Abstract
Honeybees (Apis mellifera) provide crucial pollination services to agricultural systems globally, however, their healthspan in these contexts is constantly at risk. Agricultural environments impose a variety of sublethal stressors onto honeybees, including parasites, pathogens, pesticides, and poor nutrition. Synergies between age, age-associated tasks, and these stressors are believed to underlie colony failure trends of the past decade. Identifying the mechanisms by which age and stressors impact honeybee physiology is an important priority in protecting honeybee and other pollinator populations. An underexplored physiological structure in honeybees is the blood-brain barrier, a protective layer of cells that surround the brain. Here, we assess a key dimensions of blood-brain barrier function, paracellular and transcellular permeability to molecules in the hemolymph. We assess these modes of permeability in multiple age groups and after exposure to varying levels of infestation by the parasitic mite Varroa destructor during development. Our results demonstrate that the paracellular permeability of the honeybee blood-brain barrier is stable across their lifespan and upon Varroa exposure. In contrast, we found that transcellular permeability is increased in honeybees exposed to a high Varroa load. These results demonstrate how age and stress variably impact a primary protective structure of the honeybee central nervous system, which may lead to targeted interventions for protecting honeybee healthspan. The assay developed here may be easily applied to different aging- and stress contexts, further enabling studies focused on understanding maintenance and decline of the honeybee blood-brain barrier.
Competing Interest Statement
The authors have declared no competing interest.