Midgut damage triggers thromboxane A2-dependent hemocyte recruitment in Culex pipiens molestus
Midgut damage triggers thromboxane A2-dependent hemocyte recruitment in Culex pipiens molestus
Lee, D.; Choi, D.-Y.; Kang, D.; Oh, S.; Shatta, A.; Yi, M.-h.; Choi, J. h.; Jang, Y. S.; Park, C.; Lee, I.-Y.; Kim, J. Y.
AbstractMosquitoes transmit diverse pathogens through repeated blood feeding, a process that subjects the midgut to significant mechanical stress and cellular damage. While hemocyte association with the midgut is known to occur following injury, the mechanisms promoting their recruitment remain poorly defined. Given the conserved roles of eicosanoid signaling in injury responses, we hypothesized that thromboxane A2 (TXA2) mediates hemocyte recruitment to the damaged midgut. Here, we demonstrate that chemically induced midgut damage significantly increases both the number of hemocytes attached to the midgut and those in circulation. Pharmacological inhibition of cyclooxygenase suppresses hemocyte recruitment whereas supplementation with a stable TXA2 analog restores the response, indicating that TXA2 signaling is required for this process. To identify candidate enzymes involved in TXA2 biosynthesis, we performed in silico docking analyses and identified two cytochrome P450 (CYP) candidates. Among these, CYP6D3 was shown to be strongly upregulated in hemocyte populations following midgut damage. RNA interference-mediated knockdown of CYP6D3 significantly reduced both hemocyte recruitment to the midgut and systemic TXB2 levels, supporting its role in the eicosanoid-mediated immune response. Together, our findings demonstrate that TXA2 signaling drives hemocyte recruitment to the damaged mosquito midgut and suggest a conserved lipid-mediated mechanism underlying insect tissue-associated immune responses that may influence vector competence.