Project description:Voltage gated calcium channels play a central role in regulating the electrical and biochemical properties of neurons and muscle cells. Cells coordinate the expression of voltage gated calcium channels with the expression of other proteins that regulate membrane potential and calcium homeostasis. We report that the C-terminus of CaV 1.2, an L-type calcium channel (LTC) contains a C-terminal fragment that translocates to the nucleus and regulates transcription. This calcium channel associated transcription factor (CCAT) associates with transcriptional co-regulators such as p54nrb/NonO and binds to endogenous promoters. CCAT regulates the expression of gap junctions, sodium calcium exchangers, NMDA receptors, potassium channels and other proteins that regulate neuronal signaling. Electrical activity and developmental processes regulate the nuclear localization of CCAT, suggesting that the CCAT integrates information about the number of LTCs with information about the developmental history and electrical activity of a cell. These findings provide the first evidence that voltage gated calcium channels can directly activate transcription and suggest a novel mechanism linking voltage gated channels to the function and differentiation of excitable cells. Experiment Overall Design: The goal of these experiments was to identify the genes that are regulated by CCAT, a novel transcription factor derived from the C-terminus of CaV1.2. Neuro2A neuroblastoma cells were transfected with the last 503 AA of CaV1.2 which is full length CCAT (CCAT FL) or with the last 280 AA of CaV1.2, a form of CCAT that lacks the transcriptional activation domain (CCAT DTA). The mRNA from either CCAT FL or CCAT DTA expressing cells was hybridized to Agilent mouse genome microarrays along with mRNA from untransfected neuro2A cells (CCAT FL or DTA A series). Subsequent investigation revealed that transfection with the PA1 plasmid by itself increases the expression of some genes. To control for this effect we compared Neuro2A cells transfected with full length CCAT (in PA1) with Neuro2A cells transfectected with PA1 alone (CCAT FL B series). The microarray data was analyzed with the Rossetta Luminator gene expression data analysis system.

Project description:Elasmobranch fishes, including sharks, rays, and skates, use specialized electrosensory organs called Ampullae of Lorenzini to detect extremely small changes in environmental electric fields. Electrosensory cells within these ampullae are able to discriminate and respond to minute changes in environmental voltage gradients through an as-yet unknown mechanism. Here we show that the voltage-gated calcium channel CaV1.3 and big conductance calcium-activated potassium (BK) channel are preferentially expressed by electrosensory cells in little skate (Leucoraja erinacea) and functionally couple to mediate electrosensory cell membrane voltage oscillations, which are important in the detection of specific, weak electrical signals. Both channels exhibit unique properties compared with their mammalian orthologues to support electrosensory functions: structural adaptations in CaV1.3 mediate a low voltage threshold for activation, while alterations in BK support specifically tuned voltage oscillations. These findings reveal a molecular basis of electroreception and demonstrate how discrete evolutionary changes in ion channel structure facilitate sensory adaptation.

Project description:Using whole-cell patch clamp recording and unbiased gene expression profiling in rat dissociated hippocampal neurons cultured at high density, we demonstrate here that chronic activity blockade induced by the sodium channel blocker tetrodotoxin leads to a homeostatic increase in action potential firing and down-regulation of potassium channel genes. In addition, chronic activity blockade reduces total potassium current, as well as protein expression and current of voltage-gated Kv1 and Kv7 potassium channels, which are critical regulators of action potential firing. Importantly, inhibition of N-Methyl-D-Aspartate receptors alone mimics the effects of tetrodotoxin, including the elevation in firing frequency and reduction of potassium channel gene expression and current driven by activity blockade, whereas inhibition of L-type voltage-gated calcium channels has no effect.

Project description:We study the role of glycosylation in ion channel function. Specfically, we are focusing on how ion channel glycosylation modulates, controls, and impacts cardiac, skeletal muscle, and neuronal electrical activity. We wish to determine differences in gene expression through development and between the atria and ventricles of the mouse heart. Our data indicate differential sialylation directly affects voltage-gated sodium channel function through the developing heart in a chamber-specific manner. We wish to expand our findings to include other ion channels involved in the cardiac action potential, and to eventually create a map of the cardiac conduction system that details the role of differential glycosylation in cardiac excitability. Determining differential expression of the genes that regulate ion channel glycosylation is vital to these goals.

