Ca2+-induced redistribution of Ca2+/calmodulin-dependent protein kinase II associated with an endoplasmic reticulum stress response in vascular smooth muscle.

The relation between CaM kinase II activity and high Ca2+-mediated stress responses was studied in cultured vascular smooth muscle cells. Treatment with ionomycin (1 microM) for 5 min caused a significant loss of CaM kinase II activity in whole cell homegenates and prominent vesiculation of the endoplasmic reticulum (ER). Similar losses of CaM kinase II activity were observed in the soluble lysate as assessed by activity measurements and Western blotting. Examination of the post-lysate particulate fraction showed that the loss of CaM kinase II from the soluble lysate was accompanied by a redistribution of CaM kinase II to this fraction. The ionomycin-mediated response was limited to this concentration (1 microM); lower concentrations of ionomycin as well as stimulation with angiotensin II (1 microM) orATP (100 microM) did not cause a shift in CaM kinase II distribution. Treatment with neither the CaM kinase II inhibitor KN-93 nor the phosphatase inhibitor okadaic acid altered the ionomycin-induced redistribution indicating that CaM kinase II activation and/or phosphorylation was not part of the mechanism. The response, however, was eliminated when the cells were treated in Ca2+-free medium. Washout of ionomycin led to only a partial restoration of the kinase activity in the soluble fraction after 10 min. Immunofluorescence microscopy of resting cells indicated colocalization of antibodies to CaM kinase II and an ER protein marker. ER vesiculation induced by ionomycin coincided with a parallel redistribution of CaM kinase II and ER marker proteins. These data link ionomycin-induced ER restructuring to a progressive redistribution of CaM kinase II protein to an insoluble particulate fraction and loss of cellular CaM kinase II activity. We propose that redistribution of CaM kinase II and loss of cellular activity are components of a common Ca2+-overload induced cellular stress response in cells.

Myosin light chain kinase phosphorylation in nitrovasodilator induced swine carotid artery relaxation.

Nitrovasodilators are hypothesized to induce smooth muscle relaxation by their metabolism to nitric oxide, which then activates soluble guanylyl cyclase, increases [cGMP], and activates cGMP-dependent protein kinase. cGMP-dependent phosphorylation is then proposed to decrease intracellular [Ca2+] ([Ca2+]i) and to reduce the Ca(2+)-sensitivity of contraction. We hypothesized that one component of decreased Ca(2+)-sensitivity, reduced Ca(2+)-sensitivity of MLC phosphorylation, was due to phosphorylation of myosin light chain kinase (MLCK) on the peptide site A. In the swine carotid artery, histamine (10 microM) stimulation increased aequorin-estimated [Ca2+]i, MLCK site A phosphorylation, MLC phosphorylation, and force. Subsequent addition of 100 microM nitroglycerin (NTG) or 100 microM sodium nitroprusside (NP) to histamine-stimulated tissues increased [cGMP], decreased both MLC phosphorylation and force, but did not significantly alter [cAMP], [Ca2+]i, or MLCK site A phosphorylation. Addition of NTG and NP alone to unstimulated tissues increased MLCK site A phosphorylation, but did not alter [Ca2+]i. In tissues preincubated with NP, subsequent histamine contraction was slowed compared with controls, however, this slowed rate of contraction appeared to result from an attenuation of histamine-dependent increases in [Ca2+]i. These data suggest that, in swine carotid artery, nitrovasodilators can decrease the Ca(2+)-sensitivity of MLC phosphorylation without increasing MLCK site A phosphorylation. Nitrovasodilators, per se, can induce site A MLCK phosphorylation, potentially by cGMP dependent activation of cAMP-dependent protein kinase.

Focal increases in [Ca2+]i may account for apparent low Ca2+ sensitivity in swine carotid artery.

