Panic results in unique molecular and network changes in the amygdala that facilitate fear responses.

Recurrent panic attacks (PAs) are a common feature of panic disorder (PD) and post-traumatic stress disorder (PTSD). Several distinct brain regions are involved in the regulation of panic responses, such as perifornical hypothalamus (PeF), periaqueductal gray, amygdala and frontal cortex. We have previously shown that inhibition of GABA synthesis in the PeF produces panic-vulnerable rats. Here, we investigate the mechanisms by which a panic-vulnerable state could lead to persistent fear. We first show that optogenetic activation of glutamatergic terminals from the PeF to the basolateral amygdala (BLA) enhanced the acquisition, delayed the extinction and induced the persistence of fear responses 3 weeks later, confirming a functional PeF-amygdala pathway involved in fear learning. Similar to optogenetic activation of PeF, panic-prone rats also exhibited delayed extinction. Next, we demonstrate that panic-prone rats had altered inhibitory and enhanced excitatory synaptic transmission of the principal neurons, and reduced protein levels of metabotropic glutamate type 2 receptor (mGluR2) in the BLA. Application of an mGluR2-positive allosteric modulator (PAM) reduced glutamate neurotransmission in the BLA slices from panic-prone rats. Treating panic-prone rats with mGluR2 PAM blocked sodium lactate (NaLac)-induced panic responses and normalized fear extinction deficits. Finally, in a subset of patients with comorbid PD, treatment with mGluR2 PAM resulted in complete remission of panic symptoms. These data demonstrate that a panic-prone state leads to specific reduction in mGluR2 function within the amygdala network and facilitates fear, and mGluR2 PAMs could be a targeted treatment for panic symptoms in PD and PTSD patients.

Blockade of the metabotropic glutamate (mGluR2) modulates arousal through vigilance states transitions: evidence from sleep-wake EEG in rodents.

Accumulating data continue to support the therapeutic potential of glutamate metabotropic (mGluR2) receptors for treatment of psychiatric disorders such as depression, anxiety and schizophrenia. Glutamate neurotransmission is an integral component of sleep-wake mechanisms, which have translational relevance to assess on-target activity of drugs. Here, we investigated the influence of mGluR2 inactivation upon sleep-wake electroencephalogram (EEG) in rodents. Rats were administered with vehicle, the specific mGluR2 antagonist LY341495 (2.5, 5, 10mg/kg) or negative allosteric modulator (NAM) Ro-4491533 (2.5, 10 and 40 mg/kg) at lights onset. mGluR2 (-/-) mice were used to confirm the selectivity of functional response. Both LY341495 and Ro-4491533 induced an immediate and endured desynchronized cortical activity during 3-6h associated with enhanced theta and gamma oscillations and depressed slow oscillations during sleep. The arousal-promoting effect is consistent with the marked lengthening of sleep onset latency, an increased number of state transitions from light sleep to waking and the gradual increase in homeostatic compensatory sleep. The arousal response to mGluR2 blockade was not accompanied by sharp rebound hypersomnolence as found with the classical psycho-stimulant amphetamine. mGluR2 (-/-) mice and their WT littermates exhibited similar sleep-wake phenotype, while Ro-4491533 (40 mg/kg) enhanced waking associated with increased locomotor activity and body temperature in WT but not in mGluR2 (-/-) mice, which confirm the role of mGluR2 inactivation in the arousal response. Our results lend support for a role of mGluR2 blockade in promoting cortical arousal associated with theta/gamma oscillations as well as high thresholds transitions from sleep to waking.

Subchronic memantine induced concurrent functional disconnectivity and altered ultra-structural tissue integrity in the rodent brain: revealed by multimodal MRI.

