Stephan E. Philipp

Lack of an endothelial store-operated Ca2+ current impairs agonist-dependent vasorelaxation in TRP4-/- mice.

Agonist-induced Ca2+ entry into cells by both store-operated channels and channels activated independently of Ca2+-store depletion has been described in various cell types. The molecular structures of these channels are unknown as is, in most cases, their impact on various cellular functions. Here we describe a store-operated Ca2+ current in vascular endothelium and show that endothelial cells of mice deficient in TRP4 (also known as CCE1) lack this current. As a consequence, agonist-induced Ca2+ entry and vasorelaxation is reduced markedly, showing that TRP4 is an indispensable component of store-operated channels in native endothelial cells and that these channels directly provide an Ca2+-entry pathway essentially contributing to the regulation of blood vessel tone.

A novel capacitative calcium entry channel expressed in excitable cells

In addition to voltage‐gated calcium influx, capacitative calcium entry (CCE) represents a major pathway for calcium entry into the cell. Here we report the structure, expression and functional properties of a novel CCE channel, TRP5. This channel is a member of a new subfamily of mammalian homologues of the Drosophila transient receptor potential (TRP) protein, now comprising TRP5 (also CCE2) and the structurally related CCE1 (also TRP4). Like TRP4, TRP5 forms ion channels mainly permeable for Ca2+ which are not active under resting conditions but can be activated by manoeuvres known to deplete intracellular calcium stores. Accordingly, dialysis of TRP5‐expressing cells with inositol‐(1,4,5)‐trisphosphate evokes inward rectifying currents which reversed polarity at potentials more positive than +30 mV. Ca2+ store depletion with thapsigargin induced TRP5‐mediated calcium entry dependent on the concentration of extracellular calcium, as seen by dual wavelength fura‐2 fluorescence ratio measurements. TRP5 transcripts are expressed almost exclusively in brain, where they are present in mitral cells of the olfactory bulb, in lateral cerebellar nuclei and, together with TRP4 transcripts, in CA1 pyramidal neurons of the hippocampus, indicating the presence of CCE channels in excitable cells and their participation in neuronal calcium homeostasis.

A mammalian capacitative calcium entry channel homologous to Drosophila TRP and TRPL

Intracellular Ca2+ signalling evoked by Ca2+ mobilizing agonists, like angiotensin II in the adrenal gland, involves the activation of inositol(1,4,5)trisphosphate(InsP3)‐mediated Ca2+ release from internal stores followed by activation of a Ca2+ influx termed capacitative calcium entry. Here we report the amino acid sequence of a functional capacitative Ca2+ entry (CCE) channel that supports inward Ca2+ currents in the range of the cell resting potential. The expressed CCE channel opens upon depletion of Ca2+ stores by InsP3 or thapsigargin, suggesting that the newly identified channel supports the CCE coupled to InsP3 signalling.

Overcoming Intrinsic Multidrug Resistance in Melanoma by Blocking the Mitochondrial Respiratory Chain of Slow-Cycling JARID1Bhigh Cells

Despite success with BRAFV600E inhibitors, therapeutic responses in patients with metastatic melanoma are short-lived because of the acquisition of drug resistance. We identified a mechanism of intrinsic multidrug resistance based on the survival of a tumor cell subpopulation. Treatment with various drugs, including cisplatin and vemurafenib, uniformly leads to enrichment of slow-cycling, long-term tumor-maintaining melanoma cells expressing the H3K4-demethylase JARID1B/KDM5B/PLU-1. Proteome-profiling revealed an upregulation in enzymes of mitochondrial oxidative-ATP-synthesis (oxidative phosphorylation) in this subpopulation. Inhibition of mitochondrial respiration blocked the emergence of the JARID1B(high) subpopulation and sensitized melanoma cells to therapy, independent of their genotype. Our findings support a two-tiered approach combining anticancer agents that eliminate rapidly proliferating melanoma cells with inhibitors of the drug-resistant slow-cycling subpopulation.

Transient receptor potential M3 channels are ionotropic steroid receptors in pancreatic beta cells.