Estimates of [Ca2+]i sensitivity in intact smooth muscle are frequently obtained by measuring [Ca2+]i with indicators such as aequorin or Fura-2. We investigated whether focal increases in [Ca2+]i could impair such measures of [Ca2+]i sensitivity. Stimulation of swine carotid artery with 10 microM histamine increased aequorin estimated [Ca2+]i, Fura-2 estimated [Ca2+]i and Ca2+ sensitivity without significantly altering the aequorin/Fura-2 ratio (an estimate of [Ca2+]i homogeneity). Subsequent inhibition of Na+/Ca2+ exchange by replacement of Na+ in the PSS with choline+ significantly increased aequorin-estimated [Ca2+]i but only minimally increased Fura-2 estimated [Ca2+]i, myosin light chain (MLC) phosphorylation and force. This resulted in a large increase in the aequorin/Fura-2 ratio, suggesting an increase in [Ca2+] inhomogeneity. Addition of 100 microM histamine to tissues in the choline+ buffer initially increased both aequorin and Fura-2 estimated [Ca2+]i, but after 10 min exposure both of the [Ca2+]i estimates declined to pre-histamine levels. Histamine addition significantly increased MLC phosphorylation and force, indicating increased Ca2+ sensitivity, but the aequorin/Fura-2 ratio remained elevated and unchanged from pre-histamine values. These data show that under certain conditions, aequorin and Fura-2 can yield widely differing estimates of [Ca2+]i and thus can cause misleading assessments of Ca2+ sensitization mechanisms. These discrepancies may arise from inhomogeneous or focal increases in [Ca2+]i which can be evaluated with the aequorin/Fura-2 ratio.

Focal [Ca2+]i increases detected by aequorin but not by fura-2 in histamine- and caffeine-stimulated swine carotid artery.

1. We hypothesized that the homogeneity of intracellular [Ca2+] ([Ca2+]i) varies and is regulated in arterial smooth muscle. 2. We evaluated this hypothesis by exploiting the different characteristics of several [Ca2+]i indicators: (1) aequorin, which theoretically can measure focal increases in [Ca2+]i, (2) fura-2, which is predominantly a measure of mean cytoplasmic [Ca2+], and (3) myosin light chain phosphorylation and force, which reflect increases in [Ca2+] near the contractile apparatus. 3. From the differences in the observed aequorin and fura-2 signals, we developed an index of the relative degree of [Ca2+]i homogeneity as the ratio of the aequorin signal and fura-2 signal. 4. Stimulation with intermediate concentrations of histamine (1 and 10 microM) or high [K+]o (25 and 40 mM) increased [Ca2+]i and contractile stress. Relative [Ca2+]i homogeneity, estimated from the aequorin/fura-2 ratio, remained similar to levels observed in unstimulated tissues. 5. Higher concentrations of histamine (100 microM) also increased [Ca2+]i and stress, but the aequorin/fura 2 ratio declined , indicating increased [Ca2+]i homogeneity. Similarly, the aequorin/fura-2 ratio decreased when extracellular Ca2+ was removed. 6. Stimulation with histamine in low extracellular [Ca2+] transiently increased [Ca2+]i and the aequorin/fura-2 ratio. Similarly, in tissues treated with low extracellular [Ca2+], restoration of extracellular Ca2+ transiently increased both [Ca2+]i and the aequorin/fura-2 ratio. Although both of these experiments demonstrated a transient decrease in [Ca2+]i homogeneity, only histamine stimulation led to increased myosin light chain phosphorylation and force. These results indicate that the focal increases in [Ca2+]i observed with histamine stimulation and Ca2+ restoration occurred in different cellular regions. 7. Addition of caffeine (20 mM) increased [Ca2+]i and [cAMP], but this was not accompanied by sustained increased myosin light chain phosphorylation or contraction. Phosphorylation of myosin light chain kinase did not appear to underlie the lack of increase in myosin light chain phosphorylation. Rather, caffeine induced a sustained increase in the aequorin/fura-2 ratio, suggesting that caffeine inhibits smooth muscle contraction by localizing increases in [Ca2+]i to a region distant from the contractile apparatus. 8. These data suggest that there can be transient and sustained focal increases in [Ca2+]i. Aequorin detected increased [Ca2+]i in small regions of the cytoplasm during release from and refilling of the intracellular Ca2+ store and with caffeine stimulation. Dual use of aequorin and fura-2 permits determination of relative [Ca2+]i homogeneity in smooth muscle.

Myosin light chain kinase phosphorylation in swine carotid artery contraction and relaxation.

