G alpha(q)-coupled receptors in human atrium function through protein kinase C epsilon and delta

Cardiac G alpha(q)-coupled receptors (such as endothelin, angiotensin, and alpha1-adrenergic receptors) mediate cardiac inotropy and chronotropy, as well as the development of hypertrophy. These receptors signal through protein kinase C (PKC), a family of 12 isozymes including PKC alpha, beta I, beta II, gamma, delta, epsilon, theta, eta, lambda, iota, zeta, and mu. Of these PKC isozymes, alpha, beta II, gamma, epsilon, delta, and zeta have been implicated in signaling through cardiac G alpha(q)-coupled receptors in various animal models. However, the profile of which isozymes are activated by a given G alpha(q)-coupled receptor varies among animal species. Thus, these results can not be extrapolated to human heart. In this study, we examine PKC isozymes activated by three different G alpha(q)-coupled receptors in human atrial tissue. Live atrial appendages obtained from the operating room were sliced and treated with agonists of G alpha(q)-coupled receptors, and cellular redistribution of PKC isozymes was examined by immunoblotting. We find that stimulation of G alpha(q)-coupled receptors in human atrium activates PKC epsilon and delta only, under both acute (5 min) and longer (35 min) stimulations. Further, PKC epsilon and delta exhibit distinct subcellular redistribution patterns; while both translocate to the plasma membrane upon G alpha(q) stimulation, PKC delta also redistributes to mitochondria. We conclude that PKC epsilon and delta are the main PKC isozymes involved in G alpha(q)-mediated signaling in human atria.     

Tissue angiotensin II during progression or ventricular hypertrophy to heart failure in hypertensive rats; differential effects on PKC epsilon and PKC beta

The protein kinase C (PKC) family has been implicated as second messengers in mechanosensitive modulation of cardiac hypertrophy. However, little information is available on the role of expression and activation of specific cardiac PKC isozymes during development of left ventricular hypertrophy (LVH) and failure (LVF). Dahl salt-sensitive rats fed an 8% salt diet developed systemic hypertension and concentric LVH at 11 weeks of age that is followed by left ventricle (LV) dilatation and global hypokinesis at 17 weeks. Among several PKC isozymes expressed in the LV myocardium, only PKC epsilon showed a 94% increase at the LVH stage. At the LVF stage, however, PKC epsilon returned to the control level, whereas PKC beta I and beta II increased by 158% and 155%, respectively. Hearts were studied at each stage using the Langendorff set-up, and a LV balloon was inflated to achieve an equivalent diastolic wall stress. Following mechanical stretch, PKC epsilon was significantly activated in LVH myocardium in which tissue angiotensin II levels were increased by 59%. Pre-treatment with valsartan, an AT(1)-receptor blocker, abolished the stretch-mediated PKC epsilon activation. Mechanical stretch no longer induced PKC epsilon activation in LVF. Chronic administration of valsartan blunted the progression of LVF and inhibited the increase in PKC beta. Mechanosensitive PKC epsilon activation is augmented and therefore may contribute to the development of compensatory hypertrophy. This effect was dependent on activation of tissue angiotensin II. However, this compensatory mechanism becomes inactive in LVF, where PKC beta may participate in the progression to cardiac dysfunction and LV remodeling.     

Survival role of protein kinase C (PKC) in chronic lymphocytic leukemia and determination of isoform expression pattern and genes altered by PKC inhibition

Recent studies have suggested that protein kinase C (PKC) activation plays an important role in survival of chronic lymphocytic leukemia (CLL). In order to characterize the role of PKC in CLL, we investigated the expression pattern of PKC isoforms in CLL cells (7 cases) and evaluated the effect of PKC inhibition on the survival of CLL cells (20 cases). Expression of the classical PKC isoforms beta and gamma, the novel isoform delta and the atypical isoform zeta was seen in all analyzed patient samples by Western blot analysis. Expression of the PKC isoforms alpha, epsilon, and iota was variable. Following incubation with the PKC inhibitor, safingol, CLL cells underwent marked apoptosis in all cases. In order to characterize the molecular events associated with the apoptotic effect of PKC inhibition, gene expression patterns in CLL cells were evaluated by cDNA-microarray analysis. Following safingol treatment, several genes showed marked downregulation and PKC-related proteins demonstrated decreased hybridization signals. Among these proteins, CREB and Daxx were further studied by using Western blotting, nuclear binding assay and confocal immunofluorescent microscopy. These studies showed significant inhibition of these proteins, consistent with the results of microarray gene analysis. Overall, these findings suggest that PKC activation is important for CLL cell survival and that inhibitors of PKC may have a role in the treatment of patients with CLL.     