Transient receptor potential (TRP) cation channels are renowned for their ability to sense diverse chemical stimuli. Still, for many members of this large and heterogeneous protein family it is unclear how their activity is regulated and whether they are influenced by endogenous substances. On the other hand, steroidal compounds are increasingly recognized to have rapid effects on membrane surface receptors that often have not been identified at the molecular level. We show here that TRPM3, a divalent-permeable cation channel, is rapidly and reversibly activated by extracellular pregnenolone sulphate, a neuroactive steroid. We show that pregnenolone sulphate activates endogenous TRPM3 channels in insulin-producing β cells. Application of pregnenolone sulphate led to a rapid calcium influx and enhanced insulin secretion from pancreatic islets. Our results establish that TRPM3 is an essential component of an ionotropic steroid receptor enabling unanticipated crosstalk between steroidal and insulin-signalling endocrine systems.

TRP4 (CCE1) protein is part of native calcium release-activated Ca2+-like channels in adrenal cells.

Mammalian TRP proteins have been implicated to function as ion channel subunits responsible for agonist-induced Ca2+ entry. To date, TRP proteins have been extensively studied by heterologous expression giving rise to diverse channel properties and activation mechanisms including store-operated mechanisms. However, the molecular structure and the functional properties of native TRP channels still remain elusive. Here we analyze the properties of TRP4 (CCE1) channels in their native environment and characterize TRP expression patterns and store-operated calcium currents that are endogenous to bovine adrenal cells. We show by Northern blot analysis, immunoblots, and immunohistochemistry thatTRP4 transcripts and TRP4 protein are present in the adrenal cortex but absent in the medulla. Correspondingly, bovine adrenal cortex cells express TRP4 abundantly. The only otherTRP transcript found at considerable levels wasTRP1, whereas TRP2, TRP3, TRP5(CCE2), andTRP6 were not detectable. Depletion of calcium stores with inositol 1,4,5-trisphosphate or thapsigargin activates store-operated ion channels in adrenal cells. These channels closely resemble calcium release-activated Ca2+ (CRAC) channels. Expression of trp4(CCE1) cDNA in antisense orientation significantly reduces both, the endogenous CRAC-like currents and the amount of native TRP4 protein. These results demonstrate that TRP4 contributes essentially to the formation of native CRAC-like channels in adrenal cells.

Increased IgE-dependent mast cell activation and anaphylactic responses in mice lacking the calcium-activated nonselective cation channel TRPM4

Mast cells are key effector cells in allergic reactions. Aggregation of the receptor FcεRI in mast cells triggers the influx of calcium (Ca2+) and the release of inflammatory mediators. Here we show that transient receptor potential TRPM4 proteins acted as calcium-activated nonselective cation channels and critically determined the driving force for Ca2+ influx in mast cells. Trpm4−/− bone marrow–derived mast cells had more Ca2+ entry than did TRPM4+/+ cells after FcεRI stimulation. Consequently, Trpm4−/− bone marrow–derived mast cells had augmented degranulation and released more histamine, leukotrienes and tumor necrosis factor. Trpm4−/− mice had a more severe IgE-mediated acute passive cutaneous anaphylactic response, whereas late-phase passive cutaneous anaphylaxis was not affected. Our results establish the physiological function of TRPM4 channels as critical regulators of Ca2+ entry in mast cells.

Properties of heterologously expressed hTRP3 channels in bovine pulmonary artery endothelial cells

1 We combined patch clamp and fura‐2 fluorescence methods to characterize human TRP3 (hTRP3) channels heterologously expressed in cultured bovine pulmonary artery endothelial (CPAE) cells, which do not express the bovine trp3 isoform (btrp3) but express btrp1 and btrp4. 2 ATP, bradykinin and intracellular InsP3 activated a non‐selective cation current (IhTRP3) in htrp3‐transfected CPAE cells but not in non‐transfected wild‐type cells. During agonist stimulation, the sustained rise in [Ca2+]i was significantly higher in htrp3‐transfected cells than in control CPAE cells. 3 The permeability for monovalent cations was PNa > PCs≈PK >> PNMDG and the ratio PCa/PNa was 1·62 ± 0·27 (n= 11). Removal of extracellular Ca2+ enhanced the amplitude of the agonist‐activated IhTRP3 as well as that of the basal current The trivalent cations La3+ and Gd3+ were potent blockers of IhTRP3 (the IC50 for La3+ was 24·4 ± 0·7 μM). 4 The single‐channel conductance of the channels activated by ATP, assessed by noise analysis, was 23 pS. 5 Thapsigargin and 2,5‐di‐tert‐butyl‐1,4‐benzohydroquinone (BHQ), inhibitors of the organellar Ca2+‐ATPase, failed to activate IhTRP3. U‐73122, a phospholipase C blocker, inhibited IhTRP3 that had been activated by ATP and bradykinin. Thimerosal, an InsP3 receptor‐sensitizing compound, enhanced IhTRP3, but calmidazolium, a calmodulin antagonist, did not affect IhTRP3. 6 It is concluded that hTRP3 forms non‐selective plasmalemmal cation channels that function as a pathway for agonist‐induced Ca2+ influx.

