Data Sheet 3_Transcriptomic profiling and targeted validation reveal molecular mechanisms of oxygen therapy in high-altitude cerebral injury.pdf

BackgroundExposure to high-altitude hypoxia is associated with an increased risk of impaired brain structure and function, with oxidative stress and neuroinflammation widely recognized as key mechanisms involved. In this context, hyperbaric oxygen therapy is considered a potential intervention; however, the mechanism by which it affects cerebral function changes caused by high-altitude exposure remains to be further elucidated. ObjectiveThis study aims to explore and compare the therapeutic effects of normobaric oxygen (NBO) and hyperbaric oxygen (HBO) on high-altitude cerebral injury (HACI), and to elucidate the molecular mechanisms underlying their neuroprotective effects using transcriptomic profiling and targeted validation. MethodsA mouse model of high-altitude cerebral injury was established using a hypobaric hypoxia chamber. Mice were exposed to a simulated altitude of 7,000 m (approximately 9.8% O₂ at 0.47 ATA) for 3 consecutive days to induce severe hypoxia. Animals were divided into four groups: Control (Con), High-Altitude exposure (HH), post-HH treated with normobaric oxygen (NBO; 100% O₂ at 1.0 ATA for 1 h daily for 3 days), and post-HH treated with hyperbaric oxygen (HBO; 100% O₂ at 2.0 ATA for 1 h daily for 3 days). Brain tissues were analyzed using H&E staining, RNA sequencing (RNA-seq), Western blotting for key pathway proteins, immunofluorescence for glial cell activation, and ELISA for inflammatory cytokines. Oxidative stress markers (SOD, MDA, GSH, NO) were also assessed. ResultsHistopathological analysis confirmed cerebral damage in the HH group, which was significantly ameliorated by both HBO and NBO treatments. RNA-seq revealed widespread disruption of the cerebral transcriptome following high-altitude exposure. Oxygen therapy was associated with partial restoration of global gene expression patterns. KEGG pathway analysis highlighted significant enrichment in pathways related to NF-κB signaling, cytokine–cytokine receptor interaction, IL-17 signaling, and PI3K–AKT signaling. Subsequent targeted validation demonstrated that oxygen treatment reduced oxidative stress (increased SOD and GSH; decreased MDA and NO) and modulated the PI3K–AKT signaling pathway (increased p-AKT/AKT). Concurrently, oxygen therapy attenuated neuroinflammatory responses, inhibiting microglial and astrocytic activation, reducing pro-inflammatory cytokine levels (IL-1β, IL-6, TNF-α), and modulating the TLR4–NF-κB signaling axis (decreased TLR4 and p-p65/p65). HBO treatment was associated with broader modulation of several molecular pathways involved in oxidative stress and inflammation. ConclusionExisting evidence suggests that HBO may exert protective effects against altitude-related brain injury. This mechanism likely involves activating the PI3K–AKT/Nrf2 axis to alleviate oxidative stress and inhibiting the TLR4–NF-κB pathway to reduce neuroinflammation, thereby partially restoring transcriptional homeostasis. However, the causal relationships between these pathways and their interactions require further validation and refinement.