The small neurotoxin apamin blocks not only small conductance Ca2+ activated K+ channels (SK type) but also the voltage dependent Kv1.3 channel.

Apamin is frequently used as a specific blocker of small-conductance Ca2+-activated (SK type) K+ channels. Here we show that the small neurotoxin is not as specific as anticipated. It is also a high-affinity inhibitor with an IC50 of 13 nM of the Kv1.3 channel; it blocks the latter with potency similar to the Kv1.3 blocker PAP-1. Since SK type channels and Kv1.3 channels are frequently coexpressed in different tissues such as cells of the immune system, apamin must be used with caution as a pharmacological tool.

Apamin-Sensitive Small Conductance Calcium-Activated Potassium Channels were Negatively Regulated by Captopril in Volume-Overload Heart Failure Rats.

In heart failure (HF), the malignant arrhythmias occur frequently; a study demonstrated that upregulation of I KAS resulted in recurrent spontaneous ventricular fibrillation in HF. However, the regulation of SK channels was poorly understood. The activation of SK channels depended on [Ca(2+)]i and PP2A; studies suggested that angiotensin II can regulate them. So, we hypothesized that in HF, the excess of angiotensin may regulate the SK channels and result in the remodeling of SK channels. To test the hypothesis, we used volume-overload-induced HF rat model, treated with captopril, performed whole-cell patch clamp to record apamin-sensitive currents (I KAS), and I-V curve was studied. The sensitivity of I KAS to [Ca(2+)]i was also explored by setting various [Ca(2+)]i (10, 100, 500, 900, 1000, and 10,000 nM), and the steady-state Ca(2+) response of I KAS was attained and performed Hill fitting with the equation (y = 1/[1 + (EC50/x) (n) ]). Immunofluorescent staining, real-time PCR, Western blot were also carried out to furtherly investigate the underlying molecular mechanisms of the regulation. Captopril significantly decreased the mean density of I KAS when [Ca(2+)]i was 500, 900, 1000, and 10000 nM. The Hill fitting showed significantly different EC50 values and the Hill coefficients and showed captopril significantly shifted rightward the steady-state Ca(2+) response of I KAS. The results of real-time PCR and Western blot demonstrated captopril decreased the mRNA and protein expression of SK3 channels. Captopril significantly downregulated the sensitivity of SK channels to [Ca(2+)]i and the SK3 channels expression in HF, and reversed the SK channels remodeling.

Sex-specific IKAS activation in rabbit ventricles with drug-induced QT prolongation.

BACKGROUND: Female sex is a known risk factor for drug-induced long QT syndrome (diLQTS). We recently demonstrated a sex difference in apamin-sensitive small-conductance Ca2+-activated K+ current (IKAS) activation during ß-adrenergic stimulation. OBJECTIVE: The purpose of this study was to test the hypothesis that there is a sex difference in IKAS in the rabbit models of diLQTS. METHODS: We evaluated the sex difference in ventricular repolarization in 15 male and 22 female Langendorff-perfused rabbit hearts with optical mapping techniques during atrial pacing. HMR1556 (slowly activating delayed rectifier K+ current [IKs] blocker), E4031 (rapidly activating delayed rectifier K+ current [IKr] blocker) and sea anemone toxin (ATX-II, late Na+ current [INaL] activator) were used to simulate types 1-3 long QT syndrome, respectively. Apamin, an IKAS blocker, was then added to determine the magnitude of further QT prolongation. RESULTS: HMR1556, E4031, and ATX-II led to the prolongation of action potential duration at 80% repolarization (APD80) in both male and female ventricles at pacing cycle lengths of 300-400 ms. Apamin further prolonged APD80 (pacing cycle length 350 ms) from 187.8±4.3 to 206.9±7.1 (P=.014) in HMR1556-treated, from 209.9±7.8 to 224.9±7.8 (P=.003) in E4031-treated, and from 174.3±3.3 to 188.1±3.0 (P=.0002) in ATX-II-treated female hearts. Apamin did not further prolong the APD80 in male hearts. The Cai transient duration (CaiTD) was significantly longer in diLQTS than baseline but without sex differences. Apamin did not change CaiTD. CONCLUSION: We conclude that IKAS is abundantly increased in female but not in male ventricles with diLQTS. Increased IKAS helps preserve the repolarization reserve in female ventricles treated with IKs and IKr blockers or INaL activators.

