CaMKIIb activity is differentially modulated in a depression/resilience GxE model CaMKIIb activity is critical for determining stress susceptibility and resilience CaMKIIb-mediated TARPg-8 activation exerts pro-resilience effects TARPg-8-mediated synaptic expression of GluA1 confers chronic stress resiliency
Mammalian target of rapamycin (mTOR) is a central regulator of cellular metabolism. The importance of mTORC1 signaling in neuronal development and functions has been highlighted by its strong relationship with many neurological and neuropsychiatric diseases. Previous studies demonstrated that hyperactivation of mTORC1 in forebrain recapitulates tuberous sclerosis and neurodegeneration. In the mouse cerebellum, Purkinje cell-specific knockout of
Tsc1/2
has been implicated in autistic-like behaviors. However, since TSC1/2 activity does not always correlate with clinical manifestations as evident in some cases of tuberous sclerosis, the intriguing possibility is raised that phenotypes observed in
Tsc1/2
knockout mice cannot be attributable solely to mTORC1 hyperactivation. Here we generated transgenic mice in which mTORC1 signaling is directly hyperactivated in Purkinje cells. The transgenic mice exhibited impaired synapse elimination of climbing fibers and motor discoordination without affecting social behaviors. Furthermore, mTORC1 hyperactivation induced prominent apoptosis of Purkinje cells, accompanied with dysregulated cellular homeostasis including cell enlargement, increased mitochondrial respiratory activity, and activation of pseudohypoxic response. These findings suggest the different contributions between hyperactivated mTORC1 and
Tsc1/2
knockout in social behaviors, and reveal the perturbations of cellular homeostasis by hyperactivated mTORC1 as possible underlying mechanisms of neuronal dysfunctions and death in tuberous sclerosis and neurodegenerative diseases.
Soluble amyloid- (A) oligomers (AOs), which elicit neurotoxicity and synaptotoxicity, are thought to play an initiating role in the pathology of Alzheimer's disease (AD). Since AOs are a key therapeutic target, we attempted to identify natural agents that reduce AO neurotoxicity. Using an assay system in which primary cultured neurons are treated with AOs, we found that Rhodiola rosea extracts and one of its main constituents, tyrosol, significantly inhibited AO-induced caspase-3 activation. We then assessed the in vivo efficacy of tyrosol by oral administration of the compound into AD model (5XFAD) transgenic and non-transgenic mice from either 2 or 4 to 7 months of age. In both paradigms, tyrosol treatment did not affect body weights of mice. Immunohistochemical analysis revealed that the immunoreactivity of spinophilin, a dendritic synaptic protein, was significantly reduced in three hippocampal subregions of vehicle-treated AD mice compared with non-transgenic mice, which was reversed in tyrosol-treated AD mice. Tyrosol treatment also prevented the enhancement of 4-hydroxy-2-nonenal immunoreactivity in the hippocampal CA3 region of AD mice. By contrast,
It is observed that the increase in blood-brain barrier (BBB) permeability (BBBP) is
associated with ischemic stroke and thought to trigger neuronal damage and deteriorate
ischemic infarction, even though there is no experimental proof. Here, we investigated the
effect of BBBP increase on brain damage, using a combination of photochemically-induced
thrombotic brain damage (PIT-BD) model, a focal brain ischemic model, and transient
bilateral carotid artery occlusion model (CAO, a whole brain ischemic model), in mice. In
PIT-BD, BBBP increased in the region surrounding the ischemic damage from 4 h till 24 h
with a peak at 8 h. On day 4, the damaged did not expand to the region with BBBP increase
in mice with PIT-BD alone or with 30 min CAO at 1 h before PIT-BD, but expanded in mice
with 30 min CAO at 3.5 h after PIT-BD. This expansion was paralleled with the increase in
the number of apoptotic cells. These findings indicate that increase in BBBP does not
cause direct neuronal death, but it facilitates ischemic neuronal loss, which was
attributed, at least partially, to acceleration of apoptotic cell death.
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