Mitochondrial channelopathies in aging

Defects in ion channels (channelopathies) are increasingly found in a large spectrum of human pathologies including aging. Mutations in genes encoding ion channel proteins, which disrupt channel function, are the most commonly identified cause of channelopathies. Mutations in associated proteins, alterations in the expression of ion channels, or changes in the activity of non-mutated channel genes or associated proteins can also produce acquired channelopathies. Mitochondria, the powerhouse of the cells, are considered to be the most important cellular organelles to contribute to aging mainly because of their role in the production of reactive oxygen species in the initiation of apoptotic cell remodeling and in efficient ATP synthesis. During the past 50 years, multiple ion channels or transporters have been found in mitochondria, and the relationship between the activity of these channels and cellular aging, as well as the overall cellular biological function, has been intensively studied in a number of cell types and animal models. In this review, we discuss the better characterized mitochondrial ion channels whose dysfunction (mitochondrial channelopathies) may affect or accelerate the aging processes. These channels include the mitochondrial ATP-sensitive potassium channel (mitoK(ATP)), Ca(2+) transporters, voltage-dependent anion channel, and the mitochondrial permeability transition pore (mitoPTP).     

肥大心肌钠钙交换体的调控机制

心肌肥大是心脏对几乎所有引起心脏病变因素的一种适应性反应,虽然心肌肥大是心脏维持正常心输出量的一种有效代偿机制,但是持续的心肌肥大会导致失代偿而发生扩张性心肌病、心衰和猝死.是心血管病患者死亡的重要原因之一.     

Postmortem ion analysis of the myocardium in surgically correctible heart malformations

Commonly, children dying after operation on congenital cardiac malformation, show only minor histological changes in the myocardium. We have attempted to correlate the myocardial ion (Na+, K+, Ca2+) composition with the probable severity of hypoxia. Mean Ca2+ content has been plotted against the mean Na+/K+ ratio of every heart in the present study. A good correlation between these two parameters was demonstrated with full separation of controls and hearts with congenital malformations.     

Modulation of ion channels by reactive oxygen and nitrogen species: a pathophysiological role in brain aging?

An ever increasing number of reports shows the involvement of free radicals in the functional and structural changes occurring in the brain as a part of the "normal" aging process. Given that plasma membrane and intracellular ion channels play a critical role in maintaining intracellular ion homeostasis, which is crucial for neuronal cell survival, in the present review we have attempted to elaborate on the idea that functional changes in ion channel activity induced by reactive oxygen species (ROS) and reactive nitrogen species (RNS) might occur during the aging process. To this aim, we have reviewed the available literature and the data obtained in our laboratory on the ability of ROS and RNS to modify the activity of several plasma membrane and intracellular ion channels and transporters, in an attempt to correlate such changes with those occurring with the aging process. Particular emphasis is given to voltage-gated Na(+), Ca(2+), and K(+) channels, although second messenger-activated channels like Ca(2+)- and ATP-dependent K(+) channels, and intracellular channels controlling intracellular Ca(2+) storage and release will also be discussed. On the basis of the available data it is not yet possible to establish a strict correlation between the changes in neuronal electrophysiological properties induced by oxidative modification at the level of ion channels and the neurodegenerative process accompanying brain aging. However, an increasing amount of information suggests that the modulatory effects exerted by ROS and RNS on ion channel proteins might have a relevant role for neuronal cell survival or death. Obviously, more work is needed to establish the possible involvement of ion channels and of their modulation by ROS and RNS as important mechanisms for the aging process. Only when a more complete molecular picture of the aging process will be available, it will be possible to test the fascinating hypothesis that aging might be pharmacologically delayed by modulating ROS and RNS action on ion channels or the biochemical pathways involved in their modulation.     

Sodium/calcium exchange: its physiological implications.

