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| Hv1 proton channels are required for high-level NADPH oxidase-dependent superoxide production during the phagocyte respiratory burst | Ramsey, Ruchti, Kaczmarek, Clapham | PNAS | 2009 | PDF | | |
| Essential role for TRPC5 in amygdala function and fear-related behavior | Riccio et al | Cell | 2009 | PDF | | |
| TRPM1 forms ion channels associated with melanin content in melanocytes | Oancea, E. Vriens, J. Brauchi, S. et al. | Sci Signal | 2009 | PDF | | |
| Intracellular calcium strongly potentiates agonist-activated TRPC5 channels | Blair, N. T. Kaczmarek, J. S. et al. | J Gen Physiol | 2009 | PDF | | |
| TRPM7 facilitates cholinergic vesicle fusion with the plasma membrane. | Brauchi S, Krapivinsky G, Krapivinsky L, et al. | PNAS | 2008 | PDF | | |
| Citral sensing by transient receptor potential channels in dorsal root ganglion neurons. | Stotz, SC, Vriens, J, Martyn, D, et al. | PLoS One | 2008 | PDF | | |
| Deletion of Trpm7 Disrupts Embryonic Development and Thymopoiesis Without Altering Mg2+ Homeostasis | Jie Jin,Bimal N. Desai, Betsy Navarro, et al. | Science | 2008 | PDF | | |
| Transient Receptor Potential (TRP) Channels | Clapham, DE | Encyclopedia of Neuroscience | 2008 | PDF | | |
| Evolutionary genomics reveals lineage-specific gene loss and rapid evolution of a sperm-specific ion channel complex: CatSpers and CatSper beta | Cai, X and Clapham, DE | PLoS One | 2008 | PDF | | |
| All four CatSper ion channel proteins are required for male fertility and sperm cell hyperactivated motility. | Qi, H, Moran, MM, Navarro, B, et al. | PNAS | 2007 | PDF | | |
| TRPC Canonical (Short) TRP Channel Table | Clapham Lab | Clapham Lab | 2007 | PDF | | |
| TRP Channels Table - TRPA (Ankyrin), TRPP (Polycystins), TRPML (mucolipins) | Clapham Lab | Clapham Lab | 2007 | PDF | | |
| TRPM Channel Family (Melastatin-Related, Long TRPs) Table | Clapham Lab | Clapham Lab | 2007 | PDF | | |
| TRPV Channel Family (Vanilloid) Table | Clapham Lab | Clapham Lab | 2007 | PDF | | |
| KSper, a pH-sensitive K+ current that controls sperm membrane potential. | Navarro, B, Kirichok, Y, and Clapham, et al. | PNAS | 2007 | PDF | | |
| CatSper beta: A novel transmembrane protein in the CatSper channel complex | Jin Liu, Jingsheng Xia, Kwang-Hyun Cho, et al. | JBC | 2007 | PDF | | |
| Activating mutation in a mucolipin transient receptor potential channel leads to melanocyte loss in varitint–waddler mice | Xu, Delling, Li, Dong, Clapham | PNAS | 2007 | PDF | | |
| Functional TRPM7 channels accumulate at the plasma membrane in response to fluid flow | Elena Oancea, Joshua Wolfe, David E. et al. | Circulation Research | 2006 | PDF | | |
| Whole-cell patch-clamp measurements of spermatazoa reveal an alkaline-activated Ca channel | Yuriy Kirichok, Betsy Navarro, and David et al. | Nature | 2006 | PDF | | |
| International Union of Pharmacology. XLIX. Nomenclature and structure-function relationships of transient receptor potential channels | Clapham, DE, Julius, DJ, Montell, C, et al. | Pharm Rev | 2006 | PDF | | |
| An Introduction to TRP Channels | I. Scott Ramsey, Markus Delling, and et al. | Annual Reviews of Physiology | 2006 | PDF | | |
| Flavors and skin sensitizers activate specific TRP channels. | Xu, Delling, Jun, Clapham | Nature Neuroscience | 2006 | PDF | | |
| A voltage-gated proton-selective channel lacking the pore domain. | Ramsey, Moran, Chong, Clapham | Nature | 2006 | PDF | | |
| Bisandrographalide from Andrographis Paniculata activates TRPV4 channels | Smith, Maloney, Pothen, Clardy, Clapham | Journal of Biological Chemistry | 2006 | PDF | HTML | |
| The TRPM7 ion channel functions in cholinergic synaptic vesicles and affects transmitter release. | Krapivinsky, G, Mochida, S, Krapivinsky, L, et al. | Neuron | 2006 | PDF | | |
| TRPC6 is a glomerular slit diaphragm-associated channel requiredd for normal renal function | Reiser, Polu, Moller, Kenlan, Altintas, Wei, et al. | Nature Genetics | 2005 | PDF | | |
| TRP channels and mice deficient in TRP channels. | Desai, B and Clapham, DE | Pfluegers’ Arch Eur. J Physiol, | 2005 | PDF | | |
