4.8 Article

Neuronally produced betaine acts via a ligand-gated ion channel to control behavioral states

出版社

NATL ACAD SCIENCES
DOI: 10.1073/pnas.2201783119

关键词

betaine; ion channel; C. elegans; behavior

资金

  1. NIH Office of Research Infrastructure Programs [P40 OD010440]
  2. Medical Research Council [MC-A023-5PB91]
  3. Wellcome Trust [WT103784MA]
  4. Research Foundation-Flanders [G079521N]
  5. National Institutes of Health [R35GM131877, R01NS110391]
  6. Swedish Research council [2017-00236]
  7. Knut och Alice Wallenbergs foundation [KAW2019,0293]
  8. Magnus Bergvalls stiftelse
  9. Ake Wibergs stiftelse
  10. Swedish Research Council [2017-00236] Funding Source: Swedish Research Council
  11. Forte [2017-00236] Funding Source: Forte

向作者/读者索取更多资源

Betaine, a derivative of amino acid, has been found in diverse organisms and has well-established functions as a methyl donor and osmolyte. It is also present in the nervous system, but its role there is not well understood. A study on nematode worm, Caenorhabditis elegans, shows that betaine is synthesized in its nervous system and plays a role in controlling different behavioral states. It is produced in specific interneurons and is packed into synaptic vesicles by the vesicular monoamine transporter. The study also reveals a betaine-gated chloride channel that is broadly expressed in the navigation circuit. These findings suggest that neuronally produced betaine acts as a neuromodulator and may have a similar role in other animal nervous systems.
Trimethylglycine, or betaine, is an amino acid derivative found in diverse organisms, from bacteria to plants and animals, with well-established functions as a methyl donor and osmolyte in all cells. In addition, betaine is found in the nervous system, though its function there is not well understood. Here, we show that betaine is synthesized in the nervous system of the nematode worm, Caenorhabditis elegans, where it functions in the control of different behavioral states. Specifically, we find that betaine can be produced in a pair of interneurons, the RIMs, and packed into synaptic vesicles by the vesicular monoamine transporter, CAT-1, expressed in these cells. Mutant animals defective in betaine synthesis are unable to control the switch from local to global foraging, a phenotype that can be rescued by restoring betaine specifically to the RIM neurons. These effects on behavior are mediated by a newly identified betaine-gated chloride channel, LGC-41, which is expressed broadly in the navigation circuit. These results implicate neuronally produced betaine as a neuromodulator in vivo and suggest a potentially similar role for betaine in nervous systems of other animals.

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