MgATP activates the β cell KATP channel by interaction with its SUR1 subunit

ATP-sensitive potassium (KATP) channels in the pancreatic β cell membrane mediate insulin release in response to elevation of plasma glucose levels. They are open at rest but close in response to glucose metabolism, producing a depolarization that stimulates Ca2+ influx and exocytosis. Metabolic regulation of KATP channel activity currently is believed to be mediated by changes in the intracellular concentrations of ATP and MgADP, which inhibit and activate the channel, respectively. The β cell KATP channel is a complex of four Kir6.2 pore-forming subunits and four SUR1 regulatory subunits: Kir6.2 mediates channel inhibition by ATP, whereas the potentiatory action of MgADP involves the nucleotide-binding domains (NBDs) of SUR1. We show here that MgATP (like MgADP) is able to stimulate KATP channel activity, but that this effect normally is masked by the potent inhibitory effect of the nucleotide. Mg2+ caused an apparent reduction in the inhibitory action of ATP on wild-type KATP channels, and MgATP actually activated KATP channels containing a mutation in the Kir6.2 subunit that impairs nucleotide inhibition (R50G). Both of these effects were abolished when mutations were made in the NBDs of SUR1 that are predicted to abolish MgATP binding and/or hydrolysis (D853N, D1505N, K719A, or K1384M). These results suggest that, like MgADP, MgATP stimulates KATP channel activity by interaction with the NBDs of SUR1. Further support for this idea is that the ATP sensitivity of a truncated form of Kir6.2, which shows functional expression in the absence of SUR1, is unaffected by Mg2+.

Phentolamine block of KATP channels is mediated by Kir6.2

The ATP-sensitive K+-channel (KATP channel) plays a key role in insulin secretion from pancreatic β cells. It is closed both by glucose metabolism and the sulfonylurea drugs that are used in the treatment of noninsulin-dependent diabetes mellitus, thereby initiating a membrane depolarization that activates voltage-dependent Ca2+ entry and insulin release. The β cell KATP channel is a complex of two proteins: Kir6.2 and SUR1. The former is an ATP-sensitive K+-selective pore, whereas SUR1 is a channel regulator that endows Kir6.2 with sensitivity to sulfonylureas. A number of drugs containing an imidazoline moiety, such as phentolamine, also act as potent stimulators of insulin secretion, but their mechanism of action is unknown. We have used a truncated form of Kir6.2, which expresses independently of SUR1, to show that phentolamine does not inhibit KATP channels by interacting with SUR1. Instead, our results argue that phentolamine may interact directly with Kir6.2 to produce a voltage-independent reduction in channel activity. The single-channel conductance is unaffected. Although the ATP molecule also contains an imidazoline group, the site at which phentolamine blocks is not identical to the ATP-inhibitory site, because phentolamine block of an ATP-insensitive mutant (K185Q) is normal. KATP channels also are found in the heart where they are involved in the response to cardiac ischemia: they also are blocked by phentolamine. Our results suggest that this may be because Kir6.2, which is expressed in the heart, forms the pore of the cardiac KATP channel.

Abnormalities of pancreatic islets by targeted expression of a dominant-negative KATP channel

ATP-sensitive K+ (KATP) channels are known to play important roles in various cellular functions, but the direct consequences of disruption of KATP channel function are largely unknown. We have generated transgenic mice expressing a dominant-negative form of the KATP channel subunit Kir6.2 (Kir6.2G132S, substitution of glycine with serine at position 132) in pancreatic beta cells. Kir6.2G132S transgenic mice develop hypoglycemia with hyperinsulinemia in neonates and hyperglycemia with hypoinsulinemia and decreased beta cell population in adults. KATP channel function is found to be impaired in the beta cells of transgenic mice with hyperglycemia. In addition, both resting membrane potential and basal calcium concentrations are shown to be significantly elevated in the beta cells of transgenic mice. We also found a high frequency of apoptotic beta cells before the appearance of hyperglycemia in the transgenic mice, suggesting that the KATP channel might play a significant role in beta cell survival in addition to its role in the regulation of insulin secretion.