Changes in SK channel expression in the basal ganglia after partial nigrostriatal dopamine lesions in rats: Functional consequences.

Parkinson's disease (PD) is a progressive neurodegenerative disease originating from the loss of dopamine (DA) neurons in the substantia nigra pars compacta (SNC). The small-conductance calcium-activated potassium (SK) channels play an essential role in the regulation of midbrain DA neuron activity patterns, as well as excitability of other types of neurons of the basal ganglia. We therefore questioned whether the SK channel expression in the basal ganglia is modified in parkinsonian rats and how this could impact behavioral performance in a reaction time task. We used a rat model of early PD in which the progressive nigrostriatal DA degeneration was produced by bilateral infusions of 6-hydroxydopamine (6-OHDA) into the striatum. In situ hybridization of SK2 and SK3 mRNA and binding of iodinated apamin (SK2/SK3 blocker) were performed at 1, 8 or 21 days postsurgery in sham and 6-OHDA lesion groups. A significant decrease of SK3 channel expression was found in the SNC of lesioned animals at the three time points, with no change of SK2 channel expression. Interestingly, an upregulation of SK2 mRNA and apamin binding was found in the subthalamic nucleus (STN) at 21 days postlesion. These results were confirmed using quantitative real time polymerase chain reaction (qRT-PCR) approach. Functionally, the local infusion of apamin into the STN of parkinsonian rats enhanced the akinetic deficits produced by nigrostriatal DA lesions in a reaction time task while apamin infusion into the SNC had an opposite effect. These effects disappear when the positive modulator of SK channels (CyPPA) is co-administered with apamin. These findings suggest that an upregulation of SK2 channels in the STN may underlie the physiological adjustment to increased subthalamic excitability following partial DA denervation.

Apamin-induced alterations in J774 1. 6 macrophage metabolism / [Alterações induzidas por apamina no metabolismo de macrófagos J774 1. 6]

Among the immune system cells, macrophages have an important role. Apamin, a bee venom constituent, is important in the defense of these insects. Thus, we aimed to evaluate the metabolism of J774 1.6 macrophage cell line when exposed to isolated and purified apamin, using cytotoxicity tests by MTT reduction and analysis by flow cytometry (apoptosis / necrosis, production of reactive oxygen species (ROS), membranous lipoperoxidation (LPO), electrical potential of the mitochondrial membrane (mMP) and DNA fragmentation). None of the tested concentrations (10 to 100µg/mL) were cytotoxic according to MTT reductions. Apoptosis rates decreased at concentrations of 2.5, 5.0, and 10.0µg/mL (P<0.05), while necrosis rates increased (P<0.05). However, rates of healthy cells at the highest tested concentration (10µg/mL) did not differ from control (P>0.05). Apamin did not alter ROS, LPO, or DNA fragmentation. Therefore, all analyzed concentrations (1.25 to 10µg/mL) decreased mMP. Such decrease in apoptosis might be due to a suppression of mitochondrial pro-apoptotic messengers, as this peptide causes no oxidative stress, lipid peroxidation, and DNA damage. Highly sensitive techniques are majorly important for proper interpretation of cellular toxicity mechanisms, combined with routine laboratory methods.(AU)

Das células do sistema imunológico, macrófagos desempenham um papel fundamental. Apamina, constituinte do veneno de abelhas, é importante na defesa destas. Objetivou-se avaliar o metabolismo da linhagem de macrófagos J774 1.6 expostos à apamina isolada e purificada, avaliando-se citotoxicidade por redução de MTT e análise por citometria de fluxo (apoptose / necrose, produção de espécies reativas de oxigênio (EROs), lipoperoxidação membranosa (LPO), potencial elétrico da membrana mitocondrial (MMP) e fragmentação do DNA). Nenhuma concentração testada (10 a 100µg / mL) foi citotóxica. As taxas de apoptose diminuíram nas concentrações 2,5, 5,0 e 10,0µg / mL (P<0,05), enquanto as de necrose aumentaram (P<0,05). Entretanto, as taxas de células saudáveis na maior concentração testada (10µg / mL) não diferiram do controle (P>0,05). A apamina não alterou as ERO, a LPO nem a fragmentação do DNA. Portanto, todas as concentrações analisadas (1,25 a 10µg / mL) diminuíram a mMP. Tal diminuição na apoptose pode ser por uma supressão de mensageiros pró-apoptóticos mitocondriais, já que este peptídeo não causa estresse oxidativo, peroxidação lipídica nem dano ao DNA. Técnicas altamente sensíveis são importantes para adequada interpretação dos mecanismos de citotoxicidade.(AU)

KCNN Genes that Encode Small-Conductance Ca2+-Activated K+ Channels Influence Alcohol and Drug Addiction.