We investigated the role of myosin light chain kinase (MLCK) phosphorylation in regulating the sensitivity of vascular smooth muscle myosin light chain (MLC) phosphorylation to intracellular Ca2+ concentration ([Ca2+]i). 32PO4-loaded swine carotid arteries were stimulated with histamine or high K+, MLCK was isolated, and the relative phosphorylation of tryptic peptides was measured. In nonlabeled tissues, we measured [Ca2+]i with aequorin, MLCK activity ratio, MLC phosphorylation, and force. A comparison of MLCK phosphorylation on peptide A (mol P in site A/mol MLCK) and MLCK activity ratio showed an inverse relation, suggesting that MLCK site A phosphorylation can regulate the Ca2+ sensitivity of MLCK. MLCK site A phosphorylation and MLCK activity ratio depended on [Ca2+]i. Histamine stimulation yielded greater MLC phosphorylation than high K+ stimulation over a range of [Ca2+]i; however, there were no apparent stimulus-dependent differences in MLCK phosphorylation, suggesting that stimulus-dependent differences in the Ca2+ sensitivity of MLC phosphorylation are not based on differences in MLCK phosphorylation. We also determined whether MLCK phosphorylation was involved in adenosine 3',5'-cyclic monophosphate-mediated relaxation. In histamine-contracted tissues, forskolin decreased [Ca2+]i, MLC phosphorylation, and force. MLCK phosphorylation decreased to an extent consistent with the decrease in [Ca2+]i. In KCl-stimulated tissues, forskolin did not alter [Ca2+]i or increase MLCK phosphorylation but forskolin did decrease MLC phosphorylation. Thus, in swine carotid artery, MLCK phosphorylation appears to be regulated exclusively by Ca2+ and plays little role in stimulus-dependent differences in Ca2+ sensitivity of MLC phosphorylation or in mediating forskolin-induced relaxation.

Electrical field stimulation-mediated relaxation of rabbit middle cerebral artery. Evidence of a cholinergic endothelium-dependent component.

The effects of electrical field stimulation (EFS) of rabbit middle cerebral arteries were examined using wire-mounted arterial segments. EFS of segments maintained at rest tension caused a tetrodotoxin-sensitive sympathetic contraction. In agonist-contracted segments maintained at approximately 60% of tissue maximum force, EFS caused a relaxation in two thirds of the preparations. Maximum response (mean +/- SEM) was 33 +/- 3.5% of maximal relaxation. The EFS relaxation was tetrodotoxin-sensitive but was not blocked by either chronic surgical sympathectomy or exposure to guanethidine (5 microM). Electron microscopy of chromaffin-fixed arterial sections showed the presence of chromaffin-positive large and small vesicles. Within the same sheath of Schwann were also a smaller number of nerve profiles containing many small clear vesicles. Removal of the vascular endothelium or treatment with atropine (10 nM) eliminated the EFS relaxation in approximately 50% of the segments and reduced the response in another 35-40%; in the remainder, relaxation was unaffected. Combined data for endothelium removal and atropine treatment showed that each caused a significant (p less than 0.01) reduction in the EFS relaxation. Atropine also significantly reduced EFS relaxation in guanethidine-treated segments. There was no reduction in EFS relaxation after procedures that antagonized ATP- or substance P-mediated relaxations. These results indicate that EFS of precontracted rabbit middle cerebral artery causes a neurogenic nonadrenergic relaxation. The neuroeffector mechanism mediating this response has a predominantly cholinergic endothelium-dependent component as well as a noncholinergic endothelium-independent component.

Selective variation of agonist and neurally mediated vasoconstriction with rabbit middle cerebral artery branch order.

