Repetitive behaviors and hyperactivity are common features of developmental disorders, including autism. Neuropathology of the cerebellum is also a frequent occurrence in autism and other developmental disorders. Recent studies have indicated that cerebellar pathology may play a causal role in the generation of repetitive and hyperactive behaviors. In this study, we examined the relationship between cerebellar pathology and these behaviors in a mouse model of Purkinje cell loss. Specifically, we made aggregation chimeras between Lc/+ mutant embryos and +/+ embryos. Lc/+ mice lose 100% of their Purkinje cells postnatally due to a cell‐intrinsic gain‐of‐function mutation. Through our histological examination, we demonstrated that Lc/+↔+/+ chimeric mice have Purkinje cells ranging from zero to normal numbers. Our analysis of these chimeric cerebella confirmed previous studies on Purkinje cell lineage. The results of both open‐field activity and hole‐board exploration testing indicated negative relationships between Purkinje cell number and measures of activity and investigatory nose‐poking. Additionally, in a progressive‐ratio operant paradigm, we found that Lc/+ mice lever‐pressed significantly less than +/+ controls, which led to significantly lower breakpoints in this group. In contrast, chimeric mice lever‐pressed significantly more than controls and this repetitive lever‐pressing behavior was significantly and negatively correlated with total Purkinje cell numbers. Although the performance of Lc/+ mice is probably related to their motor deficits, the significant relationships between Purkinje cell number and repetitive lever‐pressing behavior as well as open‐field activity measures provide support for a role of cerebellar pathology in generating repetitive behavior and increased activity in chimeric mice.