Small-conductance Ca(2+)-activated K(+) (KCa2) channels control neuronal excitability and synaptic plasticity, and have been implicated in substance abuse. However, it is unknown if genes that encode KCa2 channels (KCNN1-3) influence alcohol and drug addiction. In the present study, an integrative functional genomics approach shows that genetic datasets for alcohol, nicotine, and illicit drugs contain the family of KCNN genes. Alcohol preference and dependence QTLs contain KCNN2 and KCNN3, and Kcnn3 transcript levels in the nucleus accumbens (NAc) of genetically diverse BXD strains of mice predicted voluntary alcohol consumption. Transcript levels of Kcnn3 in the NAc negatively correlated with alcohol intake levels in BXD strains, and alcohol dependence enhanced the strength of this association. Microinjections of the KCa2 channel inhibitor apamin into the NAc increased alcohol intake in control C57BL/6J mice, while spontaneous seizures developed in alcohol-dependent mice following apamin injection. Consistent with this finding, alcohol dependence enhanced the intrinsic excitability of medium spiny neurons in the NAc core and reduced the function and protein expression of KCa2 channels in the NAc. Altogether, these data implicate the family of KCNN genes in alcohol, nicotine, and drug addiction, and identify KCNN3 as a mediator of voluntary and excessive alcohol consumption. KCa2.3 channels represent a promising novel target in the pharmacogenetic treatment of alcohol and drug addiction.

Identification of two toxins from scorpion (Leiurus quinquestriatus) venom which block distinct classes of calcium-activated potassium channel.

Two polypeptide toxins from scorpion (Leiurus quinquestriatus) venom which block distinct classes of calcium-activated potassium channels have been identified and partially purified. One toxin, at 50-100 ng/ml, blocks apamin-sensitive potassium fluxes in hepatocytes and inhibits [125I]monoiodoapamin binding. The other, more basic, toxin blocks apamin-insensitive potassium fluxes in erythrocytes at 200 ng/ml and, to our knowledge, is the first toxin shown to block the erythrocyte calcium-activated potassium channel with high affinity. The possible co-identity of this latter toxin with charybdotoxin is discussed.

Quantitative autoradiographic mapping in rat brain of the receptor of apamin, a polypeptide toxin specific for one class of Ca2+-dependent K+ channels.

The localization of the receptor for apamin, a specific toxin for one class of sensitive Ca2+-dependent K+ channel, was studied in rat brain using an in vitro autoradiographic technique. Radiolabeled monoiodoapamin binds specifically to rat brain sections with a high affinity (Kd = 25 pM) to a single class of sites. Autoradiograms demonstrated a very heterogeneous distribution of the apamin receptor throughout the brain. Very high grain densities were localized on the habenula, lateral septum, supraoptic and suprachiasmatic nuclei. Areas containing high levels of apamin binding sites included anterior olfactory nucleus, stratum oriens of hippocampus, pontine nuclei and granular layer of the cerebellar cortex and inferior olive. The thalamus, some nuclei of hypothalamus, hippocampus, tegmental area, red and oculomotor nuclei, vestibular nuclei and superior olive, among others, presented intermediate grain densities. In the other main areas, in particular basal ganglia, raphe, low to very low levels of apamin binding sites have been observed.

Neurotoxicity of apamin and MCD peptide upon central application.

Besides apamin, the structurally related MCD peptide (mast cell degranulating peptide; peptide 401) is another centrally acting peptide from bee venom. In contrast to apamin, it is hardly neurotoxic upon intravenous injection in mice. Following intraventricular injection, as little as 0.3 microgram/animal produce convulsions and respiratory arrest in mice. The clinical picture differs from that elicited by apamin, and apamin is about 10 times more potent than MCD peptide when given intraventricularly. Apamin and MCD peptide injected into the spinal cord of rats in nanogram amounts, produce circumscript hyperexcitation lasting more than one day, however with complete recovery following sublethal doses. Local apamin poisoning differs from local tetanus (elicited by the same way) by its faster time course.

