[The imminent peril in the law of July the fifth 2011, two years later: the impact on health?]. / Le péril imminent dans la loi du 5 juillet 2011: quelles implications sur les soins?

In 1938, the French government decided to enact a first legislation to enforce admission of the mentally ill to hospitals. Later in 1990, the law took into consideration the evolution of practices with an increase of free admissions and the right to maintain the mentally ill in cities. Three types of psychiatric hospitalization were defined: free, on third party request and for involuntary confinement. A review had theoretically to be conducted every 5 years. In practice this was not the case, probably due to the balance between individual freedom, patient care and public safety always hard to find. However, considering the imperative European harmonization and the fact the Constitutional Council declared a double unconstitutionality of the law, the Act of July 5th was enacted in a hurry during the summer 2011. The Act defines the "rights and the protection of people subject to psychiatric care and methods of coverage". In this document, we will briefly review the context of this law. We will also explore the clinical implications of the very innovative measure: the "péril imminent". We will use the admissions at the Sainte-Anne hospital in Paris in 2010 to 2012. Three major key points were introduced in the law: a judge controls an agreeable release after 15 days and 6 months of continuous hospitalization. The law let the new possibility to provide ambulatory cares under constraints, and these to make an involuntary confinement without a third party request, using the "imminent peril". This law implies the involvement of the judge and the lawyer. This one has to defend a client who needs care, he controls the formal validity of decisions concerning the patient. To provide treatment without consent in "imminent peril" to someone, conditions are requested: these mental disorders make his consent impossible and his mental state requires immediate care with immediate care of constant medical monitoring justifying a full hospitalization or regular medical monitoring for support under another form of full hospitalization (Article L.3212. 1 of the Code of Public Health). Moreover, a demand for care by a third party has also to be impossible to obtain and an imminent peril to the person's health has to exist, supported by a medical certificate from a doctor who does not belong to the patient's psychiatric hospital. The imminent peril would be an immediate danger to the health or life of the patient. What has been the impact of this law adopted in emergency at Sainte-Anne hospital? This psychiatric hospital is in charge of the population in southern Paris, where reside about 655,000 people. This work observes the evolution of the type of hospitalization and care before and after the adoption of the law. We can observe an overall increase in entries under constraints. There is a decrease in admissions for involuntary confinement for the benefit of imminent peril. This imminent peril corresponds to only a small proportion of hospitalizations without consent but are rising between 2011 and 2012, perhaps in part due to a better understanding of the law. But this progression is to monitor to ensure compliance with the restrictive conditions laid down by this law. Also note that the imminent peril may be used at the refusal of the family or entourage to make the demand for care. The number of hospitalizations at the request of a third party with two certificates is down, which is probably due to a change in status of the CPOA, emergency structure within Sainte-Anne, which is no longer seen as extraterritorial. The imminent peril has advantages: it allows access to the care of people isolated and desocialized, of people whose identity is unknown, of pathological travellers. It avoids hospitalization at the request of the representative of the State for social reasons and not for risks to the safety of persons, even when this type of hospitalization is more stigmatizing and often more difficult to remove. It protects the entourage sometimes, when the family is ambivalent or hostile to care, or has been designated as a persecutor. The imminent peril also has disadvantages. One of them is the risk of its misuse to allow rapid hospitalization without taking the time to seek a third party. The imminent danger made when there is an entourage but which refuses to request care can undermine the development work on information about the disease, the need for care and treatment and the importance of the involvement of the entourage in the care plan. The alliance with the patient may be compromised. In some cases, a decision of care by the request of the representative of the State is more appropriate than the "imminent peril". The "imminent peril" may be preferred because of the administrative burden of prefectural measures when patient presents clinical improvement and we would go up to the ambulatory care in a care program. Yet, the use of a symbolic third, carrying authority, can avoid the too direct confrontation with the patient. Do not use it can complicate the management of the patient. Finally, with desocialized patients, imminent peril can facilitate access to care, but not continuity of care. Indeed, for the care program it is necessary to have an address for the patient. Once the crisis is not to develop a plan of care. Finally in some situations of desocialized patients, the imminent peril can promote access to care but not the continuity of care as to the care program it is necessary to have an address for the patient. Once the crisis is past, it is impossible to implement a program of care. The Law of 5 July 2011 marks a change in the practice of psychiatrists. Take into account the fundamental rights of the patient and to harmonize legislation at EU level was necessary. Some measures are designed to promote access to care as the "imminent peril", we now need to be vigilant to ensure that it is not diverted to promote an increase in care under constraints and that psychiatrists remain in an obligation of means and not of result.