The Na+/Ca2+ exchanger, an ion transport protein, is expressed in the plasma membrane (PM) of virtually all animal cells. It extrudes Ca2+ in parallel with the PM ATP-driven Ca2+ pump. As a reversible transporter, it also mediates Ca2+ entry in parallel with various ion channels. The energy for net Ca2+ transport by the Na+/Ca2+ exchanger and its direction depend on the Na+, Ca2+, and K+ gradients across the PM, the membrane potential, and the transport stoichiometry. In most cells, three Na+ are exchanged for one Ca2+. In vertebrate photoreceptors, some neurons, and certain other cells, K+ is transported in the same direction as Ca2+, with a coupling ratio of four Na+ to one Ca2+ plus one K+. The exchanger kinetics are affected by nontransported Ca2+, Na+, protons, ATP, and diverse other modulators. Five genes that code for the exchangers have been identified in mammals: three in the Na+/Ca2+ exchanger family (NCX1, NCX2, and NCX3) and two in the Na+/Ca2+ plus K+ family (NCKX1 and NCKX2). Genes homologous to NCX1 have been identified in frog, squid, lobster, and Drosophila. In mammals, alternatively spliced variants of NCX1 have been identified; dominant expression of these variants is cell type specific, which suggests that the variations are involved in targeting and/or functional differences. In cardiac myocytes, and probably other cell types, the exchanger serves a housekeeping role by maintaining a low intracellular Ca2+ concentration; its possible role in cardiac excitation-contraction coupling is controversial. Cellular increases in Na+ concentration lead to increases in Ca2+ concentration mediated by the Na+/Ca2+ exchanger; this is important in the therapeutic action of cardiotonic steroids like digitalis. Similarly, alterations of Na+ and Ca2+ apparently modulate basolateral K+ conductance in some epithelia, signaling in some special sense organs (e.g., photoreceptors and olfactory receptors) and Ca2+-dependent secretion in neurons and in many secretory cells. The juxtaposition of PM and sarco(endo)plasmic reticulum membranes may permit the PM Na+/Ca2+ exchanger to regulate sarco(endo)plasmic reticulum Ca2+ stores and influence cellular Ca2+ signaling.     

Genesis and regulation of the heart automaticity

The heart automaticity is a fundamental physiological function in higher organisms. The spontaneous activity is initiated by specialized populations of cardiac cells generating periodical electrical oscillations. The exact cascade of steps initiating the pacemaker cycle in automatic cells has not yet been entirely elucidated. Nevertheless, ion channels and intracellular Ca(2+) signaling are necessary for the proper setting of the pacemaker mechanism. Here, we review the current knowledge on the cellular mechanisms underlying the generation and regulation of cardiac automaticity. We discuss evidence on the functional role of different families of ion channels in cardiac pacemaking and review recent results obtained on genetically engineered mouse strains displaying dysfunction in heart automaticity. Beside ion channels, intracellular Ca(2+) release has been indicated as an important mechanism for promoting automaticity at rest as well as for acceleration of the heart rate under sympathetic nerve input. The potential links between the activity of ion channels and Ca(2+) release will be discussed with the aim to propose an integrated framework of the mechanism of automaticity.     

Local potassium signaling couples neuronal activity to vasodilation in the brain

The mechanisms by which active neurons, via astrocytes, rapidly signal intracerebral arterioles to dilate remain obscure. Here we show that modest elevation of extracellular potassium (K+) activated inward rectifier K+ (Kir) channels and caused membrane potential hyperpolarization in smooth muscle cells (SMCs) of intracerebral arterioles and, in cortical brain slices, induced Kir-dependent vasodilation and suppression of SMC intracellular calcium (Ca2+) oscillations. Neuronal activation induced a rapid (<2 s latency) vasodilation that was greatly reduced by Kir channel blockade and completely abrogated by concurrent cyclooxygenase inhibition. Astrocytic endfeet exhibited large-conductance, Ca2+-sensitive K+ (BK) channel currents that could be activated by neuronal stimulation. Blocking BK channels or ablating the gene encoding these channels prevented neuronally induced vasodilation and suppression of arteriolar SMC Ca2+, without affecting the astrocytic Ca2+ elevation. These results support the concept of intercellular K+ channel-to-K+ channel signaling, through which neuronal activity in the form of an astrocytic Ca2+ signal is decoded by astrocytic BK channels, which locally release K+ into the perivascular space to activate SMC Kir channels and cause vasodilation.     

