A leak K + channel TWK-40 sustains the rhythmic motor program.
Zhongpu YueYi LiBin YuYueqing XuLili ChenJyothsna ChitturiJun MengYing WangYuhang TianSonia El MouridiCun-Tai ZhangMei ZhenThomas BoulinShangbang GaoPublished in: PNAS nexus (2024)
Leak potassium (K + ) currents, conducted by two-pore domain K + (K 2P ) channels, are critical for the stabilization of the membrane potential. The effect of K 2P channels on motor rhythm remains enigmatic. We show here that the K 2P TWK-40 contributes to the rhythmic defecation motor program (DMP) in Caenorhabditis elegans . Disrupting TWK-40 suppresses the expulsion defects of nlp-40 and aex-2 mutants. By contrast, a gain-of-function ( gf ) mutant of twk-40 significantly reduces the expulsion frequency per DMP cycle. In situ whole-cell patch clamping demonstrates that TWK-40 forms an outward current that hyperpolarize the resting membrane potential of dorsorectal ganglion ventral process B (DVB), an excitatory GABAergic motor neuron that activates expulsion muscle contraction. In addition, TWK-40 substantially contributes to the rhythmic activity of DVB. Specifically, DVB Ca 2+ oscillations exhibit obvious defects in loss-of-function ( lf ) mutant of twk-40 . Expression of TWK-40( gf ) in DVB recapitulates the expulsion deficiency of the twk-40(gf) mutant, and inhibits DVB Ca 2+ oscillations in both wild-type and twk-40(lf) animals. Moreover, DVB innervated enteric muscles also exhibit rhythmic Ca 2+ defects in twk-40 mutants. In summary, these findings establish TWK-40 as a crucial neuronal stabilizer of DMP, linking leak K 2P channels with rhythmic motor activity.