Identification and affinity labeling of very high affinity binding sites for the phenylalkylamine series of Ca+ channel blockers in the Drosophila nervous system

Distinct roles of Drosophila cacophony and Dmca1D Ca(2+) channels in synaptic homeostasis: genetic interactions with slowpoke Ca(2+) -activated BK channels in presynaptic excitability and postsynaptic response

Ca(2+) influx through voltage-activated Ca(2+) channels and its feedback regulation by Ca(2+) -activated K(+) (BK) channels is critical in Ca(2+) -dependent cellular processes, including synaptic transmission, growth and homeostasis. Here we report differential roles of cacophony (CaV 2) and Dmca1D (CaV 1) Ca(2+) channels in synaptic transmission and in synaptic homeostatic regulations induced by slowpoke (slo) BK channel mutations. At Drosophila larval neuromuscular junctions (NMJs), a well-established homeostatic mechanism of transmitter release enhancement is triggered by experimentally suppressing postsynaptic receptor response. In contrast, a distinct homeostatic adjustment is induced by slo mutations. To compensate for the loss of BK channel control presynaptic Sh K(+) current is upregulated to suppress transmitter release, coupled with a reduction in quantal size. We demonstrate contrasting effects of cac and Dmca1D channels in decreasing transmitter release and muscle excitability, respectively, consistent with their predominant pre- vs. postsynaptic localization. Antibody staining indicated reduced postsynaptic GluRII receptor subunit density and altered ratio of GluRII A and B subunits in slo NMJs, leading to quantal size reduction. Such slo-triggered modifications were suppressed in cac;;slo larvae, correlated with a quantal size reversion to normal in double mutants, indicating a role of cac Ca(2+) channels in slo-triggered homeostatic processes. In Dmca1D;slo double mutants, the quantal size and quantal content were not drastically different from those of slo, although Dmca1D suppressed the slo-induced satellite bouton overgrowth. Taken together, cac and Dmca1D Ca(2+) channels differentially contribute to functional and structural aspects of slo-induced synaptic modifications.

Synchronized neural activity in the Drosophila memory centers and its modulation by amnesiac

The mushroom bodies are key features of the brain circuitry for insect associative learning, especially when evoked by olfactory cues. Mushroom bodies are also notable for the close-packed parallel architecture of their many intrinsic neuronal elements, known as Kenyon cells. Here, we report that Kenyon cells of adult Drosophila exhibit synchronous oscillation of intracellular calcium concentration, with a mean period of approximately 4 min. Robust oscillation within a dissected brain persists for hours in insect saline and is strongly modulated in amplitude by the product(s) of the memory consolidation gene, amnesiac. It is also sensitive to pharmacological agents specific for several classes of ion channel and for acetylcholine and GABA receptors. A role in memory consolidation involving transcriptionally mediated synaptic strengthening is proposed.

omega-AgaIVA-sensitive (P/Q-type) and -resistant (R-type) high-voltage-activated Ba(2+) currents in embryonic cockroach brain neurons