Modulation of ion channels by somatostatin and acetylcholine.

Somatostatin and muscarinic acetylcholine receptors are similar as far as modulation of voltage-gated Ca2+ channels and anomalously rectifying K+ channels are concerned. Activation of either type of receptors induces inhibition of Ca2+ channels and activation of anomalous K+ channels without depending on intracellular cAMP. Somatostatin appears to act on the same receptor subtype for these two actions since somatostatin receptors are homogenous in pituitary cells (Srikant and Patel, 1982; Tran et al., 1985) where the peptide produces these two effects as well as an inhibition of adenylate cyclase. In the case of muscarinic receptors, however, it remains unclear whether the same subtype of receptors is involved in both inhibition of Ca2+ channels and activation of K+ channels. Activation of muscarinic receptors in hippocampal neurones evidently produces a cAMP-independent suppression of Ca2+ channel. In cardiac cells, however, muscarinic stimulation does not cause a cAMP-independent suppression of Ca2+ channels but does activate an anomalous rectifier. These findings do not necessarily mean that the muscarinic receptor involved in the inhibition of Ca2+ channels in hippocampal neurones is not of m2 type which is assumed to mediate the activation of anomalous K+ channels in cardiac cells. There is no evidence that cardiac Ca2+ channels are identical to hippocampal Ca2+ channels susceptible to muscarinic inhibition. In addition, a similar argument could be applied to G proteins coupling muscarinic receptors to Ca2+ channels in neurones and cardiac myocytes. In this regard, it should be noted that activation of GABAB receptors or mu and delta opiate receptors, an event known to inhibit adenylate cyclase activity through a PTX-sensitive Gi protein, also produces both inhibition of Ca2+ channels and activation of anomalous K channels in a cAMP-independent manner. This close correlation between inhibition of adenylate cyclase activity and cAMP-independent modulation of Ca2+ and K+ channels suggests the possible involvement of m2 subtype in the inhibition of Ca2+ channels in hippocampal neurones. Circumstantial evidence indicates that anomalous K+ channels are directly activated by alpha subunits of Gi, but not Go, proteins. The alpha subunit of Go protein seems to mediate inhibition of the Ca2+ channel, probably in a direct manner. The most striking difference between somatostatin and muscarinic receptors would be their opposite actions on the M channel. All the inhibitory receptors on the M channel, including m1 and m3 receptors, are known to stimulate PI hydrolysis via a PTX-insensitive G protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

When calcium turns arrhythmogenic: intracellular calcium handling during the development of hypertrophy and heart failure

Alterations of intracellular Ca2+ handling in hypertrophied myocardium have been proposed as a mechanism of ventricular tachyarrhythmias, which are a major cause of sudden death in patients with heart failure. In this review, alterations in intracellular Ca2+ handling and Ca2+ handling proteins in the development of myocardial hypertrophy and the transition to heart failure are discussed. The leading question is at what stage of hypertrophy or heart failure Ca2+ handling can turn arrhythmogenic. During the development of myocardial hypertrophy and the transition to failure, Ca2+ handling is progressively altered. Recordings of free myocyte Ca2+ concentrations during a cardiac cycle (Ca2+ transients) are prolonged early in the development of hypertrophy. However, resting (or diastolic) Ca2+ does not increase before end-stage heart failure has developed. These alterations are due to progressively defective Ca2+ uptake into the sarcoplasmic reticulum that seems to be caused by quantitative changes of gene expression of the Ca2+ ATPase of the sarcoplasmic reticulum. Increased expression and activity of the Na+/Ca2+ exchanger might compensate for this defective Ca2+ uptake, probably at the expense of increased arrhythmogenicity. When the Ca2+ handling proteins no longer efficiently counterbalance increasing intracellular Ca2+ - during stress conditions, resulting Ca2+ overload can lead to spontaneous intracellular Ca2+ oscillations, after depolarizations. Thus, after the transition to heart failure, Ca2+ overloaded sarcoplasmic reticulum, increasing resting intracellular Ca2+, and increased Na+/Ca2+ activity may all provoke afterdepolarizations, triggered activity, and finally, life-threatening ventricular arrhythmias. This increased susceptibility to ventricular arrhythmias in heart failure should not be treated with calcium antagonists.     