BACKGROUND: An effective NMDA antagonist imaging model may find key utility in advancing schizophrenia drug discovery research. We investigated effects of subchronic treatment with the NMDA antagonist memantine by using behavioural observation and multimodal MRI. METHODS: Pharmacological MRI (phMRI) was used to map the neuroanatomical binding sites of memantine after acute and subchronic treatment. Resting state fMRI (rs-fMRI) and diffusion MRI were used to study the changes in functional connectivity (FC) and ultra-structural tissue integrity before and after subchronic memantine treatment. Further corroborating behavioural evidences were documented. RESULTS: Dose-dependent phMRI activation was observed in the prelimbic cortex following acute doses of memantine. Subchronic treatment revealed significant effects in the hippocampus, cingulate, prelimbic and retrosplenial cortices. Decreases in FC amongst the hippocampal and frontal cortical structures (prelimbic, cingulate) were apparent through rs-fMRI investigation, indicating a loss of connectivity. Diffusion kurtosis MRI showed decreases in fractional anisotropy and mean diffusivity changes, suggesting ultra-structural changes in the hippocampus and cingulate cortex. Limited behavioural assessment suggested that memantine induced behavioural effects comparable to other NMDA antagonists as measured by locomotor hyperactivity and that the effects could be reversed by antipsychotic drugs. CONCLUSION: Our findings substantiate the hypothesis that repeated NMDA receptor blockade with nonspecific, noncompetitive NMDA antagonists may lead to functional and ultra-structural alterations, particularly in the hippocampus and cingulate cortex. These changes may underlie the behavioural effects. Furthermore, the present findings underscore the utility and the translational potential of multimodal MR imaging and acute/subchronic memantine model in the search for novel disease-modifying treatments for schizophrenia.

Robust anti-arrhythmic efficacy of verapamil and flunarizine against dofetilide-induced TdP arrhythmias is based upon a shared and a different mode of action.

BACKGROUND AND PURPOSE: The high predisposition to Torsade de Pointes (TdP) in dogs with chronic AV-block (CAVB) is well documented. The anti-arrhythmic efficacy and mode of action of Ca(2+) channel antagonists, flunarizine and verapamil against TdP were investigated. EXPERIMENTAL APPROACH: Mongrel dogs with CAVB were selected based on the inducibility of TdP with dofetilide. The effects of flunarizine and verapamil were assessed after TdP and in different experiments to prevent dofetilide-induced TdP. Electrocardiogram and ventricular monophasic action potentials were recorded. Electrophysiological parameters and short-term variability of repolarization (STV) were determined. In vitro, flunarizine and verapamil were added to determine their effect on (i) dofetilide-induced early after depolarizations (EADs) in canine ventricular myocytes (VM); (ii) diastolic Ca(2+) sparks in RyR2(R4496+/+) mouse myocytes; and (iii) peak and late I(Na) in SCN5A-HEK 293 cells. KEY RESULTS: Dofetilide increased STV prior to TdP and in VM prior to EADs. Both flunarizine and verapamil completely suppressed TdP and reversed STV to baseline values. Complete prevention of TdP was achieved with both drugs, accompanied by the prevention of an increase in STV. Suppression of EADs was confirmed after flunarizine. Only flunarizine blocked late I(Na). Ca(2+) sparks were reduced with verapamil. CONCLUSIONS AND IMPLICATIONS: Robust anti-arrhythmic efficacy was seen with both Ca(2+) channel antagonists. Their divergent electrophysiological actions may be related to different additional effects of the two drugs.

Endogenous and exogenous ghrelin enhance the colonic and gastric manifestations of dextran sodium sulphate-induced colitis in mice.