Negative transcriptional regulation of human colonic smooth muscle Cav1.2 channels by p50 and p65 subunits of nuclear factor-kappaB

BACKGROUND & AIMS: The expression of Cav1.2 channels in colonic circular smooth muscle cells and the contractility of these cells are suppressed in inflammation. Our aim was to investigate whether the activation of p50 and p65 nuclear factor-kappaB subunits mediates these effects. METHODS: Primary cultures of human colonic circular smooth muscle cells and muscle strips were used. RESULTS: The messenger RNA and protein expression of the pore-forming alpha1C subunit of Cav1.2 channels decreased time dependently in response to tumor necrosis factor alpha. This effect was blocked by prior transient transfection of the cells with antisense oligonucleotides to p50 or p65. The overexpression of p50 and p65 inhibited the constitutive expression of alpha1C. Three putative kappaB binding motifs were identified on the 5' flanking region of exon 1b of the human L-type calcium channel alpha1C gene. Progressive 5' deletions of the promoter and point mutations of the kappaB binding motifs indicated that the two 5' binding sites, but not the third 3' binding site, were essential for the suppression of alpha1C. Transient transfection of human colonic circular muscle strips with antisense oligonucleotides to p50 and p65 decreased expression of the 2 nuclear factor-kappaB units and reversed the suppression of alpha1C, as well as that of the contractile response to acetylcholine, by 24 hours of treatment with tumor necrosis factor alpha. CONCLUSIONS: The activation of p50 and p65 by tumor necrosis factor alpha suppresses the expression of the alpha1C subunit of Cav1.2 channels in human colonic circular smooth muscle cells and their contractile response to acetylcholine. Nuclear factor-kappaB must bind concurrently to the two 5' kappaB motifs on the promoter of alpha1C to produce this effect.     

Down-regulation of L-type calcium channels in inflamed circular smooth muscle cells of the canine colon

BACKGROUND & AIMS: Circular smooth muscle phasic contractions and tone are suppressed during colonic inflammation, but the contributing factors are poorly understood. This study investigated if the expression level of voltage-gated long-lasting (L-type) Ca(2+) channel protein and functional Ca(2+) channel current are down-regulated in the circular muscle cells of the inflamed canine colon. METHODS: L-type Ca(2+) channel expression was compared between normal and inflamed smooth muscle cells by Western immunoblots using an antibody directed against the pore-forming alpha 1C-subunit, and patch-clamp methods were used to evaluate Ca(2+) channel current density. RESULTS: The expression of the L-type Ca(2+) channel protein was significantly reduced in inflamed compared with normal circular smooth muscle cell membranes, and this finding was associated with suppressed levels of Ca(2+) channel current in patch-clamped cells. The L-type Ca(2+) channel current in normal and inflamed cells increased proportionately in response to Bay K 8644, but the maximal current density was still lower in the inflamed cells. Acetylcholine increased the L-type Ca(2+) channel current in normal but not in inflamed cells. CONCLUSIONS: The expression level of L-type Ca(2+) channels is down-regulated in the circular smooth muscle cell membranes of the inflamed colon, which may result in reduced Ca(2+) influx. The functional and pharmacologic properties of the channels seem normal. Although some Ca(2+) channels are still present in the inflamed cells, acetylcholine does not activate these channels, which may be caused by additional upstream defects in the receptor signaling cascade. The down-regulation of L-type Ca(2+) channel expression may suppress circular smooth muscle contractions in the inflamed colon and contribute to the abnormalities in motility and digestion observed during inflammatory disorders.     