By means of the whole cell patch-clamp technique, the biophysical and pharmacological properties of voltage-dependent Ba(2+) currents (I(Ba)) were characterized in embryonic cockroach brain neurons in primary culture. I(Ba) was characterized by a threshold of approximately -30 mV, a maximum at approximately 0 mV, and a reversal potential near +40 mV. Varying the holding potential from -100 to -40 mV did not modify these properties. The steady-state, voltage-dependent activation and inactivation properties of the current were determined by fitting the corresponding curves with the Boltzmann equation and yielded V(0.5) of -10 +/- 2 (SE) mV and -30 +/- 1 mV, respectively. I(Ba) was insensitive to the dihydropyridine (DHP) agonist BayK8644 (1 microM) and antagonist isradipine (10 microM) but was efficiently and reversibly blocked by the phenylalkylamine verapamil in a dose-dependent manner (IC(50) = 170 microM). The toxin omega-CgTxGVIA (1 microM) had no significant effect on I(Ba). Micromolar doses of omega-CmTxMVIIC were needed to reduce the current amplitude significantly, and the effect was slow. At 1 microM, 38% of the peak current was blocked after 1 h. In contrast, I(Ba) was potently and irreversibly blocked by nanomolar concentrations of omega-AgaTxIVA in approximately 81% of the neurons. Approximately 20% of the current was unaffected after treatment of the neurons with high concentrations of the toxin (0. 4-1 microM). The steady-state dose-response relationship was fitted with a Hill equation and yielded an IC(50) of 17 nM and a Hill coefficient (n) of 0.6. A better fit was obtained with a combination of two Hill equations corresponding to specific (IC(50) = 9 nM; n = 1) and nonspecific (IC(50) = 900 nM; n = 1) omega-AgaTxIVA-sensitive components. In the remaining 19% of the neurons, concentrations >/=100 nM omega-AgaTxIVA had no visible effect on I(Ba). On the basis of these results, it is concluded that embryonic cockroach brain neurons in primary culture express at least two types of voltage-dependent, high-voltage-activated (HVA) calcium channels: a specific omega-AgaTxIVA-sensitive component and DHP-, omega-CgTxGVIA-, and omega-AgaTxIVA-resistant component related respectively to the P/Q- and R-type voltage-dependent calcium channels.

Presynaptic calcium-channel currents in normal and csp mutant Drosophila peptidergic terminals

The study of regulated vesicle exocytosis, which underlies neurotransmitter and neuropeptide release, has benefited from a convergence of several independent approaches. These include the use of genetically tractable organisms and model preparations that allow a direct characterization of presynaptic ionic currents. Aiming for a comprehensive analysis of release, we had already developed a Drosophila preparation in which electrophysiological recordings from peptidergic terminals are feasible. Here, we report on the characterization of the Ca2+-channel currents present in these terminals. With Ba2+ as the charge carrier, the presynaptic membrane expresses a current type with high-activation threshold and little inactivation. This current is blocked by verapamil and diltiazem at micromolar concentrations, it is relatively insensitive to nifedipine and completely resistant to non-L-type Ca2+-channel antagonists. As a comparison, we also analysed the pharmacology of high-threshold Ba+2 currents on muscle fibres. A high-activation threshold Ca2+-channel current is also present in muscle fibres, albeit with a distinct pharmacological profile. Thus, peptidergic terminals and muscle fibres exhibit different subtypes of voltage-gated Ca2+ channels. The putative role of cysteine string protein (CSP) as a neuronal Ca2+-channel modulator was tested by examining the peptidergic presynaptic current in csp null mutants. We show that CSP is expressed in peptidergic boutons and abolished in the mutant. Direct recordings, under conditions that inhibit calcium influx into glutamatergic terminals, show that Ca2+-currents in peptidergic csp terminals are entirely normal. This result indicates that CSP is not a generic Ca2+-channel modulator and it might perform different functions in fast versus slow forms of release.

Genetic analysis of voltage-dependent calcium channels

Molecular cloning of calcium channel subunit genes has identified an unexpectedly large number of genes and splicing variants, and a central problem of calcium channel biology is to now understand the functional significance of this genetic complexity. While electrophyisological, pharmacological, and molecular cloning techniques are providing one level of understanding, a complete understanding will require many additional kinds of studies, including genetic studies done in intact animals. In this regard, an intriguing variety of episodic diseases have recently been identified that result from defects in calcium channel genes. A study of these diseases illustrates the kind of insights into calcium channel function that can be expected from this method of inquiry.

A Drosophila calcium channel alpha1 subunit gene maps to a genetic locus associated with behavioral and visual defects

We have cloned cDNAs that encode a complete open reading frame for a calcium channel alpha1 subunit from Drosophila melanogaster. The deduced 1851 amino acid protein belongs to the superfamily of voltage-gated sodium and calcium channels. Phylogenetic analysis shows that the sequence of this subunit is relatively distant from sodium channel alpha subunits and most similar to genes encoding the A, B, and E isoforms of calcium channel alpha1 subunits. To indicate its similarity to this subfamily of vertebrate isoforms, we name this protein Dmca1A, for Drosophila melanogaster calcium channel alpha1 subunit, type A. Northern blot analysis detected a single 10. 5 kb transcript class that is regulated developmentally, with expression peaks in the first larval instar, midpupal, and late pupal stages. In late-stage embryos, Dmca1A is expressed preferentially in the nervous system. Variant transcripts are generated by alternative splicing. In addition, single nucleotide variations between cDNAs and genomic sequence are consistent with RNA editing. Dmca1A maps to a chromosomal region implicated in, and is the likely candidate for, the gene involved in the generation of behavioral, physiological, and lethal phenotypes of the cacophony, nightblind-A, and lethal(1)L13 mutants.