Ghrelin is an important orexigenic peptide that not only exerts gastroprokinetic but also immunoregulatory effects. This study aimed to assess the role of endogenous and exogenous ghrelin in the pathogenesis of colitis and in the disturbances of gastric emptying and colonic contractility during this process. Dextran sodium sulphate colitis was induced for 5 days in (i) ghrelin(+/+) and ghrelin(-/-) mice and clinical and histological parameters were monitored at days 5, 10 and 26 and (ii) in Naval Medical Research Institute non-inbred Swiss (NMRI) mice treated with ghrelin (100 nmol kg(-1)) twice daily for 5 or 10 days. Neural contractility changes were measured in colonic smooth muscle strips, whereas gastric emptying was measured with the (14)C octanoic acid breath test. Inflammation increased ghrelin plasma levels. Body weight loss, histological damage, myeloperoxidase activity and IL-1beta levels were attenuated in ghrelin(-/-) mice. Whereas absence of ghrelin did not affect changes in colonic contractility, gastric emptying in the acute phase was accelerated in ghrelin(+/+) but not in ghrelin(-/-) mice. In agreement with the studies in ghrelin knockout mice, 10 days treatment of NMRI mice with exogenous ghrelin enhanced the clinical disease activity and promoted infiltration of neutrophils and colonic IL-1beta levels. Unexpectedly, ghrelin treatment decreased excitatory and inhibitory neural responses in the colon of healthy but not of inflamed NMRI mice. Endogenous ghrelin enhances the course of the inflammatory process and is involved in the disturbances of gastric emptying associated with colitis. Treatment with exogenous ghrelin aggravates colitis, thereby limiting the potential therapeutic properties of ghrelin during intestinal inflammation.

Determination of the source of increased serotonin (5-HT) concentrations in blood and peritoneal fluid of colic horses with compromised bowel.

REASONS FOR PERFORMING STUDY: Increased plasma (5-HT) concentrations are reported in horses predisposed to develop laminitis and after i.v. infusion of endotoxins. In the equine jejunum contractile 5-HT1A-like receptors show tachyphylaxia upon prolonged activation with 5-HT. Therefore, increased systemic 5-HT release in colic horses could play a possible role in the pathophysiology of ileus. OBJECTIVE: To investigate possible increased systemic release of 5-HT in colic horses with compromised bowel and to identify the source of 5-HT overload. METHODS: Concentrations of 5-HT were determined in plasma and peritoneal fluid (PF) of healthy horses (n = 10), strangulating small intestinal colic horses (n = 18), nonsurgical colic horses (n = 10) and cryptorchid stallions (n = 6). It was attempted to identify the source of 5-HT overload by comparing the blood and PF 5-HT concentrations within horses and by assessing the in vivo platelet activation through determination of the beta-thromboglobulin (beta-TG)/platelet factor 4 (PF4) ratio. RESULTS: All horses in the strangulating small intestinal colic group had plasma (P = 0.006) and PF (P = 0.01) 5-HT concentrations above those found in the control group. Plasma beta-TG/PF4 ratio in these horses exceeded 2 in all cases, indicating in vivo platelet activation. Concentrations of 5-HT in PF of colic horses with compromised bowel were significantly lower than the corresponding plasma concentrations (P = 0.005). POTENTIAL RELEVANCE: In horses with compromised bowel, significant amounts of 5-HT can be released into the systemic circulation, through massive release of platelet-stored 5-HT. 5-HT is a very potent proinflammatory, vasoconstrictive and immunomodulatory agent. In view of the rapid and prolonged tachyphylaxia, shown for the jejunal 5-HT1A-like receptors, this increased systemic 5-HT release could play a role in the pathophysiology of ileus in horses.

Effect of peripheral obestatin on food intake and gastric emptying in ghrelin-knockout mice.

