Dietary modulation of lung lipids influences inflammatory responses to inhaled ozone

• Published in: Journal of lipid research Vol. 65; no. 9; p. 100630
• Main Authors: Hunter, Russell, Baird, Brenna, Mazloumi-Bakhshayesh, Milad, Goitom, Siem, Lucas, Selita, Herbert, Guy, Scieszka, David, Davis, Edward, Gu, Haiwei, Jin, Yan, Bleske, Barry E., Campen, Matthew J.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.09.2024; American Society for Biochemistry and Molecular Biology; Elsevier
• Subjects: dietary fat; lung; omega-3 fatty acids; oxidized lipids; ozone; phospholipids; toxicology; triglycerides; toxicology; lung; SC; dietary fat; FO; omega-3 fatty acids; triglycerides; phospholipids; oxidized lipids; CO; SO; ozone
• ISSN: 0022-2275; 1539-7262; 1539-7262
• DOI: 10.1016/j.jlr.2024.100630

The pulmonary system represents a unique lipidomic environment as it contains cellular membrane-bound lipid species and a specialized reservoir of lipids in the airway epithelial lining fluid. As a major initial point of defense, airway lipids react to inhaled contaminants such as volatile organic compounds, oxides of nitrogen, or ozone (O3), creating lipokine signaling that is crucial for both the initiation and resolution of inflammation within the lung. Dietary modulation of eicosanoids has gained increased attention in recent years for improvements to cardiovascular health. The current study sought to examine how dietary supplementation with eicosanoid precursors (i.e, oils rich in saturated or polyunsaturated fatty acids) might alter the lung lipid composition and subsequently modify the inflammatory response to ozone inhalation. Our study demonstrated that mice fed a diet high in saturated fatty acids resulted in diet-specific changes to lung lipid profiles and increased cellular recruitment to the lung following ozone inhalation. Bioinformatic analysis revealed an ozone-dependent upregulation of several lipid species, including phosphoserine 37:5. Pathway analysis of lipid species revealed the process of lateral diffusion of lipids within membranes to be significantly altered due to ozone exposure. These results show promising data for influencing pulmonary lipidomic profiles via diet, which may provide a pragmatic therapeutic approach to protect against lung inflammation and damage following pulmonary insult.