ABSTRACT Many of the spatial patterns observed in nature are governed by interactions between species and between species and their environment, providing valuable information about which processes are determinants in shaping ecological communities. In a system composed of Mimosa bimucronata, the bruchine Acanthoscelides schrankie and its parasitoids, we examined the spatial distribution patterns of these insects and fruit quality. We tested the hypothesis that an aggregate pattern of parasitism is predominant, characterizing a direct density-dependent pattern. Because nitrogen, water, and phenols are crucial fruit traits that can affect the fitness of many insects, we also tested the hypothesis that the spatial distribution of A. schrankie and its parasitoids is positively associated with water and nitrogen content in the fruits and negatively associated (i.e., dissociation) with phenols. The distribution of bruchine and its parasitoids varied over time, from random to aggregated. The spatial patterns of parasitism varied between direct density dependence, inverse density dependence, and density independence. Dissociations were found between the abundance of A. schrankiae and the phenolic content, and similar results were found for the parasitoids. Our results suggest that a combination of bottom-up and top-down effects may drive spatiotemporal dynamics between A. schrankiae and its parasitoids.