, voltage-dependent Ca2+ channel in porcine coronary artery smooth muscle. The vasoconstrictor action of endothelin is efficiently antagonized by low doses of the dihydropyridine Ca2+-channel blocker nicardipine. Endothelin augments the Ca2+-induced contraction in a high-K+ depolarizing solution, markedly enhances high-threshold Ca2+-channel current on the whole-cell patch clamp recording, and causes a sustained increase in the intracellular Ca2+ that is largely dependent on extracellular Ca2+. These findings suggest that endothelin exerts its vasoconstrictor effect by either directly or indirectly activating the voltage-dependent Ca2+ channel.     

Phosphorylation-dependent alteration in myofilament ca2+ sensitivity but normal mitochondrial function in septic heart

The subcellular mechanisms responsible for myocardial depression during sepsis remain unclear. Recent data suggest a role for impaired energy generation and utilization, resulting in altered contractile function. Here, we studied the energetic and mechanical properties of skinned fibers isolated from rabbit ventricle in a nonlethal but hypotensive model of endotoxemia. Thirty-six hours after lipopolysaccharide (LPS) injection (in the presence of altered myocardial contractility), mitochondrial respiration, coupling between oxidation and phosphorylation, and creatine kinase function were similar in preparations from endotoxemic (LPS) and control animals. The maximal Ca2+-activated force was similar in LPS and control preparations. However, the Ca2+ concentration corresponding to half-maximal force (pCa50, where pCa = -log10[Ca2+]) was 5.55 +/- 0.01 (n = 11) in LPS fibers versus 5.61 +/- 0.01 (n = 10) in control fibers (p < 0.01). Both protein kinase A (PKA) and alkaline phosphatase treatment led to the disappearance in the difference between control and LPS pCa50 values. Incubation of control fibers with the nitric oxide donor S-nitroso-N-acetylpenicillamine (SNAP) did not change the Ca2+ sensitivity after subsequent skinning, whereas isoproterenol decreased pCa50 from 5.62 +/- 0.01 to 5.55 +/- 0.01 (p < 0.01). These data suggest that during sepsis, cardiac mitochondrial and creatine kinase systems remain unaltered, whereas protein phosphorylation decreases myofibrillar Ca2+ sensitivity and may contribute to the depression of cardiac contractility.     

Length dependence of cardiac myofilament Ca(2+) sensitivity in the presence of substitute nucleoside triphosphates

Although ATP is the immediate source of energy for muscle contraction other nucleoside triphosphates (NTP) can substitute for ATP as substrates for myosin and as sources of energy for contraction of skinned muscle fibers. However, experiments with skinned skeletal muscle fibers in the presence of substitute NTP indicate significant differences with respect to cross-bridge kinetics, force generation, and Ca(2+) regulation. In this study the length dependence of Ca(2+) sensitivity of skinned bovine cardiac muscle was analyzed in the presence of MgATP, MgCTP, MgUTP, and MgITP. Ca(2+) regulation in the presence of MgCTP and MgUTP was essentially the same as in the presence of MgATP, although the maximum force generated (at sarcomere length 2.4 microm) was about 25% less. However, the length dependence of Ca(2+) sensitivity was eliminated in the presence of MgUTP. With MgITP the maximum force generated (at sarcomere length 2.4 microm) was about the same as in the presence of MgATP, but there was an impairment of relaxation such that at pCa 8 the force developed was about 50-60% of that developed at pCa 5. Moreover, the Ca(2+)-dependent component showed no length-dependent sensitivity. Thus length modulation of Ca(2+) sensitivity is a function of the myosin substrate. Taken in conjunction with other data, the results are consistent with the hypothesis that length-dependence of Ca(2+) sensitivity is modulated at a step upstream from the force-generating reaction.     

Novel diazinone derivatives separate myofilament Ca2+ sensitization and phosphodiesterase III inhibitory effects in guinea pig myocardium.

The inotropic state of the myocardium can be enhanced via an increase in cell Ca2+ loading or in myofilament responsiveness to Ca2+. Although different pharmacological agents combine these properties, no presently available drug acts predominantly as a myofilament sensitizer in situ. We have investigated the effects and the mechanism of action of novel diazinone derivatives, EMD 54622, EMD 53998, and EMD 54650 (developed by E. Merck, Darmstadt), on guinea pig myocardial preparations. Force- and ATPase-pCa relations in skinned fibers show differing potencies of these agents on myofilament sensitization: EMD 54622 greater than EMD 53998 much greater than EMD 54650. This is in contrast to their relative potencies to inhibit isolated myocardial phosphodiesterase III: EMD 54650 greater than EMD 53998 greater than EMD 54622. In isolated hearts studied at constant coronary flow, each of the three diazinone derivatives had a positive inotropic effect. In enzymatically dissociated left ventricular myocytes loaded with the Ca2+ probe indo-1, the positive inotropic effect of EMD 54622 occurred with no change in the amplitude of the cytosolic [Ca2+] (Cai) transient. In contrast, both EMD 53998 and EMD 54650 enhanced Cai transient and twitch contraction amplitudes. Length-indo-1 fluorescence relations were analyzed to determine the effects of the three substances on myofilament responsiveness to Ca2+. EMD 54622 enhanced and EMD 54650 had no effect on myofilament responsiveness to Ca2+. Less uniform results were obtained with EMD 53998 (in two of five cells the myofilament responsiveness to Ca2+ was increased, whereas in three other cells it was unaltered). Our results indicate that structural changes in the diazinone molecule shift the mechanism of action for the positive inotropic effect of the diazinone derivatives in the intact cell from a predominant myofilament sensitization (EMD 54622) to an enhancement in cell Ca2+ loading and an augmentation in the Cai transient (EMD 54650).     

