Calcium channel, voltage-dependent
Crystallographic structure of the L-type calcium channel complex (subunits α1S, α2, δ, β, and γ).
Identifiers
Symbol	Calcium channel, voltage-dependent

TheL-type calcium channel (also known as the dihydropyridine channel, orDHP channel) is part of the high-voltage activated family ofvoltage-dependent calcium channel.^[2]"L" stands for long-lasting referring to the length of activation. This channel has four isoforms:Cav1.1,Cav1.2,Cav1.3, andCav1.4.

L-type calcium channels are responsible for the excitation-contraction coupling ofskeletal,smooth,cardiac muscle, and foraldosterone secretion inendocrine cells of theadrenal cortex.^[1] They are also found in neurons, and with the help of L-type calcium channels in endocrine cells, they regulateneurohormones andneurotransmitters. They have also been seen to play a role in gene expression,mRNA stability, neuronal survival, ischemic-induced axonal injury, synaptic efficacy, and both activation and deactivation of other ion channels.^[3]

In cardiac myocytes, the L-type calcium channel passes inward Ca²⁺ current (I_CaL) and triggers calcium release from the sarcoplasmic reticulum by activatingryanodine receptor 2 (RyR2) (calcium-induced-calcium-release).^[4] Phosphorylation of these channels increases their permeability to calcium and increases the contractility of their respective cardiac myocytes.

L-typecalcium channel blocker drugs are used as cardiacantiarrhythmics orantihypertensives, depending on whether the drugs have higher affinity for theheart (thephenylalkylamines, likeverapamil), or for the blood vessels (thedihydropyridines, likenifedipine).^[5]

In skeletal muscle, there is a very high concentration of L-type calcium channels, situated in theT-tubules. Muscle depolarization results in large gating currents, but anomalously low calcium flux, which is now explained by the very slow activation of the ionic currents. For this reason, little or no Ca²⁺ passes across the T-tubule membrane during a single action potential.

In 1953, Paul Fatt and Bernard Katz discovered voltage gated calcium channels in crustacean muscle. The channels exhibited different activation voltages and calcium conducting properties and were thus separated into High Voltage Activating channels (HVA) and Low Voltage Activating channels (LVA). After further experimentation, it was found that HVA channels were blocked by derivatives of1,4-dihydropyridine (DHPs).^[6] Using DHPs, it was found that HVA channels were specific to certain tissues and reacted differently, which led to further categorization of the HVA channels into L-type,P-type, andN-type.^[3] L-type calcium channels were peptide sequenced and it was found that there were 4 kinds of L-type calcium channels: α₁S (Skeletal Muscle), α₁C (Cardiac), α₁ D (found in the brain), and α₁F (found in the retina).^[6] In 2000, after more research was done on α₁ subunits in voltage-gated calcium channels, a new nomenclature was used that called L-type calcium channels CaV1 with its subunits being calledCaV1.1,Cav1.2,CaV1.3, andCaV1.4.^[3] Research on the CaV1 subunits continues to reveal more about their structure, function, and pharmaceutical applications.^[7]

L-type Calcium Channels contain 5 different subunits, the α1(170–240 kDa), α2(150kDa), δ(17-25 kDa), β(50-78 kDa), and γ(32 kDa) subunits.^[8] The α2, δ, and β subunits are non-covalently bonded to the α1 subunit and modulate ion trafficking and biophysical properties of the α1 subunit. The α2 and δ subunits are in the extracellular space while the β and γ subunits are located in the cytosolic space.^[8]

The α1 subunit is a heterotetramer that has fourtransmembrane regions, known as Domains I-IV, that cross the plasma six times asα-helices, being called S0-S6 (S0 and S1 together cross the membrane once).^[3] The α1 subunit as a whole contains the voltage sensing domain, the conduction pore, and gating apparatus.^[9] Like mostvoltage-gated ion channels, the α-subunit is composed of 4 subunits. Each subunit is formed by 6 alpha-helical, transmembrane domains that cross the membrane (numbered S1-S6). The S1-S4 subunits make up the voltage sensor, while S5-S6 subunits make up the selectivity filter.^[10] To sense the cell's voltage, the S1-S3 helices contain many negatively charged amino acids while S4 helices contain mostly positively charged amino acids with aP-loop connecting the S4 to S5 helices. After the S1-6 domains, there are six C domains that consist of twoEF-hand motifs (C1-2 and C3-4) and a Pre-IQ domain (C5) andIQ domain (C6). There are also two EF-hand motifs on theN-terminus. Both the N and C terminus are in the cytosolic space with the C-terminus being much longer than the N-terminus.^[11]