BACKGROUND AND PURPOSE: The finding that obestatin, a peptide encoded by the ghrelin gene, opposes ghrelin's stimulatory effect on food intake and gastric emptying has been questioned. The effect of obestatin has been mostly investigated in fasted rodents, a condition associated with high blood levels of ghrelin which may mask the effect of obestatin. We therefore investigated the effect of obestatin on food intake, gastric emptying and gastric contractility in ghrelin knockout mice. EXPERIMENTAL APPROACH: The effect of obestatin on 6-h cumulative food intake was studied in fasted wildtype (ghrelin+/+) and ghrelin knockout (ghrelin-/-) mice. In both genotypes, the effect of obestatin and/or ghrelin was studied in vivo on gastric emptying measured with the (14)C-octanoic acid breath test and in vitro on neural responses elicited by electrical field stimulation (EFS) of fundic smooth muscle strips. KEY RESULTS: Administration of obestatin did not influence fasting-induced hyperphagia or gastric emptying in both genotypes. Injection of ghrelin accelerated gastric emptying in ghrelin+/+ and ghrelin-/- mice but the effect was not reversed by co-injection with obestatin. In fundic strips from ghrelin+/+ and ghrelin-/- mice, ghrelin increased EFS-induced contractions, but obestatin was without effect. However, co-administration with obestatin tended to reduce the excitatory effect of ghrelin in both genotypes. CONCLUSIONS AND IMPLICATIONS: In ghrelin-/- mice, obestatin failed to affect food intake and gastric motility. These results suggest that endogenous ghrelin does not mask the effect of obestatin and confirm that obestatin administered peripherally is not a major regulator of satiety signalling or gut motility.

Mapping slow waves and spikes in chronically instrumented conscious dogs: automated on-line electrogram analysis.

Myoelectric recordings from the gastrointestinal (GI) tract in conscious animals have been limited in duration and site. Recently, we have implanted 24 electrodes and obtained electrograms from these sites simultaneously (200 Hz sampling rate; 1.1 MB/min data stream). An automated electrogram analysis was developed to process this large amount of data. Myoelectrical recordings from the GI tract often consist of slow wave deflections followed by one or more action potentials (=spike deflections) in the same traces. To analyze these signals, a first module separates the signal into one containing only slow waves and a second one containing only spikes. The timings of these waveforms were then detected, in real time, for all 24 electrograms, in a separate slow wave detection module and a separate spike-detection module. Basic statistics such as timing and amplitudes and the number of spikes per slow wave were performed and displayed on-line. In summary, with this online analysis, it is possible to study for long periods of time and under various experimental conditions major components of gastrointestinal motility.

The effects of cholinergic stimulation and of nucleoside transport inhibition on spikes and spike patches in the canine small intestine in vivo.

Muscarinic agonists are known to enhance small intestinal contractions. A similar effect was also seen in pilot experiments with a nucleoside transport inhibitor. However, there is no information on their effects on the spatial pattern of action potential propagation. In an anesthetized, open-abdomen, canine (n=8) model, the propagation patterns of the slow wave and the ensuing action potentials (= spikes) were recorded before and during the i.v. administration of bethanechol or nucleoside transport inhibitor. Vehicle injections in 8 dogs served as controls. Electrical recordings were made using a 240-electrode array positioned on a 5-cm segment of the jejunum in situ. The incidence and the propagation of the action potentials were analyzed. Bethanechol dose-dependently increased the number of both longitudinally and circumferentially propagating spikes per slow wave. As during control, spikes in bethanechol propagated for a limited distance before terminating spontaneously, thereby exciting only a limited area (= patch). However, bethanechol did not change the size of the longitudinal spike patches (18.8+/-6.9 mm(2) at baseline and 25.0+/-18.6 mm(2) at 0.5 mg/kg) nor of the circular spike patches (90.0+/-41.2 mm(2) at baseline and 95.4+/-36.5 mm(2) at 0.5 mg/kg). The nucleoside transport inhibitor increased the occurrence of circular spikes in a step-wise fashion (>or=0.5 mg/kg). The size of the nucleoside transport inhibitor-induced circular spike patches (136.6+/-46.8 mm(2)) was larger than those during baseline or muscarinic stimulation. Muscarinic agonists stimulate small intestinal contractility by inducing more action potentials, which in turn would trigger increased calcium release from intracellular stores. On the other hand, nucleoside transport inhibition enhances contractility by increasing both the number and the size of the circular spike patches.

Mapping slow waves and spikes in chronically instrumented conscious dogs: implantation techniques and recordings.

