Project description:Ca2+ channel beta subunits are important molecular determinants of the kinetics and voltage dependence of Ca2+ channel gating. Through direct interactions with channel-forming alpha1 subunits, beta subunits enhance expression levels, accelerate activation, and have variable effects on inactivation. Four distinct beta subunit genes each encode five homologous sequence domains (D1-5), three of which (D1, D3, and D5) undergo alternative splicing. We have isolated from human spinal cord a novel alternatively spliced beta4 subunit containing a short form of domain D1 (beta4a) that is highly homologous to N termini of Xenopus and rat beta3 subunits. The purpose of this study was to compare the gating properties of various alpha1 subunit complexes containing beta4a with those of complexes containing a beta4 subunit with a longer form of domain D1, beta4b. Expression in Xenopus oocytes revealed that, relative to alpha1A and alpha1B complexes containing beta4b, the voltage dependence of activation and inactivation of complexes containing beta4a were shifted to more depolarized potentials. Moreover, alpha1A and alpha1B complexes containing beta4a inactivated at a faster rate. Interestingly, beta4 subunit alternative splicing did not influence the gating properties of alpha1C and alpha1E subunits. Experiments with beta4 deletion mutants revealed that both the N and C termini of the beta4 subunit play critical roles in setting voltage-dependent gating parameters and that their effects are alpha1 subunit specific. Our data are best explained by a model in which distinct modes of activation and inactivation result from beta-subunit splice variant-specific interactions with an alpha1 subunit gating structure.

Project description:In superior cervical ganglion (SCG) neurons, stimulation of M(1) receptors (M(1)Rs) produces a distinct pattern of modulation of N-type calcium (N-) channel activity, enhancing currents elicited with negative test potentials and inhibiting currents elicited with positive test potentials. Exogenously applied arachidonic acid (AA) reproduces this profile of modulation, suggesting AA functions as a downstream messenger of M(1)Rs. In addition, techniques that diminish AA's concentration during M(1)R stimulation minimize N-current modulation. However, other studies suggest depletion of phosphatidylinositol-4,5-bisphosphate during M(1)R stimulation suffices to elicit modulation. In this study, we used an expression system to examine the physiological mechanisms regulating modulation. We found the beta subunit (Ca(V)beta) acts as a molecular switch regulating whether modulation results in enhancement or inhibition. In human embryonic kidney 293 cells, stimulation of M(1)Rs or neurokinin-1 receptors (NK-1Rs) inhibited activity of N channels formed by Ca(V)2.2 and coexpressed with Ca(V)beta1b, Ca(V)beta3, or Ca(V)beta4 but enhanced activity of N channels containing Ca(V)beta2a. Exogenously applied AA produced the same pattern of modulation. Coexpression of Ca(V)beta2a, Ca(V)beta3, and Ca(V)beta4 recapitulated the modulatory response previously seen in SCG neurons, implying heterogeneous association of Ca(V)beta with Ca(V)2.2. Further experiments with mutated, chimeric Ca(V)beta subunits and free palmitic acid revealed that palmitoylation of Ca(V)beta2a is essential for loss of inhibition. The data presented here fit a model in which Ca(V)beta2a blocks inhibition, thus unmasking enhancement. Our discovery that the presence or absence of palmitoylated Ca(V)beta2a toggles M(1)R- or NK-1R-mediated modulation of N current between enhancement and inhibition identifies a novel role for palmitoylation. Moreover, these findings predict that at synapses, modulation of N-channel activity by M(1)Rs or NK-1Rs will fluctuate between enhancement and inhibition based on the presence of palmitoylated Ca(V)beta2a.

