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NEUROBIOLOGICAL MECHANISMS OF FEAR GENERALIZATIONCullen, Patrick Kennedy 23 July 2013 (has links)
No description available.
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CREB-mediated Enhancement of Hippocampus-dependent Memory Consolidation and ReconsolidationSekeres, Melanie Jay 12 December 2013 (has links)
Memory stabilization following encoding (synaptic consolidation) or memory reactivation (reconsolidation) requires gene expression and protein synthesis. Although consolidation and reconsolidation may be mediated by distinct molecular mechanisms, disrupting the function of the transcription factor CREB (cAMP responsive element binding protein) impairs both processes. We use a gain-of-function approach to show that CREB (and CREB-coactivator CRTC1) can facilitate both synaptic and systems consolidation and reconsolidation.
We first examine whether acutely increasing CREB levels in the dorsal hippocampus is sufficient to enhance spatial memory formation in the watermaze. Locally and acutely increasing CREB in the dorsal hippocampus using viral vectors is sufficient to induce robust spatial memory in two conditions which do not normally support consolidation, weakly-trained wild-type (WT) mice and strongly-trained mutant mice with brain-wide disrupted CREB function.
CRTCs (CREB regulated transcription co-activators) are a powerful co-activator of CREB, but their role in memory is virtually unexplored. We show, for the first time, that the novel CREB co-activator CRTC1 enhances memory consolidation. Locally increasing CRTC1 (or CREB) in the dorsal hippocampus of WT mice prior to weak context fear conditioning facilitates consolidation of precise context memory.
Last, we show that CREB or CRTC1 facilitates precise and enduring memory consolidation and reconsolidation. Acute enhancement of hippocampal CREB or CRTC1 during initial synaptic consolidation can maintain precision of remote context memory, while increasing CREB or CRTC1 just prior to reactivation of a weak remote context memory enhances context memory reconsolidation. These gain-of-function manipulations indicate that increasing CRTC1 or CREB function is sufficient to enhance the strength of new, as well as reactivated established, memories without compromising memory specificity.
Together with previous results, these findings indicate that CREB is both necessary and sufficient for hippocampal-dependent memory formation, and underline its pivotal role in the hippocampal molecular machinery underlying long-term memory consolidation and reconsolidation.
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CREB-mediated Enhancement of Hippocampus-dependent Memory Consolidation and ReconsolidationSekeres, Melanie Jay 12 December 2013 (has links)
Memory stabilization following encoding (synaptic consolidation) or memory reactivation (reconsolidation) requires gene expression and protein synthesis. Although consolidation and reconsolidation may be mediated by distinct molecular mechanisms, disrupting the function of the transcription factor CREB (cAMP responsive element binding protein) impairs both processes. We use a gain-of-function approach to show that CREB (and CREB-coactivator CRTC1) can facilitate both synaptic and systems consolidation and reconsolidation.
We first examine whether acutely increasing CREB levels in the dorsal hippocampus is sufficient to enhance spatial memory formation in the watermaze. Locally and acutely increasing CREB in the dorsal hippocampus using viral vectors is sufficient to induce robust spatial memory in two conditions which do not normally support consolidation, weakly-trained wild-type (WT) mice and strongly-trained mutant mice with brain-wide disrupted CREB function.
CRTCs (CREB regulated transcription co-activators) are a powerful co-activator of CREB, but their role in memory is virtually unexplored. We show, for the first time, that the novel CREB co-activator CRTC1 enhances memory consolidation. Locally increasing CRTC1 (or CREB) in the dorsal hippocampus of WT mice prior to weak context fear conditioning facilitates consolidation of precise context memory.
Last, we show that CREB or CRTC1 facilitates precise and enduring memory consolidation and reconsolidation. Acute enhancement of hippocampal CREB or CRTC1 during initial synaptic consolidation can maintain precision of remote context memory, while increasing CREB or CRTC1 just prior to reactivation of a weak remote context memory enhances context memory reconsolidation. These gain-of-function manipulations indicate that increasing CRTC1 or CREB function is sufficient to enhance the strength of new, as well as reactivated established, memories without compromising memory specificity.
Together with previous results, these findings indicate that CREB is both necessary and sufficient for hippocampal-dependent memory formation, and underline its pivotal role in the hippocampal molecular machinery underlying long-term memory consolidation and reconsolidation.
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[en] BEHAVIORAL AND PHARMACOLOGICAL EVALUATION BETWEEN ANXIETY AND PANIC IN ANIMALS MODELS / [pt] AVALIAÇÃO COMPORTAMENTAL E FARMACOLÓGICA DA RELAÇÃO ENTRE ANSIEDADE E PÂNICO EM MODELOS ANIMAISBRUNO DE OLIVEIRA GALVAO 13 May 2008 (has links)
[pt] A matéria cinzenta periaquedutal dorsal (MCPD) é associada
com comportamento defensivo e ataques de pânico em humanos.
Estimulações elétricas ou farmacológicas da MCPD induzem a
reações aversivas de corrida e pulo em ratos. Os resultados
no experimento 1 indicaram que animais submetidos a um
contexto previamente associado com choques nas patas,
obtiveram um comportamento defensivo de congelamento
robusto e tiveram menores reações defensivas de corridas e
pulos através da microinjeção de de 0.3 µl N-metil-D-
aspartato (NMDA; 15.0 mg/kg), quando comparado com o grupo
controle que não foi exposto ao procedimento de medo ao
contexto. No experimento 2, o efeito de injeções de
pentilenotetrazol (PTZ; 15.0 mg/kg i.p.) em ratos
microinjetados com NMDA nas reações de corridas e pulos foi
investigado. Os resultados mostraram que o PTZ (1ml/100gr)
foi capaz de minimizar as reações aversivas de corridas e
pulos induzidas pela microinjeção de NMDA na MCPD. Esses
resultados sugerem que a ativação de mecanismos cerebrais
que permeiam a ansiedade produzem um efeito inibitório em
ataques de pânico. / [en] The dorsal portion of the periaqueductal gray (DPAG) is
notably associated with defensive behavior and panic
attacks in humans. Electrical or pharmacological
stimulation of the DPAG induces aversive reactions such as
running and jumping in rats. Our results indicate that
animals exposed to contextual cues, that were previously
associated with electrical footshocks, engaged in robust
defensive freezing behavior and were less likely to display
running and jumping defensive reactions by microinjection
of 0.3 µl N-methyl-D-aspartate (NMDA; 15.0 mg/kg) into DPAG
when compared with control animals that were not exposed to
the context fear conditioning procedure. Furthermore the
effect of pentylenotetrazole injections (PTZ; 15.0 mg/kg
i.p.) in microinjected NMDA rats in aversive reactions of
running and jumping was investigated. The result showed
that PTZ dose (1ml/100gr) was capable to minimize the
aversive reactions of running and jumping induced by
microinjection of NMDA into DPAG. These results suggest
that activation of the brain mechanisms that underlie
anxiety produces an inhibitory effect on panic attacks.
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