Protein kinase C isozymes epsilon and alpha in murine erythroleukemia cells.

Protein kinase C (PKC) has a role in signal transduction during hexamethylene bisacetamide (HMBA)-induced differentiation of murine erythroleukemia cells (MELC). Separation of MELC PKC isozymes by hydroxylapatite chromatography yields a major peak (III) and a minor peak (II) of PKC activity, previously reported to contain the PKC alpha and beta isozymes, respectively. In the present study, we confirm that peak III activity is PKC alpha but show that peak II contains PKC epsilon and little or no PKC beta. Immunoblot analysis with isozyme-specific anti-alpha and anti-epsilon PKC antibodies detected PKC alpha in peak III and PKC epsilon in peak II. Peak III activity was markedly enhanced (up to 20-fold) by phosphatidylserine, diolein, and Ca2+, whereas addition of these cofactors to the reaction mixture stimulated peak II activity only 2- to 4-fold. RNase protection analysis of MELC RNA showed that PKC alpha and PKC epsilon RNAs were in a ratio of approximately 2:1, but PKC beta RNA was barely detectable. Taken together, these data indicate that MELC contain PKC alpha and PKC epsilon but little or no PKC beta.     

Role of protein kinase C in eosinophil function.

Protein kinase C (PKC) isoforms are being elucidated as an increasingly diverse family of enzymes involved in the downstream signal transduction and cell function in various types of cells. To date, 11 PKC isoforms have been identified; they are grouped according to their molecular structure and mode of activation: conventional PKCs (alpha, beta I, beta II, and gamma), novel PKCs (delta, epsilon, mu, theta, and eta), and atypical PKCs (zeta, and iota/lambda). Eosinophils are involved in the pathogenesis of allergic diseases such as bronchial asthma, pollinosis, and atopic dermatitis as well as in the inflammatory response to parasitic infections. Recent studies using selective activators and inhibitors of individual PKC isoforms have revealed that this enzyme is involved in eosinophil dynamics such as cell motility and other functions. However, the role of PKCs in eosinophil functions has been not wholly understood. In this review, we have focused upon and summarized the current knowledge regarding the role of PKC isoforms in eosinophil functions.     

Effect of pinaverium bromide on stress-induced colonic smooth muscle contractility disorder in rats

AIM: To investigate the effect of pinaverium bromide, a L-type calcium channel blocker with selectivity for the gastrointestinal tract on contractile activity of colonic circular smooth muscle in normal or cold-restraint stressed rats and its possible mechanism. METHODS: Cold-restraint stress was conducted on rats to increase fecal pellets output. Each isolated colonic circular muscle strip was suspended in a tissue chamber containing warm oxygenated Tyrode-Ringer solution. The contractile response to ACh or KCl was measured isometrically on ink-writing recorder. Incubated muscle in different concentrations of pinaverium and the effects of pinaverium were investigated on ACh or KCl-induced contraction. Colon smooth muscle cells were cultured from rats and (Ca(2+))(i) was measured in cell suspension using the Ca(2+) fluorescent dye fura-2/AM. RESULTS: During stress, rats fecal pellet output increased 61 % (P<0.01). Stimulated with ACh or KCl, the muscle contractility was higher in stress than that in control. Pinaverium inhibited the increment of (Ca(2+))(i) and the muscle contraction in response to ACh or KCl in a dose dependent manner. A significant inhibition of pinaverium to ACh or KCl induced (Ca(2+))(i) increment was observed at 10(-6) mol/L. The IC(50) values for inhibition of ACh induced contraction for the stress and control group were 1.66X10(-6) mol/L and 0.91X10(-6) mol/L, respectively. The IC(50) values for inhibition of KCl induced contraction for the stress and control group were 8.13X10(-7) mol/L and 3.80X10(-7) mol/L, respectively. CONCLUSION: Increase in (Ca(2+))(i) of smooth muscle cells is directly related to the generation of contraction force in colon. L-type Ca(2+) channels represent the main route of Ca(2+) entry. Pinaverium inhibits the calcium influx through L-type channels; decreases the contractile response to many kinds of agonists and regulates the stress-induced colon hypermotility.     