Ionic channels underlying cardiac automaticity: new insights from genetically-modified mouse strains.

The spontaneous activity (or pacemaker activity) of the heart constitutes a fundamental physiological function in higher organisms. Pacemaker activity is generated in the sino-atrial node (SAN) by a specialized cell population adapted to the generation of a rhythmic electrical oscillation. The precise ionic mechanisms underlying initiation of pacemaking in automatic cells has not been entirely elucidated. Ionic channels and intracellular Ca2+ signalling in pacemaker cells are both required for the proper setting of pacemaking. Understanding the mechanisms of pacemaker activity is important for developing new therapeutic approaches for controlling the heart rate in the diseased myocardium. Controlling the heart rate in the clinical practice is a promising way to increase cardioprotection and improve patient's survival in cardiac ischemic pathology. We describe here the contribution of several ion channels families into the generation and regulation of the heart rate using new approaches involving genetically modified mouse strains. These studies underline the functional redundancy of mechanisms underlying pacemaking, an important safety parameter for new drugs targeting ion channels to modulate cardiac frequency.

Physiological and pharmacological insights into the role of ionic channels in cardiac pacemaker activity.

The generation of cardiac pacemaker activity is a complex phenomenon which requires the coordinated activity of different membrane ionic channels, as well as intracellular signalling factors including Ca(2+) and second messengers. The precise mechanism initiating automaticity in primary pacemaker cells is still matter of debate and certain aspects of how channels cooperate in the regulation of pacemaking by the autonomic nervous system have not been entirely elucidated. Research in the physiopathology of cardiac automaticity has also gained a considerable interest in the domain of cardiovascular pharmacology, since accumulating clinical and epidemiological evidence indicate a link between an increase in heart rate and the risk of cardiac mortality and morbidity. Lowering the heart rate by specific bradycardic agents in patients with heart disease constitutes a promising way to increase cardioprotection and improve survival. Thus, the elucidation of the mechanisms underlying the generation of pacemaker activity is necessary for the development of new therapeutic molecules for controlling the heart rate. Recent work on genetically modified mouse models provided new and intriguing evidence linking the activity of ionic channels genes to the generation and regulation of pacemaking. Importantly, results obtained on genetically engineered mouse strains have demonstrated that some channels are specifically involved in the generation of cardiac automaticity and conduction, but have no functional impact on the contractile activity of the heart. In this article, we will outline the current knowledge on the role of ionic channels in cardiac pacemaker activity and suggest new potential pharmacological targets for controlling the heart rate without concomitant negative inotropism.

If current inhibition: cellular basis and physiology.

The slow diastolic depolarization phase in cardiac pacemaker cells is the electrical basis of cardiac automaticity. The hyperpolarization-activated current (I(f)) is one of the key mechanisms underlying diastolic depolarization. Particularly, I(f) is unique in being activated on membrane hyperpolarization following the repolarization phase of the action potential. I(f) has adapted biophysical properties and voltage-dependent gating to initiate pacemaker activity. I(f) possibly constitutes the first voltage-dependent trigger of the diastolic depolarization. For these reasons, I(f) is a natural pharmacological target for controlling heart rate in cardiovascular disease. In this view, I(f) inhibitors have been developed in the past, yet the only molecule to have reached the clinical development is ivabradine. At the cellular level, the remarkable success of ivabradine is to be ascribed to its relatively high affinity for f-channels. Furthermore, ivabradine is the most I(f)-specific inhibitor known to date, since moderate inhibition of other voltage-dependent ionic currents involved in automaticity can be observed only at very high concentrations of ivabradine, more than one order of magnitude from that inhibiting I(f). Finally, the mechanism of block of f-channels by ivabradine has particularly favorable properties in light of controlling heart rate under variable physiological conditions. In this article, we will discuss how I(f) inhibition by ivabradine can lead to reduction of heart rate. To this aim, we will comment on the role of I(f) in cardiac automaticity and on the mechanism of action of ivabradine on f-channels. Some aspects of the cardiac pacemaker mechanism that improve the degree of security of ivabradine will also be highlighted.