Project description:Airway smooth muscle is richly endowed with muscarinic receptors of the M(2) and M(3) subtype. Stimulation of these receptors inhibits large conductance calcium-activated K(+) (BK) channels, a negative feed back regulator, in a pertussis toxin-sensitive manner and thus facilitates contraction. The underlying mechanism, however, is unknown. We therefore studied the activity of bovine trachea BK channels in HEK293 cells expressing the M(2) or M(3) receptor (M(2)R or M(3)R). In M(2)R- but not M(3)R-expressing cells, maximal effective concentrations of carbamoylcholine (CCh) inhibited whole cell BK currents by 53%. This M(2)R-induced inhibition was abolished by pertussis toxin treatment or overexpression of the Gbetagamma scavenger transducin-alpha. In inside-out patches, direct application of 300 nm purified Gbetagamma decreased channel open probability by 55%. The physical interaction of Gbetagamma with BK channels was confirmed by co-immunoprecipitation. Interestingly, inhibition of phospholipase C as well as protein kinase C activities also reversed the CCh effect but to a smaller (approximately 20%) extent. Mouse tracheal cells responded similarly to CCh, purified Gbetagamma and phospholipase C/protein kinase C inhibition as M(2)R-expressing HEK293 cells. Our results demonstrate that airway M(2)Rs inhibit BK channels by a dual, Gbetagamma-mediated mechanism, a direct membrane-delimited interaction, and the activation of the phospholipase C/protein kinase C pathway.

Project description:Ca2+ channel beta subunits regulate trafficking and gating (opening and closing) of voltage-dependent Ca2+ channel alpha1 subunits. Based on primary sequence comparisons, they are thought to be modular structures composed of five domains (A-E) that are related to the large family of membrane associated guanylate-kinase (MAGUK) proteins. The crystal structures of the beta subunit core, B-D, domains have recently been reported; however, very little is known about the structures of the A and E domains. The N-terminal A domain is a hypervariable region that differs among the four subtypes of Ca2+ channel beta subunits (beta1-beta4). Furthermore, this domain undergoes alternative splicing to create multiple N-terminal structures within a given gene class that have distinct effects on gating. We have solved the solution structure of the A domain of the human beta4a subunit, a splice variant that we have shown previously to have alpha1 subunit subtype-specific effects on Ca2+ channel trafficking and gating.

Project description:Glutamate release from goldfish bipolar cell terminals is driven by Ca2+ influx through L-type calcium channels that exhibit several uncommon features, including rapid kinetics of activation and deactivation, slow inactivation, and activation at an unusually negative voltage range for L-type channels. The purpose of this study was to establish the molecular identities of the alpha1 subunits responsible for these distinctive properties.Transcripts for calcium channel alpha1 subunits expressed in individual goldfish ON-type bipolar cells were identified using single-cell reverse transcriptase polymerase chain reaction (RT-PCR). After cloning the goldfish homologs of the zebrafish and mammalian subunits, we designed sets of nested primers that are specific for Cav1.3a, and Cav1.3b L-type calcium channels.Large-terminal, ON-type bipolar cells express transcripts of Cav1.3a and/or Cav1.3b.The endogenous expression of only one or both subunits in a single cell raises the possibility of functionally distinct classes of bipolar cells that differ in calcium current properties.

Project description:DNA polymerase delta (Pol delta) plays a central role in eukaryotic chromosomal DNA replication, repair and recombination. In fission yeast, Pol delta is a tetrameric enzyme, comprising the catalytic subunit Pol3 and three smaller subunits, Cdc1, Cdc27 and Cdm1. Previous studies have demonstrated a direct interaction between Pol3 and Cdc1, the B-subunit of the complex. Here it is shown that removal of the tandem zinc finger modules located at the C-terminus of Pol3 by targeted proteolysis renders the Pol3 protein non-functional in vivo, and that the C-terminal zinc finger module ZnF2 is both necessary and sufficient for binding to the B-subunit in vivo and in vitro. Extensive mutagenesis of the ZnF2 module identifies important residues for B-subunit binding. In particular, disruption of the ZnF2 module by substitution of the putative metal-coordinating cysteines with alanine abolishes B-subunit binding and in vivo function. Finally, evidence is presented suggesting that the ZnF region is post-translationally modified in fission yeast cells.

Project description:Generalized epilepsy with febrile seizures plus (GEFS+) is a familial epilepsy syndrome characterized by the presence of febrile and afebrile seizures. The first gene, GEFS1, was mapped to chromosome 19q and was identified as the sodium-channel beta1-subunit, SCN1B. A second locus on chromosome 2q, GEFS2, was recently identified as the sodium-channel alpha1-subunit, SCN1A. Single-stranded conformation analysis (SSCA) of SCN1A was performed in 53 unrelated index cases to estimate the frequency of mutations in patients with GEFS+. No mutations were found in 17 isolated cases of GEFS+. Three novel SCN1A mutations-D188V, V1353L, and I1656M-were found in 36 familial cases; of the remaining 33 families, 3 had mutations in SCN1B. On the basis of SSCA, the combined frequency of SCN1A and SCN1B mutations in familial cases of GEFS+ was found to be 17%.