| TATA-Binding Protein (TBP)-Like Factor (TLF) Is a Functional Regulator of Transcription: Reciprocal Regulation of the Neurofibromatosis Type 1 and c-fos Genes by TLF/TRF2 and TBP | Jayhong A. Chong, Magdalene M. Moran, et al. | MOLECULAR AND CELLULAR BIOLOGY, | 2005 | PDF | | Suppl. Data |
| Camphor Activates and Strongly Desensitizes the Transient Receptor Potential Vanilloid Subtype 1 Channel in a Vanilloid-Independent Mechanism | Haoxing Xu, Nat Blair, and David et al. | Journal of Neuroscience | 2005 | PDF | | |
| International Union of Pharmacology. XLIX. Nomenclature and structure-function relationships of of CatSper and Two-Pore Channels. | Clapham, DE, and Garbers, DL | Pharmacol Rev. | 2005 | PDF | | |
| International Union of Pharmacology. LIV. Nomenclature and Molecular Relationships of Inwardly Rectifying Potassium Channels | Kubo, Y, Adelman, JP, Clapham, DE, et al. | Pharmacol Rev. | 2005 | PDF | | |
| A Superfamily of Voltage-gated Sodium Channels in Bacteria | Ryuta Koishi, Haoxing Xu, Dejian Ren, et al. | Journal of Biological Chemistry | 2004 | PDF | | |
| The mitochondrial calcium uniporteris a highly selective ion channel | Yuriy Kirichok, Grigory Krapivinsky & David et al. | Nature | 2004 | PDF | | |
| A spontaneous, recurrent mutation in Divalent Metal Transporter-1 exposes a calcium entry pathway
in Divalent Metal Transporter-1
Exposes a Calcium Entry Pathway | Haoxing Xu, Jie Jin, Louis et al. | Public Library of Science (PLoS) | 2004 | PDF | | |
| TRP ion channels in the nervous system | Magdalene M Moran, Haoxing Xu and et al. | Current Opinions in Neurobiology | 2004 | PDF | | |
| The voltage-gated Na+ channel NaVBP has a rolein motility, chemotaxis, and pH homeostasisof an alkaliphilic Bacillus | Masahiro Ito, Haoxing Xu, Arthur A. et al. | PNAS | 2004 | PDF | | |
| Rapid vesicular translocation and insertion ofTRP channels | Vassilios J. Bezzerides, I. Scott Ramsey, et al. | Nature Cell Biology | 2004 | PDF | | |
| SynGAP-MUPP1-CaMKII Synaptic Complexes Regulatep38 MAP Kinase Activity and NMDA Receptor-Dependent Synaptic AMPA Receptor Potentiation | Grigory Krapivinsky, Igor Medina,Luba Krapivinsky, Svetlana et al. | Neuron | 2004 | PDF | | |
| Phosphatidylinositol 3-Kinase Activates ERK in Primary
Sensory Neurons and Mediates Inflammatory Heat
Hyperalgesia through TRPV1 Sensitization | Zhi-Ye Zhuang, Haoxing Xu, David E. et al. | The Journal of Neuroscience | 2004 | PDF | | |
| Real-Time Imaging of Nuclear Permeation by EGFP in Single | Xunbin Wei, Vanessa G. Henke, Carsten et al. | Biophysical Journal | 2003 | PDF | | |
| Mechanism of Persistent Protein Kinase D1 Translocation and Activation | Elena Oancea, Vassilios J. Bezzerides, Anna et al. | Developmental Cell | 2003 | PDF | | |
| Formation of novel TRPC channels by complex subunit interactions in embryonic brain | Carsten Strübing, Grigory Krapivinsky, Luba Krapivinsky, et al. | The Journal of Biological Chemistry | 2003 | PDF | | |
| The NMDA Receptor Is Coupled to the ERK Pathway by a Direct Interaction
between NR2B and RasGRF1 | Krapivinsky, Krapivinsky, Manasian, Ivanov, Tyzio, Pellegrino, et al. | Neuron | 2003 | PDF | | |
| TRPC5 is a regulator of hippocampal neurite length and growth cone morphology | Greka, A, Navarro, B, Oancea, E, et al. | Nature Neuroscience | 2003 | PDF | | |
| Formation of Novel TRPC Channels by Complex Subunit Interactions in Embryonic Brain | Carsten Struebing, Grigory Krapivinsky, Luba Krapivinsky, et al. | The Journal of Biological Chemistry | 2003 | PDF | | |
| Transient Receptor Potential Ion Channels | Clapham, Julius, Montell, Schultz | IUPHAR Compendium | 2003 | PDF | | |
| CatSper1 required for evoked Ca2+ entry and control of flagellar function in sperm. | Carlson, AE, Westenbroek, RE, Quill, T, et al. | PNAS | 2003 | PDF | | |
| TRP channels as cellular sensors | Clapham, DE | Nature | 2003 | PDF | | |
| Symmetry, Selectivity, and the 2003 Nobel Prize | Clapham, DE | Cell | 2003 | PDF | | |
| TRP CHANNELS | Clapham, DE | For Clapham WEB site clapham.tch.harvard.edu | 2003 | PDF | | |
| A superfamily of voltage-gated sodium channels in bacteria. | Koishi, R, Xu, H, Ren, D, et al. | The Journal of Biological Chemistry | 2003 | PDF | | |
| International Union of Pharmacology. XLI.
