Excitotoxic cell death is hypothesized to contribute to numerous neuropathologic conditions, including hypoxic/ischemic encephalopathy, hypoglycemia, Parkinson's disease, and Huntington's disease. Neuronal death from excitotoxic lesions has been shown to be an active process, with activation of immediate early gene transcription, resulting in secondary changes in gene expression. Another feature of neurotoxic cell death that has been examined is the presence of DNA fragmentation, which presumably indicates impending nuclear disintegration. A technique has been described for labeling fragmented DNA in situ, allowing precise determination of the anatomic and temporal distribution of neurons after an excitotoxic lesion. To investigate this phenomenon, we performed in situ nick translation on brain tissue from rats that have undergone stereotaxically placed intrastriatal quinolinic acid injections. Furthermore, in these same animals we analyzed the expression of c-fos mRNA to compare the time course and regional distribution of DNA fragmentation with immediate early gene activation after an excitotoxic lesion. Our analysis indicates that c-fos expression increases soon after quinolinic acid injection, is widespread in rat brain, but is effectively absent by 24 h postinjection. DNA fragmentation, however, is limited to striatum and is maximal at 24 h after injection. These results demonstrate the sensitivity of in situ nick translation for the detection of regional neuropathology and illustrate the temporal and spatial relationship of c-fos expression to excitotoxic neuronal death.