Myoelectric recordings from the intestines in conscious animals have been limited to a few electrode sites with relatively large inter-electrode distances. The aim of this project was to increase the number of recording sites to allow high-resolution reconstruction of the propagation of myoelectrical signals. Sets of six unipolar electrodes, positioned in a 3x2 array, were constructed. A silver ring close to each set served as the reference electrodes. Inter-electrode distances varied from 4 to 8 mm. Electrode sets, to a maximum of 4, were implanted in various configurations allowing recording from 24 sites simultaneously. Four sets of 6 electrodes each were implanted successfully in 11 female Beagles. Implantation sites evaluated were the upper small intestine (n=10), the lower small intestine (n=4) and the stomach (n=3). The implants remained functional for 7.2 months (median; range 1.4-27.3 months). Recorded signals showed slow waves at regular intervals and spike potentials. In addition, when the sets were positioned close together, it was possible to re-construct the propagation of individual slow waves, to determine their direction of propagation and to calculate their propagation velocity. No signs or symptoms of interference with normal GI-function were observed in the tested animals. With this approach, it is possible to implant 24 extracellular electrodes on the serosal surface of the intestines without interfering with its normal physiology. This approach makes it possible to study the electrical activities of the GI system at high resolution in vivo in the conscious animal.

Electrical activity in the rectum of anaesthetized dogs.

There is limited data available on the electrical activity of the rectum. An in vivo canine model was developed to record 240 extracellular electrograms simultaneously from the serosal surface of the rectum thereby enabling an off-line reconstruction of the behaviour of the electrical signals. Serosal rectal electrical activity is characterized by brief bursts of action potentials (=spikes) with a frequency of 22 cycles min(-1). High-resolution mapping of these signals revealed predominant propagation of these spikes in the longitudinal direction, originating from any site and conducted for a limited time and length before stopping spontaneously, thereby describing a patch of activity. The dimension of the patches in the longitudinal direction was significantly longer than the transversal width (13.6 vs 2.4 mm; P < 0.001). Spike propagation could occur in the aboral (46% of cases), in the oral (34%) or in both directions (20%). A bolus of betanechol (i.v., 0.5 mg kg(-1)) increased the frequency of the spikes without affecting size, shape or orientation of the patches. As in other parts of the gastrointestinal system, individual spike propagation in the rectum is limited to small areas or patches. The contractile activity of the organ could possibly reflect this underlying pattern of electrical behaviour.

Spatial determination of successive spikes in the isolated cat duodenum.

In seven isolated segments of the feline duodenum, the timings of all spikes and the locations of all spike patches that occurred after 12-16 successive slow waves were analysed. Simultaneous recordings were performed during 1-min periods using 240 extracellular electrodes (24 x 10 array; interelectrode distance 2 mm) positioned onto the serosal surface. In all seven preparations, spikes always occurred during the first half of the slow wave cycle. From preparation to preparation, and within 1-min periods in each preparation, there was limited variation in the spike-spike intervals, in the times between the spikes and the preceding slow wave and in the number of spikes at each electrode site. In contrast, the number of electrode sites that recorded spikes and the number of spike patches both showed great variability between preparations and sometimes within a single preparation. In addition, the location of spikes and spike patches was not random but was significantly concentrated in certain areas, often located along the anti-mesenteric border, while other sites showed little or no spike activity. In conclusion, spikes and spike patches tend to occur significantly in some areas and not in others. This spatial heterogeneity will play a role in intestinal motility.

Adult rabbit cardiomyocytes undergo hibernation-like dedifferentiation when co-cultured with cardiac fibroblasts.

