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Journal home Advance online publication Current issue Archive Press releases Supplements Focuses Guide to authors Online submission Permissions For referees Free online issue Contact the journal Subscribe Advertising work@npg naturereprints About this site For librarians   NPG Resources Nature Nature Reviews Neuroscience Nature Cell Biology Nature Medicine Neuroscience Gateway UCSD-Nature Signaling Gateway NPG Subject areas Biotechnology Cancer Chemistry Clinical Medicine Dentistry Development Drug Discovery Earth Sciences Evolution & Ecology Genetics Immunology Materials Science Medical Research Microbiology Molecular Cell Biology Neuroscience Pharmacology Physics Browse all publications Article Nature Neuroscience  7, 1360 - 1369 (2004) Published online: 21 November 2004; | doi:10.1038/nn1357 Respiratory control by ventral surface chemoreceptor neurons in rats Daniel K Mulkey, Ruth L Stornetta, Matthew C Weston, Johnny R Simmons, Anson Parker, Douglas A Bayliss & Patrice G Guyenet Department of Pharmacology, University of Virginia, Charlottesville, Virginia 22908, USA. Correspondence should be addressed to Patrice G Guyenet pgg@virginia.eduA long-standing theory posits that central chemoreception, the CNS mechanism for CO2 detection and regulation of breathing, involves neurons located at the ventral surface of the medulla oblongata (VMS). Using in vivo and in vitro electrophysiological recordings, we identify VMS neurons within the rat retrotrapezoid nucleus (RTN) that have characteristics befitting these elusive chemoreceptors. These glutamatergic neurons are vigorously activated by CO2 in vivo, whereas serotonergic neurons are not. Their CO2 sensitivity is unaffected by pharmacological blockade of the respiratory pattern generator and persists without carotid body input. RTN CO2-sensitive neurons have extensive dendrites along the VMS and they innervate key pontomedullary respiratory centers. In brainstem slices, a subset of RTN neurons with markedly similar morphology is robustly activated by acidification and CO2. Their pH sensitivity is intrinsic and involves a background K+ current. In short, the CO2-sensitive neurons of the RTN are good candidates for the long sought-after VMS chemoreceptors. MORE ARTICLES LIKE THIS These links to content published by NPG are automatically generated. NEWS AND VIEWS Back to the future: carbon dioxide chemoreceptors in the mammalian brain Nature Neuroscience News and Views (01 Dec 2004) Practice makes perfect, even for breathing Nature Neuroscience News and Views (01 Aug 2009) RESEARCH MafB deficiency causes defective respiratory rhythmogenesis and fatal central apnea at birth Nature Neuroscience Article (01 Oct 2003) See all 8 matches for Research  Top Abstract Previous | Next Table of contents Full text Download PDF Send to a friend Save this link Open Innovation Challenges Methods of Modeling Adaptation in Populations Deadline: Dec 30 2009 Reward: $15,000 USD The analysis of adaptation with a population is a frequently encountered computational modeling scen... Optimizing Sub-cellular Localization Tags Deadline: Jan 31 2010 Reward: $20,000 USD The Seeker is looking for methods to optimize sub-cellular localization tags for protein expression.... More Challenges Powered by: nature jobs Data Manager Philip Morris International (PMI) Neuchatel Switzerland Professor of Cognitive Neuroscience Karolinska Institute Stockholm Sweden More science jobs Post a job for free Figures & Tables Supplementary info See also: News and Views by Mitchell Export citation Search buyers guide:   ADVERTISEMENT

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