Project description:We study the role of glycosylation in ion channel function. Specfically, we are focusing on how ion channel glycosylation modulates, controls, and impacts cardiac, skeletal muscle, and neuronal electrical activity. We wish to determine differences in gene expression through development and between the atria and ventricles of the mouse heart. Our data indicate differential sialylation directly affects voltage-gated sodium channel function through the developing heart in a chamber-specific manner. We wish to expand our findings to include other ion channels involved in the cardiac action potential, and to eventually create a map of the cardiac conduction system that details the role of differential glycosylation in cardiac excitability. Determining differential expression of the genes that regulate ion channel glycosylation is vital to these goals. We analyzed four sets of pooled RNA to be run in triplicate: one each from neonatal and adult mouse atria and ventricles.

Project description:Voltage-gated sodium channels are responsible for the initiation and propagation of action potentials in excitable cells. While the channel is functional on its own, it is the transient and stable protein-protein interactions that modulate functional outcomes. AP-MS has been successfully applied to a number of ion channels. However to the best of our knowledge, no AP-MS study has been carried out on any member of the voltage-gated sodium channel family.

Project description:Defective ion channel turnover and clearance of damaged proteins are associated with aging and neurodegeneration. The L-type CaV1.2 voltage-gated calcium channel mediate depolarization-induced calcium signals in heart and brain. Here, we determined the interaction surface between the L-type calcium channel CaVβ subunit and actin using cross-linking mass spectrometry and protein-protein docking, and uncovered a role in replenishing damaged CaV1.2 channels. Computational and in vitro mutagenesis identified hotspots in CaVβ that decrease its affinity for actin but not for CaV1.2. Coexpression of an actin-association-deficient CaVβ mutant with the CaV1.2 channel downregulated current amplitudes with a concomitant reduction in the number of functionally available channels. Neither alterations in the single-channel properties nor changes in the total number of channels at the cell surface were found, indicating that current inhibition resulted from a build-up of conduction-defective channels. Our findings established CaVβ–actin interaction as a key player for selective monitoring and clearing corrupted CaV proteins to ensure the maintenance of a functional pool of channels and proper calcium signal transduction. The CaVβ–actin molecular model introduces a potentially druggable protein-protein interface to intervene CaV-mediated signaling processes.

Project description:Defective ion channel turnover and clearance of damaged proteins are associated with aging and neurodegeneration. The L-type CaV1.2 voltage-gated calcium channel mediate depolarization-induced calcium signals in heart and brain. Here, we determined the interaction surface between the L-type calcium channel CaVβ subunit and actin using cross-linking mass spectrometry and protein-protein docking, and uncovered a role in replenishing damaged CaV1.2 channels. Computational and in vitro mutagenesis identified hotspots in CaVβ that decrease its affinity for actin but not for CaV1.2. Coexpression of an actin-association-deficient CaVβ mutant with the CaV1.2 channel downregulated current amplitudes with a concomitant reduction in the number of functionally available channels. Neither alterations in the single-channel properties nor changes in the total number of channels at the cell surface were found, indicating that current inhibition resulted from a build-up of conduction-defective channels. Our findings established CaVβ–actin interaction as a key player for selective monitoring and clearing corrupted CaV proteins to ensure the maintenance of a functional pool of channels and proper calcium signal transduction. The CaVβ–actin molecular model introduces a potentially druggable protein-protein interface to intervene CaV-mediated signaling processes.

Project description:For screening mouse models for CNS diseases for changes in ncRNA expression, we first investigated two models with impaired voltage-gated Ca2+ channel activity, i.e. the lethargic mutant of the auxiliary calcium channel β4 subunit (Cacnb4lh; (Burgess et al. 1997)) and knockout mice for the L-type calcium channel CaV1.3 (Platzer et al. 2000), which have been implicated in a variety of neurological disorders such as psychiatric disorders (Cacnb4) or Parkinsons disease (Cav1.3).

Project description:For screening mouse models for CNS diseases for changes in ncRNA expression, we first investigated two models with impaired voltage-gated Ca2+ channel activity, i.e. the lethargic mutant of the auxiliary calcium channel β4 subunit (Cacnb4lh; (Burgess et al. 1997)) and knockout mice for the L-type calcium channel CaV1.3 (Platzer et al. 2000), which have been implicated in a variety of neurological disorders such as psychiatric disorders (Cacnb4) or Parkinson’s disease (Cav1.3).