Molecular physiology of cardiac repolarization

The heart is a rhythmic electromechanical pump, the functioning of which depends on action potential generation and propagation, followed by relaxation and a period of refractoriness until the next impulse is generated. Myocardial action potentials reflect the sequential activation and inactivation of inward (Na(+) and Ca(2+)) and outward (K(+)) current carrying ion channels. In different regions of the heart, action potential waveforms are distinct, owing to differences in Na(+), Ca(2+), and K(+) channel expression, and these differences contribute to the normal, unidirectional propagation of activity and to the generation of normal cardiac rhythms. Changes in channel functioning, resulting from inherited or acquired disease, affect action potential repolarization and can lead to the generation of life-threatening arrhythmias. There is, therefore, considerable interest in understanding the mechanisms that control cardiac repolarization and rhythm generation. Electrophysiological studies have detailed the properties of the Na(+), Ca(2+), and K(+) currents that generate cardiac action potentials, and molecular cloning has revealed a large number of pore forming (alpha) and accessory (beta, delta, and gamma) subunits thought to contribute to the formation of these channels. Considerable progress has been made in defining the functional roles of the various channels and in identifying the alpha-subunits encoding these channels. Much less is known, however, about the functioning of channel accessory subunits and/or posttranslational processing of the channel proteins. It has also become clear that cardiac ion channels function as components of macromolecular complexes, comprising the alpha-subunits, one or more accessory subunit, and a variety of other regulatory proteins. In addition, these macromolecular channel protein complexes appear to interact with the actin cytoskeleton and/or the extracellular matrix, suggesting important functional links between channel complexes, as well as between cardiac structure and electrical functioning. Important areas of future research will be the identification of (all of) the molecular components of functional cardiac ion channels and delineation of the molecular mechanisms involved in regulating the expression and the functioning of these channels in the normal and the diseased myocardium.     

A brief history of trp: commentary and personal perspective

The history of the discovery of the transient receptor potential (TRP) cation channel superfamily began in 1969 with Cosens and Manning's isolation of the Drosophila transient receptor potential mutant, in which the photoreceptor response decays during continuous illumination. Early studies from Minke found that the elementary light response was unaffected in trp mutants, and he attributed the defect to an intermediate stage of phototransduction. Montell and Rubin cloned the trp gene in 1989: they recognised it as a transmembrane protein, but also concluded that it did not encode the light-sensitive channels. In 1991, Minke and Selinger proposed that TRP represented a Ca2+ transporter required for refilling intracellular InsP3-sensitive Ca2+ stores, in turn required for activation of the light-sensitive channels. Also in 1991, after developing a photoreceptor patch clamp preparation, I showed that the light-sensitive channels themselves were highly permeable to Ca2+, questioning the need for such a dedicated Ca2+ transporter. In 1992, in collaboration with Minke, I resolved this paradox by showing there were two classes of light-sensitive channels, one highly Ca2+ permeable and eliminated in trp mutants. This represented the first and compelling evidence that TRP represented a light-sensitive channel and was supported by the cloning of the second light-sensitive channel, TRPL, by Kelly's lab. Three years later, in 1995, the labs of Montell and Birnbaumer independently cloned TRPC1, the first of 29 vertebrate TRP isoforms distributed amongst seven subfamilies.     