Compendium of Voltage-Gated Ion Channels:
Potassium Channels | GEORGE A. GUTMAN, K. GEORGE CHANDY, et al. | PHARMACOLOGICAL REVIEWS | 2003 | PDF | | |
| International Union of Pharmacology. XLIII.
Compendium of Voltage-Gated Ion Channels:
Transient Receptor Potential Channels | DAVID E. CLAPHAM, CRAIG MONTELL, GUENTER et al. | PHARMACOLOGICAL REVIEWS | 2003 | PDF | | |
| International Union of Pharmacology: Approaches to
the Nomenclature of Voltage-Gated Ion Channels | W. A. CATTERALL, K. G. CHANDY, et al. | PHARMACOLOGICAL REVIEWS | 2003 | PDF | | |
| Hot and cold ion channels | Clapham | Science | 2002 | PDF | | |
| Structural characterization of the mouse Girk genes | Wickman, Pu, and Clapham | Gene | 2002 | PDF | | |
| The TRPM7 channel is inactivated by PIP2 hydrolysis | Runnels, L, Yue, L, and Clapham, et al. | Nature Cell Biology | 2002 | PDF | | |
| Supplementary data to Xu, Ramsey, Kotecha et al | Xu, Ramsey, Kotecha et al | Nature | 2002 | PDF | | |
| TRPV3 is a calcium-permeable temperature-sensitive cation channel | Haoxing Xu, I. Scott Ramsey, et al. | Nature | 2002 | PDF | | |
| Sorting out MIC, TRP, and CRAC ion channels | Clapham, DE | The Journal of General Physiology | 2002 | PDF | | |
| The cation selectivity filter of the bacterial sodium channel, NaChBac. | Yue, L, Navarro, B, Ren, et al. | The Journal of General Physiology, 2002, DOI:10.1085/jgp 20028699. | 2002 | PDF | | |
| Modified herpes simplex virus delivery of enhanced GFP into the central nervous system | Sandler, V, Wang, S, Angelo, K, et al. | Journal of Neuroscience Methods | 2002 | PDF | | |
| The TRP Ion Channel Family | Clapham, DE, Montell, C, Schultz, G, et al. | IUPHAR Compendium | 2002 | PDF | | |
| A voltage-gated ion channel expressed specifically in spermatozoa | Timothy A. Quill, Dejian Ren, David et al. | Proceedings of the National Academy of Sciences | 2002 | PDF | | |
| TRP-PLIK, a bifunctional protein with kinase and ion channel activities | Runnels, Yue, Clapham | Science | 2001 | PDF | | |
| TRPC1 and TRPC5 form a novel cation channel in mammalian brain | Strübing, Krapivinsky, Krapivinsky, Clapham | Neuron | 2001 | PDF | | |
| CaT1 manifests the pore properties of the calcium-release-activated calcium channel | Yue, Peng, Hediger, Clapham | Nature | 2001 | PDF | | |
| How to lose your hippocampus by working on chloride channels | Clapham | Neuron | 2001 | PDF | | |
| The stoichiometry of G-beta/gamma binding G-protein-regulated inwardly rectifying K+ channels (GIRKs) | Corey, Clapham | JBC | 2001 | PDF | | |
| Fundamental Ca2+ signaling mechanisms in mouse dendritic cells: CRAC is the major Ca2+ entry pathway | Hsu, O'Connell, Klyachko, et al. | J Immunol | 2001 | PDF | | |
| Evaluation of the role of I-kach in atrial fibrillation using a mouse knockout model | Kovoor, Wickman, Maguire, et al. | J Amer Coll Cardio | 2001 | PDF | | |
| A sperm ion channel required for sperm motility and male fertility | Ren, Navarro, Perez, et al. | Nature | 2001 | PDF | | |
| The TRP ion channel family | Clapham, Runnels, and Strubing | Nature | 2001 | PDF | | |
| A prokaryotic voltage-gated sodium channel | Ren, Navarro, Xu, Yu, Shi, and et al. | Science | 2001 | PDF | | |
| Function and biochemical evidence for G-protein-gated inwardly rectifying K+ (GIRK) channels composed of GIRK2 and GIRK3 | Jelacic, Kennedy, Wickman, Clapham | JBC | 2000 | PDF | | |
| Distinct ion channel classes are expressed in the outer nuclear envelope of T- and B-lymphocyte cell lines | Franco-Obregon, Wang, Clapham | Biophys J | 2000 | PDF | | |