The in vitro contractions of four successive branches of the rabbit middle cerebral artery to norepinephrine (NE), serotonin (5HT), histamine, and electrical field stimulation (EFS) were examined. Internal lumen diameters of the four branches (designated MCA, M1, M2, M3, proximal to distal) ranged from a mean of 270 microns in the MCA to 160 microns in the M3 segments. NE produced a small alpha adrenoceptor-mediated response in the MCA (12% of tissue maximum); this was diminished in the M1 segment and there was no evidence of alpha adrenoceptor-mediated responses in the M2 and M3 branches. NE contractions, mediated through low affinity sites (extraceptors), did not change with branch order. Maximal responses to 5HT (1 microM) were small and also diminished with branch order; the MCA and M1 contracted to 24 and 18% of tissue maximum, respectively. Negligible responses were obtained in M2 and M3. EFS resulted in contractions that were tetrodotoxin- and guanethidine-sensitive. Maximum EFS responses were 21% tissue maximum in the MCA, 13% in the M1, and less than 5% in the M2 and M3. In contrast, maximal contractile responses to histamine (100 microM) were at or near tissue maximum in all segments. Removal of the endothelium did not influence the size of the contraction to NE, 5HT or histamine in the MCA and M1 segments. Neither NE, 5HT, nor histamine caused relaxation responses in agonist or KCl-contracted segments. The results indicate a differential variation in responsiveness with increasing branch order in the rabbit cerebrovascular bed.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence that neuropeptide Y and norepinephrine mediate electrical field-stimulated vasoconstriction of rabbit middle cerebral artery.

We investigated the contractile response of isolated rabbit middle cerebral artery (MCA) segments to electrical field stimulation (EFS). The dynamics of the EFS contraction were compared with a similar-sized branch of rabbit ear artery. In comparison with the ear artery, the EFS contractions of the MCA displayed a longer latency and a higher stimulus frequency threshold. Greater stimulation train lengths were required to attain equilibrium, and the time course of EFS response--including force development, plateau, and return to rest tension--was significantly slower than in the ear artery. Morphological and pharmacological studies of the MCA showed that it receives sympathetic adrenergic innervation: whole-mount preparations displayed catecholamine histofluorescence; electron micrographs of MCA sections revealed a population of varicosities containing chromaffin positive large and small vesicles; and EFS contractions were blocked by tetrodotoxin (30 nM) and guanethidine (5 microM) and by chronic surgical sympathectomy. Exposure to prazosin (10 microM) or phenoxybenzamine (1 microM) blocked norepinephrine contractions but did not significantly influence the EFS contraction. Procedures and drugs that antagonized the responses to neuropeptide Y, serotonin, or histamine were also ineffective in blocking the EFS contraction. The involvement of ATP could not be assessed, since the purinergic P2 agonist alpha,beta-methylene ATP was ineffective in blocking ATP-mediated contractions. The EFS contraction, however, could be blocked by a combination of neuropeptide Y desensitization and phenoxybenzamine (30 nM) or prazosin (0.1 microM). These results suggest that norepinephrine and neuropeptide Y are released from sympathetic nerves and mediate EFS contraction by occupation of postjunctional alpha-adrenoceptor and neuropeptide Y receptors. Since the blockade of only one of these components does not diminish the response to EFS, the adrenergic neuroeffector system in this artery may involve complex prejunctional regulatory mechanisms.

Muscarinic receptors on intact human fibroblasts. Absence of receptor activity in adult skin cells.

The intact human fibroblast has been used in clinical and basic research studies of receptor-mediated control of cell function, however there is little information about the relationship between muscarinic receptor density and the regulation of cyclic AMP (cAMP) accumulation. We have compared the muscarinic receptor characteristics of both lung and skin intact fibroblasts at fetal and adult stages of development using carbachol-mediated inhibition of cAMP accumulation and the binding of [3H]quinuclidinyl benzilate (QNB). Prostaglandin E1 (PGE1) stimulated cAMP accumulation in all four cell lines, while carbachol inhibited cAMP accumulation only in the fetal lung, adult lung, and to a lesser extent, the fetal skin. Adult skin fibroblasts did not display significant evidence of inhibitory muscarinic receptor activity. [3H]QNB binding was saturable for the fetal and adult lung, and the fetal skin, yielding Kd values of approximately 0.5 nM for these cell lines. Bmax values were 360 fmol/mg for fetal skin, 600 fmol/mg for adult lung, and 876 fmol/mg for the fetal lung. Specific binding of [3H]QNB to adult skin fibroblasts was found to be low and variable. Comparisons of the Bmax values and maximal inhibitory capacities showed that the receptor density paralleled receptor activity in all cell lines. The lack of muscarinic receptor activity in the adult skin fibroblast was confirmed in several different adult skin cell lines, indicating that the adult skin fibroblast may not be an appropriate model for muscarinic receptor activity in clinical investigations.