Repetitive increases in cytosolic Ca2+ of guard cells by abscisic acid activation of nonselective Ca2+ permeable channels.

Many signal-transduction processes in higher plant cells have been suggested to be triggered by signal-induced opening of Ca2+ channels in the plasma membrane. However, direct evidence for activation of plasma-membrane Ca2+ channels by physiological signals in higher plants has not yet been obtained. In this context, several lines of evidence suggest that Ca2+ flux into the cytosol of guard cells is a major factor in the induction of stomatal closing by abscisic acid (ABA). ABA closes stomatal pores, thereby reducing transpirational loss of water by plants under drought conditions. To directly investigate initial events in ABA-induced signal transduction in guard cells, we devised an experimental approach that allows simultaneous photometric measurements of cytosolic Ca2+ and patch-clamp recordings of ion currents across the plasma membrane of single Vicia faba guard cells. Using this approach, we found that the resting cytosolic Ca2+ concentration was 0.19 +/- 0.09 microM (n = 19). In responsive guard cells, external exposure to ABA produced transient repetitive increases in the cytosolic free Ca2+ concentration. These Ca2+ transients were accompanied by concomitantly occurring increases in an inward-directed ion current. Depolarization of the membrane terminated both repetitive elevations in cytosolic Ca2+ and inward-directed ion currents, suggesting that ABA-mediated Ca2+ transients were produced by passive influx of Ca2+ from the extracellular space through Ca2(+)-permeable channels. Detailed voltage-clamp measurements revealed that ABA-activated ion currents could be reversed by depolarizations more positive than -10 mV. Interestingly, reversal potentials of ABA-induced currents show that these currents are not highly Ca2(+)-selective, thereby permitting permeation of both Ca2+ and K+. These results provide direct evidence for ABA activation of Ca2(+)-permeable ion channels in the plasma membrane of guard cells. ABA-activated ion channels allow repetitive elevations in the cytosolic Ca2+ concentration, which, in turn, can modulate cellular responses promoting stomatal closure.     

Role of Ca2+- and swelling-activated Cl- channels in alpha1-adrenoceptor-mediated tone in pressurized rabbit mesenteric arterioles

BACKGROUND: Ca2+-activated (I(Cl(Ca))) and swelling-induced (I(Cl(swell))) Cl- channels have, respectively, been postulated to participate in the membrane depolarization and contraction mediated by activation of alpha1-adrenoceptors and vascular wall distension during pressurization. Their respective function in generating active force in pressurized arterioles during alpha1-adrenoceptor stimulation remains unsettled. OBJECTIVES: Experimental protocols were designed to: (1) assess the relative contribution of I(Cl(Ca)) to the pressure-dependence of lumen diameter of mesenteric arterioles at different states of activation of the alpha1-adrenoceptor, and (2) investigate the potential role of I(Cl(swell)) in spontaneous and agonist-mediated myogenic reactivity. METHODS: Segments of endothelium-denuded rabbit mesenteric arterioles with a lumen diameter of approximately 70 microm were cannulated at both ends and studied under isobaric conditions at 36 degrees C. Steady-state lumen diameter at each pressure step investigated (0-100 mmHg, in 20-mmHg increments) was measured by a video-microscopy edge-detection technique. RESULTS: Under control conditions, 23% of the arterioles developed nifedipine-sensitive spontaneous myogenic tone. In the presence of 1 mM tetraethylammonium chloride (TEA) to inhibit Ca2+-dependent K+ channels, the alpha1-agonist phenylephrine (PE) contracted the vessels in a concentration-dependent manner (0.1-10 microM) and potentiated myogenic reactivity. The contraction mediated by 1 microM PE/TEA was abolished by 1 microM nifedipine, indicating that Ca2+ entry through voltage-gated Ca2+ channels was a necessary step in the cascade leading to contraction. Niflumic acid (NfA, 100 microM), a relatively selective inhibitor of I(Cl(Ca)), had no effect on myogenic tone but reversed the PE-induced contraction, varying with the concentration of PE and transmural pressure. For PE concentrations between 0.1 and 1 microM, but not for 10 microM PE, the relaxing efficacy of NfA decreased as applied pressure was raised from 0 to 100 mmHg. At all pressure steps, the NfA-induced relaxation was inversely related to the concentration of PE. DIDS (200 microM), another Cl- channel blocker, inhibited spontaneous myogenic tone, and partially suppressed a component of contraction at elevated transmural pressures in arterioles incubated in 1 microM PE/1 mM TEA/100 microM NfA. CONCLUSIONS: Our data indicate that under low to moderate stimulation of the alpha1-adrenoceptor signaling pathway, I(Cl(Ca)) channels play an important role in the sustained contraction produced. Their declining contribution to contraction with increasing transmural pressure may be explained, at least in part, by a progressive enhancement of stretch-induced ionic conductances, possibly volume-sensitive Cl- channels.