KATP channel inhibition by ATP requires distinct functional domains of the cytoplasmic C terminus of the pore-forming subunit

ATP-sensitive potassium (“KATP”) channels are rapidly inhibited by intracellular ATP. This inhibition plays a crucial role in the coupling of electrical activity to energy metabolism in a variety of cells. The KATP channel is formed from four each of a sulfonylurea receptor (SUR) regulatory subunit and an inwardly rectifying potassium (Kir6.2) pore-forming subunit. We used systematic chimeric and point mutagenesis, combined with patch-clamp recording, to investigate the molecular basis of ATP-dependent inhibition gating of mouse pancreatic β cell KATP channels expressed in Xenopus oocytes. We identified distinct functional domains of the presumed cytoplasmic C-terminal segment of the Kir6.2 subunit that play an important role in this inhibition. Our results suggest that one domain is associated with inhibitory ATP binding and another with gate closure.

Defective insulin secretion and enhanced insulin action in KATP channel-deficient mice

ATP-sensitive K+ (KATP) channels regulate many cellular functions by linking cell metabolism to membrane potential. We have generated KATP channel-deficient mice by genetic disruption of Kir6.2, which forms the K+ ion-selective pore of the channel. The homozygous mice (Kir6.2−/−) lack KATP channel activity. Although the resting membrane potential and basal intracellular calcium concentrations ([Ca2+]i) of pancreatic beta cells in Kir6.2−/− are significantly higher than those in control mice (Kir6.2+/+), neither glucose at high concentrations nor the sulfonylurea tolbutamide elicits a rise in [Ca2+]i, and no significant insulin secretion in response to either glucose or tolbutamide is found in Kir6.2−/−, as assessed by perifusion and batch incubation of pancreatic islets. Despite the defect in glucose-induced insulin secretion, Kir6.2−/− show only mild impairment in glucose tolerance. The glucose-lowering effect of insulin, as assessed by an insulin tolerance test, is increased significantly in Kir6.2−/−, which could protect Kir6.2−/− from developing hyperglycemia. Our data indicate that the KATP channel in pancreatic beta cells is a key regulator of both glucose- and sulfonylurea-induced insulin secretion and suggest also that the KATP channel in skeletal muscle might be involved in insulin action.

Defective trafficking and function of KATP channels caused by a sulfonylurea receptor 1 mutation associated with persistent hyperinsulinemic hypoglycemia of infancy

The ATP-sensitive potassium channel (KATP) regulates insulin secretion in pancreatic β cells. Loss of functional KATP channels because of mutations in either the SUR1 or Kir6.2 channel subunit causes persistent hyperinsulinemic hypoglycemia of infancy (PHHI). We investigated the molecular mechanism by which a single phenylalanine deletion in SUR1 (ΔF1388) causes PHHI. Previous studies have shown that coexpression of ΔF1388 SUR1 with Kir6.2 results in no channel activity. We demonstrate here that the lack of functional expression is due to failure of the mutant channel to traffic to the cell surface. Trafficking of KATP channels requires that the endoplasmic reticulum-retention signal, RKR, present in both SUR1 and Kir6.2, be shielded during channel assembly. To ask whether ΔF1388 SUR1 forms functional channels with Kir6.2, we inactivated the RKR signal in ΔF1388 SUR1 by mutation to AAA (ΔF1388 SUR1AAA). Inactivation of similar endoplasmic reticulum-retention signals in the cystic fibrosis transmembrane conductance regulator has been shown to partially overcome the trafficking defect of a cystic fibrosis transmembrane conductance regulator mutation, ΔF508. We found that coexpression of ΔF1388 SUR1AAA with Kir6.2 led to partial surface expression of the mutant channel. Moreover, mutant channels were active. Compared with wild-type channels, the mutant channels have reduced ATP sensitivity and do not respond to stimulation by MgADP or diazoxide. The RKR → AAA mutation alone has no effect on channel properties. Our results establish defective trafficking of KATP channels as a molecular basis of PHHI and show that F1388 in SUR1 is critical for normal trafficking and function of KATP channels.

