Spread your wings: insect–plant–landscape interactions mediate the wing shape of a multivoltine polyphagous insect

Abstract

Wing morphology may affect the foraging efficiency of polyphagous insects via effects on their flight ability. Variations in wing morphology may be triggered by host plant quality, while landscape composition can also play a role in filtering the ability of variants to colonize new habitats. We investigated how intraspecific variations in wing morphology in a polyphagous insect are mediated by the quality of local resources and the role of the landscape in filtering these variations. We used Bemisia tabaci MEAM‐1 (Hemiptera: Aleyrodidae) as a model since the existence of morphotypes that engage in long‐ and short‐distance flights has been proposed previously. We collected B. tabaci adults in the vegetative, flowering, and senescence stages of tomato plants on 15 farms embedded in distinct landscape types. We also performed a greenhouse experiment to evaluate whether resource quality influences B. tabaci wing shape. The wing shape of individuals was measured using geometric morphometry analyses. We found sexual dimorphism in wing shape, with males presenting more straight wings and females with more elongated wings. The dispersal morphotypes appear with more rounded wings at the vegetative (colonizing individuals) and senescence stages (dispersing individuals). When the resource is predictable (flowering stage), the wing shape becomes more adapted for short‐distance flights, possibly dictated by an intergenerational effect that facilitates habitat exploitation. The natural vegetation acted as an environmental filter in morphotype selection by impairing individuals' movement among habitat patches. We showed for the first time that insect–plant–landscape interactions mediate intraspecific variation in the wing morphology of B. tabaci. This polyphagous multivoltine pest insect presents a specialized morphological response to food resource quality, and the amount of natural vegetation may constrain its movement across the landscape. Our results indicate that local resources and landscape features produce interacting bottom–up effects that affect polyphagous insects' morphological variation within the habitat.