Phorbol myristate acetate and ATP-sensitive potassium channels in insulin-secreting cells

ERK3 associates with MAP2 and is involved in glucose-induced insulin secretion

The adaptation of pancreatic islets to pregnancy includes increased beta cell proliferation, expansion of islet mass, and increased insulin synthesis and secretion. Most of these adaptations are induced by prolactin (PRL). We have previously described that in vitro PRL treatment increases ERK3 expression in isolated rat pancreatic islets. This study shows that ERK3 is also upregulated during pregnancy. Islets from pregnant rats treated with antisense oligonucleotide targeted to the PRL receptor displayed a significant reduction in ERK3 expression. Immunohistochemical double-staining showed that ERK3 expression is restricted to pancreatic beta cells. Transfection with antisense oligonucleotide targeted to ERK3 abolished the insulin secretion stimulated by glucose in rat islets and by PMA in RINm5F cells. Therefore, we examined the participation of ERK3 in the activation of a cellular target involved in secretory events, the microtubule associated protein MAP2. PMA induced ERK3 phosphorylation that was companied by an increase in ERK3/MAP2 association and MAP2 phosphorylation. These observations provide evidence that ERK3 is involved in the regulation of stimulus-secretion coupling in pancreatic beta cells.

Liver receptor homologue-1 mediates species- and cell line-specific bile acid-dependent negative feedback regulation of the apical sodium-dependent bile acid transporter

Intestinal reclamation of bile salts is mediated in large part by the apical sodium-dependent bile acid transporter (ASBT). The bile acid responsiveness of ASBT is controversial. Bile acid feeding in mice results in decreased expression of ASBT protein and mRNA. Mouse but not rat ASBT promoter activity was repressed in Caco-2, but not IEC-6, cells by chenodeoxycholic acid. A potential liver receptor homologue-1 (LRH-1) cis-acting element was identified in the bile acid-responsive region of the mouse but not rat promoter. The mouse, but not rat, promoter was activated by LRH-1, and this correlated with nuclear protein binding to the mouse but not rat LRH-1 element. The short heterodimer partner diminished the activity of the mouse promoter and could partially offset its activation by LRH-1. Interconversion of the potential LRH-1 cis-elements between the mouse and rat ASBT promoters was associated with an interconversion of LRH-1 and bile acid responsiveness. LRH-1 protein was found in Caco-2 cells and mouse ileum, but not IEC-6 cells or rat ileum. Bile acid response was mediated by the farnesoid X receptor, as shown by the fact that overexpression of a dominant-negative farnesoid X-receptor eliminated the bile acid mediated down-regulation of ASBT. In addition, ASBT expression in farnesoid X receptor null mice was unresponsive to bile acid feeding. In summary cell line- and species-specific negative feedback regulation of ASBT by bile acids is mediated by farnesoid X receptor via small heterodimer partner-dependent repression of LRH-1 activation of the ASBT promoter.

ATP-sensitive potassium channel traffic regulation by adenosine and protein kinase C

ATP-sensitive potassium (K(ATP)) channels activate under metabolic stress to protect neurons and cardiac myocytes. However, excessive channel activation may cause arrhythmia in the heart and silence neurons in the brain. Here, we report that PKC-mediated downregulation of K(ATP) channel number, via dynamin-dependent channel internalization, can act as a brake mechanism to control K(ATP) activation. A dileucine motif in the pore-lining Kir6.2 subunit of K(ATP), but not the site of PKC phosphorylation for channel activation, is essential for PKC downregulation. Whereas K(ATP) activation results in a rapid shortening of the action potential duration (APD) in metabolically inhibited ventricular myocytes, adenosine receptor stimulation and consequent PKC-mediated K(ATP) channel internalization can act as a brake to lessen this APD shortening. Likewise, in hippocampal CA1 neurons under metabolic stress, PKC-mediated, dynamin-dependent K(ATP) channel internalization can also act as a brake to dampen the rapid decline of excitability due to K(ATP) activation.