Project description:The control of excitable cell action potentials is central to animal behavior. We show that the egl-19 gene plays a pivotal role in regulating muscle excitation and contraction in the nematode Caenorhabditis elegans and encodes the alphal subunit of a homologue of vertebrate L-type voltage-activated Ca2+ channels. Semi-dominant, gain-of-function mutations in egl-19 cause myotonia: mutant muscle action potentials are prolonged and the relaxation delayed. Partial loss-of-function mutations cause slow muscle depolarization and feeble contraction. The most severe loss-of-function mutants lack muscle contraction and die as embryos. We localized two myotonic mutations in the sixth membrane-spanning domain of the first repeat (IS6) region, which has been shown to be responsible for voltage-dependent inactivation. A third myotonic mutation implicates IIIS4, a region involved in sensing plasma-membrane voltage change, in the inactivation process.

Project description:TRPC5 forms non-selective cation channels. Here we studied the role of internal Ca(2+) in the activation of murine TRPC5 heterologously expressed in human embryonic kidney cells. Cell dialysis with various Ca(2+) concentrations (Ca(2+)(i)) revealed a dose-dependent activation of TRPC5 channels by internal Ca(2+) with EC(50) of 635.1 and 358.2 nm at negative and positive membrane potentials, respectively. Stepwise increases of Ca(2+)(i) induced by photolysis of caged Ca(2+) showed that the Ca(2+) activation of TRPC5 channels follows a rapid exponential time course with a time constant of 8.6 +/- 0.2 ms at Ca(2+)(i) below 10 microM, suggesting that the action of internal Ca(2+) is a primary mechanism in the activation of TRPC5 channels. A second slow activation phase with a time to peak of 1.4 +/- 0.1 s was also observed at Ca(2+)(i) above 10 microM. In support of a Ca(2+)-activation mechanism, the thapsigargin-induced release of Ca(2+) from internal stores activated TRPC5 channels transiently, and the subsequent Ca(2+) entry produced a sustained TRPC5 activation, which in turn supported a long-lasting membrane depolarization. By co-expressing STIM1 plus ORAI1 or the alpha(1)C and beta(2) subunits of L-type Ca(2+) channels, we found that Ca(2+) entry through either calcium-release-activated-calcium or voltage-dependent Ca(2+) channels is sufficient for TRPC5 channel activation. The Ca(2+) entry activated TRPC5 channels under buffering of internal Ca(2+) with EGTA but not with BAPTA. Our data support the hypothesis that TRPC5 forms Ca(2+)-activated cation channels that are functionally coupled to Ca(2+)-selective ion channels through local Ca(2+) increases beneath the plasma membrane.

Project description:Inhibition of calcium channels by G-protein-coupled receptors depends on the nature of the Galpha subunit, although the Gbetagamma complex is thought to be responsible for channel inhibition. Ca currents in hypothalamic neurons and N-type calcium channels expressed in HEK-293 cells showed robust inhibition by G(i)/G(o)-coupled galanin receptors (GalR1), but not by Gq-coupled galanin receptors (GalR2). However, deletions in the C terminus of alpha(1B-1) produced Ca channels that were inhibited after activation of both GalR1 and GalR2. Inhibition of protein kinase C (PKC) also revealed Ca current modulation by GalR2. Imaging studies using green fluorescent protein fusions of the C terminus of alpha(1B) demonstrated that activation of the GalR2 receptor caused translocation of the C terminus of alpha(1B-1) to the membrane and co-localization with Galphaq and PKC. Similar translocation was not seen with a C-terminal truncated splice variant, alpha(1B-2). Immunoprecipitation experiments demonstrated that Galphaq interacts directly with the C terminus of the alpha(1B) subunit. These results are consistent with a model in which local activation of PKC by channel-associated Galphaq blocks modulation of the channel by Gbetagamma released by Gq-coupled receptors.