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Cav1.3

January 01, 1970


Calcium channel, voltage-dependent, L type, alpha 1D subunit (also known as Cav1.3) is a protein that in humans is encoded by the CACNA1D gene.[5] Cav1.3 channels belong to the Cav1 family, which form L-type calcium currents and are sensitive to selective inhibition by dihydropyridines (DHP).

CACNA1D
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
AliasesCACNA1D, CACH3, CACN4, CACNL1A2, CCHL1A2, Cav1.3, PASNA, SANDD, calcium voltage-gated channel subunit alpha1 D
External IDsOMIM: 114206 MGI: 88293 HomoloGene: 578 GeneCards: CACNA1D
Orthologs
SpeciesHumanMouse
Entrez

776

12289

Ensembl

ENSG00000157388

ENSMUSG00000015968

UniProt

Q01668

Q99246

RefSeq (mRNA)

NM_000720
NM_001128839
NM_001128840

NM_001083616
NM_028981
NM_001302637

RefSeq (protein)

NP_000711
NP_001122311
NP_001122312

NP_001077085
NP_001289566
NP_083257

Location (UCSC)Chr 3: 53.33 – 53.81 MbChr 14: 29.76 – 30.21 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Structure and function edit

 
Schematic representation of the alpha subunit of VDCCs showing the four homologous domains, each with six transmembrane subunits. P-loops are highlighted red, S4 subunits are marked with a plus indicative of positive charge.

Voltage-dependent calcium channels (VDCC) are selectively permeable to calcium ions, mediating the movement of these ions in and out of excitable cells. At resting potential, these channels are closed, but when the membrane potential is depolarised these channels open. The influx of calcium ions into the cell can initiate a myriad of calcium-dependent processes including muscle contraction, gene expression, and secretion. Calcium-dependent processes can be halted by lowering intracellular calcium levels, which, for example, can be accomplished by calcium pumps.[6]

Voltage-dependent calcium channels are multi-proteins composed of α1, β, α2δ and γ subunits. The major subunit is α1, which forms the selectivity pore, voltage-sensor and gating apparatus of VDCCs. In Cav1.3 channels, the α1 subunit is α1D. This subunit differentiates Cav1.3 channels from other members of the Cav1 family, such as the predominant and better-studied Cav1.2, which has an α1C subunit. The significance of the α1 subunit also means that it is the primary target for calcium-channel blockers such as dihydropyridines. The remaining β, α2δ and γ subunits have auxiliary functions.

The α1 subunit has four homologous domains, each with six transmembrane segments. Within each homologous domain, the fourth transmembrane segment (S4) is positively charged, as opposed to the other five hydrophobic segments. This characteristic enables S4 to function as the voltage-sensor. Alpha-1D subunits belong to the Cav1 family, which is characterised by L-type calcium currents. Specifically, α1D subunits confer low-voltage activation and slowly inactivating Ca2+ currents, ideal for particular physiological functions such as neurotransmitter release in cochlea inner hair cells.

The biophysical properties of Cav1.3 channels are closely regulated by a C-terminal modulatory domain (CTM), which affects both the voltage dependence of activation and Ca2+ dependent inactivation.[7] Cav1.3 have a low affinity for DHP and activate at sub-threshold membrane potentials, making them ideal for a role in cardiac pacemaking.[8]

Regulation edit

Alternative splicing edit

Post-transcriptional alternative splicing of Cav1.3 is an extensive and vital regulatory mechanism. Alternative splicing can significantly affect the gating properties of the channel. Comparable to alternative splicing of Cav1.2 transcripts, which confers functional specificity,[9] it has recently been discovered that alternative splicing, particularly in the C-terminus, affects the pharmacological properties of Cav1.3.[10][11] Strikingly, up to 8-fold differences in dihydropyridine sensitivity between alternatively spliced isoforms have been reported.[12][13]

Negative feedback edit

Cav1.3 channels are regulated by negative feedback to achieve Ca2+ homeostasis. Calcium ions are a critical second messenger, intrinsic to intracellular signal transduction. Extracellular calcium levels are approximated to be 12000-fold greater than intracellular levels. During calcium-dependent processes, the intracellular level of calcium rises by up to 100-fold. It is vitally important to regulate this calcium gradient, not least because high levels of calcium are toxic to the cell, and can induce apoptosis.

Ca2+-bound calmodulin (CaM) interacts with Cav1.3 to induce calcium-dependent inactivation (CDI). Recently, it has been shown that RNA editing of Cav1.3 transcripts is essential for CDI.[14] Contrary to expectation, RNA editing does not simply attenuate the binding of CaM, but weakens the pre-binding of Ca2+-free calmodulin (apoCaM) to channels. The upshot is that CDI is continuously tuneable by changes in levels of CaM.

Clinical significance edit

Hearing edit

Cav1.3 channels are widely expressed in humans.[15] Notably, their expression predominates in cochlea inner hair cells (IHCs). Cav1.3 have been shown through patch clamp experiments to be essential for normal IHC development and synaptic transmission.[16] Therefore, Cav1.3 are required for proper hearing.[17]

Chromaffin cells edit

Cav1.3 are densely expressed in chromaffin cells. The low-voltage activation and slow inactivation of these channels makes them ideal for controlling excitability in these cells. Catecholamine secretion from chromaffin cells is particularly sensitive to L-type currents, associated with Cav1.3. Catecholamines have many systemic effects on multiple organs. In addition, L-type channels are responsible for exocytosis in these cells.[18]

Neurodegeneration edit

Parkinson's disease is the second most common neurodegenerative disease, in which the death of dopamine-producing cells in the substantia nigra of the midbrain leads to impaired motor function, perhaps best characterised by tremor. Recent evidence suggests that L-type Cav1.3 Ca2+ channels contribute to the death of dopaminergic neurones in patients with Parkinson's disease.[8] The basal activity of these neurones is also dependent on L-type Ca2+ channels, such as Cav1.3. Continuous pacemaking activity drives permanent intracellular dendritic and somatic calcium transients, which appears to make the dopaminergic substantia nigra neurones vulnerable to stressors that contribute to their death. Therefore inhibition of L-type channels, in particular Cav1.3 is protective against the pathogenesis of Parkinson's in some animal models.[8][19] A clinical phase III trial (STEADY-PD III 2019-04-07 at the Wayback Machine) testing this hypothesis in patients with early Parkinsons's failed to show efficacy in slowing the progression of Parkinson's.[20]