磷脂酰乙醇胺N-甲基转移酶2过表达对大鼠肝癌细胞不同亚型蛋白激酶C表达及转位的影响

目的 探讨转染磷脂酰乙醇胺N-甲基转移酶2-（PEMT2）基因抑制大鼠肝癌CBRH-7919细胞增殖的机制。方法 采用免疫细胞化学和蛋白质印迹法观察Pemt2过表达对肝癌细咆不矧亚型蛋白激酶C-（PKC）表达及在细胞内转位的影响，同时采用高效薄板层忻技术对细胞内二脂酰甘油（DAG）的水平进行检测。结果 转染PEMT2使细胞cPKC-α表达降低，cPKC-β2表达增加，并由胞浆向质膜转位。同时细胞内DAG水平下降。转染PEMT2对其它PKC亚型的表达及细胞内转位无显著影响。结论 转染PEMT2对不同亚型PKC表达及细胞内转位的影响可能与其抑制细胞增殖、诱导凋亡的机制有关。     

Increased particulate partitioning of PKC epsilon reverses susceptibility of phospholamban knockout hearts to ischemic injury

Cytosolic Ca(2+) overload is a critical mediator of myocardial damage following cardiac ischemia-reperfusion. It has therefore been proposed that normalization of sarcoplasmic reticulum Ca(2+) cycling through inhibition or ablation of the Ca(2+) ATP-ase inhibitor phospholamban (PLN), which shows promise as a treatment for heart failure, could be beneficial in ischemic heart disease. However, a recent study has shown that globally ischemic PLN-deficient hearts exhibit increased ischemic injury, with impaired contractile, ATP, and phosphocreatine recoveries, compared to wild-type hearts. Since protein kinase C (PKC) family members are widely recognized as mediators of both post-ischemic injury and ischemic preconditioning, we assessed PKC levels in PLN-deficient hearts. Compared to genetically normal hearts, PLN-deficient hearts exhibited diminished particulate partitioning of PKC, a known cardioprotective PKC isoform, without alterations in the levels of membrane-associated PKC delta nor PKC alpha. To determine if decreased particulate partitioning of cardioprotective PKC epsilon was a cause of increased ischemic injury in PLN-deficient hearts, PLN-deficient mice were mated with mice expressing a myocardial-specific PKC epsilon translocation activator peptide, pseudo-epsilon receptor for activated kinase C (psi epsilon RACK). In psi epsilon RACK/PLN knockout (KO) hearts, PKC epsilon translocation to membranous cellular structures was augmented and this was associated with a significant acceleration of post-ischemic contraction and relaxation rates, as well as reduction of creatine phosphokinase release, compared to PLN-deficient hearts. Importantly, post-ischemic functional recovery reached pre-ischemic hyperdynamic values in psi epsilon RACK/PLN KO hearts, indicating super-rescue by the combination of PLN ablation and psi epsilon RACK expression. These findings suggest that diminished PKC epsilon particulate partitioning in PLN-deficient hearts is associated with attenuated contractile recovery upon ischemia-reperfusion and that increased translocation of PKC to membranous cellular structures confers full cardioprotection.     

Na+/K+ATPase activity inhibition and isoform-specific translocation of protein kinase C following angiotensin II administration in isolated eel enterocytes