OBJECTIVES: Little is known about the causal factors which induce the typical structural changes accompanying cardiomyocyte dedifferentiation in vivo such as in chronic hibernating myocardium. For identifying important factors involved in cardiomyocyte dedifferentiation, as seen in chronic hibernation, an in vitro model mimicking those morphological changes, would be extremely helpful. METHODS: Adult rabbit cardiomyocytes were co-cultured with cardiac fibroblasts. The typical changes induced by this culturing paradigm were investigated using morphometry, electron microscopy and immunocytochemical analysis of several structural proteins, which were used as dedifferentiation markers, i.e., titin, desmin, cardiotin and alpha-smooth muscle actin. RESULTS: Close apposition of fibroblasts with adult rabbit cardiomyocytes induced hibernation-like dedifferentiation, similar to the typical changes seen in chronic hibernation in vivo. Both changes in ultrastructure and in the protein expression pattern of dedifferentiation markers as seen in chronic hibernating myocardium were seen in the co-cultured cardiomyocytes. CONCLUSION: Hibernation-like changes can be induced by co-culturing adult rabbit cardiomyocytes with fibroblasts. This cellular model can be a valuable tool in identifying and characterizing the pathways involved in the dedifferentiation phenotype in vivo, and already suggests that many of the structural changes accompanying dedifferentiation are not per se dependent on a decreased oxygen availability.

Changes in ultrastructural calcium distribution in goat atria during atrial fibrillation.

It has been suggested that Ca(2+)content of atrial cardiomyocytes is increased at the onset of atrial fibrillation (AF). Whether this phenomenon is transient is currently unknown. Therefore, in this study the time-related changes in Ca(2+)location in atrial myocytes from goats with chronic AF have been investigated. The distribution of calcium was assessed with the electron microscope using the cytochemical phosphate-pyroantimonate and oxalate-pyroantimonate methods in atrial biopsies from goats in sinus rhythm and goats with 1-16 weeks of burst-pacing-induced AF. In atrial myocytes from control goats in sinus rhythm, a normal Ca(2+)distribution was observed, with regular deposits along the sarcolemma (an average of 3.4 deposits per microm at a regular distance). The number of sarcolemma-bound Ca(2+)deposits substantially increased after 1 and 2 weeks of atrial fibrillation. After this period the amount of Ca(2+)precipitate decreased at 4 and 8 weeks, and became below control level at 16 weeks. A similar time-related redistribution of Ca(2+)occurred in mitochondria. Whereas mitochondria from control goats displayed very few Ca(2+)deposits (average 4.0 deposits per micro m(2)), their number markedly increased after 1 and 2 weeks of atrial fibrillation, which indicates cellular Ca(2+)overload. From 4 weeks, Ca(2+)deposits reached control levels and were below control level after 16 weeks of atrial fibrillation (2.5 deposits per microm(2)). Our findings are consistent with the previously observed Ca(2+)overload early after the onset of atrial fibrillation. The present study shows that this overload persists for at least 2 weeks, after which the cardiomyocytes apparently adapt to a new Ca(2+)homeostasis, thereby avoiding Ca(2+)overload. This protection against Ca(2+)overload co-occurs with dedifferentiation like cellular remodeling.

Calcium homeostasis in cardiomyocytes isolated from heat-shocked rats.

The cellular mechanism of heat shock-mediated cardioprotection is still under debate. Because heat pretreatment negatively affects the normoxic left ventricular contractile performance in vitro when the extracellular Ca2+ concentration ([Ca2+]o) is relatively low (0.65-1.25 mM), the intracellular Ca2+ homeostasis was studied in more detail in cardiomyocytes isolated from adult rats 24 h after heat stress (42 degrees C for 15 min) or anesthesia (control). Sensitivity to Ca2+ overload was assessed by exposure to veratridine (quiescent cells) or to [Ca2+]o ranging from 0.125 to 20 mM in quiescent and paced cardiomyocytes. The fraction of irreversibly hypercontracted cells was not different between groups. The fura-2 fluorescence ratio (I340/I380), which was used as a measure for cytoplasmic Ca2+ concentration ([Ca2+]i) in quiescent cells after exposure to [Ca2+]o (0.5-10 mM), was also not different between groups. Myofilament Ca2+ sensitivity was assessed in paced (0.5 Hz) cells by simultaneous measurement of [Ca2+]i transients and cell shortening. At stepwise increases of [Ca2+]o from 1 to 10 mM, these parameters were comparable between groups. The diastolic cell length shortened progressively and equally in both groups after increasing [Ca2+]o. However, within 2 min of return from 10 to 1 mM [Ca2+]o, cells from heat-shocked rats retained the same length, whereas cells from control rats contracted further (P = 0.05). These data suggest that heat stress improves relaxation after challenge with high [Ca2+]o.