Acetaminophen: a central analgesic drug that involves a spinal tropisetron-sensitive, non-5-HT(3) receptor-mediated effect.

The reversal of the antinociceptive effect of systemically administered acetaminophen (paracetamol) by intrathecal administration of the potent 5-HT(3) receptor antagonist tropisetron has been reported in rats subjected to the paw pressure test, suggesting that acetaminophen action is mediated through spinal 5-HT(3) receptors. However, more recent data, showing differences between the pharmacological profiles of various 5-HT(3) receptor antagonists, led us to reconsider the involvement of spinal 5-HT(3) receptors. To address this question, two different approaches were used: 1) electrophysiological recordings to assess whether acetaminophen directly modulates 5-HT(3) receptor activity and 2) pharmacological investigations with various 5-HT(3) receptor antagonists and spinal 5-HT(3) receptors antisense oligodeoxynucleotides (AODNs) to determine how those treatments might affect the antinociceptive action of acetaminophen. Electrophysiological studies demonstrated that acetaminophen had no direct agonist or antagonist effects on 5-HT(3A) receptors. Unlike tropisetron, other 5-HT(3) receptor antagonists, such as ondansetron and granisetron, injected intrathecally were unable to reverse the antinociceptive effect of acetaminophen. Moreover, pretreatment with AODNs did not reverse the acetaminophen-induced antinociceptive effect, although it suppressed the antinociceptive effect of m-chlorophenylbiguanide, a specific agonist of 5-HT(3) receptors, and significantly reduced (30%) the expression of these receptors in the dorsal horn of the spinal cord. These results suggest that acetaminophen-induced antinociceptive action involves a spinal tropisetron-sensitive receptor that is not the 5-HT(3) receptor and that remains to be identified.

[Genetic diversity of voltage-gated calcium channels]. / Diversité génétique des canaux calciques activés par la dépolarisation membranaire.

Understanding of the properties of normal and diseased voltage-dependent calcium channels has greatly improved these last Years after the extensive development of the patch-clamp and molecular biology studies and the functional expression strategies. The calcium channel diversity is based on the expression of numerous genes that encode pore channel subunits (10 genes) and auxiliary/regulatory subunits (16 genes). In addition, most of these genes are subject to alternative splicing. The study of calcium channels has also benefited from the discovery of genetic diseases linked to calcium channel mutations: the calcium channelopathies. The review describes the recent data and working hypothesis that address the challenging question of how the calcium channel diversity occurs and how alterations in channel function lead to selective cellular dysfunction.

Direct inhibition of T-type calcium channels by the endogenous cannabinoid anandamide.

Low-voltage-activated or T-type Ca(2+) channels (T-channels) are widely expressed, especially in the central nervous system where they contribute to pacemaker activities and are involved in the pathogenesis of epilepsy. Proper elucidation of their cellular functions has been hampered by the lack of selective pharmacology as well as the absence of generic endogenous regulations. We report here that both cloned (alpha(1G), alpha(1H) and alpha(1I) subunits) and native T-channels are blocked by the endogenous cannabinoid, anandamide. Anandamide, known to exert its physiological effects through cannabinoid receptors, inhibits T-currents independently from the activation of CB1/CB2 receptors, G-proteins, phospholipases and protein kinase pathways. Anandamide appears to be the first endogenous ligand acting directly on T-channels at submicromolar concentrations. Block of anandamide membrane transport by AM404 prevents T-current inhibition, suggesting that anandamide acts intracellularly. Anandamide preferentially binds and stabilizes T-channels in the inactivated state and is responsible for a significant decrease of T-currents associated with neuronal firing activities. Our data demonstrate that anandamide inhibition of T-channels can regulate neuronal excitability and account for CB receptor-independent effects of this signaling molecule.

Properties of the hyperpolarization-activated current (I(f)) in isolated mouse sino-atrial cells.

