Envenomation leads to venom protein reduction and recovery delay in bumblebee workers

The evolution and deployment of venom systems in animals has been central to their ecological success, though not without costs. For social bees, venom plays a key role in nest defence yet for species, such as honeybees, the act of stinging generally leads to death. However, for other social bee species, such as bumblebees, where stinging is not apparently fatal, it raises the question of what, if any, are the costs associated with venom usage (envenomation). Here, we investigated proteomic changes in the venom sac, the primary reservoir for venom storage, of Bombus terrestris workers over a short time-course post-envenomation. Our analysis reveals three key findings: 1) envenomation leads to changes in the venom sac proteome with affected proteins generally reduced in the bumblebee venom sac, suggestive of a molecular cost; 2) quantified reductions of traditional venom-associated proteins post-envenomation indicate changes in venom composition post-usage; and 3) recovery of reduced venom-associated proteins post-envenomation was delayed further indicating a potential cost at the molecular level associated with usage. Overall, our findings provide new insights into the consequences of venom usage in bumblebees.