Environmental stress differentially affects phenotypic modularity and fluctuating asymmetry in generalist and specialist cactophilic Drosophila.

Modularity and developmental (in)stability have the potential to influence phenotype production and, consequently, the evolutionary trajectories of species. Depending on the environmental factors involved and the buffering capacity of an organism, different developmental outcomes are expected. Cactophilic Drosophila species provide an established eco-evolutionary model with well-studied ecological conditions, making them ideal for studying these phenomena. Here, we investigated how variations in larval diet and exposure to alkaloids on primary and secondary host plants affect the degree of integration/modularity and fluctuating asymmetry (a proxy for developmental instability) of wing shape in two sibling species with different degrees of specialization: D. buzzatii (generalist) and D. koepferae (specialist). Additionally, we compared the anterior-posterior modular configuration with a recently proposed proximal-distal modular configuration. Our results revealed greater independence among proximal-distal modules compared to anterior-posterior modules. Moreover, we observed sex-specific responses, with males exhibiting greater susceptibility to stressful environments than females. Each species showed a particular trait pattern across treatments: D. buzzatii showed increased integration and fluctuating asymmetry when reared in a nutrient-poor, alkaloid-rich secondary host, while D. koepferae displayed similar responses in novel environments characterized by double doses of alkaloids on the secondary host plant. These findings align with the generalist-specialist paradigm, suggesting that specialists may be challenged by novel environments, whereas generalists may be more affected by stressful conditions. Our study highlights the importance of considering each part of the proximal-distal wing axis independently, and the need to consider ecological-evolutionary history when investigating the relationship between complex phenotypic traits and environmental stress.