The role of AP-1 in the transcriptional regulation of the rat apical sodium-dependent bile acid transporter

Ileal reclamation of bile salts, a critical determinant of their enterohepatic circulation, is mediated primarily by the apical sodium-dependent bile acid transporter (ASBT=SLC10A2). We have defined mechanisms involved in the transcriptional regulation of ASBT. The ASBT gene extends over 17 kilobases and contains five introns. Primer extension analysis localized two transcription initiation sites 323 and 255 base pairs upstream of the initiator methionine. Strong promoter activity is imparted by both a 2.7- and 0.2-kilobase 5'-flanking region of ASBT. The promoter activity is cell line specific (Caco-2, not Hep-G2, HeLa-S3, or Madin-Darby canine kidney cells). Four distinct specific binding proteins were identified by gel shift and cross-linking studies using Caco-2 or rat ileal nuclear extracts. Two AP-1 consensus sites were identified in the proximal promoter. DNA binding and promoter activity could be abrogated by mutation of the proximal AP-1 site. Supershift analysis revealed binding of c-Jun and c-Fos to this AP-1 element. Co-expression of c-Jun enhanced promoter activity in Caco-2 cells and activated the promoter in Madin-Darby canine kidney cells. Region and developmental stage-specific expression of ASBT in the rat intestine correlated with the presence of one of these DNA-protein complexes and both c-Fos and c-Jun proteins. A specific AP-1 element regulates transcription of the rat ASBT gene.

Phorbol ester impairs electrical excitation of rat pancreatic beta-cells through PKC-independent activation of KATP channels

BACKGROUND

Phorbol 12-myristate 13-acetate (PMA) is often used as an activating phorbol ester of protein kinase C (PKC) to investigate the roles of the kinase in cellular functions. Accumulating lines of evidence indicate that in addition to activating PKC, PMA also produces some regulatory effects in a PKC-independent manner. In this study, we investigated the non-PKC effects of PMA on electrical excitability of rat pancreatic beta-cells by using patch-clamp techniques.

RESULTS

In current-clamp recording, PMA (80 nM) reversibly inhibited 15 mM glucose-induced action potential spikes superimposed on a slow membrane depolarization and this inhibition can not be prevented by pre-treatment of the cell with a specific PKC inhibitor, bisindolylmaleimide (BIM, 1 microM). In the presence of a subthreshold concentration (5.5 mM) of glucose, PMA hyperpolarized beta-cells in a concentration-dependent manner (0.8-240 nM), even in the presence of BIM. Based on cell-attached single channel recordings, PMA increased ATP-sensitive K+ channel (KATP) activity. Based on inside-out patch-clamp recordings, PMA had little effect on KATP activity if no ATP was in the bath, while PMA restored KATP activity that was suppressed by 10 microM ATP in the bath. In voltage-clamp recording, PMA enhanced tolbutamide-sensitive membrane currents elicited by repetitive ramp pulses from -90 to -50 mV in a concentration-dependent manner, and this potentiation could not be prevented by pre-treatment of cell with BIM. 4alpha-phorbol 12,13-didecanoate (4alpha-PDD), a non-PKC-activating phorbol ester, mimicked the effect of PMA on both current-clamp and voltage-clamp recording configurations. With either 5.5 or 16.6 mM glucose in the extracellular solution, PMA (80 nM) increased insulin secretion from rat islets. However, in islets pretreated with BIM (1 microM), PMA did not increase, but rather reduced insulin secretion.

CONCLUSION

In rat pancreatic beta-cells, PMA modulates insulin secretion through a mixed mechanism: increases insulin secretion by activation of PKC, and meanwhile decrease insulin secretion by impairing beta-cell excitability in a PKC-independent manner. The enhancement of KATP activity by reducing sensitivity of KATP to ATP seems to underlie the PMA-induced impairment of beta-cells electrical excitation in response to glucose stimulation.

Intestinal bile acid transport: biology, physiology, and pathophysiology

Intestinal reabsorption of bile salts plays a crucial role in human health and disease. This process is primarily localized to the terminal ileum and is mediated by a 48-kd sodium-dependent bile acid cotransporter (SLC10A2 = ASBT). ASBT is also expressed in renal tubule cells, cholangiocytes, and the gallbladder. Exon skipping leads to a truncated version of ASBT, which sorts to the basolateral surface and mediates efflux of bile salts. Inherited mutation of ASBT leads to congenital diarrhea secondary to bile acid malabsorption. Partial inhibition of ASBT may be useful in the treatment of hypercholesterolemia and intrahepatic cholestasis. During normal development in the rat ileum, ASBT undergoes a biphasic pattern of expression with a prenatal onset, postnatal repression, and reinduction at the time of weaning. The bile acid responsiveness of the ASBT gene is not clear and may be dependent on both the experimental model used and the species being investigated. Future studies of the transcriptional and posttranscriptional regulation of the ASBT gene and analysis of ASBT knockout mice will provide further insight into the biology, physiology, and pathophysiology of intestinal bile acid transport.