Inhibition of Cav1.3 can be achieved using calcium channel blockers, such as dihydropyridines (DHPs). These drugs are used since decades to treat arterial hypertension and angina. This is due to their potent vasorelaxant properties, which are mediated by the inhibition of Cav1.2 L-type calcium channels in arterial smooth muscle.[15] Therefore, hypotensive reactions (and leg edema) are regarded dose-limiting side effects when using DHPs for inhibiting Cav1.3 channel in the brain.[21] In the face of this issue, attempts have been made to discover selective Cav1.3 channel blockers. One candidate has been claimed to be a potent and highly selective inhibitor of Cav1.3. This compound, 1-(3-chlorophenethyl)-3-cyclopentylpyrimidine-2,4,6-(1H,3H,5H)-trione was therefore put forward as a candidate for the future treatment of Parkinson's.[22] However, its selectivity and potency could not be confirmed in two independent studies from two other groups.[23] One of them even reported gating changes induced by this drug., which indicate channel activating rather than blocking effects.[24]

Prostate cancer edit

Recent evidence from immunostaining experiments shows that CACNA1D is highly expressed in prostate cancers compared with benign prostate tissues. Blocking L-type channels or knocking down gene expression of CACNA1D significantly suppressed cell-growth in prostate cancer cells.[25] It is important to recognise that this association does not represent a causal link between high levels of α1D protein and prostate cancer. Further investigation is needed to explore the role of CACNA1D gene overexpression in prostate cancer cell growth.

Aldosteronism edit

De novo somatic mutations in conserved regions within the channel's activation gate of its pore-forming α1-subunit (CACNA1D) cause excessive aldosterone production in aldosterone-producing adenomas (APA) resulting in primary aldosteronism, which causes treatment - resistant arterial hypertension. These mutations allow increased Ca2+ influx through Cav1.3, which in turn triggers Ca2+ - dependent aldosterone production.[26][27] The number of validated APA mutations is constantly growing.[28] In rare cases, APA mutations have also been found as germline mutations in individuals with neurodevelopmental disorders of different severity, including autism spectrum disorder.[26][28][29]