Regulation of cloned, Ca2+-activated K+ channels by cell volume changes

Ca2+-activated K+ channels of big (hBK), intermediate (hIK) or small (rSK3) conductance were co-expressed with aquaporin 1 (AQP1) in Xenopus laevis oocytes. hBK channels were activated by depolarization, whereas hIK and rSK3 channels were activated by direct injection of Ca2+ or Cd2+ into the oocyte cytoplasm, before the oocytes were subjected to hyperosmolar or hypoosmolar (+/-50 mOsm mannitol) challenges. In all cases, the oocytes responded rapidly to the osmotic changes with shrinkage or swelling and the effects on the K+ currents were measured. hIK and rSK3 currents were highly sensitive to volume changes and increased immediately to 178% (hIK) or 165% (rSK3) of control in response to swelling and decreased to 64% (hIK) or 61% (rSK3) of control after shrinkage. These responses were dependent on the channels being pre-activated and were almost totally abolished after injection of cytochalasin D into the oocyte cytoplasm (final concentration: 1 microM). In contrast, hBK channels showed only a minor sensitivity to volume changes; the hBK channel activity decreased approximately 20% after swelling and increased approximately 20% after shrinkage. The opposite effects of volume changes on hIK/rSK3 and hBK channels suggest that the significant stimulation of hIK and rSK3 channels during swelling is not mediated by changes in intracellular Ca2+, but rather through interactions with the cytoskeleton, provided that a sufficient basal concentration of intracellular Ca2+ or Cd2+ is present.     

TRPC5 is a regulator of hippocampal neurite length and growth cone morphology

Growth cone motility is regulated by both fast voltage-dependent Ca2+ channels and by unknown receptor-operated Ca2+ entry mechanisms. Transient receptor potential (TRP) homomeric TRPC5 ion channels are receptor-operated, Ca2+-permeable channels predominantly expressed in the brain. Here we show that TRPC5 is expressed in growth cones of young rat hippocampal neurons. Our results indicate that TRPC5 channel subunits interact with the growth cone-enriched protein stathmin 2, are packaged into vesicles and are carried to newly forming growth cones and synapses. Once in the growth cone, TRPC5 channels regulate neurite extension and growth-cone morphology. Dominant-negative TRPC5 expression allowed significantly longer neurites and filopodia to form. We conclude that TRPC5 channels are important components of the mechanism controlling neurite extension and growth cone morphology.     

Identical unitary current amplitude and Ca(2+) block of cardiac Na channel before and during beta-adrenergic stimulation

We examined the possibility of Ca(2+) permeation through cardiac Na channels ("slip mode conductance") by an analysis of the voltage-dependent block of Na channels by Ca(2+). A Ca(2+) block of Na channels was evident in rat and guinea pig ventricular myocytes during cell-attached single channel recordings with a physiological ionic environment (140 mM Na(+) and 1 to 10 mM Ca(2+) in the pipette solution). Increasing external Ca(2+) concentration ([Ca(2+)](o)) in the pipette solution reduced the unitary current amplitude predominantly at negative potentials. With [Ca(2+)](o) > 1 mM, unitary current amplitude did not increase at potentials negative to -40 mV in spite of augmented driving forces. The application of 5 microM isoproterenol potentiated the single channel activity elicited by depolarizing pulses from the holding potential of -120 mV, indicating that the channels in the patch under examination were modified by protein kinase A (PKA) stimulation. Increased activity was also confirmed with veratridine-modified Na channels, where channel openings were markedly prolonged. In either case, isoproterenol-induced potentiation neither reduced nor altered the properties of Ca(2+) block of cardiac Na channels, as evidenced by the stable unitary current amplitudes at potential levels from -60 to -20 mV. These results indicate that interactions among Na(+), Ca(2+), and the channel molecule were not modified with respect to permeation properties. They therefore argue against the "slip mode" concept of classical cardiac Na channel if a general concept of ion permeation through "multi-ion pores" is applicable to determine the ionic selectivity of Na channels.     

Gating, selectivity and blockage of single channels activated by cyclic GMP in retinal rods of the tiger salamander.