OBJECTIVE: We have investigated the properties of the hyperpolarization-activated (I(f)) current in pacemaker cells from the mouse sino-atrial node (SAN). METHODS: The I(f) current was studied in cells isolated enzymatically from the SAN region of adult C57BL6/J mice. The whole-cell variation of the patch-clamp technique was employed to investigate the basic properties of I(f). RESULTS: In mouse SAN cells, the I(f) current density at -120 mV was 18+/-2 pA/pF (n=23). I(f) was not detected in cells showing atrial-like morphology that were also found in SAN preparations (n=7). I(f) was blocked by 5 mM Cs(+), was inhibited by application of 5 microM acetylcholine, and was increased by 10 microM noradrenaline. The I(f) current reversal potential was -31+/-2 mV under physiological concentration of Na(+) and K(+) ions. Lowering the extracellular Na(+) concentration reduced I(f) amplitude, while increased when the extracellular K(+) concentration was augmented. I(f) voltage for half activation was -87+/-1 mV (n=6). CONCLUSIONS: We conclude that the native I(f) current in mouse SAN cells shows functional properties that are similar to I(f) described in rabbit SAN tissue. This study opens the possibility of investigating the involvement of I(f) in the regulation of heart rate in genetically modified mice.

Interaction of SNX482 with domains III and IV inhibits activation gating of alpha(1E) (Ca(V)2.3) calcium channels.

We have investigated the action of SNX482, a toxin isolated from the venom of the tarantula Hysterocrates gigas, on voltage-dependent calcium channels expressed in tsa-201 cells. Upon application of 200 nM SNX482, R-type alpha(1E) calcium channels underwent rapid and complete inhibition, which was only poorly reversible upon washout. However, upon application of strong membrane depolarizations, rapid and complete recovery from inhibition was obtained. Tail current analysis revealed that SNX482 mediated an approximately 70 mV depolarizing shift in half-activation potential, suggesting that the toxin inhibits alpha(1E) calcium channels by preventing their activation. Experiments involving chimeric channels combining structural features of alpha(1E) and alpha(1C) subunits indicated that the presence of the domain III and IV of alpha(1E) is a prerequisite for a strong gating inhibition. In contrast, L-type alpha(1C) channels underwent incomplete inhibition at saturating concentrations of SNX482 that was paralleled by a small shift in half-activation potential and which could be rapidly reversed, suggesting a less pronounced effect of the toxin on L-type calcium channel gating. We conclude that SNX482 does not exhibit unequivocal specificity for R-type channels, but highly effectively antagonizes their activation.

Inhibition of T-type and L-type calcium channels by mibefradil: physiologic and pharmacologic bases of cardiovascular effects.

Ca2+ channel antagonists of the dihydropyridine, benzothiazepine, and phenylalkylamine classes have selective effects on L-type versus T-type Ca2+ channels. In contrast, mibefradil was reported to be more selective for T-type channels. We used the whole-cell patch-clamp technique to investigate the effects of mibefradil on T-type and L-type Ca2+ currents (I(CaT) and I(CaL)) recorded at physiologic extracellular Ca2+ in different cardiac cell types. At a stimulation rate of 0.1 Hz, mibefradil blocked I(CaT) evoked from negative holding potentials (HPs) (-100 mV to -80 mV) with an IC50 of 0.1 microM in rat atrial cells. This concentration had no effect on I(CaL) in rat ventricular cells (IC50: approximately3 microM). However, block of I(CaL) was enhanced when the HP was depolarized to -50 mV (IC50: approximately 0.1 microM). Besides a resting block, mibefradil displayed voltage- and use-dependent effects on both I(CaT) and I(CaL). In addition, inhibition was enhanced by increasing the duration of the step-depolarizations. Similar effects were observed in human atrial and rabbit sinoatrial cells. In conclusion, mibefradil combines the voltage- and use-dependent effects of dihydropyridines and benzothiazepines on I(CaL). Inhibition of I(CaL), which has probably been underestimated before, may contribute to most of the cardiovascular effects of mibefradil.

Multiple structural elements contribute to voltage-dependent facilitation of neuronal alpha 1C (CaV1.2) L-type calcium channels.

