Two-pore domain potassium channels (K2P) play a central role in the control of cellular excitability and the regulation of the cell's electrical membrane potential. K2Ps have been widely conserved throughout evolution. They are polymodal ion channels that are subjected to extensive regulation by a diverse set of physical (pH, temperature, mechanical force) and biological signals (lipids, G-protein coupled receptor pathways). They are broadly expressed in excitable and non-excitable cells, and have in turn been implicated in a large spectrum of physiopathological processes, ranging from the regulation of neuronal excitability, respiratory and cardiac function to the control of cell volume, hormone secretion and cell proliferation. Recently, loss- and gain-of-function mutations in K2P channels have been directly linked to human pathologies (Birk Barel syndrome, familial migraine with aura, cardiac conduction disorder).
In contrast to many other ion channel families, comparatively little is known about the molecular and cellular processes that regulate different aspects of the cell biology of K2P channels. For instance we know only of very few factors that specifically regulate the expression, the activity and the localisation of K2P channels at the cell surface. Therefore the central question addressed by our team is: How is the number of active potassium leak channels present at the cell surface controlled in vivo?
To identify novel genes and conserved cellular processes that regulate the biology of K2P channels in vivo we take advantage of the powerful genetic tools available in the model nematode Caenorhabditis elegans. We use the full array of techniques available in C. elegans including genetics, live imaging, electrophysiology and state-of-the-art CRISPR/Cas9 genome engineering and next-generation DNA sequencing. These studies will provide new leads to understand the cellular pathways that control K2P function in other organisms.
- Microtubule severing by the katanin complex is activated by PPFR-1-dependent MEI-1 dephosphorylation.
Gomes JE, Tavernier N, Richaudeau B, Formstecher E, Boulin T, Mains PE, Dumont J, Pintard L. Journal of Cell Biology (2013) Aug 5;202(3):431-9.
- Biosynthesis of ionotropic acetylcholine receptors requires the evolutionarily conserved ER membrane complex.
Richard M, Boulin T, Robert VJ, Richmond JE, Bessereau JL. PNAS (2013) Mar ;110(11):E1055-63.
- Positive modulation of a Cys-loop acetylcholine receptor by an auxiliary transmembrane subunit.
Boulin T, Rapti G, Briseño-Roa L, Stigloher C, Richmond JE, Paoletti P, Bessereau JL. Nature Neuroscience (2012) Oct ;15(10):1374-81.
- Functional reconstitution of Haemonchus contortus acetylcholine receptors in Xenopus oocytes provides mechanistic insights into levamisole resistance.
Boulin T*, Fauvin A*, Charvet C, Cortet J, Cabaret J, Bessereau JL, Neveu C. British Journal of Pharmacology (2011) Nov ;164(5):1421-32.
- A neuronal acetylcholine receptor regulates the balance of muscle excitation and inhibition in Caenorhabditis elegans.
Jospin M, Qi YB, Stawicki TM, Boulin T, Schuske KR, Horvitz HR, Bessereau JL, Jorgensen EM, Jin Y. PLoS Biology (2009) Dec ;7(12):e1000265.
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