Meiosis reinitiation of mussel oocytes involves L-type voltage-gated calcium channel

In the present work we assessed the involvement of L-type voltage opening Ca2+ channels in KCl-induced meiosis reinitiation of metaphase-arrested blue mussel (Mytilus galloprovincialis) oocytes by performing binding assays with a tritiated dihydropyridine analog (+)PN 200110. Our data reveal the existence of a single class of dihydropyridine receptors in plasma membrane-enriched rough microsome preparations of mussel oocytes. The apparent affinity (Kd) of characterized receptors equals 1.32 +/- 0.21 microM while their maximal binding capacity (Bmax) is 620 +/- 150 pmol/mg protein. The comparison of the rank order of potency of analogs tested to: 1) inhibit [(+)-[3H]PN 200110 specific binding and 2) block KCl-induced meiosis reinitiation pointed to the pharmacological profile similar to but not identical with those previously described for mammalian dihydropyridine receptors. The efficiencies of all antagonists tested are linearly related (r = 0.995) in binding-(inhibition of [(+)-[3H]PN 200110 specific binding) and biological (inhibition of meiosis reinitiation) assays thus arguing for functional involvement of L-type Ca2+ channels in oocyte activation. Reversibility of antagonist actions on meiosis reinitiation and dependence of receptor binding characteristics on a membrane polarization state further suggested such a role.

Insect calcium channels. Molecular cloning of an alpha 1-subunit from housefly (Musca domestica) muscle

The complete amino acid sequence of an invertebrate calcium channel alpha 1-subunit from housefly (Musca domestica) larvae (designated Mdl alpha 1) has been deduced by cDNA cloning and sequence analysis. Mdl alpha 1 shares higher percent sequence identity with 1,4-dihydropyridine (DHP)-sensitive L-type than with DHP-insensitive calcium channels. As shown by whole mount in situ hybridization and immunostaining Mdl alpha 1 is predominantly expressed in the larval body wall musculature.

Very high affinity interaction of DPI 201-106 and BDF 8784 enantiomers with the phenylalkylamine-sensitive Ca2(+)-channel in Drosophila head membranes

1. Piperazinylindoles (DPI 201-106, BDF 8784), drugs known to act on voltage-dependent Na(+)-channels, bind with very high affinity to a Ca2(+)-channel-associated phenylalkylamine receptor in Drosophila melanogaster head membranes. These compounds and (+)-tetrandrine, a naturally occurring Ca2(+)-antagonist, were the most selective inhibitors for phenylalkylamine-labelled Drosophila Ca2(+)-channels compared to mammalian L-type Ca2(+)-channels. 2. Replacement of the cyano group by a methyl group in (+)-DPI 201-106 ((+)-BDF 8784) increases the IC50 value for inhibition of phenylalkylamine labelling of Drosophila Ca2(+)-channels from 0.29 to 2.1 nM but decreases the IC50 value for inhibition of phenylalkylamine labelling of mammalian skeletal muscle Ca2(+)-channels from 3480 to 49 nM. 3. DPI 201-106 enantiomers completely block (at 0.1 microM) phenylalkylamine photolabelling of a 136 K polypeptide in Drosophila head membranes whereas 10 microM aconitine or lidocaine are without effect. 4. Assessment of the Ca2(+)-antagonist effects of the substituted DPI 201-106 enantiomers in K(+)-depolarized taenia strips from guinea-pig caecum yielded pA2 values of 6.33 +/- 0.07 for (-)-BDF 8784 and 6.99 +/- 0.17 for (+)-BDF 8784, respectively. 5. Piperazinylindoles, previously believed to act nonspecifically on voltage-dependent mammalian L-type Ca2(+)-channels, therefore have stereoselectivity for a novel binding site and chemical selectivity unrelated to local anaesthetic activity. 6. It is proposed that a very high affinity piperazinylindole-selective site is coupled to the phenylalkylamine receptor of Drosophila Ca2(+)-channels. These sites are still present on mammalian L-type Ca2(+)-channels but have lower affinity and/or are less tightly coupled to phenylalkylamine receptors on the alpha 1-subunit.

