Transcriptome–Metabolome Integration Deciphers the Metabolic and Transcriptional Reprogramming in Mice Due to Vespa mandarinia Venom

Venom-mediated systemic toxicity is not fully understood. This study explored the dose-dependent effects of Vespa mandarinia venom (VMV) on mice via integrated transcriptomic and metabolomic analyses. Subcutaneous VMV injection induced dose-dependent hypothermia: 80 μg caused severe transient hypothermia and partial mortality, while 40/60 μg led to reversible hypothermia within 24 h. Whole-blood sequencing identified 2400–3281 differentially expressed genes (DEGs) per group, including 1764 shared DEGs. Immune-related pathways were significantly activated, with hub genes validated by qRT-PCR. Serum metabolomics revealed alterations in organic acids, alkaloids, and other metabolites. Integrative transcriptome–metabolome analysis predicted the potential involvement of various pathways in VMV-induced toxicity, including ferroptosis (shared in low-dose VMV groups) and apoptosis. Cumulatively, this study confirms that VMV induces immunometabolic reprogramming, providing a molecular framework for understanding venom-induced systemic toxicity.