See also edit

References edit

  1. ^ a b c GRCh38: Ensembl release 89: ENSG00000157388 – Ensembl, May 2017
  2. ^ a b c GRCm38: Ensembl release 89: ENSMUSG00000015968 – Ensembl, May 2017
  3. ^ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  4. ^ "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  5. ^ "Entrez Gene: CACNA1D calcium channel, voltage-dependent, L type, alpha 1D subunit".
  6. ^ Brown BL, Walker SW, Tomlinson S (August 1985). "Calcium calmodulin and hormone secretion". Clinical Endocrinology. 23 (2): 201–18. doi:10.1111/j.1365-2265.1985.tb00216.x. PMID 2996810. S2CID 45017291.
  7. ^ Lieb A, Scharinger A, Sartori S, Sinnegger-Brauns MJ, Striessnig J (2012). "Structural determinants of CaV1.3 L-type calcium channel gating". Channels. 6 (3): 197–205. doi:10.4161/chan.21002. PMC 3431584. PMID 22760075.
  8. ^ a b c Chan CS, Guzman JN, Ilijic E, Mercer JN, Rick C, Tkatch T, Meredith GE, Surmeier DJ (June 2007). "'Rejuvenation' protects neurons in mouse models of Parkinson's disease". Nature. 447 (7148): 1081–6. Bibcode:2007Natur.447.1081C. doi:10.1038/nature05865. PMID 17558391. S2CID 4429534.
  9. ^ Liao P, Yu D, Lu S, Tang Z, Liang MC, Zeng S, Lin W, Soong TW (November 2004). "Smooth muscle-selective alternatively spliced exon generates functional variation in Cav1.2 calcium channels". The Journal of Biological Chemistry. 279 (48): 50329–35. doi:10.1074/jbc.m409436200. PMID 15381693.
  10. ^ Singh A, Gebhart M, Fritsch R, Sinnegger-Brauns MJ, Poggiani C, Hoda JC, Engel J, Romanin C, Striessnig J, Koschak A (July 2008). "Modulation of voltage- and Ca2+-dependent gating of CaV1.3 L-type calcium channels by alternative splicing of a C-terminal regulatory domain". The Journal of Biological Chemistry. 283 (30): 20733–44. doi:10.1074/jbc.M802254200. PMC 2475692. PMID 18482979.
  11. ^ Tan BZ, Jiang F, Tan MY, Yu D, Huang H, Shen Y, Soong TW (December 2011). "Functional characterization of alternative splicing in the C terminus of L-type CaV1.3 channels". The Journal of Biological Chemistry. 286 (49): 42725–35. doi:10.1074/jbc.M111.265207. PMC 3234967. PMID 21998309.
  12. ^ Huang H, Yu D, Soong TW (October 2013). "C-terminal alternative splicing of CaV1.3 channels distinctively modulates their dihydropyridine sensitivity". Molecular Pharmacology. 84 (4): 643–53. doi:10.1124/mol.113.087155. PMID 23924992. S2CID 22439331.
  13. ^ Ortner NJ, Bock G, Dougalis A, Kharitonova M, Duda J, Hess S, Tuluc P, Pomberger T, Stefanova N, Pitterl F, Ciossek T, Oberacher H, Draheim HJ, Kloppenburg P, Liss B, Striessnig J (July 2017). "2+ Channels during Substantia Nigra Dopamine Neuron-Like Activity: Implications for Neuroprotection in Parkinson's Disease". The Journal of Neuroscience. 37 (28): 6761–6777. doi:10.1523/JNEUROSCI.2946-16.2017. PMC 6596555. PMID 28592699.
  14. ^ Bazzazi H, Ben Johny M, Adams PJ, Soong TW, Yue DT (October 2013). "Continuously tunable Ca(2+) regulation of RNA-edited CaV1.3 channels". Cell Reports. 5 (2): 367–77. doi:10.1016/j.celrep.2013.09.006. PMC 4349392. PMID 24120865.
  15. ^ a b Zamponi GW, Striessnig J, Koschak A, Dolphin AC (October 2015). "The Physiology, Pathology, and Pharmacology of Voltage-Gated Calcium Channels and Their Future Therapeutic Potential". Pharmacological Reviews. 67 (4): 821–70. doi:10.1124/pr.114.009654. PMC 4630564. PMID 26362469.
  16. ^ Brandt A, Striessnig J, Moser T (November 2003). "CaV1.3 channels are essential for development and presynaptic activity of cochlear inner hair cells". The Journal of Neuroscience. 23 (34): 10832–40. doi:10.1523/JNEUROSCI.23-34-10832.2003. PMC 6740966. PMID 14645476.
  17. ^ Platzer J, Engel J, Schrott-Fischer A, Stephan K, Bova S, Chen H, Zheng H, Striessnig J (July 2000). "Congenital deafness and sinoatrial node dysfunction in mice lacking class D L-type Ca2+ channels". Cell. 102 (1): 89–97. doi:10.1016/S0092-8674(00)00013-1. PMID 10929716. S2CID 17923472.
  18. ^ Vandael DH, Mahapatra S, Calorio C, Marcantoni A, Carbone E (July 2013). "Cav1.3 and Cav1.2 channels of adrenal chromaffin cells: emerging views on cAMP/cGMP-mediated phosphorylation and role in pacemaking". Biochimica et Biophysica Acta (BBA) - Biomembranes. 1828 (7): 1608–18. doi:10.1016/j.bbamem.2012.11.013. hdl:2318/132208. PMID 23159773.
  19. ^ Liss B, Striessnig J (January 2019). "The Potential of L-Type Calcium Channels as a Drug Target for Neuroprotective Therapy in Parkinson's Disease". Annual Review of Pharmacology and Toxicology. 59 (1): 263–289. doi:10.1146/annurev-pharmtox-010818-021214. PMID 30625283. S2CID 58619079.
  20. ^ Hoffman M (5 May 2019). "Isradipine Fails to Slow Early Parkinson Disease Progression in Phase 3 Study". NeurologyLive. Retrieved 2019-11-25.
  21. ^ Parkinson Study Group (November 2013). "Phase II safety, tolerability, and dose selection study of isradipine as a potential disease-modifying intervention in early Parkinson's disease (STEADY-PD)". Movement Disorders. 28 (13): 1823–31. doi:10.1002/mds.25639. PMID 24123224. S2CID 9594193.
  22. ^ Kang S, Cooper G, Dunne SF, Dusel B, Luan CH, Surmeier DJ, Silverman RB (2012). "CaV1.3-selective L-type calcium channel antagonists as potential new therapeutics for Parkinson's disease". Nature Communications. 3: 1146. Bibcode:2012NatCo...3.1146K. doi:10.1038/ncomms2149. PMID 23093183.
  23. ^ Huang H, Ng CY, Yu D, Zhai J, Lam Y, Soong TW (July 2014). "Modest CaV1.342-selective inhibition by compound 8 is β-subunit dependent". Nature Communications. 5: 4481. Bibcode:2014NatCo...5.4481H. doi:10.1038/ncomms5481. PMC 4124865. PMID 25057870.Ortner NJ, Bock G, Vandael DH, Mauersberger R, Draheim HJ, Gust R, Carbone E, Tuluc P, Striessnig J (June 2014). "Pyrimidine-2,4,6-triones are a new class of voltage-gated L-type Ca2+ channel activators". Nature Communications. 5: 3897. Bibcode:2014NatCo...5.3897O. doi:10.1038/ncomms4897. PMC 4083433. PMID 24941892.
  24. ^ Ortner NJ, Bock G, Vandael DH, Mauersberger R, Draheim HJ, Gust R, Carbone E, Tuluc P, Striessnig J (June 2014). "Pyrimidine-2,4,6-triones are a new class of voltage-gated L-type Ca2+ channel activators". Nature Communications. 5: 3897. Bibcode:2014NatCo...5.3897O. doi:10.1038/ncomms4897. PMC 4083433. PMID 24941892.
  25. ^ Chen R, Zeng X, Zhang R, Huang J, Kuang X, Yang J, Liu J, Tawfik O, Thrasher JB, Li B (July 2014). "Cav1.3 channel α1D protein is overexpressed and modulates androgen receptor transactivation in prostate cancers". Urologic Oncology. 32 (5): 524–36. doi:10.1016/j.urolonc.2013.05.011. PMID 24054868.
  26. ^ a b Scholl UI, Goh G, Stölting G, de Oliveira RC, Choi M, Overton JD, Fonseca AL, Korah R, Starker LF, Kunstman JW, Prasad ML, Hartung EA, Mauras N, Benson MR, Brady T, Shapiro JR, Loring E, Nelson-Williams C, Libutti SK, Mane S, Hellman P, Westin G, Åkerström G, Björklund P, Carling T, Fahlke C, Hidalgo P, Lifton RP (September 2013). "Somatic and germline CACNA1D calcium channel mutations in aldosterone-producing adenomas and primary aldosteronism". Nature Genetics. 45 (9): 1050–4. doi:10.1038/ng.2695. PMC 3876926. PMID 23913001.
  27. ^ Azizan EA, Poulsen H, Tuluc P, Zhou J, Clausen MV, Lieb A, Maniero C, Garg S, Bochukova EG, Zhao W, Shaikh LH, Brighton CA, Teo AE, Davenport AP, Dekkers T, Tops B, Küsters B, Ceral J, Yeo GS, Neogi SG, McFarlane I, Rosenfeld N, Marass F, Hadfield J, Margas W, Chaggar K, Solar M, Deinum J, Dolphin AC, Farooqi IS, Striessnig J, Nissen P, Brown MJ (September 2013). "Somatic mutations in ATP1A1 and CACNA1D underlie a common subtype of adrenal hypertension". Nature Genetics. 45 (9): 1055–60. doi:10.1038/ng.2716. PMID 23913004. S2CID 205347424.
  28. ^ a b Pinggera A, Striessnig J (October 2016). "2+ channel dysfunction in CNS disorders". The Journal of Physiology. 594 (20): 5839–5849. doi:10.1113/JP270672. PMC 4823145. PMID 26842699.
  29. ^ Pinggera A, Negro G, Tuluc P, Brown MJ, Lieb A, Striessnig J (January 2018). "2+ channels". Channels. 12 (1): 388–402. doi:10.1080/19336950.2018.1546518. PMC 6287693. PMID 30465465.