Oscillations in KATP channel activity promote oscillations in cytoplasmic free Ca2+ concentration in the pancreatic beta cell.

Pancreatic beta cells exhibit oscillations in electrical activity, cytoplasmic free Ca2+ concentration ([Ca2+](i)), and insulin release upon glucose stimulation. The mechanism by which these oscillations are generated is not known. Here we demonstrate fluctuations in the activity of the ATP-dependent K+ channels (K(ATP) channels) in single beta cells subject to glucose stimulation or to stimulation with low concentrations of tolbutamide. During stimulation with glucose or low concentrations of tolbutamide, K(ATP) channel activity decreased and action potentials ensued. After 2-3 min, despite continuous stimulation, action potentials subsided and openings of K(ATP) channels could again be observed. Transient suppression of metabolism by azide in glucose-stimulated beta cells caused reversible termination of electrical activity, mimicking the spontaneous changes observed with continuous glucose stimulation. Thus, oscillations in K(ATP) channel activity during continuous glucose stimulation result in oscillations in electrical activity and [Ca2+](i).

Levosimendan: Studies on its mechanisms of action and beyond

Acute heart failure syndrome represents a prominent and growing health problem all around the world. Ideally, medical treatment for patients admitted to hospital because of this syndrome, in addition to alleviating the acute symptoms, should also prevent myocardial damage, modulate neurohumoral and inflammatory activation, and preserve or even improve renal function. Levosimendan is a cardiac enhancer having both inotropic and vasodilatory effects. It is approved for the short-term treatment of acutely decompensated chronic heart failure, but it has been shown to have beneficial clinical effects also in ischemic heart disease and septic shock as well as in perioperative cardiac support. In the present study, the mechanisms of action of levosimendan were studied in isolated guinea-pig heart preparations: Langendorff-perfused heart, papillary muscle and permeabilized cardiomyocytes as well as in purified phosphodiesterase isoenzyme preparations. Levosimendan was shown to be a potent inotropic agent in isolated Langendorff-perfused heart and right ventricle papillary muscle. In permeabilized cardiomyocytes, it was demonstrated to be a potent calcium sensitizer in contrast to its enantiomer, dextrosimendan. It was additionally shown to be a very selective phosphodiesterase (PDE) type-3 inhibitor, the selectivity factor for PDE3 over PDE4 being 10000 for levosimendan. Irrespective of this very selective PDE3 inhibitory property in purified enzyme preparations, the inotropic effect of levosimendan was demonstrated to be mediated mainly through calcium sensitization in the isolated heart as well as the papillary muscle preparations at clinically relevant concentrations. In the isolated Lagendorff-perfused heart, glibenclamide antagonized the levosimendan-induced increase in coronary flow (CF). Therefore, the main vasodilatory mechanism in coronary veins is believed to be the opening of the ATP-sensitive potassium (KATP) channels. In the paced hearts, CF did not increase in parallel with oxygen consumption (MVO2), thus indicating that levosimendan had a direct vasodilatory effect on coronary veins. The pharmacology of levosimendan was clearly different from that of milrinone, which induced an increase in CF in parallel with MVO2. In conclusion, levosimendan was demonstrated to increase cardiac contractility by binding to cardiac troponin C and sensitizing the myofilament contractile proteins to calcium, and further to induce coronary vasodilatation by opening KATP channels in vascular smooth muscle. In addition, the efficiency of the cardiac contraction was shown to be more advantageous when the heart was perfused with levosimendan in comparison to milrinone perfusion.