Protein kinase C-dependent and -independent inhibition of Ca(2+) influx by phorbol ester in rat pancreatic beta-cells

Phorbol esters were used to investigate the action of protein kinase C (PKC) on insulin secretion from pancreatic beta-cells. Application of 80 nM phorbol 12-myristate 13-acetate (PMA), a PKC-activating phorbol ester, had little effect on glucose (15 mM)-induced insulin secretion from intact rat islets. In islets treated with bisindolylmaleimide (BIM), a PKC inhibitor, PMA significantly reduced the glucose-induced insulin secretion. PMA decreased the level of intracellular Ca(2+) concentration ([Ca(2+)](i)) elevated by the glucose stimulation when tested in isolated rat beta-cells. This inhibitory effect of PMA was not prevented by BIM. PMA inhibited glucose-induced action potentials, and this effect was not prevented by BIM. Further, 4alpha-phorbol 12,13-didecanoate (4alpha-PDD), a non-PKC-activating phorbol ester, produced an effect similar to PMA. In the presence of nifedipine, the glucose stimulation produced only depolarization, and PMA applied on top of glucose repolarized the cell. When applied at the resting state, PMA hyperpolarized beta-cells with an increase in the membrane conductance. Recorded under the voltage-clamp condition, PMA reduced the magnitude of Ca(2+) currents through L-type Ca(2+) channels. BIM prevented the PMA inhibition of the Ca(2+) currents. These results suggest that activation of PKC maintains glucose-stimulated insulin secretion in pancreatic beta-cells, defeating its own inhibition of the Ca(2+) influx through L-type Ca(2+) channels. PKC-independent inhibition of electrical excitability by phorbol esters was also demonstrated.

Molecular basis of protein kinase C-induced activation of ATP-sensitive potassium channels

Potassium channels that are inhibited by internal ATP (K(ATP) channels) provide a critical link between metabolism and cellular excitability. Protein kinase C (PKC) acts on K(ATP) channels to regulate diverse cellular processes, including cardioprotection by ischemic preconditioning and pancreatic insulin secretion. PKC action decreases the Hill coefficient of ATP binding to cardiac K(ATP) channels, thereby increasing their open probability at physiological ATP concentrations. We show that PKC similarly regulates recombinant channels from both the pancreas and heart. Surprisingly, PKC acts via phosphorylation of a specific, conserved threonine residue (T180) in the pore-forming subunit (Kir6.2). Additional PKC consensus sites exist on both Kir and the larger sulfonylurea receptor (SUR) subunits. Nonetheless, T180 controls changes in open probability induced by direct PKC action either in the absence of, or in complex with, the accessory SUR1 (pancreatic) or SUR2A (cardiac) subunits. The high degree of conservation of this site among different K(ATP) channel isoforms suggests that this pathway may have wide significance for the physiological regulation of K(ATP) channels in various tissues and organelles.

Role of membrane conductances and protein synthesis in subjective day phase advances of the hamster circadian clock by neuropeptide Y