Chiral aspects of drug action at ion channels: a commentary on the stereoselectivity of drug actions at voltage-gated ion channels with particular reference to verapamil actions at the Ca2+ channel

Ion channels may be considered as pharmacological receptors possessing specific drug binding sites with defined structure-activity relationships. Accordingly drug binding to ion channels is stereoselective. Interpretation of this stereoselectivity may be complex because of the existence of differences in affinity and access to different channel states. Such state-dependent interactions may give rise to quantitative and qualitative differences in stereoselectivity. The implications of such differences are reviewed for drug action at Na+, K+ and Ca2+ channels. Detailed attention is paid to the actions of verapamil enantiomers in the cardiovascular system where activities differ in vascular and cardiac tissues because of state-dependent interactions and stereoselective first-oass metabolism.

omega-Conotoxin GVIA and nifedipine inhibit the depolarizing action of the fungal metabolite, destruxin B on muscle from the tobacco budworm (Heliothis virescens)

Recent studies on a group of fungal metabolites, collectively called the destruxins, have suggested that these compounds activate calcium influx in insect skeletal muscle. In this study, we have investigated the sensitivity of destruxin B to the voltage-dependent calcium channel antagonists; omega-conotoxin GVIA, nifedipine, diltiazem and methoxyverapamil on skeletal muscle from the lepidopteran insect pest, tobacco budworm (Heliothis virescens). At a concentration of 1.7 microM, destruxin B caused a rapid decrease in the transmembrane resting potential. The effect of destruxin B on insect muscle was blocked by micromolar concentrations of omega-conotoxin GVIA and nifedipine but not by methoxyverapamil or diltiazem. The inhibitory activity of omega-conotoxin GVIA on invertebrate muscle tissue was surprising since this compound was previously thought to be selective to vertebrate nervous tissue. The sensitivity of the destruxin-stimulated depolarization to the two antagonists suggested that destruxin B activated a voltage-dependent calcium channel. Neuromuscular transmission was monitored in the presence of omega-conotoxin GVIA and nifedipine to investigate the physiological role of the destruxin-activated channel. Neither antagonist altered the waveform of graded action potentials produced by synaptic activation. The lack of effect of omega-conotoxin GVIA and a high dose of nifedipine could be explained by the existence of two populations of pharmacologically distinct voltage-dependent calcium channels on the muscle membrane. One population which is involved with the production of graded action potentials is insensitive to omega-conotoxin GVIA and nifedipine. The other population is activated by destruxin B and inhibited by omega-conotoxin GIVA and nifedipine.

Purification and subunit structure of a putative K+-channel protein identified by its binding properties for dendrotoxin I

The binding protein for the K+-channel toxin dendrotoxin I was purified from a detergent extract of rat brain membranes. The purification procedure utilized chromatography on DEAE-Trisacryl, affinity chromatography on a dendrotoxin-I-Aca 22 column, and wheat germ agglutinin-Affigel 10 with a final 3800- to 4600-fold enrichment and a recovery of 8-16%. The high affinity (Kd, 40-100 pM) and specificity of the binding site are retained throughout the purification procedure. Analysis of the purified material on silver-stained NaDodSO4/polyacrylamide gel revealed three bands of Mr 76,000-80,000, 38,000, and 35,000. Interestingly, the binding site for 125I-labeled mast cell degranulating peptide, another putative K+-channel ligand from bee venom, which induces long-term potentiation in hippocampus, seems to reside on the same protein complex, as both binding sites copurify through the entire purification protocol.