Abstract:Regulation of cell volume is critical for many cellular and organismal functions, yet the molecular identity of a key player, the volume-regulated anion channel VRAC, has remained unknown. A genome-wide siRNA screen in mammalian cells identified LRRC8A as a VRAC component. LRRC8A formed heteromers with other LRRC8 multispan membrane proteins.Genomic disruption of LRRC8A ablated VRAC currents. Cells with disruption of all five LRRC8 genes required LRRC8A co-transfection with other LRRC8 isoforms to reconstitute VRAC currents. The isoform combination determined VRAC inactivation kinetics. Taurine flux and regulatory volume decrease also depended on LRRC8 proteins. Our work shows that VRAC defines a class of anion channels, suggests that VRAC is identical to the volumesensitive organic osmolyte/anion channel VSOAC, and explains the heterogeneity of native VRAC currents. One Sentence Summary:We show that the swelling-activated anion channel VRAC represents a structurally new class of anion channels that also conducts organic osmolytes. Main Text:Cells regulate their volume to counteract swelling or shrinkage caused by osmotic challenges and during processes like cell growth, division, and migration. As water transport across cellular membranes is driven by osmotic gradients, cell volume regulation requires appropriate changes of intracellular concentrations of ions or organic osmolytes like taurine (1, 2). Regulatory volume decrease (RVD) follows the extrusion of intracellular Cl -and K + and other osmolytes across the plasma membrane. A key player is the volume-regulated anion channel VRAC that mediates characteristic swelling-activated Cl --currents (I Cl(swell) ) and is ubiquitously expressed in vertebrate cells (3-5). Nearly inactive under resting conditions, VRAC slowly opens upon hypotonic swelling. The mechanism behind VRAC opening remains enigmatic. VRAC currents are outwardly rectifying (hence the alternative name VSOR for volume-stimulated outward rectifier (4, 5)) and show variable inactivation at insidepositive voltages. VRAC conducts iodide better than chloride and might also conduct organic osmolytes like taurine (6) (hence VSOAC, volume-stimulated organic osmolyte/anion channel (7)), but this notion is controversial (8-10). VRAC is believed to be important for cell volume regulation and swelling-induced exocytosis (11), and also for cell cycle regulation, proliferation and migration (1,3,4). It may play a role in apoptosis and various pathological (Fig. 1F). We hypothesized that VRAC contains LRRC8A as part of a heteromer and that LRRC8A overexpression led to a subunit stoichiometry that was incompatible with channel activity. LRRC8A has four closely related homologs (LRRC8B -LRRC8E) which all have four predicted transmembrane domains (19,20). EST databases suggested that all homologs were widely expressed.Immunocytochemistry of transfected HeLa cells ( fig. S4A) and of native HEK cells (Fig. 1, G and H) detected LRRC8A at the plasma membrane. Truncation of its carboxy-terminus as in a pat...
Acid-sensing ion channels have important functions in physiology and pathology, but the molecular composition of acid-activated chloride channels had remained unclear. We now used a genome-wide siRNA screen to molecularly identify the widely expressed acid-sensitive outwardly-rectifying anion channel PAORAC/ASOR. ASOR is formed by TMEM206 proteins which display two transmembrane domains (TMs) and are expressed at the plasma membrane. Ion permeation-changing mutations along the length of TM2 and at the end of TM1 suggest that these segments line ASOR’s pore. While not belonging to a gene family, TMEM206 has orthologs in probably all vertebrates. Currents from evolutionarily distant orthologs share activation by protons, a feature essential for ASOR’s role in acid-induced cell death. TMEM206 defines a novel class of ion channels. Its identification will help to understand its physiological roles and the diverse ways by which anion-selective pores can be formed.