Neurons of the mammalian circadian pacemaker in the hypothalamic suprachiasmatic nuclei exhibit a rhythm in firing rate that can be reset by neuropeptide Y. We recorded the effects of neuropeptide Y on Na+ and K+ conductances of hamster suprachiasmatic nuclei neurons using whole-cell, perforated-patch and cell-attached patch-clamp recordings, both in dissociated and brain slice preparations. While neuropeptide Y had no effect on voltage-gated Na+ currents, neuropeptide Y activated a leak K+ current. Neuropeptide Y phase advances in the suprachiasmatic nuclei brain slice preparation were blocked by a number of K+ channel blockers (tetraethylammonium chloride, dendrotoxin-I, glybenclamide). However, a K+ ionophore, valinomycin, did not shift the rhythm. The inhibition by tetraethylammonium chloride did not persist in the presence of glutamatergic receptor blockers. We have previously shown that glutamate can oppose neuropeptide Y phase-shifting actions, suggesting that K+ channel inhibition acts by inducing glutamate release. Protein synthesis inhibitors had no effect on clock phase when applied during the subjective day, and had no influence on neuropeptide Y-induced phase shifts. On the other hand, glutamate's ability to inhibit neuropeptide Y shifts was abolished by protein synthesis inhibition. Thus, while neuropeptide Y phase shifts do not require protein synthesis, glutamate blocks neuropeptide Y shifts via increased gene expression during the subjective day, at a time when it does not reset the clock. These results indicate that neuropeptide Y phase shifts via a mechanism that does not involve changes in membrane conductance or protein synthesis.

Adenosine-induced activation of ATP-sensitive K+ channels in excised membrane patches is mediated by PKC

Both protein kinase C (PKC) and adenosine receptor activation have been shown to enhance ATP-sensitive K+ (KATP) channels. The present studies were designed to determine whether PKC mediates adenosine effects on the KATP channel. The dependence of KATP channel activity (nPo) on intracellular ATP concentration ([ATP]i) was determined in excised rabbit ventricular membrane patches. External adenosine (100 microM in the pipette solution) significantly increased KATP nPo at all [ATP]i between 5 and 50 microM by decreasing channel sensitivity to [ATP]i (dissociation constant increased from 7.4 +/- 0.8 to 22.2 +/- 3.1 microM, P < 0.001), an effect blocked by the adenosine receptor antagonist 8-phenyltheophylline (10 microM). When the highly selective PKC blocker bisindolylmaleimide (BIM) was included in the internal (bath) solution, the KATP-stimulating action of adenosine was prevented. The addition of BIM to the superfusate rapidly inhibited KATP channels activated by adenosine. Endogenous PKC activation by phorbol 12,13-didecanoate (PDD), but not administration of the inactive congener 4alpha-PDD, enhanced KATP activity. Internal guanosine 5'-O-(2-thiodiphosphate) prevented KATP activation by adenosine, an effect which could be overridden by exposure to PDD. We conclude that PKC mediates adenosine activation of KATP channels in excised membrane patches in a membrane-delimited fashion.

Neither intestinal sequestration of bile acids nor common bile duct ligation modulate the expression and function of the rat ileal bile acid transporter

The regulatory responses of bile acid (BA) transport in the terminal ileum to perturbations in BA homeostasis are complex, and conflicting results have been reported by different investigators. These studies were designed to examine the response of this system to a reduction in ileal bile salt concentrations at both a functional and molecular level. Common bile duct ligation (BDL) or feeding of a novel bile acid-binding compound, GT31-104HB, for 7 days were used to reduce ileal apical membrane bile salt flux. Apical bile acid transport function was assessed by examining sodium-dependent uptake of [3H]-taurocholate (TC) into brush border membrane vesicles (BBMV). Expression of the apical sodium-dependent bile acid transporter (ASBT) and the ileal lipid-binding protein (ILBP) were assessed by Western blotting with quantitation using [125I]-labeled secondary antibody and a phosphorimager. Neither common BDL nor intestinal sequestration of BA led to a change in ileal bile acid transport function or the expression of the ASBT or the ILBP. These results indicate that a reduction in presentation of bile salts to the apical surface of the terminal ileum does not modulate the expression of the genes involved in their transport.

New insights into bile acid transport

The enterohepatic circulation of bile acids is maintained by a series of membrane transport proteins. Recent studies of the cloned sodium bile acid cotransporters have provided new insights into their tissue expression, regulation, and their relationship to cholesterol homeostasis and human diseases such as primary bile acid malabsorption.

