Recent studies suggest a role for rapid induction of transcription factors in stimulus-induced neuronal plasticity in the mammalian brain. Synaptic activation of transcription factors has been analyzed in the hippocampus using the long-term potentiation or enhancement (LTP/LTE) paradigm. Using this approach, several studies have identified transcription factors that are induced in hippocampal granule cells by NMDA receptor-dependent mechanisms; however, the link between long-term plasticity and activation of these genes has been called into question by reports suggesting that the thresholds for LTE and gene activation differ. To address this issue, we have used a chronic in vivo recording technique to monitor mRNA responses of several transcription factor genes to two different patterns of LTE-inducing electrical stimulation of entorhinal cortical afferents to hippocampus. One pattern consisted of 10 repetitions of a 20 or 25 msec train of pulses at 400 Hz (80 or 100 pulses total). This "10-train" pattern has been used in previous studies of LTE and produces robust synaptic enhancement lasting at least 3 d (Barnes, 1979). The other stimulation pattern consisted of 50 repetitions of a 20 msec train delivered at 400 Hz (400 pulses total), which is similar to parameters used in other studies reporting induction of c-fos in association with LTE (Dragunow et al., 1989; Jeffery et al., 1990; Abraham et al., 1992). Our results indicate that expression of zif268, monitored by in situ hybridization and immunostaining, is strongly induced by the 10-train stimulus pattern to levels similar to those induced by seizure activity. JunB mRNA levels are also modestly increased by the 10-train stimulus pattern; however, increases in JunB immunostaining were not detected. Neither c-fos nor c-jun mRNA were detectably induced by this stimulus. In contrast, the 50-train stimulus pattern resulted in a robust induction of c-fos and c-jun mRNA, in addition to zif268 and junB. Transcription factor responses to either stimulus pattern were blocked by the noncompetitive NMDA receptor antagonist MK-801. Identical transcription factor responses were observed in adult (6-12-month-old) and aged (23-26-month-old) rats, suggesting that synaptic mechanisms involved in these responses are preserved in aged animals. Analysis of LTE following either the 10- or 50-train stimulus patterns revealed identical magnitudes of initial induction and decay kinetics (approximately 3 d) and indicates that the 10-train stimulus pattern is sufficient to produce maximal synaptic enhancement.(ABSTRACT TRUNCATED AT 400 WORDS)
Calcium/calmodulin-dependent protein kinase II (CaMK) and p42 mitogen-activated protein kinase (MAPK) are enriched in neurons and possess the capacity to become persistently active, or autonomous, following removal of the activating stimulus. Since persistent kinase activation may be a mechanism for information storage, we have used primary cultures of cortical neurons to investigate whether kinase autonomy can be triggered by bursts of spontaneous synaptic activity. We and others have found that both these kinases respond to synaptic stimulation, but differ markedly in their kinetics of activation and inactivation, as well as in their sensitivity to NMDA receptor blockade. While 90% of maximal CaMK activation was observed after only 10 set of synaptic bursting, MAPK activity was unaffected at this early time and rose to only 30% of maximal after 2 min of stimulation. Following blockade of synaptic stimulation, CaMK activity decreased by 50% in 1 O-30 set, while MAPK activity decayed by 50% within 6-l 0 min. Although MAPK exhibited relatively slow activation, short periods of synaptic activity could trigger the MAPK activation process, which persisted in the absence of synaptic stimulation. Comparison of the effect of NMDA receptor blockade on synaptic activation of these kinases revealed that CaMK activity is preferentially suppressed. As previous immunocytochemical studies indicate that CaMK is concentrated in dendritic processes in the vicinity of synapses, we measured synaptic calcium transients in fine dendritic processes (-1 pm diameter) to assess their sensitivity to NMDA receptor blockade. Calcium transients in these fine processes were reduced by up to 90% by NMDA receptor blockade, possibly accounting for the profound sensitivity of CaMK to this treatment. The sharp contrast between the regulation of CaMK and MAPK by synaptic activity indicates that they may mediate neuronal responses to different patterns of afferent stimulation. The relatively slow activation and inactivation
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