Certain specialist herbivorous insects have evolved elegant mechanisms to manipulate the physiology of their host plants, including the ability to redirect the fate of plant cells toward the creation of a novel, tumor-like organ, called ‘galls’. While some plants have evolved resistance to gall-inducing insects, the underlying genetic mechanisms remain poorly understood. In this study, we focused on the chalcid gall-inducing wasp, Hemadas nubilipennis (Ormyridae) and its host plant, highbush blueberry Vaccinium corymbosum (Ericaceae). To identify the genetic basis of resistance to gall induction in blueberry, we developed a genetic mapping population derived from the susceptible ‘Liberty’ and resistant ‘Draper’ cultivars. We identified four quantitative trait loci (QTLs) associated with galling resistance, with candidate genes in these regions associated with plant defense, biotic stress response, and phytohormone metabolism. Furthermore, we analyzed gene expression on days one through seven post-oviposition in both susceptible and resistant genotypes, compared to controls, to identify genes and pathways that may contribute to galling resistance. Gene expression analyses, including genes within the four identified QTL regions, revealed a robust early defense response in the resistant genotype, marked by upregulation of defense, stress, and immunity genes following oviposition, ultimately leading to insect death. Conversely, the susceptible genotype exhibited a delayed and weaker response, allowing gall development and insect survival. We expect these results to serve as a resource that will enable breeding programs to employ molecular approaches for selection of resistant cultivars, while also guiding future research aimed at studying the evolution of galling resistance.

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