Further reading edit

  • Williams ME, Feldman DH, McCue AF, Brenner R, Velicelebi G, Ellis SB, Harpold MM (January 1992). "Structure and functional expression of alpha 1, alpha 2, and beta subunits of a novel human neuronal calcium channel subtype". Neuron. 8 (1): 71–84. doi:10.1016/0896-6273(92)90109-Q. PMID 1309651. S2CID 39341712.
  • Seino S, Chen L, Seino M, Blondel O, Takeda J, Johnson JH, Bell GI (January 1992). "Cloning of the alpha 1 subunit of a voltage-dependent calcium channel expressed in pancreatic beta cells". Proceedings of the National Academy of Sciences of the United States of America. 89 (2): 584–8. Bibcode:1992PNAS...89..584S. doi:10.1073/pnas.89.2.584. PMC 48283. PMID 1309948.
  • Seino S, Yamada Y, Espinosa R, Le Beau MM, Bell GI (August 1992). "Assignment of the gene encoding the alpha 1 subunit of the neuroendocrine/brain-type calcium channel (CACNL1A2) to human chromosome 3, band p14.3". Genomics. 13 (4): 1375–7. doi:10.1016/0888-7543(92)90078-7. PMID 1324226.
  • Chin HM, Kozak CA, Kim HL, Mock B, McBride OW (December 1991). "A brain L-type calcium channel alpha 1 subunit gene (CCHL1A2) maps to mouse chromosome 14 and human chromosome 3". Genomics (Submitted manuscript). 11 (4): 914–9. doi:10.1016/0888-7543(91)90014-6. PMID 1664412.
  • Mori Y, Friedrich T, Kim MS, Mikami A, Nakai J, Ruth P, Bosse E, Hofmann F, Flockerzi V, Furuichi T (April 1991). "Primary structure and functional expression from complementary DNA of a brain calcium channel". Nature. 350 (6317): 398–402. Bibcode:1991Natur.350..398M. doi:10.1038/350398a0. PMID 1849233. S2CID 4370532.
  • Yamada Y, Masuda K, Li Q, Ihara Y, Kubota A, Miura T, Nakamura K, Fujii Y, Seino S, Seino Y (May 1995). "The structures of the human calcium channel alpha 1 subunit (CACNL1A2) and beta subunit (CACNLB3) genes". Genomics. 27 (2): 312–9. doi:10.1006/geno.1995.1048. PMID 7557998.
  • Puro DG, Hwang JJ, Kwon OJ, Chin H (April 1996). "Characterization of an L-type calcium channel expressed by human retinal Müller (glial) cells". Brain Research. Molecular Brain Research (Submitted manuscript). 37 (1–2): 41–8. doi:10.1016/0169-328X(96)80478-5. PMID 8738134.
  • Yang SN, Larsson O, Bränström R, Bertorello AM, Leibiger B, Leibiger IB, Moede T, Köhler M, Meister B, Berggren PO (August 1999). "Syntaxin 1 interacts with the L(D) subtype of voltage-gated Ca(2+) channels in pancreatic beta cells". Proceedings of the National Academy of Sciences of the United States of America. 96 (18): 10164–9. doi:10.1073/pnas.96.18.10164. PMC 17860. PMID 10468580.
  • Bell DC, Butcher AJ, Berrow NS, Page KM, Brust PF, Nesterova A, Stauderman KA, Seabrook GR, Nürnberg B, Dolphin AC (February 2001). "Biophysical properties, pharmacology, and modulation of human, neuronal L-type (alpha(1D), Ca(V)1.3) voltage-dependent calcium currents". Journal of Neurophysiology. 85 (2): 816–27. doi:10.1152/jn.2001.85.2.816. PMID 11160515. S2CID 147295966.
  • Rosenthal R, Thieme H, Strauss O (April 2001). "Fibroblast growth factor receptor 2 (FGFR2) in brain neurons and retinal pigment epithelial cells act via stimulation of neuroendocrine L-type channels (Ca(v)1.3)". FASEB Journal. 15 (6): 970–7. doi:10.1096/fj.00-0188com. PMID 11292657.
  • Davare MA, Avdonin V, Hall DD, Peden EM, Burette A, Weinberg RJ, Horne MC, Hoshi T, Hell JW (July 2001). "A beta2 adrenergic receptor signaling complex assembled with the Ca2+ channel Cav1.2". Science. 293 (5527): 98–101. doi:10.1126/science.293.5527.98. PMID 11441182.
  • Namkung Y, Skrypnyk N, Jeong MJ, Lee T, Lee MS, Kim HL, Chin H, Suh PG, Kim SS, Shin HS (October 2001). "Requirement for the L-type Ca(2+) channel alpha(1D) subunit in postnatal pancreatic beta cell generation". The Journal of Clinical Investigation. 108 (7): 1015–22. doi:10.1172/JCI13310. PMC 200955. PMID 11581302.
  • Stokes L, Gordon J, Grafton G (May 2004). "Non-voltage-gated L-type Ca2+ channels in human T cells: pharmacology and molecular characterization of the major alpha pore-forming and auxiliary beta-subunits". The Journal of Biological Chemistry. 279 (19): 19566–73. doi:10.1074/jbc.M401481200. PMID 14981074.
  • Qu Y, Baroudi G, Yue Y, Boutjdir M (June 2005). "Novel molecular mechanism involving alpha1D (Cav1.3) L-type calcium channel in autoimmune-associated sinus bradycardia". Circulation. 111 (23): 3034–41. doi:10.1161/CIRCULATIONAHA.104.517326. PMID 15939813.
  • Baroudi G, Qu Y, Ramadan O, Chahine M, Boutjdir M (October 2006). "Protein kinase C activation inhibits Cav1.3 calcium channel at NH2-terminal serine 81 phosphorylation site". American Journal of Physiology. Heart and Circulatory Physiology. 291 (4): H1614-22. doi:10.1152/ajpheart.00095.2006. PMID 16973824. S2CID 863259.
  • Olsen JV, Blagoev B, Gnad F, Macek B, Kumar C, Mortensen P, Mann M (November 2006). "Global, in vivo, and site-specific phosphorylation dynamics in signaling networks". Cell. 127 (3): 635–48. doi:10.1016/j.cell.2006.09.026. PMID 17081983. S2CID 7827573.

External links edit

  • CACNA1D+protein,+human at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • Overview of all the structural information available in the PDB for UniProt: Q01668 (Voltage-dependent L-type calcium channel subunit alpha-1D) at the PDBe-KB.

This article incorporates text from the United States National Library of Medicine, which is in the public domain.

