Neuronal excitation-driven and AP-1-dependent activation of tissue inhibitor of metalloproteinases-1 gene expression in rodent hippocampus.

Understanding of biological function of AP-1 transcription factor in central nervous system may greatly benefit from identifying its target genes. In this study, we present several lines of evidence implying AP-1 in regulating expression of tissue inhibitor of metalloproteinases-1 (timp-1) gene in rodent hippocampus in response to increased neuronal excitation. Such a notion is supported by the findings that timp-1 mRNA accumulation occurs in the rat hippocampus after either kainate- or pentylenetetrazole-evoked seizures with a delayed, in comparison with AP-1 components, time course, as well as with spatial overlap with c-Fos protein (major inducible AP-1 component) expression. Furthermore, AP-1 sequence derived from timp-1 promoter is specifically bound by hippocampal AP-1 proteins after treating the rats with either pro-convulsive agent. Finally, timp-1 promoter responds to excitatory activation both in vivo, in transgenic mice harboring the timp-LacZ gene construct, and in vitro in neurons of the hippocampal dentate gyrus cultures. These findings suggest that the AP-1 transcription factor may exert its role in the brain through affecting extracellular matrix remodeling.

Kainate-evoked modulation of gene expression in rat brain.

Kainate is a glutamate analog that produces neuronal excitation resulting in seizures within hours following its intraperitoneal injection into adult rats. Then, at 2-3 days after the treatment, neurodegeneration of apoptotic character can be observed in limbic system. As a consequence, plastic reorganization and glial reactivation phenomena occur. These physiological and pathological responses are reflected by specific changes in gene expression, that can be dissected according to their spatio-temporal patterns. The early phase of gene expression observed in all hippocampal subfields appears to reflect a sudden burst of spiking activity. Changes in mRNA levels restricted to dentate gyrus are suggestive of a link to neuronal plasticity. The late gene expression response implies its correlation either to neuronal cell death or glial reactivation, depending on cellular localization of gene products. Thus analysis of the temporal and spatial gene expression pattern in the hippocampus after kainate treatment may provide clues revealing specific phenomena to which gene expression could be attributed.