Ileal absorption of bile acids in patients with chronic cholestasis: SeHCAT test results and effect of ursodeoxycholic acid (UDCA)

The effect of cholestasis on ileal bile acid absorption is controversial in animal models (up- or down-regulation) and unknown in humans. We therefore studied values of the selena homotaurocholic acid (SeHCAT) test before and after long-term administration (>3 months, 13-15 mg/kg/day) of ursodeoxycholic acid (UDCA) in 27 patients with chronic cholestatic liver diseases (24 women, 3 men; mean age, 50 years; 24 primary biliary cirrhosis, 2 secondary biliary cirrhosis, 2 others). The control group consisted of 14 healthy volunteers. Seven-day SeHCAT percentage retention was identical in the 12 untreated cholestatic patients (serum bilirubin, 75+/-42 micromol/L, alkaline phosphatase, 4.2+/-1.0 N; mean+/-SEM) and in the control group (43.6+/-2.9 and 43.8+/-4.2%, respectively). In the 22 patients treated by UDCA for 38+/-8 months, SeHCAT percentage retention was 20.3+/-3.0%. In the seven patients with the SeHCAT test done before and after UDCA treatment (16+/-5 months), SeHCAT percentage retention decreased significantly under UDCA therapy (42.0+/-4.4 vs 19.4+/-4.1%; P < 0.02). We conclude that, in patients with chronic cholestasis (1) SeHCAT percentage retention is not altered-taken together with the known defect of biliary excretion, this lack of increase in SeHCAT percentage retention argues against up-regulation of bile acid ileal transport; and (2) UDCA treatment induces a decrease in the SeHCAT percentage retention-this effect may be related primarily to a decreased bile acid ileal absorption.

Protein kinase C-induced changes in the stoichiometry of ATP binding activate cardiac ATP-sensitive K+ channels. A possible mechanistic link to ischemic preconditioning

Activation of both ATP-sensitive K+ (KATP) channels and the enzyme protein kinase C (PKC) has been associated with the cardioprotective response of ischemic preconditioning. We recently showed that at low cytoplasmic ATP (< or = 50 mumol/L), PKC inhibits KATP channel activity. This finding is surprising, as both KATP channels and PKC are activated during preconditioning. However, PKC also altered ATP binding to the channel, changing the Hill coefficient from approximately 2 to approximately 1. This apparent change in stoichiometry would lead to a PKC-induced activation of KATP channels at more physiological (millimolar) levels of ATP. The aim of the present study was to determine whether PKC activates cardiac KATP channels at millimolar levels of ATP. The effects of PKC on single KATP channels were studied at millimolar internal ATP levels using excised inside-out membrane patches from rabbit ventricular myocytes. Application of purified constitutively active PKC (20 nmol/L) to the intracellular surface of the patches produced an approximately threefold increase in the channel open probability. The specific PKC inhibitor peptide PKC(19-31) prevented this increase. Heat-inactivated PKC had no effect on KATP channel properties. KATP channel activity spontaneously returned to control levels after washout of PKC. This spontaneous reversal did not occur in the presence of 5 nmol/L okadaic acid, suggesting that the reversal of PKC's action is dependent on activity of a membrane-associated type 2A protein phosphatase (PP2A). In the presence of exogenous PP2A (7.5 nmol/L), PKC had no effect. We conclude that the PKC-induced increase in KATP channel activity at millimolar ATP results from a crossing of the ATP concentration-response curves for inhibition of the phosphorylated and nonphosphorylated forms of the channel. This identifies a mechanism by which PKC activates KATP channels at near physiological levels of ATP and thus could link these two components in a signaling pathway that induces ischemic preconditioning.