January 01, 1970
calcium, channel, voltage, dependent, type, alpha, subunit, also, known, cav1, protein, that, humans, encoded, cacna1d, gene, cav1, channels, belong, cav1, family, which, form, type, calcium, currents, sensitive, selective, inhibition, dihydropyridines, cacna1. Calcium channel voltage dependent L type alpha 1D subunit also known as Cav1 3 is a protein that in humans is encoded by the CACNA1D gene 5 Cav1 3 channels belong to the Cav1 family which form L type calcium currents and are sensitive to selective inhibition by dihydropyridines DHP CACNA1DAvailable structuresPDBOrtholog search PDBe RCSBList of PDB id codes3LV3IdentifiersAliasesCACNA1D CACH3 CACN4 CACNL1A2 CCHL1A2 Cav1 3 PASNA SANDD calcium voltage gated channel subunit alpha1 DExternal IDsOMIM 114206 MGI 88293 HomoloGene 578 GeneCards CACNA1DGene location Human Chr Chromosome 3 human 1 Band3p21 1Start53 328 963 bp 1 End53 813 733 bp 1 Gene location Mouse Chr Chromosome 14 mouse 2 Band14 A3 B 14 18 43 cMStart29 761 896 bp 2 End30 213 412 bp 2 RNA expression patternBgeeHumanMouse ortholog Top expressed inright lungsural nerveright adrenal glandislet of Langerhanspituitary glandright uterine tubeanterior pituitaryupper lobe of left lungmiddle temporal gyrusendothelial cellTop expressed inpituitary glandsuperior frontal gyrussubstantia nigrautricleislet of Langerhanspineal glandstria vascularissuprachiasmatic nucleusvas deferensbarrel cortexMore reference expression dataBioGPSMore reference expression dataGene ontologyMolecular functionmetal ion binding voltage gated ion channel activity high voltage gated calcium channel activity ion channel activity voltage gated calcium channel activity involved in cardiac muscle cell action potential alpha actinin binding ankyrin binding voltage gated calcium channel activity voltage gated calcium channel activity involved SA node cell action potential calcium channel activity voltage gated calcium channel activity involved in positive regulation of presynaptic cytosolic calcium levelsCellular componentvoltage gated calcium channel complex L type voltage gated calcium channel complex integral component of membrane membrane plasma membrane Z disc cochlear hair cell ribbon synapse integral component of presynaptic active zone membraneBiological processregulation of atrial cardiac muscle cell membrane repolarization regulation of insulin secretion adenylate cyclase modulating G protein coupled receptor signaling pathway calcium ion import regulation of ion transmembrane transport ion transport calcium ion transmembrane transport transmembrane transport regulation of potassium ion transmembrane transporter activity membrane depolarization during cardiac muscle cell action potential regulation of potassium ion transmembrane transport calcium ion transport positive regulation of calcium ion transport sensory perception of sound cardiac muscle cell action potential involved in contraction membrane depolarization during SA node cell action potential regulation of heart rate by cardiac conduction positive regulation of presynaptic cytosolic calcium concentration induction of synaptic vesicle exocytosis by positive regulation of presynaptic cytosolic calcium ion concentration positive regulation of adenylate cyclase activity cardiac conductionSources Amigo QuickGOOrthologsSpeciesHumanMouseEntrez77612289EnsemblENSG00000157388ENSMUSG00000015968UniProtQ01668Q99246RefSeq mRNA NM 000720NM 001128839NM 001128840NM 001083616NM 028981NM 001302637RefSeq protein NP 000711NP 001122311NP 001122312NP 001077085NP 001289566NP 083257Location UCSC Chr 3 53 33 53 81 MbChr 14 29 76 30 21 MbPubMed search 3 4 WikidataView Edit HumanView Edit Mouse Contents 1 Structure and function 2 Regulation 2 1 Alternative splicing 2 2 Negative feedback 3 Clinical significance 3 1 Hearing 3 2 Chromaffin cells 3 3 Neurodegeneration 3 4 Prostate cancer 3 5 Aldosteronism 4 See also 5 References 6 Further reading 7 External linksStructure and function edit nbsp Schematic representation of the alpha subunit of VDCCs showing the four homologous domains each with six transmembrane subunits P loops are highlighted red S4 subunits are marked with a plus indicative of positive charge Voltage dependent calcium channels VDCC are selectively permeable to calcium ions mediating the movement of these ions in and out of excitable cells At resting potential these channels are closed but when the membrane potential is depolarised these channels open The influx of calcium ions into the cell can initiate a myriad of calcium dependent processes including muscle contraction gene expression and secretion Calcium dependent processes can be halted by lowering intracellular calcium levels which for example can be accomplished by calcium pumps 6 Voltage dependent calcium channels are multi proteins composed of a1 b a2d and g subunits The major subunit is a1 which forms the selectivity pore voltage sensor and gating apparatus of VDCCs In Cav1 3 channels the a1 subunit is a1D This subunit differentiates Cav1 3 channels from other members of the Cav1 family such as the predominant and better studied Cav1 2 which has an a1C subunit The significance of the a1 subunit also means that it is the primary target for calcium channel blockers such as dihydropyridines The remaining b a2d and g subunits have auxiliary functions The a1 subunit has four homologous domains each with six transmembrane segments Within each homologous domain the fourth transmembrane segment S4 is positively charged as opposed to the other five hydrophobic segments This characteristic enables S4 to function as the voltage sensor Alpha 1D subunits belong to the Cav1 family which is characterised by L type calcium currents Specifically a1D subunits confer low voltage activation and slowly inactivating Ca2 currents ideal for particular physiological functions such as neurotransmitter release in cochlea inner hair cells The biophysical properties of Cav1 3 channels are closely regulated by a C terminal modulatory domain CTM which affects both the voltage dependence