Long dismissed as a passive marker of ventilatory failure, elevated carbon dioxide (PaCO₂ > 45 mmHg) is now recognized as a potent signaling molecule that orchestrates complex cellular responses. This review synthesizes recent advances revealing how hypercapnia modulates fundamental processes, immune regulation, tissue repair, and metabolism, through direct molecular mechanisms. We detail how CO₂ triggers noncanonical NF-κB signaling, alters Wnt ligand secretion to impair alveolar regeneration, and exacerbates TLR4-primed NLRP3 inflammasome activation; this pro-inflammatory effect is most prominent in specific cell types like microglia and under conditions of sustained high CO₂ levels. Furthermore, hypercapnia drives profound metabolic reprogramming and induces lasting epigenetic changes, such as TET1-downregulation-mediated CDH1 hypermethylation, which reinforces immunosuppression in chronic lung disease. Critically, we evaluate emerging tools like CarboSen probes that enable more precise separation of CO₂-specific effects from associated acidosis in buffered experimental systems. Therapeutically, these insights argue for precision strategies: macrophage-specific Akt1 inhibition to restore antiviral immunity, localized Wnt agonists to promote repair, or targeting the leptin/STAT3/SOCS3 axis to improve ventilatory drive. However, translation requires navigating significant species differences and unresolved questions regarding epigenetic reversibility. By framing hypercapnia not as a uniform stressor but as a complex modulator whose effects are dictated by concentration, duration, and the specific tissue type involved, this review charts a course toward targeting CO₂-driven signaling for therapeutic benefit in conditions ranging from ARDS and COPD to obesity hypoventilation syndrome.
Moradi et al. (Wed,) studied this question.