Summary:Purpose: Recently the Ca v 2.3 (E/R-type) voltagegated calcium channel (VGCC) has turned out to be not only a potential target for different antiepileptic drugs (e.g., lamotrigine, topiramate) but also a crucial component in the pathogenesis of absence epilepsy, human juvenile myoclonic epilepsy (JME), and epileptiform activity in CA1 neurons. The aim of our study was to perform an electroencephalographic analysis, seizuresusceptibility testing, and histomorphologic characterization of Ca v 2.3 −/− mice to unravel the functional relevance of Ca v 2.3 in ictogenesis.Methods: Generalized and brain-specific Ca v 2.3 knockout animals were analyzed for spontaneous epileptiform discharges by using both electrocorticographic and deep intracerebral recordings. In addition, convulsive seizure activity was induced by systemic administration of either 4-aminopyridine (4-AP; 10 mg/kg, i.p.) or pentylenetetrazol (PTZ; 80 mg/kg, s.c.) to reveal possible alterations in seizure susceptibility. Besides histomorphologic analysis, expression studies of other voltage-gated Ca 2+ channels in Ca v 2.3 −/− brains were carried out by using semiquantitative reverse transcription-polymerase chain reaction (RT-PCR).Results: Both electrocorticographic and deep intrahippocampal recordings exhibited no spontaneous epileptiform discharges indicative of convulsive or nonconvulsive seizure activity during long-term observation. Gross histology and expression levels of other voltage-gated Ca 2+ channels remained unchanged in various brain regions. Surprisingly, PTZ-induced seizure susceptibility was dramatically reduced in Ca v 2.3-deficient mice, whereas 4-AP sensitivity remained unchanged.Conclusions: Ca v 2.3 ablation results in seizure resistance, strongly supporting recent findings in CA1 neurons that Ca v 2.3 triggers epileptiform activity in specialized neurons via plateau potentials and afterdepolarizations. We provide novel insight into the functional involvement of Ca v 2.3 in ictogenesis and seizure susceptibility on the whole-animal level.
A voltage-gated calcium channel containing Cav2.3e (α1Ee) as the ion conducting pore has recently been detected in rat heart. Functional evidence for this Ca2+ channel to be involved in the regulation of heart beating, besides L- and T-type channels, was derived from murine embryos where the gene for Cav1.2 had been ablated. The remaining ”L-type like“ current component was not related to recombinant splice variants of Cav1.3 containing channels. As recombinant Cav2.3 channels from rat were reported to be weakly dihydropyridine sensitive, the spontaneous activity of the prenatal hearts from Cav2.3(-|-) mice was compared to that of Cav2.3(+|+) control animals to investigate if Cav2.3 could represent such a L-type like Ca2+ channel. The spontaneous activity of murine embryonic hearts was recorded by using a multielectrode array. Between day 9.5 p.c. to 12.5 p.c., the beating frequency of isolated embryonic hearts from Cav2.3-deficient mice did not differ significantly from control mice but the coefficient of variation within individual episodes was more than four-fold increased in Cav2.3-deficient mice indicating arrhythmia. In isolated hearts from wild type mice, arrhythmia was induced by superfusion with a solution containing 200 nM SNX-482, a blocker of some R-type voltage gated Ca2+ channels, suggesting that R-type channels containing the splice variant Cav2.3e as ion conducting pore stabilize a more regular heart beat in prenatal mice.
Ca2+ influx into excitable cells is a prerequisite for neurotransmitter release and regulated exocytosis. Within the group of ten cloned voltage-gated Ca2+ channels, the Ca(v)2.3-containing E-type Ca2+ channels are involved in various physiological processes, such as neurotransmitter release and exocytosis together with other voltage-gated Ca2+ channels of the Ca(v)1, Ca(v)2 and Ca(v)3 subfamily. However, E-type Ca2+ channels also exhibit several subunit-specific features, most of which still remain poorly understood. Ca(v)2.3-containing R-type channels (here called 'E-type channels') are also located in presynaptic terminals and interact with some synaptic vesicle proteins, the so-called SNARE proteins, although lacking the classical synprint interaction site. E-type channels trigger exocytosis and are also involved in long-term potentiation. Recently, it was shown that the interaction of Ca(v)2.3 with the EF-hand motif containing protein EFHC1 is involved in the aetiology and pathogenesis of juvenile myoclonic epilepsy.
There is growing evidence that E-type voltage dependent Ca(2+) channels (Ca(v)2.3) are involved in triggering and controlling pivotal cellular processes like neurosecretion and long-term potentiation. The mechanism underlying a novel Ca(2+) dependent stimulation of E-type Ca(2+) channels was investigated in the context of the recent finding that influx of Ca(2+) through other voltage dependent Ca(2+) channels is necessary and sufficient to directly activate protein kinase C (PKC). With Ba(2+) as charge carrier through Ca(v)2.3 channel alpha(1) subunits expressed in HEK-293 cells, activation of PKC by low concentrations of phorbol ester augmented peak I(Ba) by approximately 60%. In addition, the non-inactivating fraction of I(Ba) was increased by more than three-fold and recovery from short-term inactivation was accelerated. The effect of phorbol ester on I(Ba) was inhibited by application of the specific PKC inhibitor bisindolylmaleimide I. With Ca(2+) as charge carrier, application of phorbol ester did not change the activity of Ca(v)2.3 currents but they were modified by the PKC inhibitor bisindolylmaleimide I. These results suggest that with Ca(2+) as charge carrier the incoming Ca(2+) can activate PKC, thereby augmenting Ca(2+) influx into the cytosol. No modulation of Ca(v)2.3 channels by PKC was observed when an arginine rich region in the II-III loop of Ca(v)2.3 was eliminated. Receptor independent stimulation of PKC and its interaction with Ca(v)2.3 channels therefore represents an important positive feedback mechanism to decode electrical signals into a variety of cellular functions.
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