of activation and Ca2 dependent inactivation 7 Cav1 3 have a low affinity for DHP and activate at sub threshold membrane potentials making them ideal for a role in cardiac pacemaking 8 Regulation editAlternative splicing edit Post transcriptional alternative splicing of Cav1 3 is an extensive and vital regulatory mechanism Alternative splicing can significantly affect the gating properties of the channel Comparable to alternative splicing of Cav1 2 transcripts which confers functional specificity 9 it has recently been discovered that alternative splicing particularly in the C terminus affects the pharmacological properties of Cav1 3 10 11 Strikingly up to 8 fold differences in dihydropyridine sensitivity between alternatively spliced isoforms have been reported 12 13 Negative feedback edit Cav1 3 channels are regulated by negative feedback to achieve Ca2 homeostasis Calcium ions are a critical second messenger intrinsic to intracellular signal transduction Extracellular calcium levels are approximated to be 12000 fold greater than intracellular levels During calcium dependent processes the intracellular level of calcium rises by up to 100 fold It is vitally important to regulate this calcium gradient not least because high levels of calcium are toxic to the cell and can induce apoptosis Ca2 bound calmodulin CaM interacts with Cav1 3 to induce calcium dependent inactivation CDI Recently it has been shown that RNA editing of Cav1 3 transcripts is essential for CDI 14 Contrary to expectation RNA editing does not simply attenuate the binding of CaM but weakens the pre binding of Ca2 free calmodulin apoCaM to channels The upshot is that CDI is continuously tuneable by changes in levels of CaM Clinical significance editHearing edit Cav1 3 channels are widely expressed in humans 15 Notably their expression predominates in cochlea inner hair cells IHCs Cav1 3 have been shown through patch clamp experiments to be essential for normal IHC development and synaptic transmission 16 Therefore Cav1 3 are required for proper hearing 17 Chromaffin cells edit Cav1 3 are densely expressed in chromaffin cells The low voltage activation and slow inactivation of these channels makes them ideal for controlling excitability in these cells Catecholamine secretion from chromaffin cells is particularly sensitive to L type currents associated with Cav1 3 Catecholamines have many systemic effects on multiple organs In addition L type channels are responsible for exocytosis in these cells 18 Neurodegeneration edit Parkinson s disease is the second most common neurodegenerative disease in which the death of dopamine producing cells in the substantia nigra of the midbrain leads to impaired motor function perhaps best characterised by tremor Recent evidence suggests that L type Cav1 3 Ca2 channels contribute to the death of dopaminergic neurones in patients with Parkinson s disease 8 The basal activity of these neurones is also dependent on L type Ca2 channels such as Cav1 3 Continuous pacemaking activity drives permanent intracellular dendritic and somatic calcium transients which appears to make the dopaminergic substantia nigra neurones vulnerable to stressors that contribute to their death Therefore inhibition of L type channels in particular Cav1 3 is protective against the pathogenesis of Parkinson s in some animal models 8 19 A clinical phase III trial STEADY PD III Archived 2019 04 07 at the Wayback Machine testing this hypothesis in patients with early Parkinsons s failed to show efficacy in slowing the progression of Parkinson s 20 Inhibition of Cav1 3 can be achieved using calcium channel blockers such as dihydropyridines DHPs These drugs are used since decades to treat arterial hypertension and angina This is due to their potent vasorelaxant properties which are mediated by the inhibition of Cav1 2 L type calcium channels in arterial smooth muscle 15 Therefore hypotensive reactions and leg edema are regarded dose limiting side effects when using DHPs for inhibiting Cav1 3 channel in the brain 21 In the face of this issue attempts have been made to discover selective Cav1 3 channel blockers One candidate has been claimed to be a potent and highly selective inhibitor of Cav1 3 This compound 1 3 chlorophenethyl 3 cyclopentylpyrimidine 2 4 6 1H 3H 5H trione was therefore put forward as a candidate for the future treatment of Parkinson s 22 However its selectivity and potency could not be confirmed in two independent studies from two other groups 23 One of them even reported gating changes induced by this drug which indicate channel activating rather than blocking effects 24 Prostate cancer edit Recent evidence from immunostaining experiments shows that CACNA1D is highly expressed in prostate cancers compared with benign prostate tissues Blocking L type channels or knocking down gene expression of CACNA1D significantly suppressed cell growth in prostate cancer cells 25 It is important to recognise that this association does not represent a causal link between high levels of a1D protein and prostate cancer Further investigation is needed to explore the role of CACNA1D gene overexpression in prostate cancer cell growth Aldosteronism edit De novo somatic mutations in conserved regions within the channel s activation gate of its pore forming a1 subunit CACNA1D cause excessive aldosterone production in aldosterone producing adenomas APA resulting in primary aldosteronism which causes treatment resistant arterial hypertension These mutations allow increased Ca2 influx through Cav1 3 which in turn triggers Ca2 dependent aldosterone production 26 27 The number of validated APA mutations is constantly growing 28 In rare cases APA mutations have also been found as germline mutations in individuals with neurodevelopmental disorders of different severity including autism spectrum disorder 26 28 29 See also editCalcium channelReferences edit a b c GRCh38 Ensembl release 89 ENSG00000157388 Ensembl May 2017 a b c GRCm38 Ensembl release 89 ENSMUSG00000015968 Ensembl May 2017 Human PubMed Reference