Günter Schultz

Direct activation of human TRPC6 and TRPC3 channels by diacylglycerol

Eukaryotic cells respond to many hormones and neurotransmitters with increased activity of the enzyme phospholipase C and a subsequent rise in the concentration of intracellular free calcium ([Ca2+]i). The increase in [Ca2+]i occurs as a result of the release of Ca2+ from intracellular stores and an influx of Ca2+ through the plasma membrane; this influx of Ca2+ may or may not be store-dependent. Drosophila transient receptor potential (TRP) proteins and some mammalian homologues (TRPC proteins) are thought to mediate capacitative Ca2+ entry. Here we describe the molecular mechanism of store-depletion-independent activation of a subfamily of mammalian TRPC channels. We find that hTRPC6 is a non-selective cation channel that is activated by diacylglycerol in a membrane-delimited fashion, independently of protein kinases C activated by diacylglycerol. Although hTRPC3, the closest structural relative of hTRPC6, is activated in the same way, TRPCs 1, 4 and 5 and the vanilloid receptor subtype 1 are unresponsive to the lipid mediator. Thus, hTRPC3 and hTRPC6 represent the first members of a new functional family of second-messenger-operated cation channels, which are activated by diacylglycerol.

OTRPC4, a nonselective cation channel that confers sensitivity to extracellular osmolarity.

Ca2+-permeable channels that are involved in the responses of mammalian cells to changes in extracellular osmolarity have not been characterized at the molecular level. Here we identify a new TRP (transient receptor potential)-like channel protein, OTRPC4, that is expressed at high levels in the kidney, liver and heart. OTRPC4 forms Ca2+-permeable, nonselective cation channels that exhibit spontaneous activity in isotonic media and are rapidly activated by decreases in, and are inhibited by increases in, extracellular osmolarity. Changes in osmolarity of as little as 10% result in significant changes in intracellular Ca2+ concentration. We propose that OTRPC4 is a candidate for a molecular sensor that confers osmosensitivity on mammalian cells.

Subunit composition of mammalian transient receptor potential channels in living cells

Hormones, neurotransmitters, and growth factors give rise to calcium entry via receptor-activated cation channels that are activated downstream of phospholipase C activity. Members of the transient receptor potential channel (TRPC) family have been characterized as molecular substrates mediating receptor-activated cation influx. TRPC channels are assumed to be composed of multiple TRPC proteins. However, the cellular principles governing the assembly of TRPC proteins into homo- or heteromeric ion channels still remain elusive. By pursuing four independent experimental approaches—i.e., subcellular cotrafficking of TRPC subunits, differential functional suppression by dominant-negative subunits, fluorescence resonance energy transfer between labeled TRPC subunits, and coimmunoprecipitation—we investigate the combinatorial rules of TRPC assembly. Our data show that (i) TRPC2 does not interact with any known TRPC protein and (ii) TRPC1 has the ability to form channel complexes together with TRPC4 and TRPC5. (iii) All other TRPCs exclusively assemble into homo- or heterotetramers within the confines of TRPC subfamilies—e.g., TRPC4/5 or TRPC3/6/7. The principles of TRPC channel formation offer the conceptual framework to assess the physiological role of distinct TRPC proteins in living cells.