ATP-sensitive K+ channels in the kidney

ATP-sensitive K+ channels (KATP channels) form a link between the metabolic state of the cell and the permeability of the cell membrane for K+ which, in turn, is a major determinant of cell membrane potential. KATP channels are found in many different cell types. Their regulation by ATP and other nucleotides and their modulation by other cellular factors such as pH and kinase activity varies widely and is fine-tuned for the function that these channels have to fulfill. In most excitable tissues they are closed and open when cell metabolism is impaired; thereby the cell is clamped in the resting state which saves ATP and helps to preserve the structural integrity of the cell. There are, however, notable exceptions from this rule; in pancreatic beta-cells, certain neurons and some vascular beds, these channels are open during the normal functioning of the cell. In the renal tubular system, KATP channels are found in the proximal tubule, the thick ascending limb of Henle's loop and the cortical collecting duct. Under physiological conditions, these channels have a high open probability and play an important role in the reabsorption of electrolytes and solutes as well as in K+ homeostasis. The physiological role of their nucleotide sensitivity is not entirely clear; one consequence is the coupling of channel activity to the activity of the Na-K-ATPase (pump-leak coupling), resulting in coordinated vectorial transport. In ischemia, however, the reduced ATP/ADP ratio would increase the open probability of the KATP channels independently from pump activity; this is particularly dangerous in the proximal tubule, where 60 to 70% of the glomerular ultrafiltrate is reabsorbed. The pharmacology of KATP channels is well developed including the sulphonylureas as standard blockers and the structurally heterogeneous family of channel openers. Blockers and openers, exemplified by glibenclamide and levcromakalim, show a wide spectrum of affinities towards the different types of KATP channels. Recent cloning efforts have solved the mystery about the structure of the channel: the KATP channels in the pancreatic beta-cell and in the principal cell of the renal cortical collecting duct are heteromultimers, composed of an inwardly rectifying K+ channel and sulphonylurea binding subunit(s) with unknown stoichiometry. The proteins making up the KATP channel in these two cell types are different (though homologous), explaining the physiological and pharmacological differences between these channel subtypes.

Ionic control of beta cell function in nesidioblastosis. A possible therapeutic role for calcium channel blockade

A preterm female infant presented with intractable hypoglycaemia within 10 minutes of delivery. Normoglycaemia could be maintained only by the intravenous infusion of glucose at a rate of 20-22 mg/kg/min. Persistent hyperinsulinaemic hypoglycaemia of infancy was diagnosed from an inappropriately raised plasma insulin concentration (33 mU/l) at the time of hypoglycaemia (blood glucose < 0.5 mmol/l). Medical treatment with glucagon, somatostatin, and diazoxide led to only a modest reduction in the intravenous glucose requirement; a 95% pancreatectomy was performed and histological 'nesidioblastosis' confirmed. In vitro electrophysiological studies using patch clamp techniques on isolated pancreatic beta cells characterised the ionic basis for insulin secretion in nesidioblastosis. The beta cells were depolarised in low ambient glucose concentrations with persistently firing action potentials; these were blocked reversibly by the calcium channel blocking agent verapamil. Persistent postoperative hyperinsulinaemic hypoglycaemia was treated with oral nifedipine. This increased median blood glucose concentrations from 3.5 to 4.8 mmol/l and increased in duration the child's tolerance to fasting from 3 to 10.5 hours. These data allude to an abnormality in the ionic control of insulin release in nesidioblastosis and offer a new logical approach to treatment which requires further evaluation.

Synergistic modulation of ATP-sensitive K+ currents by protein kinase C and adenosine. Implications for ischemic preconditioning

Ischemic preconditioning has been shown to involve the activation of adenosine receptors, protein kinase C (PKC), and ATP-sensitive K+ (K ATP) channels. We investigated the effects of PKC activation and adenosine on K(ATP) current (I KATP) and action potentials in isolated rabbit ventricular myocytes. Responses to pinacidil (100 to 400 micromol/L), an opener of K(ATP) channels, were markedly increased by preexposure to the PKC activator phorbol 12-myristate 13-acetate (PMA, 100 nmol/L). I(KATP) measured at 0 mV was increased by PMA pretreatment from 0.55 +/- 0.32 to 3.25 +/- 0.47 nA (n=6, P < .01). We next determined whether PKC activation abbreviates the time required to turn on I(KATP) developed after an average of 15.1 +/- 2.4 minutes (n=8). Ten-minute pretreatment with PMA alone (PMA+MI) did not significantly alter this latency (11.9 +/- 2.0 minutes, n=8). Since adenosine receptor activation has been shown to play an important role in the preconditioning response, two groups of myocytes were studied with adenosine (10 micromol/L) included during MI. Without PMA, adenosine alone (MI+Ado) did not affect the latency to develop I(KATP) (12.3 +/- 1.5 minutes, n=8). However, if cells were pretreated with PMA and then subjected to MI in the presence of adenosine (PMA+MI+Ado), the latency was greatly shortened to 5.5 +/- 1.6 minutes (n=8;P < .02 versus MI, PMA+MI, and MI+Ado groups). This effect could not be reproduced by an inactive phorbol but was completely abolished by the adenosine receptor antagonist 8-(p-sulfophenyl)-theophylline. The opening of K(ATP) channels may be cardioprotective because of the abbreviation of action potential duration (APD) during ischemia. Therefore, we tested whether PKC activation could modify the time course of APD shortening during MI. Consistent with the ionic current measurements, PMA pretreatment significantly accelerated APD shortening, but only when adenosine (10 micromol/L) was included during MI. The effects were not attributable to accelerated ATP consumption: PMA pretreatment did not alter the time required to induce rigor during MI, whether or not adenosine was included. Our results indicate that PKC activation increases the I(KATP) Induced by pinacidil or by MI. The latter effect requires concomitant adenosine receptor activation. The synergistic modulation of I(KATP) by PKC and adenosine provides an explicit basis for current paradigms of ischemic preconditioning.