Levosimendaanin vaikutusmekanismi ja nykyinen merkitys sydämen vajaatoiminnan hoidossa

Sydämen vajaatoiminta on erilaisista sydän- ja verisuonisairauksista aiheutuva monimuotoinen oireyhtymä, johon sairastuneiden ja kuolleiden potilaiden määrä on yhä suuri. Sen patofysiologiaan voi kuulua muun muassa sympaattisen hermoston ja reniini-angiotensiini-aldosteroni–järjestelmän aktiivisuutta, huonosti supistuva vasen kammio, sydämen uudelleenmuokkautumista, muutoksia [Ca2+]i:n säätelyssä, kardiomyosyyttien apoptoosia sekä systeeminen tulehdustila. Johonkin osaan sairauden patofysiologiasta eivät nykyiset lääkehoidot riittävästi vaikuta. Klassiset inotroopit lisäävät sydämen supistusvireyttä kasvattamalla solunsisäistä Ca2+-pitoisuutta, mutta ne lisäävät rytmihäiriöriskiä, sydämen hapenkulutusta sekä heikentävät ennustetta. Levosimendaani, kalsiumherkistäjä, lisää sydämen supistusvoimaa [Ca2+]i:ta kohottamatta herkistämällä sydänlihaksen kalsiumin vaikutuksille. Lisäksi levosimendaani avaa sarkolemmaalisia ja mitokondriaalisia K+-kanavia, jotka välittävät vasodilataatiota ja kardioprotektiota. Suurilla annoksilla levosimendaani on selektiivinen PDE3-estäjä. Levosimendaania suositellaan äkillisesti pahentuneen sydämen vajaatoiminnan hoitoon, mutta muitakin lupaavia indikaatioita sille on keksitty. Esimerkiksi kroonisesti annosteltu oraalinen levosimendaani on suojannut kardiovaskulaarijärjestelmää ja parantanut selviytymistä in vivo. Erikoistyössä selvitettiin kroonisesti annostellun oraalisen levosimendaanin, valsartaanin ja näiden kombinaatioterapian vaikutuksia selviytymiseen, verenpaineeseen sekä sydämen hypertrofioitumiseen Dahlin suolaherkillä (Dahl/Rapp) rotilla. Levosimendaanin suojavaikutus ilmeni vähäisempänä kuolleisuutena, mutta ero ei ollut tilastollisesti merkitsevä kontrolliryhmään nähden. Kombinaatioterapia suojasi rottia kardiovaskulaarikuolleisuudelta ja vähensi todennäköisesti verenpaineesta riippuvaisesti sydämen hypertofioitumista niin sydän/kehonpaino–suhteen kuin ultraäänitutkimuksenkin perusteella arvioituna paremmin kuin kumpikaan lääke monoterapiana. Lääkekombinaatio alensi additiivisesti hypertensiota kaikissa mittauspisteissä. Sydämen systolista toimintaa levosimendaani kohensi vain vähäisesti. Dahl/Rapp-rotille kehittyikin pääosin hypertension indusoimaa diastolista sydämen vajaatoimintaa kohonneen IVRT-arvon perusteella. Levosimendaani sekä monoterapiana että kombinaatioterapiana valsartaanin kanssa vähensi sydämen diastolista vajaatoimintaa.

GLP-1 and related peptides cause concentration-dependent relaxation of rat aorta through a pathway involving KATP and cAMP