In the eel, angiotensin II (Ang II) has a role at the level of both gill chloride and kidney tubular cells, regulating sodium balance and therefore osmoregulation. The present study extends these findings to another important osmoregulatory organ - the intestine. Enterocytes were obtained from sea-water (SW)-acclimated eels to investigate the role of Ang II on the intestinal Na+/K+ATPase activity, because in SW-acclimated animals the intestine represents an important site of water and NaCl transport from the mucosal to the serosal side. This paper demonstrates that isolated enterocytes stimulated with increasing Ang II concentrations (0.01-100 nM) showed a dose-dependent inhibition of the Na+/K+ATPase activity. The threshold decrease was at 0.01 nM Ang II; it reached a maximum at 10 nM (81.5% inhibition) and did not decrease further with the use of higher hormone doses. These hormonal effects were blocked by a specific competitive antagonist of the AT1 receptor subtype, DuP-753 (100% inhibition at 10 microM), indicating that these effects are mediated by an AT1-like receptor. Isolated enterocytes stimulated with 10 nM Ang II showed a transient increase in intracellular calcium ([Ca2+]i), followed by a lower sustained phase. Removal of extracellular Ca2+ did not reduce the initial transient response and completely abolished the plateau phase. The inhibition of the Na+/K+ATPase activity was dependent on protein kinase C (PKC) activation since PKC antagonists (calphostin C and staurosporine) abolished the inhibitory effect of Ang II, and the PKC activator phorbol 12-myristate 13-acetate reduced transporter activity. Western blot analysis with antibodies to PKC alpha, beta I, beta II, gamma, delta, epsilon, iota, eta and zeta isoforms showed that eel enterocytes expressed the conventional isoforms (alpha and beta I), the novel isoforms (delta and eta) and the atypical isoforms (zeta and iota). Ang II stimulated the translocation from the cytosol to the plasma membrane of PKC alpha, PKC delta and PKC eta isoforms. In conclusion, our results suggest that Ang II modulates intestinal Na+/K+ATPase in SW-acclimated eels via calcium mobilization and PKC activation.     

Inhibition of acetylcholine induced intestinal motility by interleukin 1 beta in the rat.

BACKGROUND/AIMS: The fact that raised interleukin 1 beta (IL 1 beta) concentrations have been found in the colonic mucosa of rats with experimentally induced colitis and of patients with inflammatory bowel disease indicates that this cytokine may participate in the disturbed intestinal motility seen during inflammatory bowel disease. This study investigated whether IL 1 beta could change the contractility of (a) a longitudinal muscle-myenteric plexus preparation from rat jejunum, ileum, and colon and (b) isolated jejunal smooth muscle cells. METHODS: Isometric mechanical activity of intestinal segments was recorded using a force transducer. Moreover, smooth muscle cell length was measured by image analysis. RESULTS: Although IL 1 beta did not affect jejunal, ileal, and colonic basal contractility, it significantly reduced contractile response to acetylcholine (ACh). This significant inhibition was seen only after 90 or 150 minutes of incubation with IL 1 beta. Pretreatment with cycloheximide blocked IL 1 beta induced inhibition of ACh stimulated jejunal contraction, suggesting that a newly synthesised protein was involved in the effect. NW-nitro-L-arginine (a nitric oxide synthase inhibitor) did not prevent the inhibition induced by IL 1 beta. Blocking neural transmission with tetrodotoxin abolished the IL 1 beta effect on jejunal contractile activity, whereas IL 1 beta had no effect on isolated and dispersed smooth muscle cells. CONCLUSIONS: IL 1 beta inhibits ACh induced intestinal contraction and this inhibitory effect involves protein synthesis but is independent of nitric oxide synthesis. This effect does not involve a myogenic mechanism but is mediated through the myenteric plexus.     

Lysophosphatidic acid stimulates protein kinase C isoforms alpha, beta, epsilon, and zeta in a pertussis toxin sensitive pathway in vascular smooth muscle cells.

The natural phospholipid lysophosphatidic acid (LPA) has been characterized as an important vascular smooth muscle cell (VSMC) mitogen whose effects are mainly mediated by pertussis toxin (PTX)-sensitive guanosine triphosphate (GTP)-binding protein (Gi-protein). Protein kinase C (PKC) isoforms play an important role in intracellular signaling cascades and in growth of VSMC. In the present study we investigated the effect of LPA on activation of PKC isoforms alpha, beta, epsilon, and zeta in VSMC by Western blot of cytosolic and membrane fractions. Furthermore, we examined the role of PKC activation on LPA-induced growth of VSMC using PKC inhibitor 19-27. Stimulation of VSMC by 5 microg/mL LPA for 10 min increased the amount of PKC alpha, beta, epsilon, and zeta in the particulate fraction by 689%, 285%, 424%, and 510%, respectively, and returned to control level after 30 min. Correspondingly, the amount of PKC alpha, beta, epsilon, and zeta in the cytosolic fraction decreased by 32%, 94%, 44%, and 95%, respectively, compared to control. Furthermore, we could show that LPA-induced activation of PKC alpha, beta, epsilon, and zeta isoforms was PTX sensitive. Incubation of VSMC with nonspecific PKC inhibitor 19-27 (10 micromol/L) for 24 h resulted in a 30% inhibition of LPA-induced DNA synthesis as measured by [3H]thymidine incorporation. In conclusion, in VSMC LPA stimulated translocation of PKC isoforms alpha, beta, epsilon, and zeta in a PTX-sensitive manner. Furthermore stimulation of PKC might be critically involved in LPA-induced mitogenesis in VSMC.     

