TMEM16A confers receptor-activated calcium-dependent chloride conductance

Calcium (Ca2+)-activated chloride channels are fundamental mediators in numerous physiological processes including transepithelial secretion, cardiac and neuronal excitation, sensory transduction, smooth muscle contraction and fertilization. Despite their physiological importance, their molecular identity has remained largely unknown. Here we show that transmembrane protein 16A (TMEM16A, which we also call anoctamin 1 (ANO1)) is a bona fide Ca2+-activated chloride channel that is activated by intracellular Ca2+ and Ca2+-mobilizing stimuli. With eight putative transmembrane domains and no apparent similarity to previously characterized channels, ANO1 defines a new family of ionic channels. The biophysical properties as well as the pharmacological profile of ANO1 are in full agreement with native Ca2+-activated chloride currents. ANO1 is expressed in various secretory epithelia, the retina and sensory neurons. Furthermore, knockdown of mouse Ano1 markedly reduced native Ca2+-activated chloride currents as well as saliva production in mice. We conclude that ANO1 is a candidate Ca2+-activated chloride channel that mediates receptor-activated chloride currents in diverse physiological processes

Anoctamin 1/TMEM16A in pruritoceptors is essential for Mas-related G protein receptor-dependent itch

Itch is an unpleasant sensation that evokes a desire to scratch. Pathologic conditions such as allergy or atopic dermatitis produce severe itching sensation. Mas-related G protein receptors (Mrgprs) are receptors for many endogenous pruritogens. However, signaling pathways downstream to these receptors in dorsal root ganglion (DRG) neurons are not yet understood. We found that Anoctamin 1 (ANO1), a Ca2+-activated chloride channel, is a transduction channel mediating Mrgprs-dependent itch signals. Genetic ablation of Ano1 in DRG neurons displayed a significant reduction in scratching behaviors in response to acute and chronic Mrgprs-dependent itch models and the epidermal hyperplasia induced by dry skin. In-vivo Ca2+ imaging and electrophysiological recording revealed that chloroquine and other agonists of Mrgpr receptors excited DRG neurons via ANO1. More importantly, the overexpression of Ano1 in DRG neurons of Ano1-deficient mice rescued the impaired itching observed in Ano1-deficient mice. These results demonstrate that ANO1 mediates the Mrgprs-dependent itch signaling in pruriceptors and provides clues to treating pathologic itch syndromes

The Piezo2 ion channel is mechanically activated by low-threshold positive pressure

Recent parallel studies clearly indicated that Merkel cells and the mechanosensitive piezo2 ion channel play critical roles in the light-touch somatosensation. Moreover, piezo2 was suggested to be a light-touch sensing ion channel without a role in pain sensing in mammals. However, biophysical characteristics of piezo2, such as single channel conductance and sensitivities to various mechanical stimuli, are unclear, hampering a precise understanding of its role in touch sensation. Here, we describe the biophysical properties of piezo2 in human Merkel cell carcinoma (MCC)-13 cells piezo2 is a low-threshold, positive pressure-specific, curvature-sensitive, mechanically activated cation channel with a single channel conductance of -28.6 pS. Application of step indentations under the whole-cell mode of the patch-clamp technique, and positive pressures >= 5 mmHg under the cell-attached mode, activated piezo2 currents in MCC-13 and human embryonic kidney 293T cells where piezo2 was overexpressed. By contrast, application of a negative pressure failed to activate piezo2 in these cells, whereas both positive and negative pressure activated piezo1 in a similar manner. Our results are the first to demonstrate single channel recordings of piezo2. We anticipate that our findings will be a starting point for a more sophisticated understanding of piezo2 roles in light-touch sensation

Influence of Zika virus 3′-end sequence and nonstructural protein evolution on the viral replication competence and virulence

Zika virus (ZIKV) has been circulating in human networks over 70 years since its first appearance in Africa, yet little is known about whether the viral 3′-terminal sequence and nonstructural (NS) protein diverged genetically from ancient ZIKV have different effects on viral replication and virulence in currently prevailing Asian lineage ZIKV. Here we show, by a reverse genetics approach using an infectious cDNA clone for a consensus sequence (Con1) of ZIKV, which represents Asian ZIKV strains, and another clone derived from the MR766 strain isolated in Uganda, Africa in 1947, that the 3′-end sequence –UUUCU-3′ homogeneously present in MR766 genome and the –GUCU-3′ sequence strictly conserved in Asian ZIKV isolates are functionally equivalent in viral replication and gene expression. By gene swapping experiments using the two infectious cDNA clones, we show that the NS1–5 proteins of MR766 enhance replication competence of ZIKV Con1. The Con1, which was less virulent than MR766, acquired severe bilateral hindlimb paralysis when its NS1–5 genes were replaced by the counterparts of MR766 in type I interferon receptor (IFNAR1)-deficient A129 mice. Moreover, MR766 NS5 RNA-dependent RNA polymerase (RdRp) alone also rendered the Con1 virulent, despite there being no difference in RdRp activity between MR766 and Con1 NS5 proteins. By contrast, the Con1 derivatives expressing MR766 Nsps, like Con1, did not develop severe disease in wild-type mice treated with an IFNAR1 blocking antibody. Together, our findings uncover an unprecedented role for ZIKV NS proteins in determining viral pathogenicity in immunocompromised hosts.</p