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Published online January 14, 2008
doi:10.1083/jcb.1802rr5
The Journal of Cell Biology, Vol. 180, No. 2, 251-
The Rockefeller University Press, 0021-9525 $30.00
© 2008 Robinson
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Research Roundup

 H+, the tiniest transmitter


Figure 1
The Na+/H+ exchanger pbo-4 (green) is expressed on the basolateral surface of intestinal epithelial cells.

JORGENSEN/ELSEVIER

Protons make muscles move in the worm gut, making the H+ ion the newest and smallest chemical transmitter known, according to Asim Beg, Erik Jorgensen (University of Utah, Salt Lake City, UT), and colleagues. The protons are released by intestinal cells and stimulate defecation.

The group discovered the phenomenon while looking for neurons that control defecation. After killing the neurons innervating the posterior body muscles, the authors found that contractions nevertheless continued. To find out how, they screened for mutants in muscle contraction and identified two genes. One was pbo-5, which encodes a receptor on the muscle surface. The other was pbo-4, whose protein product sends protons out of the intestinal epithelium. Classical neurotransmitters did not activate the PBO-5 receptor or muscle contraction, but the release of caged protons did, even in pbo-4 mutants, which are unable to release their own gut protons. By contrast, pbo-5 mutants did not respond to proton release.

"These protons possess all the attributes of a classical transmitter," says Jorgensen, including having a specific receptor. The brain might also use protons to control neuronal signaling. According to him, the gut signaling role for protons "demonstrates the creativity of evolution. Cutting out the middle man—the nervous system—allows direct communication between the epithelia and the muscle." Formula

Reference:

Beg, A., et al. 2008. Cell. 132:149–160.[CrossRef][Medline]



Richard Robinson

rrobinson{at}nasw.org


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This Article
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