Person: Cohen, Jonathan
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Cohen
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Jonathan
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Cohen, Jonathan
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Publication Multiple Non-Equivalent Interfaces Mediate Direct Activation of GABAA Receptors by Propofol(Bentham Science Publishers, 2016) Eaton, Megan M.; Germann, Allison L.; Arora, Ruby; Cao, Lily Q.; Gao, Xiaoyi; Shin, Daniel J.; Wu, Albert; Chiara, David; Cohen, Jonathan; Steinbach, Joe Henry; Evers, Alex S.; Akk, GustavAbstract: Background Propofol is a sedative agent that at clinical concentrations acts by allosterically activating or potentiating the γ-aminobutyric acid type A (GABAA) receptor. Mutational, modeling, and photolabeling studies with propofol and its analogues have identified potential interaction sites in the transmembrane domain of the receptor. At the “+” of the β subunit, in the β-α interface, meta-azipropofol labels the M286 residue in the third transmembrane domain. Substitution of this residue with tryptophan results in loss of potentiation by propofol. At the “-” side of the β subunit, in the α-β interface (or β-β interface, in the case of homomeric β receptors), ortho-propofol diazirine labels the H267 residue in the second transmembrane domain. Structural modeling indicates that the β(H267) residue lines a cavity that docks propofol with favorable interaction energy. Method We used two-electrode voltage clamp to determine the functional effects of mutations to the “+” and “-” sides of the β subunit on activation of the α1β3 GABAA receptor by propofol. Results: We found that while the individual mutations had a small effect, the combination of the M286W mutation with tryptophan mutations of selected residues at the α-β interface leads to strong reduction in gating efficacy for propofol. Conclusion: We conclude that α1β3 GABAA receptors can be activated by propofol interactions with the β-β, α-β, and β-α interfaces, where distinct, non-equivalent regions control channel gating. Any interface can mediate activation, hence substitutions at all interfaces are required for loss of activation by propofol.Publication Genetic Determinants of Phosphate Response in Drosophila(Public Library of Science, 2013) Bergwitz, Clemens; Wee, Mark J.; Sinha, Sumi; Huang, Joanne Hyunjung; DeRobertis, Charles; Mensah, Lawrence; Cohen, Jonathan; Friedman, Adam A.; Kulkarni, Meghana; Hu, Yanhui; Vinayagam, Arunachalam; Schnall-Levin, Michael; Berger, Bonnie; Perkins, Lizabeth A.; Mohr, Stephanie; Perrimon, NorbertPhosphate is required for many important cellular processes and having too little phosphate or too much can cause disease and reduce life span in humans. However, the mechanisms underlying homeostatic control of extracellular phosphate levels and cellular effects of phosphate are poorly understood. Here, we establish Drosophila melanogaster as a model system for the study of phosphate effects. We found that Drosophila larval development depends on the availability of phosphate in the medium. Conversely, life span is reduced when adult flies are cultured on high phosphate medium or when hemolymph phosphate is increased in flies with impaired Malpighian tubules. In addition, RNAi-mediated inhibition of MAPK-signaling by knockdown of Ras85D, phl/D-Raf or Dsor1/MEK affects larval development, adult life span and hemolymph phosphate, suggesting that some in vivo effects involve activation of this signaling pathway by phosphate. To identify novel genetic determinants of phosphate responses, we used Drosophila hemocyte-like cultured cells (S2R+) to perform a genome-wide RNAi screen using MAPK activation as the readout. We identified a number of candidate genes potentially important for the cellular response to phosphate. Evaluation of 51 genes in live flies revealed some that affect larval development, adult life span and hemolymph phosphate levels.