Voltage- and frequency-dependent facilitation of calcium channel activity has been implicated in a number of key physiological processes. Various mechanisms have been proposed to mediate these regulations, including a switch between channel gating modes, voltage-dependent phosphorylation, and a voltage-dependent deinhibition of G-protein block. Studying such modulation on recombinant Ca channels expressed in oocytes, we previously reported that alpha(1C) L-type calcium channel contrast with non-L type Ca channels by its ability to exhibit facilitation by pre-depolarization (Voltage-dependent facilitation of a neuronal alpha(IC) L-type calcium channel, E. Bourinet et al., EMBO Journal, 1994; 13, 5032-5039). To further analyze this effect, we have investigated the molecular determinants which mediate the differences in voltage-dependent facilitation between "facilitable" alpha(1C) and "non facilitable" alpha(1E) calcium channels. We used a series of chimeras which combine the four transmembrane domains of the two channels. Results show that the four domains of alpha(1C) contribute to facilitation, with domain I being most critical. This domain is required but not sufficient alone to generate facilitation. The minimal requirement to observe the effect is the presence of domain I plus one of the three others. We conclude that similarly to activation gating, voltage-dependent facilitation of alpha(1C) is a complex process which involves multiple structural elements were domains I and III play the major role.

Cyclosporin A increases basal intracellular calcium and calcium responses to endothelin and vasopressin in human coronary myocytes.

Cyclosporin A (CsA) is a widely used immunosuppressive agent with severe side effects including hypertension. Here, we investigated the effects of CsA on intracellular free calcium ([Ca(2+)](i)) and the mechanisms involved in vasoconstriction in cultured human coronary myocytes. We used the Fura-2 technique for Ca(2+) imaging. Acute application of CsA at therapeutic concentrations (0.1-10 micromol/l) had no effect. Chronic exposure to CsA (1 micromol/l) for 24 h induced a small (20 nmol/l) but highly significant increase of basal [Ca(2+)](i) and enhanced the occurrence of spontaneous Ca(2+) oscillations. Endothelin- and vasopressin-induced rises of [Ca(2+)](i) were also enhanced. The demonstration that CsA increases basal [Ca(2+)](i) in addition to its impact on agonist receptor stimulation is of major importance for new therapeutic approaches.

Alternatively spliced alpha(1G) (Ca(V)3.1) intracellular loops promote specific T-type Ca(2+) channel gating properties.

At least three genes encode T-type calcium channel alpha(1) subunits, and identification of cDNA transcripts provided evidence that molecular diversity of these channels can be further enhanced by alternative splicing mechanisms, especially for the alpha(1G) subunit (Ca(V)3.1). Using whole-cell patch-clamp procedures, we have investigated the electrophysiological properties of five isoforms of the human alpha(1G) subunit that display a distinct III-IV linker, namely, alpha(1G-a), alpha(1G-b), and alpha(1G-bc), as well as a distinct II-III linker, namely, alpha(1G-ae), alpha(1G-be), as expressed in HEK-293 cells. We report that insertion e within the II-III linker specifically modulates inactivation, steady-state kinetics, and modestly recovery from inactivation, whereas alternative splicing within the III-IV linker affects preferentially kinetics and voltage dependence of activation, as well as deactivation and inactivation. By using voltage-clamp protocols mimicking neuronal activities, such as cerebellar train of action potentials and thalamic low-threshold spike, we describe that inactivation properties of alpha(1G-a) and alpha(1G-ae) isoforms can support channel behaviors reminiscent to those described in native neurons. Altogether, these data demonstrate that expression of distinct variants for the T-type alpha(1G) subunit can account for specific low-voltage-activated currents observed in neuronal tissues.

The alpha1I T-type calcium channel exhibits faster gating properties when overexpressed in neuroblastoma/glioma NG 108-15 cells.