Deletion of TRPC4 and TRPC6 in Mice Impairs Smooth Muscle Contraction and Intestinal Motility In Vivo

BACKGROUND & AIMS Downstream effects of muscarinic receptor stimulation in intestinal smooth muscle include contraction and intestinal transit. We thought to determine whether classic transient receptor potential (TRPC) channels integrate the intracellular signaling cascades evoked by the stimulated receptors and thereby contribute to the control of the membrane potential, Ca-influx, and cell responses. METHODS We created trpc4-, trpc6-, and trpc4/trpc6-gene-deficient mice and analyzed them for intestinal smooth muscle function in vitro and in vivo. RESULTS In intestinal smooth muscle cells TRPC4 forms a 55 pS cation channel and underlies more than 80% of the muscarinic receptor-induced cation current (mI(CAT)). The residual mI(CAT) depends on the expression of TRPC6, indicating that TRPC6 and TRPC4 determine mI(CAT) channel activity independent of other channel subunits. In TRPC4-deficient ileal myocytes the carbachol-induced membrane depolarizations are diminished greatly and the atropine-sensitive contraction elicited by acetylcholine release from excitatory motor neurons is reduced greatly. Additional deletion of TRPC6 aggravates these effects. Intestinal transit is slowed down in mice lacking TRPC4 and TRPC6. CONCLUSIONS In intestinal smooth muscle cells TRPC4 and TRPC6 channels are gated by muscarinic receptors and are responsible for mI(CAT). They couple muscarinic receptors to depolarization of intestinal smooth muscle cells and voltage-activated Ca(2+)-influx and contraction, and thereby accelerate small intestinal motility in vivo.

Phenotype of a recombinant store-operated channel: highly selective permeation of Ca2+

1 Genes related to trp (transient receptor potential) are proposed to encode store‐operated channels. We examined the ionic permeation of recombinant channels formed by stable and transient expression of the TRP homologue bCCE1 in Chinese hamster ovary (CHO) cells (CHO(CCE1)) and rat basophilic leukaemia (RBL) cells, respectively. 2 Store‐operated currents were activated in CHO(CCE1) cells by internal dialysis of IP3 under strong buffering of intracellular Ca2+. The action of IP3 was mimicked by thapsigargin but not by IP4. 3 With extracellular Ca2+, Na+ and Mg2+, the store‐operated currents of CHO(CCE1) rectified inwardly in the presence of internal Cs+. Outward currents were not detected below +80 mV. Identical currents were recorded with external Ba2+ and also with no external Na+ and Mg2+. In the absence of external Mg2+, the inward currents showed an anomalous mole fraction behaviour between Ca2+ and Na+. Half‐maximal inhibition of Na+ currents was observed with ≈100 nM and full block with 2‐5 μM external Ca2+. 4 In the parental CHO(‐) cells, IP3 dialysis evoked inward currents that also displayed anomalous mole fraction behaviour between Ca2+ and Na+. However, half‐maximal block of Na+ currents required 5 times higher Ca2+ concentrations in CHO(‐) cells. Additionally, the density of Ca2+ and Na+ currents at ‐80 mV was 5 and 2 times larger in CHO(CCE1) cells, respectively. 5 In RBL cells, dialysis of IP3 evoked store‐operated currents that showed 1.4‐fold larger densities at ‐80 mV in cells expressing bCCE1. 6 The enhanced density of store‐operated currents in CHO(CCE1) cells and in bCCE1‐transfected RBL cells probably reflects the phenotype of CCE1. These results suggest a highly selective permeation of Ca2+ through recombinant channels formed by CCE1 either alone or in combination with endogenous channel proteins.