| First Author | Ray RS | Year | 2013 |
| Journal | Brain Res | Volume | 1511 |
| Pages | 115-25 | PubMed ID | 23261662 |
| Mgi Jnum | J:206549 | Mgi Id | MGI:5551363 |
| Doi | 10.1016/j.brainres.2012.12.017 | Citation | Ray RS, et al. (2013) Egr2-neurons control the adult respiratory response to hypercapnia. Brain Res 1511:115-25 |
| abstractText | `The early growth response 2 transcription factor, Egr2, establishes a population of brainstem neurons essential for normal breathing at birth. Egr2-null mice die perinatally of respiratory insufficiency characterized by subnormal respiratory rate and severe apneas. Here we bypass this lethality using a noninvasive pharmacogenetic approach to inducibly perturb neuron activity postnatally, and ask if Egr2-neurons control respiration in adult mice. We found that the normal ventilatory increase in response to elevated tissue CO(2) was impaired, blunted by 63.1 +/- 8.7% after neuron perturbation due to deficits in both respiratory amplitude and frequency. By contrast, room-air breathing was unaffected, suggesting that the drive for baseline breathing may not require those Egr2-neurons manipulated here. Of the multiple brainstem sites proposed to affect ventilation in response to hypercapnia, only the retrotrapezoid nucleus, a portion of the serotonergic raphe, and a portion of the A5 nucleus have a history of Egr2 expression. We recently showed that acute inhibition of serotonergic neurons en masse blunts the CO(2) chemoreflex in adults, causing a difference in hypercapnic response of approximately 50% after neuron perturbation through effects on respiratory amplitude only. The suppressed respiratory frequency upon perturbation of Egr2-neurons thus may stem from non-serotonergic neurons within the Egr2 domain. Perturbation of Egr2-neurons did not affect body temperature, even on exposure to ambient 4 degrees C. These findings support a model in which Egr2-neurons are a critical component of the respiratory chemoreflex into adulthood. Methodologically, these results highlight how pharmacogenetic approaches allow neuron function to be queried in unanesthetized adult animals, reaching beyond the roadblocks of developmental lethality and compensation as well as the anatomical disturbances associated with invasive methods. This article is part of a Special Issue entitled Optogenetics (7th BRES). |