Protein kinase C activates ATP-sensitive K+ current in human and rabbit ventricular myocytes

Mediators involved in ischemia preconditioning such as adenosine and norepinephrine, can activate protein kinase C (PKC), and a variety of observations suggest that both PKC and ATP-sensitive K+ current (I (KATP) play essential roles in ischemic preconditioning. PKC is therefore a candidate to link receptor binding to I(KATP) activation, but it has not been shown whether and how PKC can activate I(KATP) in the heart. The present study was designed to determine whether PKC can activate I(KATP) in rabbit and human ventricular myocytes. Under conditions designed to minimize Na+ and Ca2+ currents, dialysis of rabbit ventricular myocytes with pipette solutions containing reduced [ATP] elicited I(KATP)++, with a 50% effective concentration (EC50)of 260 micromol/L. In cells that failed to show I (KATP) under control conditions, superfusion with 1 micromol/L phorbol 12,13-didecanoate (PDD) elicited I(KATP) in a fashion that depended on pipette [ATP], with an [ATP] EC 50 of 601 micromol/L. PDD-induced I(KATP) activation was concentration dependent, with an EC 50 of 7.1 nmol/L. The highly selective PKC inhibitor bisindolylmaleimide totally prevented I(KATP) activation by PDD, and in blinded experiments, 1 micromol/L PDD elicited I(KATP) in eight of nine cells, whereas its non-PKC-stimulating analogue 4 alpha-PDD failed to elicit I(KATP) in any of the five cells tested (P = .003). Similar experiments were conducted in human ventricular myocytes and showed that 0.1 micromol/L PDD elicited I( KATP) at pipette [ATP] of 100 and 400 micromol/L (five of five cells at each concentration) but not at 1 mmol/L [ATP] (none of five cells). We conclude that PKC activates I(KATP) in rabbit and human ventricular myocytes by reducing channel sensitivity to intracellular ATP. This finding has potentially important implications for understanding the mechanisms of ischemic preconditioning.

Carbachol, substance P, and phorbol ester promote the tyrosine phosphorylation of protein kinase C delta in salivary gland epithelial cells

The initiation of saliva formation by parotid acinar cells, which comprise the majority of cells in this salivary gland, is initiated by the release of neurotransmitters (acetylcholine, substance P) from parasympathetic nerves. In response to substance P and the muscarinic agonist carbachol, two ligands that activate phospholipase C-linked receptors, which stimulate fluid secretion, PKC delta was phosphorylated on tyrosine residues. The maximal agonist-dependent tyrosine phosphorylation occurred within seconds of the addition of either agonist and then returned rapidly to a smaller increased level. Phorbol ester also caused a rapid increase in tyrosine phosphorylation, which reached a maximal level 5 min after the addition of phorbol 12-myristate 13-acetate. The increase in tyrosine phosphorylation of PKC delta was blocked by tyrosine kinase inhibitors genistein and staurosporine. Ionophore-mediated elevation of [Ca2+]i or activation of the beta-adrenergic receptor, epidermal growth factor receptor, or insulin receptor did not promote the tyrosine phosphorylation of PKC delta. These results indicate that tyrosine phosphorylation plays a role in early signal transduction events promoted by the activation of muscarinic and substance P receptors and suggests that the tyrosine phosphorylation of PKC delta has a role in the activation of fluid secretion by neurotransmitters binding to phospholipase C-linked receptors.