National Center for Biotechnology Information U S National Library of Medicine Mouse PubMed Reference National Center for Biotechnology Information U S National Library of Medicine Entrez Gene CACNA1D calcium channel voltage dependent L type alpha 1D subunit Brown BL Walker SW Tomlinson S August 1985 Calcium calmodulin and hormone secretion Clinical Endocrinology 23 2 201 18 doi 10 1111 j 1365 2265 1985 tb00216 x PMID 2996810 S2CID 45017291 Lieb A Scharinger A Sartori S Sinnegger Brauns MJ Striessnig J 2012 Structural determinants of CaV1 3 L type calcium channel gating Channels 6 3 197 205 doi 10 4161 chan 21002 PMC 3431584 PMID 22760075 a b c Chan CS Guzman JN Ilijic E Mercer JN Rick C Tkatch T Meredith GE Surmeier DJ June 2007 Rejuvenation protects neurons in mouse models of Parkinson s disease Nature 447 7148 1081 6 Bibcode 2007Natur 447 1081C doi 10 1038 nature05865 PMID 17558391 S2CID 4429534 Liao P Yu D Lu S Tang Z Liang MC Zeng S Lin W Soong TW November 2004 Smooth muscle selective alternatively spliced exon generates functional variation in Cav1 2 calcium channels The Journal of Biological Chemistry 279 48 50329 35 doi 10 1074 jbc m409436200 PMID 15381693 Singh A Gebhart M Fritsch R Sinnegger Brauns MJ Poggiani C Hoda JC Engel J Romanin C Striessnig J Koschak A July 2008 Modulation of voltage and Ca2 dependent gating of CaV1 3 L type calcium channels by alternative splicing of a C terminal regulatory domain The Journal of Biological Chemistry 283 30 20733 44 doi 10 1074 jbc M802254200 PMC 2475692 PMID 18482979 Tan BZ Jiang F Tan MY Yu D Huang H Shen Y Soong TW December 2011 Functional characterization of alternative splicing in the C terminus of L type CaV1 3 channels The Journal of Biological Chemistry 286 49 42725 35 doi 10 1074 jbc M111 265207 PMC 3234967 PMID 21998309 Huang H Yu D Soong TW October 2013 C terminal alternative splicing of CaV1 3 channels distinctively modulates their dihydropyridine sensitivity Molecular Pharmacology 84 4 643 53 doi 10 1124 mol 113 087155 PMID 23924992 S2CID 22439331 Ortner NJ Bock G Dougalis A Kharitonova M Duda J Hess S Tuluc P Pomberger T Stefanova N Pitterl F Ciossek T Oberacher H Draheim HJ Kloppenburg P Liss B Striessnig J July 2017 2 Channels during Substantia Nigra Dopamine Neuron Like Activity Implications for Neuroprotection in Parkinson s Disease The Journal of Neuroscience 37 28 6761 6777 doi 10 1523 JNEUROSCI 2946 16 2017 PMC 6596555 PMID 28592699 Bazzazi H Ben Johny M Adams PJ Soong TW Yue DT October 2013 Continuously tunable Ca 2 regulation of RNA edited CaV1 3 channels Cell Reports 5 2 367 77 doi 10 1016 j celrep 2013 09 006 PMC 4349392 PMID 24120865 a b Zamponi GW Striessnig J Koschak A Dolphin AC October 2015 The Physiology Pathology and Pharmacology of Voltage Gated Calcium Channels and Their Future Therapeutic Potential Pharmacological Reviews 67 4 821 70 doi 10 1124 pr 114 009654 PMC 4630564 PMID 26362469 Brandt A Striessnig J Moser T November 2003 CaV1 3 channels are essential for development and presynaptic activity of cochlear inner hair cells The Journal of Neuroscience 23 34 10832 40 doi 10 1523 JNEUROSCI 23 34 10832 2003 PMC 6740966 PMID 14645476 Platzer J Engel J Schrott Fischer A Stephan K Bova S Chen H Zheng H Striessnig J July 2000 Congenital deafness and sinoatrial node dysfunction in mice lacking class D L type Ca2 channels Cell 102 1 89 97 doi 10 1016 S0092 8674 00 00013 1 PMID 10929716 S2CID 17923472 Vandael DH Mahapatra S Calorio C Marcantoni A Carbone E July 2013 Cav1 3 and Cav1 2 channels of adrenal chromaffin cells emerging views on cAMP cGMP mediated phosphorylation and role in pacemaking Biochimica et Biophysica Acta BBA Biomembranes 1828 7 1608 18 doi 10 1016 j bbamem 2012 11 013 hdl 2318 132208 PMID 23159773 Liss B Striessnig J January 2019 The Potential of L Type Calcium Channels as a Drug Target for Neuroprotective Therapy in Parkinson s Disease Annual Review of Pharmacology and Toxicology 59 1 263 289 doi 10 1146 annurev pharmtox 010818 021214 PMID 30625283 S2CID 58619079 Hoffman M 5 May 2019 Isradipine Fails to Slow Early Parkinson Disease Progression in Phase 3 Study NeurologyLive Retrieved 2019 11 25 Parkinson Study Group November 2013 Phase II safety tolerability and dose selection study of isradipine as a potential disease modifying intervention in early Parkinson s disease STEADY PD Movement Disorders 28 13 1823 31 doi 10 1002 mds 25639 PMID 24123224 S2CID 9594193 Kang S Cooper G Dunne SF Dusel B Luan CH Surmeier DJ Silverman RB 2012 CaV1 3 selective L type calcium channel antagonists as potential new therapeutics for Parkinson s disease Nature Communications 3 1146 Bibcode 2012NatCo 3 1146K doi 10 1038 ncomms2149 PMID 23093183 Huang H Ng CY Yu D Zhai J Lam Y Soong TW July 2014 Modest CaV1 342 selective inhibition by compound 8 is b subunit dependent Nature Communications 5 4481 Bibcode 2014NatCo 5 4481H doi 10 1038 ncomms5481 PMC 4124865 PMID 25057870 Ortner NJ Bock G Vandael DH Mauersberger R Draheim HJ Gust R Carbone E Tuluc P Striessnig J June 2014 Pyrimidine 2 4 6 triones are a new class of voltage gated L type Ca2 channel activators Nature Communications 5 3897 Bibcode 2014NatCo 5 3897O doi 10 1038 ncomms4897 PMC 4083433 PMID 24941892 Ortner NJ Bock G Vandael DH Mauersberger R Draheim HJ Gust R Carbone E Tuluc P Striessnig J June 2014 Pyrimidine 2 4 6 triones are a new class of voltage gated L type Ca2 channel activators Nature Communications 5 3897 Bibcode 2014NatCo 5 3897O doi 10 1038 ncomms4897 PMC 4083433 PMID 24941892 Chen R Zeng X Zhang R Huang J Kuang X Yang J Liu J Tawfik O Thrasher JB Li B July 2014 Cav1 3 channel a1D protein is overexpressed and modulates androgen receptor transactivation in prostate cancers Urologic Oncology 32 5 524 36 doi 10 1016 j urolonc 2013 05 011 PMID 24054868 a b Scholl UI Goh G Stolting G de Oliveira RC Choi M Overton JD Fonseca AL Korah R Starker LF Kunstman JW Prasad ML Hartung EA Mauras N Benson MR Brady T Shapiro JR Loring E Nelson Williams C Libutti SK Mane S Hellman P Westin G Akerstrom G Bjorklund P Carling T Fahlke