The recently cloned T-type calcium channel alpha1I (Cav3.3) displays atypically slow kinetics when compared to native T-channels. Possible explanations might involve alternative splicing of the alpha1I subunit, or the use of expression systems that do not provide a suitable environment (auxiliary subunit, phosphorylation, glycosylation...). In this study, two human alpha1I splice variants, the alpha1I-a and alpha1I-b isoforms that harbour distinct carboxy-terminal regions were studied using various expression systems. As the localization of the alpha1I subunit is primarily restricted to neuronal tissues, its functional expression was conducted in the neuroblastoma/glioma cell line NG 108-15, and the results compared to those obtained in HEK-293 cells and Xenopus oocytes. In Xenopus oocytes, both isoforms exhibited very slow current kinetics compared to those obtained in HEK-293 cells, but the alpha1I-b isoform generated faster currents than the alpha1I-a isoform. Both activation and inactivation kinetics of alpha1I currents were significantly faster in NG 108-15 cells, while deactivating tail currents were two times slower, compared to those obtained in HEK-293 cells. Moreover, the alpha1-b isoform showed significantly slower deactivation kinetics both in NG 1080-15 and in HEK-293 cells. Altogether, these data emphasize the advantage of combining several expression systems to reveal subtle differences in channel properties and further indicate that the major functional differences between both human alpha1I isoforms are related to current kinetics. More importantly, these data suggest that the expression of the alpha1I subunit in neuronal cells contributes to the "normalization" of current kinetics to the more classical, fast-gated T-type Ca2+ current.

Transient down-regulation of L-type Ca(2+) channel and dystrophin expression after balloon injury in rat aortic cells.

OBJECTIVE: Migration and proliferation of arterial smooth muscle cells are critical responses during restenosis after balloon angioplasty. We investigated the changes in the expression of Ca(2+) channels and dystrophin, two determinants of contraction, after balloon injury of rat aortas. METHODS: Proliferation and migration of aortic myocytes were triggered in vivo by the passage of an inflated balloon catheter in the aortas of 12-week-old male Wistar rats. We used the whole-cell patch clamp technique to investigate Ba(2+) currents (I(Ba)) through Ca(2+) channels in single cells freshly isolated from media and neointima at various times after injury (days 2, 7, 15, 30 and 45). RESULTS: No T-type Ca(2+) channel current was recorded in any cell at any time. In contrast, a dihydropyridine (DHP)-sensitive L-type I(Ba)was recorded consistently in the media of intact aorta. After aortic injury, I(Ba) decreased dramatically (at days 2 and 7) but recovered over time to reach normal amplitude on days 30 and 45. In the neointima, I(Ba) was absent on day 15 but also increased gradually over time as observed at days 30 and 45. The use of a specific antibody directed against the L-type Ca(2+) channel alpha(1C) subunit showed, both by immunostaining and by Western blotting, no expression of the Ca(2+) channel protein on day 15. Parallel immunodetection of dystrophin showed that this marker of the contractile phenotype of SMCs was also not detectable at this stage in neointimal cells. Both proteins were re-expressed at days 45 and 63. Balloon injury induces a transient down-regulation of I(Ba) in arterial cells. CONCLUSIONS: Cell dedifferentiation and proliferation in vivo abolish the expression of L-type Ca(2+) channels and dystrophin in neointimal cells. These changes may be critical in the regulation of Ca(2+) homeostasis and, thereby, contraction of the arterial SMCs during restenosis following angioplasty.

Facilitation of the L-type calcium current in rabbit sino-atrial cells: effect on cardiac automaticity.

OBJECTIVE: The L-type Ca(2+) current (I(Ca,L)) contributes to the generation and modulation of the pacemaker action potential (AP). We investigated facilitation of I(Ca,L) in sino-atrial cells. METHODS: Facilitation was studied in regularly-beating cells isolated enzymatically from young albino rabbits (0.8-1 kg). We used the whole-cell patch-clamp technique to vary the frequency of the test depolarizations evoked at -10 mV or the conditioning diastolic membrane potential prior to the test pulse. RESULTS: High frequencies (range 0.2-3.5 Hz) slowed the decay kinetics of I(Ca,L) evoked from a holding potential (HP) of -80 mV in 68% of cells resulting in a larger Ca(2+) influx during the test pulse. The amount of facilitation increased progressively between 0.2 and 3.0 Hz. When the frequency was changed from 0.1 to 1 Hz, the averaged increase in the time integral of I(Ca,L) was 27+/-7% (n=22). Application of conditioning voltages between -80 and -50 mV induced similar facilitation of I(Ca,L) in 73% of cells. The maximal increase of Ca(2+) entry occurred between -60 and -50 mV, and was on average 38+/-14% for conditioning prepulses of 5 s in duration (n=15). Numerical simulations of the pacemaker activity showed that facilitation of I(Ca,L) promotes stability of sino-atrial rate by enhancing Ca(2+) entry, thus establishing a negative feedback control against excessive heart rate slowing. CONCLUSION: Facilitation of I(Ca,L) is present in rabbit sino-atrial cells. The underlying mechanism reflects modulation of I(Ca,L) decay kinetics by diastolic membrane potential and frequency of depolarization. This phenomenon may provide an important regulatory mechanism of sino-atrial automaticity.

