SummarySynaptic loss is the best pathological correlate of the cognitive decline in Alzheimer's Disease; yet, the molecular mechanisms underlying synaptic failure are unknown. Here we report a non-apoptotic baseline caspase-3 activity in hippocampal dendritic spines, and an enhancement of this activity at the onset of memory decline in the Tg2576-APPswe mouse model of Alzheimer's Disease. We show that, in spines, caspase-3 activates calcineurin which, in turn, triggers dephosphorylation and removal of the GluR1 subunit of AMPA-type receptor from post-synaptic sites. These molecular modifications lead to alterations of glutamatergic synaptic transmission and plasticity, and correlate with spine degeneration and a deficit in hippocampal-dependent memory. Importantly, pharmacological inhibition of caspase-3 activity in Tg2576 mice rescues the observed Alzheimerlike phenotypes. Therefore, we identify a novel caspase-3-dependent mechanism driving synaptic failure and contributing to cognitive dysfunction in Alzheimer's Disease. These findings point to caspase-3 as possible avenues for pharmacological therapy during early disease stages.Episodic hippocampal-dependent memory loss, the earliest clinical sign of Alzheimer's disease, is thought to be due to changes in synaptic function rather than neuronal loss 1,2 . Specifically, functional brain imaging studies revealed hippocampal mild abnormalities prior to clinical diagnosis and in the absence of structural brain atrophy, suggesting an altered functional connectivity of hippocampus at early stages of disease [3][4][5] .Dendritic spines are likely to be the first affected synaptic elements during early cognitive decline 6 . This is supported by several lines of evidence, such as: i) hippocampal spine-mediated plasticity underlies learning and memory 7 ; ii) post-mortem hippocampus from Alzheimer patients shows a significant decrease in dendritic spine density compared to age-matched controls 8 and iii) transgenic 3 mice expressing mutated forms of the amyloid precursor protein (APP), associated with familial Alzheimer's Disease, show age-dependent reductions in spine density, prior to plaque deposition 9 .Nevertheless, the molecular link between APP mutations triggering Alzheimer's Disease, and the occurrence of early spine loss remains elusive. Interestingly, a localized caspase-3 activity, causing synaptic failure, has been observed in vitro 10 , but the molecular mechanism linking caspase-3 activity to synaptic loss is far from being elucidated.Here, we analyzed caspase-3 activity in hippocampal synapses of the Tg2576 transgenic mouse model, harboring the human APPswe mutant allele linked to familial Alzheimer's Disease 11 . These mice develop early synaptic deficits 12 and several neuropathological features at older age, including amyloid plaques and dystrophic neurites 13 . Although Tg2576 mice lack neurofibrillary tangles and significant neuronal loss 14 , there is strong evidence that accumulation of the amyloid-β (Aβ) peptide, derived via APP proteolysis, is r...
The Formation of Recent and Remote Memory Is Associated with Time-Dependent Formation of Dendritic Spines in the Hippocampus and Anterior Cingulate Cortex
Although hippocampal-cortical interactions are crucial for the formation of enduring declarative memories, synaptic events that govern long-term memory storage remain mostly unclear. We present evidence that neuronal structural changes, i.e., dendritic spine growth, develop sequentially in the hippocampus and anterior cingulate cortex (aCC) during the formation of recent and remote contextual fear memory. We found that mice placed in a conditioning chamber for one 7 min conditioning session and exposed to five footshocks (duration, 2 s; intensity, 0.7 mA; interstimulus interval, 60 s) delivered through the grid floor exhibited robust fear response when returned to the experimental context 24 h or 36 d after the conditioning. We then observed that their fear response at the recent, but not the remote, time point was associated with an increase in spine density on hippocampal neurons, whereas an inverse temporal pattern of spine density changes occurred on aCC neurons. At each time point, hippocampal or aCC structural alterations were achieved even in the absence of recent or remote memory tests, thus suggesting that they were not driven by retrieval processes. Furthermore, ibotenic lesions of the hippocampus impaired remote memory and prevented dendritic spine growth on aCC neurons when they were performed immediately after the conditioning, whereas they were ineffective when performed 24 d later. These findings reveal that gradual structural changes modifying connectivity in hippocampal-cortical networks underlie the formation and expression of remote memory, and that the hippocampus plays a crucial but time-limited role in driving structural plasticity in the cortex.
