The chemical composition, in vitro genotoxicity, and cytotoxicity of the mainstream aerosol from the Tobacco Heating System 2.2 (THS2.2) were compared with those of the mainstream smoke from the 3R4F reference cigarette. In contrast to the 3R4F, the tobacco plug in the THS2.2 is not burnt. The low operating temperature of THS2.2 caused distinct shifts in the aerosol composition compared with 3R4F. This resulted in a reduction of more than 90% for the majority of the analyzed harmful and potentially harmful constituents (HPHCs), while the mass median aerodynamic diameter of the aerosol remained similar. A reduction of about 90% was also observed when comparing the cytotoxicity determined by the neutral red uptake assay and the mutagenic potency in the mouse lymphoma assay. The THS2.2 aerosol was not mutagenic in the Ames assay. The chemical composition of the THS2.2 aerosol was also evaluated under extreme climatic and puffing conditions. When generating the THS2.2 aerosol under "desert" or "tropical" conditions, the generation of HPHCs was not significantly modified. When using puffing regimens that were more intense than the standard Health Canada Intense (HCI) machine-smoking conditions, the HPHC yields remained lower than when smoking the 3R4F reference cigarette with the HCI regimen.
TRPM2 is a member of the melastatin-related TRP (transient receptor potential) subfamily. It is expressed in brain and lymphocytes and forms a cation channel that is activated by intracellular ADP-ribose and associated with cell death. In this study we investigated the calcium dependence of human TRPM2 expressed under a tetracycline-dependent promoter in HEK-293 cells. TRPM2 expression was associated with enhanced hydrogen peroxide-evoked intracellular calcium signals. In whole-cell patch clamp recordings, switching from barium-to calcium-containing extracellular solution markedly activated TRPM2 as long as ADP-ribose was in the patch pipette and exogenous intracellular calcium buffering was minimal. We suggest this effect reveals a critical dependence of TRPM2 channel activity on intracellular calcium. In the absence of extracellular calcium we observed concentration-dependent activation of TRPM2 channels by calcium delivered from the patch pipette (EC 50 340 nM, slope 4.9); the maximum effect was at least as large as that evoked by extracellular calcium. Intracellular dialysis of cells with high concentrations of EGTA or 1,2-bis(o-Aminophenoxy)ethane-N,N,N,Ntetraacetic acid (BAPTA) strongly reduced the amplitude of the extracellular calcium response, and the residual response was abolished by a mixture of high and low affinity calcium buffers. TRPM2 channel currents in inside-out patches showed a strong requirement for Ca 2؉ at the intracellular face of the membrane. We suggest that calcium entering via TRPM2 proteins acts at an intracellular calcium sensor closely associated with the channel, providing essential positive feedback for channel activation.The non-voltage-gated TRP Ca 2ϩ channel encoded by the transient receptor potential (trp) 1 gene has a major role in the phospholipase C-dependent light response of the Drosophila photoreceptor (1). Since this discovery, many trp-related Ca 2ϩ channels have been discovered in mammals, beginning with TRPC1 (e.g. Ref.2), which is a subunit of some store-operated Ca 2ϩ channels (e.g. Ref.3). There are now known to be at least 20 trp-related mammalian genes, all apparently encoding cationic channels, many of which are Ca 2ϩ permeable. They would appear to be the molecular basis of the many non-voltage-gated cationic channels with diverse functions and expression profiles in mammalian systems. On the basis of amino acid sequence the mammalian TRPs are divided into three subgroups, TRPC (C, canonical), TRPV (V, vanilloid receptor), and TRPM (M, melastatin receptor) (4). Increasingly it is becoming apparent that the regulation of these proteins is complex, with gating factors as diverse as temperature, menthol, diacylglycerol, arachidonic acid, and osmotic stress (5, 6).TRPM2 (also called TRPC7 or LTRPC2) is a recently characterized member of the TRPM family (7-11). It forms a cationic channel activated by intracellular ADP-ribose, -NAD ϩ , or arachidonic acid. The sensitivity of the channel to -NAD ϩ is thought to couple TRPM2 to the redox state of the cell (10). T...
A Sphingosine-1–Phosphate-Activated Calcium Channel Controlling Vascular Smooth Muscle Cell Motility
Abstract-In a screen of potential lipid regulators of transient receptor potential (TRP) channels, we identified sphingosine-1-phosphate (S1P) as an activator of TRPC5. We explored the relevance to vascular biology because S1P is a key cardiovascular signaling molecule. TRPC5 is expressed in smooth muscle cells of human vein along with TRPC1, which forms a complex with TRPC5. Importantly, S1P also activates the TRPC5-TRPC1 heteromultimeric channel. Because TRPC channels are linked to neuronal growth cone extension, we considered a related concept for smooth muscle. We find S1P stimulates smooth muscle cell motility, and that this is inhibited by E3-targeted anti-TRPC5 antibody. Ion permeation involving TRPC5 is crucial because S1P-evoked motility is also suppressed by the channel blocker 2-aminoethoxydiphenyl borate or a TRPC5 ion-pore mutant. S1P acts on TRPC5 via two mechanisms, one extracellular and one intracellular, consistent with its bipolar signaling functions. The extracellular effect appears to have a primary role in S1P-evoked cell motility. The data suggest S1P sensing by TRPC5 calcium channel is a mechanism contributing to vascular smooth muscle adaptation. Key Words: vascular smooth muscle Ⅲ vein Ⅲ sphingosine-1-phosphate Ⅲ transient receptor potential Ⅲ calcium channel S phingosine-1-phosphate (S1P) has emerged as a major endogenous signaling phospholipid with diverse roles in yeast, plants, and mammals. 1 Proposed functions include the regulation of cell proliferation, migration, programmed death, and pathological processes including cancer, asthma, inflammation, and trauma. There has been particular interest in the role of S1P in the cardiovascular system, where it accumulates in atherosclerotic lesions and plays a role in ischemic preconditioning of the heart. 2-5 S1P is derived from the phosphorylation of sphingosine catalyzed by sphingosine kinase, sphingosine being from ceramide and ceramide from sphingomyelin, a constituent lipid of signaling microdomains of plasma membrane lipid rafts and caveolae. 3 S1P is detected in serum at almost 1 mol/L, although protein binding impacts on the available concentration and local concentrations may vary substantially. 6 S1P is quite unusual among signaling molecules in having separate intracellular and extracellular effects. 1,4,7,8 It affects vascular smooth muscle cell migration, 9,10 evokes contraction of rat mesenteric artery, 11 and slows pacemaker activity of the sino-atrial node of the heart. 12 The underlying mechanisms are only partially worked out, but vascular smooth muscle cells respond to S1P with transient followed by sustained elevation of the cytosolic Ca 2ϩ concentration, 10,11,13,14 whereas cardiac myocytes show activation of potassium current and S1P-evoked "Ca 2ϩ deregulation," depending on extracellular Ca 2ϩ . 12,15 Despite positive effects on Ca 2ϩ signaling, the molecular basis of a Ca 2ϩ channel stimulated by S1P is unknown. L-type voltage-gated Ca 2ϩ channels are inhibited by S1P. 12 The Drosophila transient receptor potential ...
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