Abstract
The indirect and direct electrical and anatomical evidence for the hypothesis that central chemoreceptor neurons in the dorsal brainstem (solitary complex, SC; locus coeruleus, LC) are coupled by gap junctions, as reported primarily in rat brainstem slices, and the methods used to study gap junctions in brain slices, are critiqued and reviewed. Gap junctions allow intercellular communication that could be important in either electrical coupling (intercellular flow of ionic current), metabolic coupling (intercellular flow of signaling molecules), or both, ultimately influencing excitability within the SC and LC during respiratory acidosis. Gap junctions may also provide a mechanism for modulating neuronal activity in the network under conditions that lead to increased or decreased central respiratory chemosensitivity. Indirect measures of electrical coupling suggest that junctional conductance between chemosensitive neurons is relatively insensitive to a broad range of intracellular pH (pH i ), ranging from pH i ≈7.49 to ≈6.71 at 35–37 °C. In contrast, further reductions in pH i , down through pH i ≈6.67, abolish indirect measures of electrical coupling.
Original language | American English |
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Journal | Respiration Physiology |
Volume | 129 |
DOIs | |
State | Published - Dec 1 2001 |
Keywords
- Carbon dioxide
- Chemosensitivity
- Control of breathing
- Gap junctions
- Intracellular pH
- Methods
- brain slice
- central
- central chemosensitivity
- dorsal motor nucleus
- dye coupling
- electrical coupling
- hypercapnia
- nucleus tractus solitarius
Disciplines
- Medical Cell Biology
- Medical Neurobiology
- Medical Physiology
- Medical Sciences
- Medicine and Health Sciences
- Neurosciences
- Physiological Processes