Norepinephrine-induced changes in gene expression of phospholipase C in cardiomyocytes

Previously, we have reported that norepinephrine (NE)-mediated cardiac hypertrophy may occur due to stimulation of alpha1-adrenoceptors and phospholipase C (PLC) activity. Since the signal transduction mechanisms involving PLC isozymes in cardiomyocytes are not well established, the present study was conducted to test the hypothesis that stimulation of cardiac PLC activity by NE increases the gene expression for PLC isozymes via a PKC and ERK 1/2-dependent pathway. For this purpose, mRNA levels for PLC beta1, beta3, gamma1, and delta1 isozymes were determined in isolated adult rat cardiomyocytes upon incubation in the absence and presence of NE. The NE-induced increases in PLC isozyme mRNA levels were not only attenuated by prazosin, an inhibitor of alpha1-adrenergic receptor, but also by U73122, an inhibitor of PLC activity. Alterations in NE-induced PLC gene expression by both prazosin and U73122 were associated with inhibition of PLC activity. The inhibition of NE-stimulated PLC gene expression by bisindolylmaleimide, a PKC inhibitor, and PD98059, an ERK1/2 inhibitor, indicated that PKC-MAPK signaling may be involved in this signal transduction pathway. The observed NE-induced changes in gene expression in the presence of different inhibitors were associated with corresponding changes in the protein content. Furthermore, significant increases in mRNA levels and protein contents for all PLC isozymes were found in cardiomyocytes treated with phorbol 12-myristate 13-acetate, a PKC activator. These data indicate that PLC isozymes may regulate their own gene expression through a PKC and ERK 1/2-dependent pathway in a cycle of events associated with the cardiomyocyte hypertrophic response.     

Right ventricular hypertrophy and apoptosis after pulmonary artery banding: regulation of PKC isozymes

OBJECTIVE: Pressure overload induced by pulmonary artery banding (PAB) leads to right ventricular (RV) hypertrophy and cardiomyocyte apoptosis. The present study was performed to investigate whether protein kinase C isozymes (PKC-alpha, PKC-betaI, PKC-betaII, PKC-delta and PFC- epsilon ), calcineurin and the renin-angiotensin system (RAS) contribute to PAB-induced cardiac remodeling. METHODS AND RESULTS: PAB in male Wistar rats for 3 weeks results in enhanced PKC activity (as determined by ELISA assay) in the cytosol and membrane fraction of the hypertrophied RV, which was accompanied by increased expression (as determined by Western blot analysis) of cytosolic PKC-delta (+72%), PKC-alpha (+49%), and PKC-betaI (+39%), but not PKC-betaII and PKC- epsilon. This differential regulation of cardiac PKC isozymes was limited to the strained ventricle and was not altered in response to chronic angiotensin-converting enzyme inhibition with ramiprilate. Furthermore, no significant changes in the expression of calcineurin alpha and beta subunits were observed in RV pressure overload compared to controls. PAB-induced cardiac apoptosis was determined using Western blot analysis by a significantly increased expression of Bax protein and caspase-3 in the hypertrophied RV, which was diminished to almost control levels by chronic ramiprilate treatment. The myocardial expression of Bcl-2 was not significantly altered in the experimental groups. CONCLUSION: We have shown for the first time that PAB-induced RV hypertrophy is associated with a differential regulation of cardiac PKC isozymes independent of the RAS and further provide evidence for a pivotal role of the RAS in the development of PAB-induced cardiac apoptosis.