T-type calcium currents in rat cardiomyocytes during postnatal development: contribution to hormone secretion.

T-type Ca(2+) channels have been suggested to play a role in cardiac automaticity, cell growth, and cardiovascular remodeling. Although three genes encoding for a T-type Ca(2+) channel have been identified, the nature of the isoform(s) supporting the cardiac T-type Ca(2+) current (I(Ca,T)) has not yet been determined. We describe the postnatal evolution of I(Ca,T) density in freshly dissociated rat atrial and ventricular myocytes and its functional properties at peak current density in young atrial myocytes. I(Ca,T) displays a classical low activation threshold, rapid inactivation kinetics, negative steady-state inactivation, slow deactivation, and the presence of a window current. Interestingly, I(Ca,T) is poorly sensitive to Ni(2+) and insensitive to R-type current toxin SNX-482. RT-PCR experiments and comparison of functional properties with recombinant Ca(2+) channel subtypes suggest that neonatal I(Ca,T) is related to the alpha(1G)-subunit. Atrial natriuretic factor (ANF) secretion was measured using peptide radioimmunoassays in atrial tissue. Pharmacological dissection of ANF secretion indicates an important contribution of I(Ca,T) to Ca(2+) signaling during the neonatal period.

[Is atypical sodium current related to arterial pathophysiology?]. / Un courant sodique atypique lié à la patho-physiologie artérielle?

Primary cultured human coronary myocytes, derived from patients with end-stage heart failure (NYHA, classes III and IV) caused by an ischemic disease and undergoing heart transplantation, express a voltage-gated tetrodotoxin-sensitive sodium current (INa). This current has atypical electrophysiological and pharmacological properties and regulates intracellular sodium ([Na+]i) and calcium ([Ca2+]i). Our work is aimed at identifying its role and regulation of expression during pathophysiology. We currently investigate whether INa is expressed in vascular smooth muscles cells (VSMCs) isolated from either healthy or diseased (atheromatous) arteries in human and, in parallel, in pig, rabbit and rat. Cells were enzymatically isolated, primary cultured and macroscopic INa were recorded using the whole cell patch clamp technique. We found that INa is expressed in VSMCs grown from human aortic (90%; n = 48) and pulmonary (44%; n = 16) arteries and in the human aortic cell line HAVSMC (94%; n = 27). INa was also detected in pig coronary (60%; n = 25) and rabbit aortic (47%; n = 15) VSMCs, but not in rat aortic myocytes (n = 30). These different INa were activated at similar range of potentials (approximately -45 mV), had similar sensitivity to tetrodotoxin (IC50 around 5 nM) and similar density (2 to 4 pA/pF). Their expression was related to cell dedifferentiation in vitro. However, INa was observed more frequently in human myocytes derived from diseased arteries (ischemic cardiopathy) than in those derived from healthy tissues (dilated cardiopathy). In conclusion, INa may contribute to increase the basal arterial contractility and play a role in pathological situations including hypertension.

[Molecular diversity of calcium channel activities by depolarization]. / Diversité moléculaire des canaux calciques activés par la dépolarisation.

Voltage-gated calcium channels are involved in a large variety of cellular functions such as excitation-contraction coupling, hormone secretion, firing and pacemaker activity, gene activation and proliferation. Cloning of complementary DNAs encoding for calcium channel subunits has challenged the study of the functional properties of calcium channels and has allowed analysis of the molecular basis of calcium channel diversity. Recently, pore-forming subunits of T-type calcium channels have been cloned. Recent data describing the genes encoding calcium channels, their molecular and pharmacological studies, as well as their linkage to human genetic diseases are reviewed in this article.