A structure-guided hybridization approach using two privileged substructures gave instant access to a new series of tankyrase inhibitors. The identified inhibitor 16 displays high target affinity on tankyrase 1 and 2 with biochemical and cellular IC values of 29 nM, 6.3 nM and 19 nM, respectively, and high selectivity toward other poly (ADP-ribose) polymerase enzymes. The identified inhibitor shows a favorable in vitro ADME profile as well as good oral bioavailability in mice, rats, and dogs. Critical for the approach was the utilization of an appropriate linker between 1,2,4-triazole and benzimidazolone moieties, whereby a cyclobutyl linker displayed superior affinity compared to a cyclohexane and phenyl linker.
Maize Activator (Ac) is one of the prototype transposable elements of the hAT transposon superfamily, members of which were identified in plants, fungi, and animals. The autonomous Ac and nonautonomous Dissociation (Ds) elements are mobilized by the single transposase protein encoded by Ac. To date Ac/Ds transposons were shown to be functional in approximately 20 plant species and have become the most widely used transposable elements for gene tagging and functional genomics approaches in plants. In this chapter we review the biology, regulation, and transposition mechanism of Ac/Ds elements in maize and heterologous plants. We discuss the parameters that are known to influence the functionality and transposition efficiency of Ac/Ds transposons and need to be considered when designing Ac transposase expression constructs and Ds elements for application in heterologous plant species.
Activator/Dissociation (Ac/Ds) transposable elements from maize are widely used as insertional mutagenesis and gene isolation tools in plants and more recently also in medaka and zebrafish. They are particularly valuable for plant species that are transformation-recalcitrant and have long generation cycles or large genomes with low gene densities. Ac/Ds transposition frequencies vary widely, however, and in some species they are too low for large-scale mutagenesis. We discovered a hyperactive Ac transposase derivative, AcTPase 4x , that catalyzes in the yeast Saccharomyces cerevisiae 100-fold more frequent Ds excisions than the wild-type transposase, whereas the reintegration frequency of excised Ds elements is unchanged (57%). Comparable to the wild-type transposase in plants, AcTPase 4x catalyzes Ds insertion preferentially into coding regions and to genetically linked sites, but the mutant protein apparently has lost the weak bias of the wild-type protein for insertion sites with elevated guanine-cytosine content and nonrandom protein-DNA twist. AcTPase 4x exhibits hyperactivity also in Arabidopsis thaliana where it effects a more than sixfold increase in Ds excision relative to wild-type AcTPase and thus may be useful to facilitate Ac/Ds-based insertion mutagenesis approaches. DNA transposons are widely used in plants and animals as functional genomics tools and gene transfer vehicles. In plants, transposable elements are particularly valuable when large-scale T-DNA insertion mutagenesis is not feasible, e.g., for transformation-recalcitrant species or plants with long generation cycles. The success of transposon insertion mutagenesis strategies depends on high forward mutagenesis rates and a favorable distribution of novel insertions. As forward mutagenesis rates are frequently limited by transposase activity, attempts were made to find hyperactive transposase mutants. For some transposons, such mutants were fortuitously found; in other instances, systematic screening approaches and molecular evolution were successful (Goryshin and Reznikoff 1998;Beall et al. 2002;Baus et al. 2005;Keravala et al. 2006;Mates et al. 2009).The maize Activator/Dissociation (Ac/Ds) transposable elements have been widely used in plants for gene tagging and functional genomics approaches because they are active in numerous plant species, integrate preferentially into or near to coding regions, and frequently transpose to genetically linked sites, enabling local saturation mutagenesis approaches (reviewed in Kunze and Weil 2002). The successful introduction of Ac/Ds elements into yeast revealed that application of these elements is not restricted to plants (Weil and Kunze 2000). Their recent adoption as tools for transgenesis and the generation of gene trap lines in the teleost fishes zebrafish and medaka further emphasized the wide range functionality of Ac/Ds elements (Emelyanov et al. 2006;Boon Ng and Gong 2011;Froschauer et al. 2012).An impediment for a universal application is the variability of Ac/Ds transposition fr...
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