A Unified Nomenclature for the Superfamily of TRP Cation Channels

The TRP superfamily includes a diversity of non-voltage-gated cation channels that vary significantly in their selectivity and mode of activation. Nevertheless, members of the TRP superfamily share significant sequence homology and predicted structural similarities. Currently, most of the genes and proteins that comprise the TRP superfamily have multiple names and, in at least one instance, two distinct genes belonging to separate subfamilies have the same name. Moreover, there are many cases in which highly related proteins that belong to the same subfamily have unrelated names. Therefore, to minimize confusion, we propose a unified nomenclature for the TRP superfamily.The current effort to unify the TRP nomenclature focuses on three subfamilies (TRPC, TRPV, and TRPM) that bear significant similarities to the founding member of this superfamily, Drosophila TRP, and which include highly related members in worms, flies, mice, and humans (Table 1)(Table 1). Members of the three subfamilies contain six transmembrane segments, a pore loop separating the final two transmembrane segments, and similarity in the lengths of the cytoplasmic and extracellular loops. In addition, the charged residues in the S4 segment that appear to contribute to the voltage sensor in voltage-gated ion channels are not conserved. The TRP-Canonical (TRPC) subfamily (formerly short-TRPs or STRPs) is comprised of those proteins that are the most highly related to Drosophila TRP. The TRPV subfamily (formerly OTRPC), is so named based on the original designation, Vanilloid Receptor 1 (VR1), for the first mammalian member of this subfamily (now TRPV1). The name for the TRPM subfamily (formerly long-TRPs or LTRPs) is derived from the first letter of Melastatin, the former name (now TRPM1) of the founding member of this third subfamily of TRP-related proteins. Based on amino acid homologies, the mammalian members of these three subfamilies can be subdivided into several groups each (Table 2Table 2 and Figure 1Figure 1) .Table 1Number of TRP Genes in Worms (C. elegans), Flies (Drosophila melanogaster), Mice, and HumansSubfamilyWormsFliesMiceHumansTRPC3376aaTRPV5255TRPM4188aTRPC2 is a pseudogene and is not counted.Table 2Nomenclature of the Mammalian TRP SuperfamilyNameGroupFormer NamesAccession NumbersTRPC11TRP1CAA61447, AAA93252TRPC1TRPC22TRP2X89067, AAD17195, AAD17196, AAG29950, AAG29951, AAD31453,TRPC2CAA06964TRPC33TRP3AAC51653TRPC3TRPC44TRP4CAA68125, BAA23599TRPC4TRPC54TRP5AAC13550, CAA06911, CAA06912TRPC5TRPC63TRP6NP_038866TRPC6TRPC73TRP7AAD42069, NP_065122TRPC7TRPV11VR1AAC53398OTRPC1TRPV21VRL-1AAD26363, AAD26364, BAA78478OTRPC2GRCTRPV3 (not assigned)TRPV42OTRPC4AAG17543, AAG16127, AAG28027, AAG28028, AAG28029,VR-OACCAC20703TRP12VRL-2TRPV53ECaC1CAB40138CaT2TRPV63CaT1AAD47636ECaC2CAC20416CaT-LCAC20417TRPM11MelastatinAAC13683, AAC80000TRPM22TRPC7BAA34700LTRPC2TRPM31KIAA1616AA038185LTRPC3TRPM43TRPM4H18835LTRPC4TRPM53MTR1AAF26288LTRPC5TRPM64Chak2AF350881TRPM74TRP-PLIKAAF73131Chak1LTRPC7TRPM82TRP-p8AC005538Indicated are the suggested gene and protein names, the groups within each subfamily, the former names, and accession numbers.Figure 1Phylogenetic Tree of the TRP SuperfamilyThe tree, which was adapted from Clapham et al., 2001 (Nat. Rev. Neurosci. 2, 387–396), was calculated using the neighbor-joining method and human, rat, and mouse sequences.View Large Image | View Hi-Res Image | Download PowerPoint SlideThe numbering system for the mammalian TRPC, TRPV, and TRPM proteins takes into account the order of their discovery and, in as many cases as possible, the number that has already been assigned to the genes and proteins (Table 2)(Table 2). In the case of the TRPV proteins, the numbering system is also based in part on the groupings of the TRPV proteins. New members of each subfamily will maintain the same root name and, with the exception of TRPV3, will be assigned the next number in the sequence. Currently, TRPV3 is unassigned to maintain the TRPV1/ TRPV2 and TRPV5/TRPV6 groupings and so that the former OTRPC4 could be renamed TRPV4. The next TRPV protein will be designated TRPV3.We hope this new nomenclature will add clarity to the field and simplify the naming of new members of the TRP superfamily. We recommend that accession numbers be used whenever it is necessary to unambiguously specify a given variant resulting from alternative mRNA splicing. Finally, this nomenclature has been approved by the HUGO Gene Nomenclature Committee and we recommend that this system be used in all future publications concerning TRPC, TRPV, and TRPM subfamily members.

From worm to man: three subfamilies of TRP channels

A steadily increasing number of cDNAs for proteins that are structurally related to the TRP ion channels have been cloned in recent years. All these proteins display a topology of six transmembrane segments that is shared with some voltage-gated channels and the cyclic-nucleotide-gated channels. The TRP channels can be divided, on the basis of their homology, into three TRP channel (TRPC) subfamilies: short (S), long (L) and osm (O). From the evidence available to date, this subdivision can also be made according to channel function. Thus, the STRPC family, which includes Drosophila TRP and TRPL and the mammalian homologues, TRPC1-7, is a family of Ca2+-permeable cation channels that are activated subsequent to receptor-mediated stimulation of different isoforms of phospholipase C. Members of the OTRPC family are Ca2+-permeable channels involved in pain transduction (vanilloid and vanilloid-like receptors), epithelial Ca2+ transport and, at least in Caenorhabditis elegans, in chemo-, mechano- and osmoregulation. The LTRPC family is less well characterized.

Morphological, biochemical, and electrophysiological characterization of a clonal cell (H9c2) line from rat heart.

Morphological, electrophysiological, and biochemical properties of H9c2 cells, a permanent cell line derived from rat cardiac tissue, were studied. Although the lectin binding pattern revealed similar sugar residues in the surface coat of H9c2 cells and isolated rat cardiocytes, heart-specific morphological structures could not be detected in H9c2 cells. Under physiological ionic conditions, H9c2 cells exhibited an outwardly rectifying, transient K+ current. When this current component was blocked by Ba2+ and Cs+, we observed an inward current through Ca2+ channels (15.8 +/- 2.2 pA/pF, n = 18, measured as Ba2+ current) that showed all characteristics of cardiac L-type currents. The activation kinetics were fast, and the current was stimulated by isoproterenol. The effect of isoproterenol was mimicked by forskolin or intracellularly applied cAMP. In radioligand binding experiments, we identified a specific, saturable, stereoselective and reversible high-affinity [3H]-(+)PN 200-110 binding with a dissociation constant Kd = 0.53 +/- 0.28 nM and a maximal specific binding of Bmax = 129.3 +/- 16.1 fmol/mg protein. There was an additional low-affinity/high-capacity binding site, which is unlikely to be related to a Ca2+ channel protein. Signal-transducing G proteins in membranes were characterized by [32P]ADP-ribosylation catalyzed by bacterial toxins and by the use of various antibodies. Cholera toxin substrates of 42 and 45 kd were identified that apparently correlated to Gs alpha-subunits. Pertussis toxin substrates of 40-41 kd were tentatively identified as Gi alpha-subunits. The G protein Go was absent or at least extremely low in concentration.