| A switch mechanism for G-beta/gamma activation of I-kach | Medina, Krapivinsky, Arnold, et al. | JBC | 2000 | PDF | | |
| Brain localization and behavioral impact of the G-protein-gated K+ channel subunit GIRK4 | Wickman, Karschin, Karschin, Picciotto. Clapham | J Neurosci | 2000 | PDF | | |
| ICln is essential for cellular and early embryonic viability | Pu, Wickman | J Biol Chem | 2000 | PDF | | |
| Molecular determinants for subcellular localization of PSD-95 with an interacting K+ channel | Arnold, Clapham | Neuron | 1999 | PDF | | |
| More pieces of the K+ ion channel puzzle | Clapham | Nature Struct Bio | 1999 | PDF | | |
| Functional expression and characterization of G-protein gated inwardly rectifying K+ channels containing GIRK3 | Jelacic, Sims | J Memb Biol | 1999 | PDF | | |
| GIRK4 confers appropriate processing and cell surface localization to G-protein-gated potassium channels | Kennedy, Nemec, Corey, Wickman | JBC | 1999 | PDF | | |
| G-beta/gamma binding increases the open time of Ikach: kinetic evidence for multiple G-beta/gamma binding sites | Nemec, Wickman | Biophys J | 1999 | PDF | | |
| Conformational changes of the in situ nuclear pore complex | Wang, Clapham | Biophys J | 1999 | PDF | | |
| pICln binds to a mammalian homolog of a yeast protein involved in regulation of cell morphology | Krapivinsky, Wickman, Pu, Krapivinsky | JBC | 1998 | PDF | | |
| A novel inward rectifier K+ channel with unique pore properties | Krapivinsky, Medina, Eng, et al. | Neuron | 1998 | PDF | | |
| NMDA receptors amplify calcium influx into dendritic spines during associative pre- and post-synaptic activation | Schiller, Schiller, Clapham | Nature | 1998 | PDF | | |
| Active nuclear import and export is independent of lumenal Ca2+ stores in intact mammalian cells | Strübing, Clapham | J Gen Physiol | 1998 | PDF | | |
| Abnormal heart rate regulation in GIRK4 knockout mice | Wickman, Nemec, Gendler | Neuron | 1998 | PDF | | |
| Identification of native atrial G-protein-regulated inwardly rectifying K+ (GIRK4) channel homomultimers | Corey, Clapham | JBC | 1998 | PDF | | |
| Number and stoichiometry of subunits in the native atrial G-protein-gated K+ channle, Ikach | Corey, Krapivinsky, Krapivinsky | JBC | 1998 | PDF | | |
| Localization and interaction of epitope-tagged GIRK1 and CIR inward rectifier K+ channel subunits | Kennedy, Nemec | Neuropharm | 1998 | PDF | | |
| G beta/gamma binding to GIRK4 subunit is critical for G-protein-gated K+ channel activation | Krapivinsky, Kennedy, Nemec, et al. | JBC | 1998 | PDF | | |
| Ion Channels: Basic Science and Clinical Disease | Ackerman, M, and Clapham DE | New England Journal of Medicine | 1997 | PDF | | |
| Cloning of a Xenopus laevis inwardly rectifying K+ channel subunit that permits GIRK1 expression of Ikach currents in oocytes | Hedin, Lim, Clapham | Neuron | 1996 | PDF | | |
| Non-selective and G beta/gamma insensitive weaver K+ channels | Navarro, Kennedy, Velimirovic, et al. | Science | 1996 | PDF | | |
| Conformational states of the nuclear pore complex induced by depletion of nuclear Ca2+ stores | Perez-Terzic, Pyle, Jaconi, Stehno-Bittel | Science | 1996 | PDF | | |
| Diffusion across the nuclear envelope inhibited by depletion of the nuclear Ca2+ store | Stehno-BIttel, Perez-Terzic | Science | 1995 | PDF | | |
| The G-protein gated atrial K+ channel Ikach is a heterodimer of two inwardly rectifying K+ channel proteins | Krapivinky, Gordon, Wickman, et al. | Nature | 1995 | PDF | | |