C Hidalgo P Lifton RP September 2013 Somatic and germline CACNA1D calcium channel mutations in aldosterone producing adenomas and primary aldosteronism Nature Genetics 45 9 1050 4 doi 10 1038 ng 2695 PMC 3876926 PMID 23913001 Azizan EA Poulsen H Tuluc P Zhou J Clausen MV Lieb A Maniero C Garg S Bochukova EG Zhao W Shaikh LH Brighton CA Teo AE Davenport AP Dekkers T Tops B Kusters B Ceral J Yeo GS Neogi SG McFarlane I Rosenfeld N Marass F Hadfield J Margas W Chaggar K Solar M Deinum J Dolphin AC Farooqi IS Striessnig J Nissen P Brown MJ September 2013 Somatic mutations in ATP1A1 and CACNA1D underlie a common subtype of adrenal hypertension Nature Genetics 45 9 1055 60 doi 10 1038 ng 2716 PMID 23913004 S2CID 205347424 a b Pinggera A Striessnig J October 2016 2 channel dysfunction in CNS disorders The Journal of Physiology 594 20 5839 5849 doi 10 1113 JP270672 PMC 4823145 PMID 26842699 Pinggera A Negro G Tuluc P Brown MJ Lieb A Striessnig J January 2018 2 channels Channels 12 1 388 402 doi 10 1080 19336950 2018 1546518 PMC 6287693 PMID 30465465 Further reading editWilliams ME Feldman DH McCue AF Brenner R Velicelebi G Ellis SB Harpold MM January 1992 Structure and functional expression of alpha 1 alpha 2 and beta subunits of a novel human neuronal calcium channel subtype Neuron 8 1 71 84 doi 10 1016 0896 6273 92 90109 Q PMID 1309651 S2CID 39341712 Seino S Chen L Seino M Blondel O Takeda J Johnson JH Bell GI January 1992 Cloning of the alpha 1 subunit of a voltage dependent calcium channel expressed in pancreatic beta cells Proceedings of the National Academy of Sciences of the United States of America 89 2 584 8 Bibcode 1992PNAS 89 584S doi 10 1073 pnas 89 2 584 PMC 48283 PMID 1309948 Seino S Yamada Y Espinosa R Le Beau MM Bell GI August 1992 Assignment of the gene encoding the alpha 1 subunit of the neuroendocrine brain type calcium channel CACNL1A2 to human chromosome 3 band p14 3 Genomics 13 4 1375 7 doi 10 1016 0888 7543 92 90078 7 PMID 1324226 Chin HM Kozak CA Kim HL Mock B McBride OW December 1991 A brain L type calcium channel alpha 1 subunit gene CCHL1A2 maps to mouse chromosome 14 and human chromosome 3 Genomics Submitted manuscript 11 4 914 9 doi 10 1016 0888 7543 91 90014 6 PMID 1664412 Mori Y Friedrich T Kim MS Mikami A Nakai J Ruth P Bosse E Hofmann F Flockerzi V Furuichi T April 1991 Primary structure and functional expression from complementary DNA of a brain calcium channel Nature 350 6317 398 402 Bibcode 1991Natur 350 398M doi 10 1038 350398a0 PMID 1849233 S2CID 4370532 Yamada Y Masuda K Li Q Ihara Y Kubota A Miura T Nakamura K Fujii Y Seino S Seino Y May 1995 The structures of the human calcium channel alpha 1 subunit CACNL1A2 and beta subunit CACNLB3 genes Genomics 27 2 312 9 doi 10 1006 geno 1995 1048 PMID 7557998 Puro DG Hwang JJ Kwon OJ Chin H April 1996 Characterization of an L type calcium channel expressed by human retinal Muller glial cells Brain Research Molecular Brain Research Submitted manuscript 37 1 2 41 8 doi 10 1016 0169 328X 96 80478 5 PMID 8738134 Yang SN Larsson O Branstrom R Bertorello AM Leibiger B Leibiger IB Moede T Kohler M Meister B Berggren PO August 1999 Syntaxin 1 interacts with the L D subtype of voltage gated Ca 2 channels in pancreatic beta cells Proceedings of the National Academy of Sciences of the United States of America 96 18 10164 9 doi 10 1073 pnas 96 18 10164 PMC 17860 PMID 10468580 Bell DC Butcher AJ Berrow NS Page KM Brust PF Nesterova A Stauderman KA Seabrook GR Nurnberg B Dolphin AC February 2001 Biophysical properties pharmacology and modulation of human neuronal L type alpha 1D Ca V 1 3 voltage dependent calcium currents Journal of Neurophysiology 85 2 816 27 doi 10 1152 jn 2001 85 2 816 PMID 11160515 S2CID 147295966 Rosenthal R Thieme H Strauss O April 2001 Fibroblast growth factor receptor 2 FGFR2 in brain neurons and retinal pigment epithelial cells act via stimulation of neuroendocrine L type channels Ca v 1 3 FASEB Journal 15 6 970 7 doi 10 1096 fj 00 0188com PMID 11292657 Davare MA Avdonin V Hall DD Peden EM Burette A Weinberg RJ Horne MC Hoshi T Hell JW July 2001 A beta2 adrenergic receptor signaling complex assembled with the Ca2 channel Cav1 2 Science 293 5527 98 101 doi 10 1126 science 293 5527 98 PMID 11441182 Namkung Y Skrypnyk N Jeong MJ Lee T Lee MS Kim HL Chin H Suh PG Kim SS Shin HS October 2001 Requirement for the L type Ca 2 channel alpha 1D subunit in postnatal pancreatic beta cell generation The Journal of Clinical Investigation 108 7 1015 22 doi 10 1172 JCI13310 PMC 200955 PMID 11581302 Stokes L Gordon J Grafton G May 2004 Non voltage gated L type Ca2 channels in human T cells pharmacology and molecular characterization of the major alpha pore forming and auxiliary beta subunits The Journal of Biological Chemistry 279 19 19566 73 doi 10 1074 jbc M401481200 PMID 14981074 Qu Y Baroudi G Yue Y Boutjdir M June 2005 Novel molecular mechanism involving alpha1D Cav1 3 L type calcium channel in autoimmune associated sinus bradycardia Circulation 111 23 3034 41 doi 10 1161 CIRCULATIONAHA 104 517326 PMID 15939813 Baroudi G Qu Y Ramadan O Chahine M Boutjdir M October 2006 Protein kinase C activation inhibits Cav1 3 calcium channel at NH2 terminal serine 81 phosphorylation site American Journal of Physiology Heart and Circulatory Physiology 291 4 H1614 22 doi 10 1152 ajpheart 00095 2006 PMID 16973824 S2CID 863259 Olsen JV Blagoev B Gnad F Macek B Kumar C Mortensen P Mann M November 2006 Global in vivo and site specific phosphorylation dynamics in signaling networks Cell 127 3 635 48 doi 10 1016 j cell 2006 09 026 PMID 17081983 S2CID 7827573 External links editCACNA1D protein human at the U S National Library of Medicine Medical Subject Headings MeSH Overview of all the structural information available in the PDB for UniProt Q01668 Voltage dependent L type calcium channel subunit alpha 1D at the PDBe KB This article incorporates text from the United States National Library of Medicine which is in the public domain Retrieved from https en 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