1. Patches in the inside-out configuration were excised from the membrane of outer and inner segments of the larval tiger salamander, Ambystoma tigrinum. The current flowing through single channels opened by cyclic GMP was studied with the voltage clamp technique. 2. Amplitude histograms of current recordings from patches containing only one flickering channel, excised from the inner segment and in the presence of 100 microM cyclic GMP, could be fitted by a theoretical scheme in which the single channel conductance was at least 55 pS at +40 mV and at least 45 pS at -40 mV. The mean open time was no longer than the time constant of our recording system, about 35 microseconds. Similar results were obtained by analysis of the amplitude histograms of patches from the outer segment containing many channels, and in the presence of 1-5 microM cyclic GMP. 3. In membrane patches excised from the outer segment, reducing the temperature from 24 to 8 degrees C did not reduce the flickering, but changed the amplitude histograms of current fluctuations activated by 1 microM cyclic GMP in a way consistent with a decrease of 50% in the single channel conductance and a decrease of 50% in the open probability. 4. In the presence of 1 microM cyclic GMP at +60 mV, when Na+ was replaced by NH4+ or K+, brief outward current transients flowing through single channels were observed. When Na+ was replaced with Li+, Rb+ or Cs+, current transients were very small. 5. The shape of the power spectrum of current fluctuations induced by 1 microM cyclic GMP at +60 mV did not change when the permeating ion was Na+, K+ or NH4+. Analysis of the amplitude histogram did not show any effect of the tested monovalent cations on the open probability or on channel gating. At +60 mV, the estimated single channel currents were at least 4, 2.8 and 2 pA for NH4+, Na+ and K+ respectively. 6. The addition of 0.5 or 1 mM Ca2+ to the medium bathing the cytoplasmic side of the membrane greatly reduced the frequency of openings, but single channel activity could still be observed. The blocking effect of 1 mM Ca2+ on the channel activity induced by 2 microM cyclic GMP could be counterbalanced by increasing the cyclic GMP concentration. The addition of 0.5 or 1 mM Ca2+ did not change the shape of power spectra obtained at membrane voltages between -100 and +100 mV.(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional roles of ion channels in lymphocytes.

The application of patch-clamp and video-imaging techniques has enabled responses of lymphocytes to be examined at the level of individual cells. Eight distinct types of ion channel activity have been revealed in T lymphocytes. A variety of external stimuli shifts the pattern of channel activity from the resting state, which is dominated by voltage-gated K+ channels. Channel regulation is achieved both by acute modulation and by altered expression in the membrane. During mitogen stimulation, Ca2+ channels and Ca(2+)-activated K+ channels become active and appear to underlie Ca2+ oscillations. These acute changes are followed by increased expression of voltage-gated K+ channels. In response to osmotic challenge in hypotonic media, cell swelling initiates activation of Cl- channels, which may, in turn, indirectly activate K+ channels and trigger a regulatory decrease in cell volume.     

Mechanism of increased open probability by a mutation of the BK channel

A missense mutation (D434G) has recently been identified in the alpha subunit of the human large-conductance calcium-activated potassium (BK) channel. Interestingly, although the mutation causes an increase in open probability, individuals that carry the mutation have epilepsy and/or paroxysmal dyskinesia, disorders of increased brain excitability. To define the mechanisms of the mutation, we have used recordings from single channels and measurement of macroscopic conductances to examine the gating of the alpha subunit, modulation by the regulatory beta4 subunit, and the effect of Mg2+ on channel properties. Although there was relatively little difference in open dwell times for the mutant and wild-type alpha subunits, the mutant channel spent less time in a long-lived closed state. Co-expression of the beta4 subunit caused the wild-type channel to be less sensitive to calcium at low Ca2+ concentrations but had little effect on the mutant channel, further accentuating the difference between the wild-type and the mutant channels. In the absence of Ca2+, there was no difference in Mg2+ or voltage sensitivity of the mutant and wild-type channels, whereas in 2 mM Ca2+, the mutant channel had greater open probability at every Mg2+ concentration tested. We conclude that the D434G mutation modifies Ca2+ -dependent activation, but we find no evidence of a direct effect on activation by Mg2+ or voltage. The resulting enhancement of BK channel function leads to an increase in brain excitability, possibly due to more rapid repolarization of action potentials.     

