Acute oxygen sensing by the carotid body: from mitochondria to plasma membrane

• Published in: Journal of applied physiology (1985) Vol. 123; no. 5; pp. 1335 - 1343
• Main Author: Chang, Andy J.
• Format: Journal Article
• Language: English
• Published: United States American Physiological Society 01.11.2017
• Subjects: Adaptation, Physiological; Animals; Bifurcations; Blood; Blood levels; Brain stem; Breathing; Carotid artery; Carotid body; Carotid Body - cytology; Carotid Body - physiology; Cell Membrane - metabolism; Chemoreception; Detection; Glomus cells; Heart; Heart diseases; Homeostasis; Humans; Hyperactivity; Hypoxia; Insulin; Membrane proteins; Membranes; Mitochondria; Mitochondria - metabolism; Nerves; Oxygen; Oxygen - metabolism; Plasma; Proteins; Respiration; Sensory neurons; Sleep; potassium channel; oxygen sensing; olfactory receptor; mitochondria
• ISSN: 8750-7587; 1522-1601; 1522-1601
• DOI: 10.1152/japplphysiol.00398.2017

Maintaining oxygen homeostasis is crucial to the survival of animals. Mammals respond acutely to changes in blood oxygen levels by modulating cardiopulmonary function. The major sensor of blood oxygen that regulates breathing is the carotid body (CB), a small chemosensory organ located at the carotid bifurcation. When arterial blood oxygen levels drop in hypoxia, neuroendocrine cells in the CB called glomus cells are activated to signal to afferent nerves that project to the brain stem. The mechanism by which hypoxia stimulates CB sensory activity has been the subject of many studies over the past 90 years. Two discrete models emerged that argue for the seat of oxygen sensing to lie either in the plasma membrane or mitochondria of CB cells. Recent studies are bridging the gap between these models by identifying hypoxic signals generated by changes in mitochondrial function in the CB that can be sensed by plasma membrane proteins on glomus cells. The CB is important for physiological adaptation to hypoxia, and its dysfunction contributes to sympathetic hyperactivity in common conditions such as sleep-disordered breathing, chronic heart failure, and insulin resistance. Understanding the basic mechanism of oxygen sensing in the CB could allow us to develop strategies to target this organ for therapy. In this short review, I will describe two historical models of CB oxygen sensing and new findings that are integrating these models.