Cover Image for this issue: doi: 10.1111/jnc.12561.
Targeted gene mutation of E2F1 evokes age-dependent synaptic disruption and behavioral deficits
Article first published online: 12 FEB 2014
© 2014 International Society for Neurochemistry
Journal of Neurochemistry
Volume 129, Issue 5, pages 850–863, June 2014
How to Cite
J. Neurochem. (2014) 129, 850–863.
- Issue published online: 18 MAY 2014
- Article first published online: 12 FEB 2014
- Accepted manuscript online: 26 JAN 2014 02:40AM EST
- Manuscript Accepted: 10 JAN 2014
- Manuscript Revised: 21 NOV 2013
- Manuscript Received: 22 AUG 2013
- National Institute of Health
- adult neurogenesis;
- cell cycle;
- synaptic proteins;
- transgenic mice
Aberrant expression and activation of the cell cycle protein E2F1 in neurons has been implicated in many neurodegenerative diseases. As a transcription factor regulating G1 to S phase progression in proliferative cells, E2F1 is often up-regulated and activated in models of neuronal death. However, despite its well-studied functions in neuronal death, little is known regarding the role of E2F1 in the mature brain. In this study, we used a combined approach to study the effect of E2F1 gene disruption on mouse behavior and brain biochemistry. We identified significant age-dependent olfactory and memory-related deficits in E2f1 mutant mice. In addition, we found that E2F1 exhibits punctated staining and localizes closely to the synapse. Furthermore, we found a mirroring age-dependent loss of post-synaptic protein-95 in the hippocampus and olfactory bulb as well as a global loss of several other synaptic proteins. Coincidently, E2F1 expression is significantly elevated at the ages, in which behavioral and synaptic perturbations were observed. Finally, we show that deficits in adult neurogenesis persist late in aged E2f1 mutant mice which may partially contribute to the behavior phenotypes. Taken together, our data suggest that the disruption of E2F1 function leads to specific age-dependent behavioral deficits and synaptic perturbations.
E2F1 is a transcription factor regulating cell cycle progression and apoptosis. Although E2F1 dysregulation under toxic conditions can lead to neuronal death, little is known about its physiologic activity in the healthy brain. Here, we report significant age-dependent olfactory and memory deficits in mice with dysfunctional E2F1. Coincident with these behavioral changes, we also found age-matched synaptic disruption and persisting reduction in adult neurogenesis. Our study demonstrates that E2F1 contributes to physiologic brain structure and function.