Syntaxin-1A binds to and modulates the Slo calcium-activated potassium channel via an interaction that excludes syntaxin binding to calcium channels

From its position in presynaptic nerve terminals, the large conductance Ca(2+)-activated K+ channel, Slo, regulates neurotransmitter release. Several other ion channels known to control neurotransmitter release have been implicated in physical interactions with the neurotransmitter release machinery. For example, the Ca(v)2.2 (N-type) Ca2+ channel binds to and is modulated by syntaxin-1A and SNAP-25. Furthermore, a close juxtaposition of Slo and Ca(v)2.2 is presumed to be necessary for functional coupling between the two channels, which has been shown in neurons. We report that Slo exhibits a strong association with syntaxin-1A. Robust co-immunoprecipitation of Slo and syntaxin-1A occurs from transfected HEK293 cells as well as from brain. However, despite this strong interaction and the known association between syntaxin-1A and the II-III loop of Ca(v)2.2, these three proteins do not co-immunoprecipitate in a trimeric complex from transfected HEK293 cells. The Slo-syntaxin-1A co-immunoprecipitation is not significantly influenced by [Ca2+]. Multiple relatively weak interactions may sum up to a tight physical coupling of full-length Slo with syntaxin-1A: the C-terminal tail and the S0-S1 loop of Slo each co-immunoprecipitate with syntaxin-1A. The presence of syntaxin-1A leads to reduced Slo channel activity due to an increased V(1/2) for activation in 100 nM, 1 muM, and 10 microM Ca2+, reduced voltage-sensitivity in 1 microM Ca2+, and slower rates of activation in 10 microM Ca2+. Potential physiological consequences of the interaction between Slo and syntaxin-1A include enhanced excitability through modulation of Slo channel activity and reduced neurotransmitter release due to disruption of syntaxin-1A binding to the Ca(v)2.2 II-III loop.     

Contractile dysfunction of atrial myocardium from endotoxin-shocked guinea pigs

Atrial muscle isolated from guinea pigs subjected to Escherichia coli endotoxin shock was used to study the myocardial changes associated with this experimental disease state. Isometric contractile tension and its first derivative (dT/dt) consistently were depressed by about 45% in muscle from the shock group (P less than 0.001), but contraction time intervals of the shock tissues were not significantly altered. The inotropic deficit of shock was completely antagonized by high concentrations of Ca2+ (greater than 4.5 mM). However, the maximal positive inotropic response to increased frequency of stimulation (0.1-2.2 Hz) only partially antagonized shock-induced cardiac depression. Heart muscle from shocked animals exhibited increased sensitivity to the negative inotropic effects of Mn2+, low Ca2+, and gentamicin; recovery from the depressant actions of these agents was prolonged 3.6- to 4.8-fold in shock. However, the negative inotropic potency of slow Ca2+ channel blockers, D 600 and nifedipine, was unaffected by shock. Similarly, studies with an isoproterenol-activated slow Ca2+ channel technique demonstrated equivalent inotropic responses of shock and control heart muscle. Present data provide evidence for a disruption of myocardial Ca2+ metabolism associated with endotoxin-induced inotropic depression of the heart but suggest that slow Ca2+ channels of the sarcolemma remain functional in this disease state.     

Met-enkephalin-induced mobilization of intracellular Ca2+ in rat intracardiac ganglion neurones.

The effects of Met-enkephalin on Ca2+-dependent K+ channel activity were investigated using the cell-attached patch recording technique on isolated parasympathetic neurones of rat intracardiac ganglia. Large-conductance, Ca2+-dependent K+ channels (BK(Ca)) were examined as an assay of agonist-induced changes in the intracellular free calcium ion concentration ([Ca2+]i). These BK(Ca) channels had a conductance of approximately 200 pS and were charybdotoxin- and voltage-sensitive. Caffeine (5 mM), used as a control, evoked a large increase in BK(Ca) channel activity, which was inhibited by 10 microM ryanodine. Met-enkephalin (10 microM) evoked a similar increase in BK(Ca) channel activity, which was dependent on the presence of extracellular Ca2+ and inhibited by either ryanodine (10 microM) or naloxone (1 microM). In Fura-2-loaded intracardiac neurones, Met-enkephalin evoked a transient increase in [Ca2+]i. Met-enkephalin-induced mobilization of intracellular Ca+ may play a role in neuronal excitability and firing behaviour in mammalian intracardiac ganglia.