Receptor-mediated Regulation of the Nonselective Cation Channels TRPC4 and TRPC5

Mammalian transient receptor potential channels (TRPCs) form a family of Ca2+-permeable cation channels currently consisting of seven members, TRPC1–TRPC7. These channels have been proposed to be molecular correlates for capacitative Ca2+ entry channels. There are only a few studies on the regulation and properties of the subfamily consisting of TRPC4 and TRPC5, and there are contradictory reports concerning the possible role of intracellular Ca2+ store depletion in channel activation. We therefore investigated the regulatory and biophysical properties of murine TRPC4 and TRPC5 (mTRPC4/5) heterologously expressed in human embryonic kidney cells. Activation of Gq/11-coupled receptors or receptor tyrosine kinases induced Mn2+ entry in fura-2-loaded mTRPC4/5-expressing cells. Accordingly, in whole-cell recordings, stimulation of Gq/11-coupled receptors evoked large, nonselective cation currents, an effect mimicked by infusion of guanosine 5′-3-O-(thio)triphosphate (GTPγS). However, depletion of intracellular Ca2+ stores failed to activate mTRPC4/5. In inside-out patches, single channels with conductances of 42 and 66 picosiemens at −60 mV for mTRPC4 and mTRPC5, respectively, were stimulated by GTPγS in a membrane-confined manner. Thus, mTRPC4 and mTRPC5 form nonselective cation channels that integrate signaling pathways from G-protein-coupled receptors and receptor tyrosine kinases independently of store depletion. Furthermore, the biophysical properties of mTRPC4/5 are inconsistent with those ofI CRAC, the most extensively characterized store-operated current.

Brain nitric oxide synthase is a biopterin- and flavin-containing multi-functional oxido-reductase

Brain nitric oxide synthase is a Ca2+/calmodulin‐regulated enzyme which converts L‐arginine into NO. Enzymatic activity of this enzyme essentially depends on NADPH and is stimulated by tetrahydrobiopterin (H4biopterin). We found that purified NO synthase contains enzyme‐bound H4 biopterin, explaining the enzymatic activity observed in the absence of added cofactor. Together with the finding that H4 biopterin was effective at substoichiometrical concentrations, these results indicate that NO synthase essentially depends on H4 biopterin as a cofactor which is recycled during enzymatic NO formation. We found that the purified enzyme also contains FAD, FMN and non‐heme iron in equimolar amounts and exhibits striking activities, including a Ca2+/calmodulin‐dependent NADPH oxidase activity, leading to the formation of hydrogen peroxide at suboptimal concentrations of L‐arginine or H4 biopterin.

Cloning and Functional Expression of a Human Ca2+-Permeable Cation Channel Activated by Calcium Store Depletion

Depletion of intracellular calcium stores generates a signal that activates Ca2+-permeable channels in the plasma membrane. We have identified a human cDNA, TRPC1A, from a human fetal brain cDNA library. TRPC1A is homologous to the cation channels trp and trpl in Drosophila and is a splice variant of the recently identified cDNA Htrp-1. Expression of TRPC1A in CHO cells induced nonselective cation currents with similar permeabilities for Na+, Ca2+, and Cs+. The currents were activated by intracellular infusion of myo inositol 1,4,5-trisphosphate or thapsigargin. Expression of TRPC1A significantly enhanced increases in the intracellular free calcium concentration induced by Ca2+ restitution after prolonged depletion. Similar results were obtained in Sf9 cells. We conclude that TRPC1A encodes a Ca2+-permeable cation channel activated by depletion of intracellular calcium stores.

SENSITIZING SOLUBLE GUANYLYL CYCLASE TO BECOME A HIGHLY CO-SENSITIVE ENZYME

It took at least a decade to realize that the toxic gas NO is the physiological activator of soluble guanylyl cyclase (sGC), thereby acting as a signaling molecule in the nervous and cardiovascular systems. Despite its rather poor sGC‐activating property, CO has also been implicated as a physiological stimulator of sGC in neurotransmission and vasorelaxation. Here, we establish YC‐1 as a novel NO‐independent sGC activator that potentiates both CO‐ and NO‐induced sGC stimulation. As this potentiating effect is also observed with protoporphyrin IX which activates sGC independently of a gaseous ligand, we conclude that stabilization of the enzymes active configuration is the underlying mechanism of YC‐1′s action. Moreover, the results obtained with YC‐1 reveal that CO is capable of stimulating sGC to a degree similar to NO, and thus provide the molecular basis for CO functioning as a signaling molecule.