increasing evidence from both clinical and experimental studies indicates that the insulin-releasing hormone, glucagon-like peptide-1 (GLP-1) may exert additional protective/reparative effects on the cardiovascular system. The aim of this study was to examine vasorelaxant effects of GLP-1(7-36)amide, three structurally-related peptides and a non-peptide GLP-1 agonist in rat aorta. Interestingly, all GLP-1 compounds, including the established GLP-1 receptor antagonist, exendin (9-39) caused concentration-dependent relaxation. Mechanistic studies employing hyperpolarising concentrations of potassium or glybenclamide revealed that these relaxant effects are mediated via specific activation of ATP-sensitive potassium channels. Further experiments using a specific membrane-permeable cyclic AMP (cAMP) antagonist, and demonstration of increased cAMP production in response to GLP-1 illustrated the critical importance of this pathway. These data significantly extend previous observations suggesting that GLP-1 may modulate vascular function, and indicate that this effect may be mediated by the GLP-1 receptor. However, further studies are required in order to establish whether GLP-1 related agents may confer additional cardiovascular benefits to diabetic patients. (c) 2008 Elsevier Inc. All rights reserved.

Functional expression of KCNQ (Kv7) channels in guinea-pig bladder smooth muscle and their contribution to spontaneous activity

Background and Purpose: The aim of the study was to determine whether KCNQ channels are functionally expressed in bladder smooth muscle cells (SMC) and to investigate their physiological significance in bladder contractility. 

Experimental Approach: KCNQ channels were examined at the genetic, protein, cellular and tissue level in guinea pig bladder smooth muscle using RT-PCR, immunofluorescence, patch-clamp electrophysiology, calcium imaging, detrusor strip myography, and a panel of KCNQ activators and inhibitors. 

Key Results: KCNQ subtypes 1-5 are expressed in bladder detrusor smooth muscle. Detrusor strips typically displayed TTX-insensitive myogenic spontaneous contractions that were increased in amplitude by the KCNQ channel inhibitors XE991, linopirdine or chromanol 293B. Contractility was inhibited by the KCNQ channel activators flupirtine or meclofenamic acid (MFA). The frequency of Ca2+-oscillations in SMC contained within bladder tissue sheets was increased by XE991. Outward currents in dispersed bladder SMC, recorded under conditions where BK and KATP currents were minimal, were significantly reduced by XE991, linopirdine, or chromanol, and enhanced by flupirtine or MFA. XE991 depolarized the cell membrane and could evoke transient depolarizations in quiescent cells. Flupirtine (20M) hyperpolarized the cell membrane with a simultaneous cessation of any spontaneous electrical activity. 

Conclusions and Implications: These novel findings reveal the role of KCNQ currents in the regulation of the resting membrane potential of detrusor SMC and their important physiological function in the control of spontaneous contractility in the guinea pig bladder.

Molecular mechanisms mediating the beneficial metabolic effects of [Arg4]tigerinin-1R in mice with diet-induced obesity and insulin resistance

The frog skin host-defense peptide tigerinin-1R stimulates insulin release in vitro and improves glucose tolerance and insulin sensitivity in animal models of type 2 diabetes. This study extends these observation by investigating the molecular mechanisms of action underlying the beneficial metabolic effects of the analogue [Arg4]tigerinin-1R in mice with diet induced obesity, glucose intolerance and insulin resistance. The study also investigates the electrophysiological effects of the peptide on KATP and L-type Ca2+ channels in BRINBD11 clonal β cells. Non-fasting plasma glucose and glucagon concentrations were significantly (P<0.05) decreased and plasma insulin increased by twice daily treatment with [Arg4]tigerinin-1R (75 nmol.kg-1 body weight) for 28 days. Oral and intraperitoneal glucose tolerance were significantly (P < 0.05) improved accompanied by enhanced secretion and action of insulin. The peptide blocked KATP channels and, consistent with this, improved beta cell responses of isolated islets to a range of secretagogues. Peptide administration resulted in up-regulation of key functional genes in islets involved insulin secretion (Abcc8, Kcnj11, Cacna1c and Slc2a2) and in skeletal muscle involved with insulin action (Insr, Irs1, Pdk1, Pik3ca, and Slc2a4). These observations encourage further development of tigerinin-1R analogues for the treatment of patients with type 2 diabetes.