The effects of apamin in rats with pretrigeminal or high spinal transsection of the central nervous system.

Rats were injected in one lateral cerebral ventricle (i.c.v.) with apamin (100 ng per animal). The resulting desynchronisation pattern in the electrocorticogram (ECoG) and the symptoms of poisoning were monitored before and after transsection at different levels, and following morphine. Apamin acts primarily on the brain stem and spinal cord, i.e. structures possessing a sensory input, and then indirectly on the higher integrating systems. There is no general parallelism between receptor density and locus of action.

Compared toxicity of the potassium channel blockers, apamin and dendrotoxin.

The central toxicities of two potassium ion channel blockers, apamin and alpha-dendrotoxin (DTx), have been compared. Both apamin and dendrotoxin injected intracerebroventricularly produced signs of poisoning, including tremor and ataxia; however, only DTx produced changes in brain electrical activity, with high voltage spikes and epileptiform activity and subsequent brain damage. DTx, but not apamin, increased the amplitude of evoked field potentials and caused repetitive firing of neurones in hippocampal slices. Signs of poisoning following peripheral (intraperitoneal) administration of apamin were similar to those following central administration, including dramatic haemorrhagic effects on the lungs of decedent animals. These results are consistent with dendrotoxin being a centrally-active neurotoxin producing epileptiform activity and brain damage, whilst apamin produces its most significant pathology in the lung, possibly involving a neurogenic mechanism.

Acetylcholine response in guinea pig outer hair cells. II. Activation of a small conductance Ca(2+)-activated K+ channel.

The type of K+ channel involved in the acetylcholine (ACh) evoked response (Ksub; sub stands for suberyldicholine) in guinea pig outer hair cells (OHCs) is still uncertain. The present study tests the hypotheses that Ksub is one of the following: a big conductance Ca(2+)-dependent K+ channel (BK), a small conductance Ca(2+)-dependent K+ channel (SK), a KA type of K+ channel, or a Kn type of K+ channel. Patch-clamp technique in the whole-cell mode was used to record from single guinea pig OHCs. ACh (100 microM) was applied to voltage-clamped OHCs and the ACh-induced currents (IACh) were measured. Charybdotoxin (100 nM) had no effect on IACh, while apamin (1 microM) blocked more than 90% of IACh. Lowering the external Ca2+ concentration caused a hyperpolarizing shift of the IACh monitored as a function of the prepulse voltage. Increasing internal Mg2+ (Mgi2+) concentration caused a reduction in the outward IACh without affecting the inward IACh. The Ksub channel was found to be permeable to Cs+. In Cs+ solutions, IACh was 45% of the IACh in K+ solutions. The block of IACh by apamin, the dependence on extracellular Ca2+, the incomplete block of IACh by Cs+, and the ACh-induced Cs+ currents favor the hypothesis that Ksub belongs to the SK type of channels. An ionotropic/nicotinic nature of the ACh mechanism of action is favored. It is suggested that, in vivo, the amplitude of the ACh-induced hyperpolarization may depend on the Ca2+/Mg2+ ratio inside and outside the cell.

Functional reduction of SK3-mediated currents precedes AMPA-receptor-mediated excitotoxicity in dopaminergic neurons.

In primary cultures of mesencephalon small-conductance calcium-activated potassium channels (SK) are expressed in dopaminergic neurons. We characterized SK-mediated currents (I(SK)) in this system and evaluated their role on homeostasis against excitotoxicity. I(SK) amplitude was reduced by the glutamatergic agonist AMPA through a reduction in SK channel number in the membrane. Blockade of I(SK) for 12 h with apamin or NS8593 reduced the number of dopaminergic neurons in a concentration-dependent manner. The effect of apamin was not additive to AMPA toxicity. On the other hand, two I(SK) agonists, 1-EBIO and CyPPA, caused a significant reduction of spontaneous loss of dopaminergic neurons. 1-EBIO reversed the effects of both AMPA and apamin as well. Thus, I(SK) influences survival and differentiation of dopaminergic neurons in vitro, and is part of protective homeostatic responses, participating in a rapidly acting negative feedback loop coupling calcium levels, neuron excitability and cellular defenses. This article is part of a Special Issue entitled 'Trends in neuropharmacology: in memory of Erminio Costa'.