Inhibition of sodium and calcium overload pathology in the myocardium: a new cytoprotective principle.

Ca2+ overload is known to play a major role in cell dysfunctioning in ischaemia/reperfusion and in cardiac glycoside intoxication. Suppression of Ca2+ overload or its consequences may therefore improve cellular function in these pathological conditions. Recent evidence suggests that Ca2+ overload occurs secondary to Na+ overload. Both depressed efflux and increased influx mechanisms have been mentioned as factors contributing to Na+ load. Prevention of this initial Na+ overload, without interfering with the normal Na+ current during the action potential, may therefore represent a novel pharmacological approach in the management of Ca2+ overload. The new cardioprotective drug R 56865 potently protects the heart against Ca2+ overload: ischaemia induced and ouabain induced arrhythmias and cell death are prevented in the absence of negative inotropism (no L-type Ca2+ channel blockade). At least three interactions at the cellular level may be held responsible for protection in these conditions. First, excessive Na+ entry into myocardial cells due to non-inactivating Na+ channels in depolarised cells is inhibited at concentrations that do not affect action potential configuration or contractile force. This leads to prevention of Na+ overload and subsequent Ca2+ overload and cell death. Second, R 56865 inhibits the transient inward current in Ca(2+)-(over)loaded cells, thus effectively preventing after-depolarisations and triggered propagated contractions. It has been proposed that R 56865, independent of its action on Na+ loading, might reduce oscillatory Ca2+ release from the intracellular Ca2+ stores, without interfering with the normal release mechanisms. Third, the drug attenuates K+ efflux in Na+ and Ca2+ loaded cells. In this way, R 56865 may contribute to prevention of action potential shortening and inhomogeneous repolarisation.(ABSTRACT TRUNCATED AT 250 WORDS)

Lysophosphatidylcholine-induced Ca(2+)-overload in isolated cardiomyocytes and effect of cytoprotective drugs.

It has been previously demonstrated that lysophosphatides accumulate rapidly in ischaemic tissue, and may play a key role in the genesis of ischaemia-reperfusion injury. The present study investigated the effects of exogenously added lysophosphatidylcholine (1-20 microM) on single isolated cardiomyocytes from adult rabbit hearts. Quiescent cells exposed to > or = 8 microM lysophosphatidylcholine dose-dependently displayed irreversible hypercontraction, whereas after 60 min at 3 microM lysophosphatidylcholine, most cells remained rod-shaped (87.2 +/- 2.0%, mean +/- S.E.M.). However, when combined with electrical field stimulation (1 Hz), exposure to 3 microM lysophosphatidylcholine resulted in irreversible hypercontracture of most cells after 60 min: only 27.5 +/- 7.5% of the cells remained rod-shaped. Contracture depended upon the presence of extracellular Ca2+, and coincided with a significant rise in the median intracellular free Ca2+ level from 72.2 to 352.1 nM (P = 0.0001), suggesting intracellular Ca(2+)-overload. Pretreatment with 10(-6) M flunarizine or R 56865 significantly reduced the fraction of damaged cells when exposed to 3 microM lysophosphatidylcholine and electrical stimulation: 78.3 +/- 12.2% and 56.3 +/- 13.1% respectively of the cells remained rod-shaped. No protection was observed when quiescent cells were exposed to 10 microM lysophosphatidylcholine. Cytochemical localization of Ca2+ showed that lysophosphatidylcholine induced a loss of sarcolemma-bound Ca2+ precipitate and an accumulation of Ca2+ clusters in mitochondria of damaged cells in a dose and time dependent way. These results suggest that lysophosphatidylcholine induces functional and structural damage (Ca(2+)-overload) in isolated cardiomyocytes and that this can be prevented by cytoprotective drugs.