Implication des canaux K+ dans les processus de réparation de l’épithélium respiratoire sain et fibrose kystique

La pathologie de la fibrose kystique (FK) est causée par des mutations du gène codant pour le canal Cl- CFTR. Au niveau respiratoire, cette dysfonction du transport transépithélial de Cl- occasionne une altération de la composition et du volume du liquide de surface des voies aériennes. Une accumulation de mucus déshydraté favorise alors la colonisation bactérienne et une réponse inflammatoire chronique, entraînant des lésions épithéliales sévères au niveau des voies aériennes et des alvéoles pouvant culminer en défaillance respiratoire. Le principal objectif de mon projet de maîtrise était d’étudier les processus de réparation de l’épithélium alvéolaire sain, l’épithélium bronchique sain et FK à l’aide d’un modèle in vitro de plaies mécaniques. Nos résultats démontrent la présence d’une boucle autocrine EGF/EGFR contrôlant les processus de migration cellulaire et de réparation des lésions mécaniques. D’autre part, nos expériences montrent que l’EGF stimule l’activité et l’expression des canaux K+ KATP, KvLQT1 et KCa3.1 des cellules épithéliales respiratoires. L’activation de ces canaux est cruciale pour les processus de réparation puisque la majeure partie de la réparation stimulée à l’EGF est abolie en présence d’inhibiteurs de ces canaux. Nous avons également observé que les cellules FK présentent un délai de réparation, probablement causé par un défaut de la réponse EGF/EGFR et une activité/expression réduite des canaux K+. Nos résultats permettent de mieux comprendre les mécanismes de régulation des processus de réparation de l’épithélium sain et FK. De plus, ils ouvrent de nouvelles options thérapeutiques visant à promouvoir, à l’aide d’activateurs de canaux K+ et de facteurs de croissance, la régénération de l’épithélium respiratoire chez les patients atteints de FK.

Régulation des processus de réparation de l’épithélium bronchique sain et Fibrose Kystique par le TNF-alpha

La Fibrose Kystique, causée par des mutations du canal CFTR, mène à la dysfonction du transport des fluides et des ions causant la déshydratation du liquide de surface des voies aériennes et ainsi une défaillance de la clairance mucocilliaire. Ce défaut entraine l’accumulation et l’épaississement du mucus au niveau des bronches qui devient alors un environnement idéal pour le développement d’infections chroniques et d’inflammation qui sont associées à la destruction progressive de l’épithélium chez les patients Fibrose Kystique. Même si leur rôle dans les processus lésionnels est très bien connu, l’impact de médiateurs inflammatoires sur la capacité de réparation ne l’est cependant pas. L’objectif de ma maitrise était donc d’étudier la régulation des mécanismes de réparation de l’épithélium bronchique sain et Fibrose Kystique par le facteur de nécrose tumoral (TNF)-alpha, une cytokine pro-inflammatoire cruciale dans l’initiation et la propagation de la réponse inflammatoire chez les patients FK. À l’aide d’un modèle de plaies mécaniques, nous avons montré que le TNF-alpha stimule la réparation de l’épithélium bronchique sain (NuLi-1) et Fibrose Kystique (CuFi-1). De façon surprenante, l’exposition chronique au TNF-alpha augmente cette stimulation tout comme le taux de migration cellulaire pendant la réparation. Cette augmentation de réparation semble être médiée par l’activation de la métalloprotéinase MMP-9, la relâche d’EGF par les cellules épithéliales et ainsi l’activation de la voie d’EGFR. De plus, l’activation de la réparation par le TNF-alpha semble aussi impliquer l’activation des canaux K+, dont nous avons démontré le rôle important dans la réparation. Contrairement à son effet sur la migration cellulaire et sur la réparation, le TNF-alpha diminue la prolifération cellulaire. En somme, en plus de son rôle dans les processus lésionnels, le TNF-alpha semble avoir un rôle complexe dans les processus de réparation puisqu’il stimule la migration et ralentit la prolifération cellulaire.