Cocaine differentially regulates activator protein-1 mRNA levels and DNA-binding complexes in the rat striatum and cerebellum.

Cocaine is a psychomotor stimulant that exerts many of its behavioral and physiological effects through alteration of catecholamine reuptake systems. One early cellular response to cocaine administration is a brain region-specific alteration in the transcriptional pattern of immediate early genes belonging to the Fos/Jun family of nucleotide sequence-specific [activator protein-1 (AP-1)] DNA-binding proteins. The work described here compares cocaine-induced transcriptional regulation of immediate early gene mRNA levels, as well as AP-1 DNA-binding activity, within the striatum and cerebellum. In the striatum, acute cocaine administration increases cellular levels of c-fos and jun-B mRNA, whereas transcriptional effects in the cerebellum are limited to c-fos mRNA. After chronic cocaine treatment a desensitization of c-fos mRNA induction is observed in the striatum, with sensitization of the same transcriptional effect occurring in the cerebellum. Pharmacological studies further reveal that the dopamine D1, dopamine D2, gamma-aminobutyric acid type B, and N-methyl-D-aspartate receptor systems mediate the effects of cocaine on cerebellar neurons, whereas striatal effects are modulated through D1 and N-methyl-D-aspartate receptors. Gel retention analysis using antibodies to the various Fos and Jun proteins was used to characterize cocaine-dependent alterations in the composition of striatal and cerebellar AP-1 DNA-binding complexes. In striatum, cocaine increases the relative levels of c-Fos, Fos-B, Jun-B, and Jun-D proteins that bind the AP-1 DNA sequence element, whereas in the cerebellum only c-Fos and Jun-D binding activities are increased. These data suggest two possible neuroanatomical sites where tolerance and sensitization to cocaine can be examined at the genomic level.