Myocardial protection by R 56865: a new principle based on prevention of ion channel pathology.

Intracellular Ca2+ overload is considered to be the final pathway leading to cell death under pathological conditions. However, both the route of Ca2+ entry and the site of action of cardioprotective drugs remain obscure. This was investigated using isolated adult rat and rabbit cardiomyocytes exposed to the experimental pathological stimuli veratridine, singlet O2, lysophosphatidylcholine, and ouabain. Under these conditions, the majority of cells displayed irreversible hypercontraction as a consequence of intracellular Ca2+ overload. Nifedipine did not prevent Ca2+ overload, but tetrodotoxin (TTX) and reduction of the extracellular Na+ concentration protected against the above pathological stimuli. This strongly suggests that intracellular Ca2+ overload after exposure to these pathological stimuli may be mediated via fast Na+ channel dysfunction, causing excessive entry of Na+, followed by Ca2+ overload via Na(+)-Ca2+ exchange. The new cardioprotective drug R 56865 dose dependently prevented hypercontracture induced by each of these stimuli, suggesting that R 56865 may interfere with this modified Na+ channel that is in a way different from class I antiarrhythmic drugs. This is regarded as a new cardiac cytoprotective principle.

Preferential block of the veratridine-induced, non-inactivating Na+ current by R56865 in single cardiac Purkinje cells.

The effect of the cardioprotective agent R56865 on the veratridine (VTD)-modified sodium current was investigated in single rabbit cardiac Purkinje cells and ventricular myocytes. A steady, tetrodotoxin (TTX)-sensitive Na+ current (the non-inactivating Na+ current) was absent in most cells studied. In the presence of veratridine (15 x 10(-6) M) a non-inactivating Na+ current could be elicited at membrane potentials between -80 to +60 mV, with a maximum at about 0 mV. R56865 blocked this current effectively. The concentration for half maximal inhibition of the non-inactivating Na+ current was 2 x 10(-7) M. Blockade of this Na+ current by R56865 increased with depolarization. R56865 was much more effective in inhibiting the non-inactivating Na+ current than in inhibiting time-dependent Na+ currents elicited by short depolarizing pulses. The blocking effect of R56865 on the steady state influx of Na+ may contribute to cardioprotection in depolarized cells and in cells with modified Na+ channels as may occur during ischemia and reperfusion.

Nebivolol increases survival in cardiomyopathic hamsters with congestive heart failure.

The genetically inbred cardiomyopathic Syrian hamster provides a valuable model of congestive cardiomyopathy: myocytolytic necrosis at 30-50 days of age is followed by cardiac hypertrophy at 150-250 days, and finally by congestive failure and death at 250-350 days. Successful drug treatment has been reported in the prenecrotic stage, but not when started during congestive failure. The present study evaluated survival of the cardiomyopathic hamster treated with the new beta-adrenoceptor blocker nebivolol, which was initiated during congestive failure. Fifty animals (BIO82.62, either sex, age 200 days) were acclimated to an environmentally controlled room for 20 days, receiving food and water ad libitum; seven hamsters died, indicating development of congestive failure. The remaining animals were then randomly assigned to one of three groups: 15 animals received control food; food for the others was supplemented with nebivolol, yielding a daily intake of either 0.1 mg/kg (n = 14) or 1 mg/kg (n = 14). At the lower nebivolol dose, death rate was unaltered in comparison with controls. However, at 1 mg/kg, survival was markedly improved (p = 0.042). Nebivolol treatment, started during congestive failure, thus significantly delays mortality in the cardiomyopathic hamster.