Fragile X syndrome, the most frequent form of hereditary mental retardation, is due to a mutation of the fragile X mental retardation 1 (FMR1) gene on the X chromosome. Like fragile X patients, FMR1-knockout (FMR1-KO) mice lack the normal fragile X mental retardation protein (FMRP) and show both cognitive alterations and an immature neuronal morphology. We reared FMR1-KO mice in a C57BL͞6 background in enriched environmental conditions to examine the possibility that experience-dependent stimulation alleviates their behavioral and neuronal abnormalities. FMR1-KO mice kept in standard cages were hyperactive, displayed an altered pattern of open field exploration, and did not show habituation. Quantitative morphological analyses revealed a reduction in basal dendrite length and branching together with more immatureappearing spines along apical dendrites of layer five pyramidal neurons in the visual cortex. Enrichment largely rescued these behavioral and neuronal abnormalities while increasing ␣-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptor subunit 1 (GluR1) levels in both genotypes. Enrichment did not, however, affect FMRP levels in the WT mice. These data suggest that FMRP-independent pathways activating glutamatergic signaling are preserved in FMR1-KO mice and that they can be elicited by environmental stimulation.fragile X mental retardation protein ͉ mental retardation ͉ FMR1 gene ͉ AMPA receptor ͉ dendritic spines S everal genes associated with mental retardation have been mapped on the X chromosome and, among them is the fragile X mental retardation 1 (FMR1) gene. The fragile X mental retardation protein (FMRP) absence or mutation is responsible for the fragile X syndrome (FXS), which is the most common form of inherited mental retardation. Most of the individuals affected carry a trinucleotide repeat that, after methylation, leads to transcriptional silencing of the FMR1 gene (1). Patients with the FXS do not express FMRP and exhibit phenotypic traits ranging from severe (IQ 20) to moderate (IQ 60) mental retardation, defective attention, autistic behavior, and physical features including an elongated face, large ears, joint laxity, and macroorchidism (2-5).FMR1 is highly conserved between human and mouse, with a nucleotide and amino acid identity of 95% and 97%, respectively (6). The expression pattern of mouse FMR1 is similar to its human counterpart in both tissue specificity and timing (7). Interestingly, FMR1-knockout (FMR1-KO) mice, the mouse model for the FXS, lack the normal FMRP and show macroorchidism, hyperactivity, and mild learning deficits (8, 9) reminiscent of the human syndrome.One common brain feature of fragile X patients and of the mouse model for the syndrome is the presence of long and thin immature dendritic spines indicative of defective pruning during development (10)(11)(12)(13)(14). At the molecular level, it has been shown that protein synthesis triggered by the type I metabotropic glutamate receptor (mGluR1) agonist dihydroxyphenylglycine is dramati...
N-cofilin is associated with neuronal migration disorders and cell cycle control in the cerebral cortex
Many neuronal disorders such as lissencephaly, epilepsy, and schizophrenia are caused by the abnormal migration of neurons in the developing brain. The role of the actin cytoskeleton in neuronal migration disorders has in large part remained elusive. Here we show that the F-actin depolymerizing factor n-cofilin controls cell migration and cell cycle progression in the cerebral cortex. Loss of n-cofilin impairs radial migration, resulting in the lack of intermediate cortical layers. Neuronal progenitors in the ventricular zone show increased cell cycle exit and exaggerated neuronal differentiation, leading to the depletion of the neuronal progenitor pool. These results demonstrate that mutations affecting regulators of the actin cytoskeleton contribute to the pathology of cortex development.[Keywords: Cortex development; cofilins; actin cytoskeleton; neuronal migration disorders; cell cycle] Supplemental material is available at http://www.genesdev.org.
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