| G-beta/gamma binds directly to the G-protein gated K+ channel, Ikach | Krapivinsky, Krapivinsky, Wickman | J Biol Chem | 1995 | PDF | | |
| The G protein beta/gamma subunit transduces the muscarinic receptor signal for Ca2+ release in xenopus oocytes | Stehno-BIttel, Krapivinksy, Krapivinksy, Perez-Terzic | J Biol Chem | 1995 | PDF | | |
| Calcium release from the nucleus by pIns3 Receptor Channels | Stehno-BIttel, Luckhoff | Neuron | 1995 | PDF | | |
| Calcium Signalling: Review | Clapham | Cell | 1995 | PDF | | |
| Molecular characterization of a swelling-induced chloride conductance regulatory protein, pICln | Krapivinsky, Ackerman, Gordon, Krapivinsky | Cell | 1994 | PDF | | |
| Recombinant G-protein beta/gamma subunits activate the muscarinic-gated atrial potassium channel | Wickman, Iniguez-Liuhl, Davenport, et al. | Nature | 1994 | PDF | | |
| Optical modifications enabling simultaneous confocal imaging with dyes excited by ultraviolet- and visible-wavelength light | Bliton, Lechleiter | J Microscopy | 1993 | PDF | | |
| Acceleration of intracellular calcium waves in xenopus oocytes by calcium influx | Girard, Clapham | Science | 1993 | PDF | | Video |
| Inositol 1,3,4,5-tetrakisphosphate activates an endothelial Ca2+ permeable channel | Luckhoff, Clapham | Nature | 1992 | PDF | | |
| New mammalian chloride channel identified by expression cloning | Paulmichl, M, Li, Y, Wickman, K, et al. | Nature | 1992 | PDF | | |
| Cloning and expression of a rat cardiac delayed rectifier potassium channel | Paulmichl, Nasmith, Hellmiss, et al. | PNAS | 1991 | PDF | | |
| Chloride channels in the nuclear membrane | Tabares, Mazzanti, Clapham | J Memb Biol | 1991 | PDF | | |
| Spiral calcium wave propagation and annihilation in xenopus laevis oocytes | Lechleiter, Girard, Peralta, Clapham | Science | 1991 | PDF | | |
| Subcellular patterns of calcium release determined by G protein specific residues of muscarinic receptors | Lechleiter, J, Girard, S, Clapham, DE, et al. | Nature | 1991 | PDF | | |
| Potassium channels in cardiac cells activated by arachidonic acid and phospholipids | Kim, Clapham | Science | 1989 | PDF | | |
| G protein betagamma subunits activate the cardiac muscarinic K channel via PLA2 | Kim, D, Lewis, DL, Graziadei, L, et al. | Nature | 1989 | PDF | | |
| Specificity of action of guanine nucelotide-binding regulatory protein subunits on the cardiac muscarinic K+ channel | Logothetis, Kim, Northup, Neer | PNAS | 1988 | PDF | | |
| Haemodynamic shear stress activates a K+ current in vascular endothelial cells | Olesen, Clapham | Nature | 1988 | PDF | | |
| The Beta/Gamma subunits of GTP-binding protein activate the muscarinic K+ channel in the heart | Logothetis, Kurachi, Galper, Neer, Clapham | Nature | 1987 | PDF | | |
| Gamma Aminobutyric acid receptor channels in adrenal chromaffin cells: A patch clamp study | Bormann and Clapham | PNAS | 1985 | PDF | | |
| Development of a delayed outward-rectifying K+ conductance in cultured mouse peritoneal macrophages | Ypey and Clapham | PNAS | 1984 | PDF | | |
| TRIFLUOPERAZINE REDUCES INWARD IONIC CURRENTS AND SECRETION BY SEPARATE MECHANISMS IN BOVINE CHROMAFFIN CELLS | Clapham, DE and Neher, E | Journal of Physiology | 1984 | PDF | | |
| SUBSTANCE P REDUCES ACETYLCHOLINEINDUCED CURRENTS IN ISOLATED BOVINE CHROMAFFIN CELLS | Clapham, DE and Neher, E | Journal of Physiology | 1984 | PDF | | |