Effect of nicotine on neuromuscular transmission in mouse motor synapses.

Nicotine (10 nM) inhibits rhythmic activity of the neuromuscular synapse in mice. This effect was prevented by alpha-cobratoxin and apamin. Hence, the effects of nicotine are realized via presynaptic neuronal nicotinic cholinoceptors and Ca(2+)-activated potassium channels.

Binding and toxicity of apamin. Characterization of the active site.

The structural features of apamin, a natural octadecapeptide from bee venom, enabling binding to its receptor and the expression of toxicity in mice, have been delineated by studying the effects on binding and toxicity of chemical modifications and amino acid substitutions in synthetic analogues. The results obtained indicate that the only hydrophobic residue, leucine at position 10, can be changed to alanine without a significant decrease in the specific activity. The need for a correct conformation has been established and also the importance of Gln-17 and the side chains of Arg-13 and Arg-14 (besides the charge effects). The interaction of apamin with its receptor, a calcium-activated potassium channel, is thus mediated by a precise topology around these three residues. Due to the ability to detect very low specific activities for some of the analogues, it has been shown that, individually, none of these interactions constitute an essential criteria for binding per se, but that their presence is necessary for the high specific activity of the toxin.

Use of synthetic analogs for a study on the structure-activity relationship of apamin.

[Lys13,Lys14]Apamin, [Lys13]apamin and [Lys14]apamin, three structural analogs of the bee venom neurotoxin, have been obtained by solid-phase peptide synthesis while an attempt to obtain [Cit13]apamin failed, probably at the step of reoxidation of cysteines. After the chemical purity of these three derivatives had been assessed, further chemical modifications led to three new peptides: [Ac-Cys1,Lys(Ac)4,Lys(Ac)13]apamin, [Ac-Cys1,Lys(Ac)4,Lys(Ac)14]apamin and [Har4,Har13,Har14]apamin. These six analogs have been tested for their neurotoxicity, i.e. determination of LD50 for mouse by subcutaneous injection. A lethal potency is observed only when the region 13-14 of the sequence contains a double positive charge. One arginyl residue is necessary for a high biological activity, while its location in position 13 or 14 is of minor importance. When homoarginine (Har) replaces arginyl residues the neurotoxicity is lowered.

Solid phase synthesis of apamin, the principal neurotoxin in bee venom. Isolation and characterization of acetamidomethyl apamin.

The synthesis of apamin, the principal neurotoxin in bee venom, has been accomplished by the solid phase method on a benzhydrylamine resin, 2-Phenylisopropyloxycarbonyl amino acids were used throughout the synthesis except for the C-terminal histidine. Improved yields in the coupling steps in the N-terminal part of the molecule were obtained by coupling each amino acid both in dichloromethane and dimethylformamide. The use of acetamidomethyl as an S-protecting group for cysteine made it possible to isolate and purify the linear peptide. The deblocked and oxidized peptide was fractionated by ion-exchange chromatography (Bio-Rex 70) to obtain a highly purified apamin with full biological activity and with the same physical and chemical properties as the natural peptide. Circular dichroism (CD) spectra of the synthetic and natural apamin were identical.

The Ca2+-dependent slow K+ conductance in cultured rat muscle cells: characterization with apamin.

The interaction of apamin, a bee venom neurotoxin, with rat skeletal muscle cell membranes has been followed using both an electrophysiological and a biochemical approach. Voltage-clamp analyses have shown that apamin, at low concentrations, specifically blocks the Ca2+-dependent slow K+ conductance in rat myotubes and myosacs . A specific binding site for apamin in rat muscle cell membranes has been characterized with the use of a highly radiolabelled apamin derivative [( 125I]apamin). The dissociation constant for the apamin-receptor complex is 36-60 pM and the maximal binding capacity is 3.5 fmol/mg of protein. [125I]Apamin binding to rat muscle membranes is displaced by quinine and quinidine with K0.5 values of 110 microM and 200 microM, respectively.