The β subunit is known to have fourisoforms (β1-β4) to regulate the channel's functions and is connected to α1 through the α1 I and II linker in the cytosol at the β α1-binding pocket (ABP).^[7][12] Each isoform contains asrc homology 3 domain (SH3) and a guanylate-kinase like domain (GK) that are separated by a HOOK domain, and three unstructured regions.^[12]

The α2 and δ subunits are connected together by disulfide bonds (sometimes known as the α2δ subunit) and interact with α1.^[7] they have four known isoforms called α2δ-1 to α2δ-2 and contain avon Willebrand A (VWA) domain and aCache domain. The α2 region is in the extracellular space while the δ region is in the cell membrane and have been seen to be anchored with aglycosylphosphatidylinositol (GPI) anchor.^[12]

The γ subunit has eight isoforms (γ1-γ8) and is connected to the α1 subunit and has only been found in muscle cells in the CaV1.1 and CaV1.2 channels.^[12] Not much is known about the γ subunit, but it has been linked to interactions in hydrophobic forces.^[3]

Opening of the pore in L-type calcium channels takes place in the α1 subunit. When the membrane depolarizes, the S4 helix moves through the S4 and S5 linkers to the cytoplasmic ends of the S5 and S6 helices. This opens theactivation gate which is formed by the inner side of the S6 helices in the α1 subunit.^[11]

The most predominant way of autoinhibition of L-type calcium channels is with theCa²⁺/Cam complex.^[11] As the pore opens and causes an influx of calcium, calcium binds tocalmodulin and then interacts with the loop that connects the adjacentEF-hand motifs and causes a conformational change in the EF-hand motif so it interacts with the pore to cause quick inhibition in the channel.^[6] It is still debated on where and how the pore and EF-hand interact. Hydrophobic pockets in theCa²⁺/Cam complex will also bind to three sections of theIQ domain known as the “aromatic anchors”.^[11] TheCa²⁺/Cam complex has a high affinity towards L-type calcium channels, allowing it to get blocked even when there are low amounts of calcium present in the cell. The pore eventually closes as the cell repolarizes and causes a conformational change in the channel to put it in the closed conformation.

One of the most recognized characteristics of the L-type calcium channel is its unique sensitivity to1,4-dihydropyridines (DHPs).^[3] Unlike other voltage gated calcium channels, L-type calcium channels are resistant to⍵-CT X (GVIA) and ⍵-AG A (IVA) inhibitory drugs.^[3]

A well observed form of modulation is due toalternative splicing. A common form of modulation from alternative splicing is the C-terminal modulator (CTM). It has a positively charged α-helix on the C-terminal called the DCRD and a negatively charged helix right after the IQ motif (CaM interaction site) called the PCRD. The two helices can form a structure that bind competitively withCaM to reduce the open-state probability and lower calcium-dependent inhibition (CDI).^[7]

Alternative splicing is also seen on the β subunits to create differentisoforms to give channels different properties due topalmitoylation^[6] andRNA editing.^[7] Other forms of modulation on the β subunit include increasing or decreasing of the subunit's expression. This is due to the fact that β subunits increase the open-probability of the channel, activity in the plasma membrane, and antagonize theubiquitination of the channel.^[6]

L-type calcium channels are also modulated byG protein-coupled receptors and theadrenergic nervous system.^[6]Protein Kinase A (PKA) activated by a G protein-coupled receptors cascade can phosphorylate L-type calcium channels, after channels form a signaling complex withA-Kinase-Anchoring proteins (AKAPs), to increase calcium current through the channel, increasing the open-state probability, and an accelerated recovery period. ActivatedPhospholipase C (PLC) from G protein-coupled receptors can breakdown polyphosphoinositides to decrease the channel's calcium current by 20%-30%.^[7]

The adrenergic nervous system has been seen to modulate L-type calcium channels by cleaving the C-terminal fragment when the β-adrenergic receptor is stimulated to increase activation of the channels.^[6]

• CACNA1C,CACNA1D,CACNA1S,CACNA1F

• CACNA1C
• CACNA1D
• CACNA1S
• CACNA1F

This article incorporates text from theUnited States National Library of Medicine, which is in thepublic domain.

• "Voltage-Gated Calcium Channels".IUPHAR Database of Receptors and Ion Channels. International Union of Basic and Clinical Pharmacology.
• L-Type+Calcium+Channel at the U.S. National Library of MedicineMedical Subject Headings (MeSH)

• Ion channels
• Electrophysiology
• Membrane biology
• Integral membrane proteins
• Calcium channels

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• Short description matches Wikidata
• Short description is different from Wikidata
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