Tau-4R suppresses proliferation and promotes neuronal differentiation in the hippocampus of tau knockin/knockout mice

Amyloid activates GSK-3beta to aggravate neuronal tauopathy in bigenic mice

The hypothesis that amyloid pathology precedes and induces the tau pathology of Alzheimer's disease is experimentally supported here through the identification of GSK-3 isozymes as a major link in the signaling pathway from amyloid to tau pathology. This study compares two novel bigenic mouse models: APP-V717I x Tau-P301L mice with combined amyloid and tau pathology and GSK-3beta x Tau-P301L mice with tauopathy only. Extensive and remarkable parallels were observed between these strains including 1) aggravation of tauopathy with highly fibrillar tangles in the hippocampus and cortex; 2) prolonged survival correlated to alleviated brainstem tauopathy; 3) development of severe cognitive and behavioral defects in young adults before the onset of amyloid deposition or tauopathy; and 4) presence of pathological phospho-epitopes of tau, including the characteristic GSK-3beta motif at S396/S404. Both GSK-3 isozymes were activated in the brain of parental APP-V717I amyloid mice, even at a young age when cognitive and behavioral defects are evident but before amyloid deposition. The data indicate that amyloid induces tauopathy through activation of GSK-3 and suggest a role for the kinase in maintaining the functional integrity of adult neurons.

Neurodegeneration and neuroinflammation in cdk5/p25-inducible mice: a model for hippocampal sclerosis and neocortical degeneration

The cyclin-dependent kinase cdk5 is atypically active in postmitotic neurons and enigmatic among the kinases proposed as molecular actors in neurodegeneration. We generated transgenic mice to express p25, the N-terminally truncated p35 activator of cdk5, in forebrain under tetracycline control (TET-off). Neuronal expression of p25 (p25(ON)) caused high mortality postnatally and early in life. Mortality was completely prevented by administration of doxycycline in the drinking water of pregnant dams and litters until P42, allowing us to study the action of p25 in adult mouse forebrain. Neuronal p25 triggered neurodegeneration and also microgliosis, rapidly and intensely in hippocampus and cortex. Progressive neurodegeneration was severe with marked neuron loss, causing brain atrophy (40% loss at age 5 months) with nearly complete elimination of the hippocampus. Neurodegeneration did not involve phosphorylation of protein tau or generation of amyloid peptide. Degenerating neurons did not stain for terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling or activated caspase-3 but were marked by FluoroJadeB in early stages. Diseased neurons were always closely associated with activated microglia already very early in the disease process. Primary neurons derived from p25 embryos were more prone to apoptosis than wild-type neurons, and they activated microglial cells in co-culture. The inducible p25 mice present as a model for neurodegeneration in hippocampal sclerosis and neocortical degeneration, with important contributions of activated microglia.

Tauopathy models and human neuropathology: similarities and differences

Much of our current understanding of the pathogenic mechanisms in human neurodegenerative disorders has been derived from animal studies. As such, transgenic mouse models have significantly contributed to the development of novel pathogenic concepts underlying human tauopathies, a group of diseases comprising various forms of neurodegenerative disorders including Alzheimer's disease, corticobasal degeneration, argyrophilic grain disease, progressive supranuclear palsy, and Pick's disease as well as hereditary fronto-temporal dementia with parkinsonism linked to chromosome 17. Here, we will review in vivo models of human tauopathies with particular preference to transgenic mouse models. Strengths and limitations of these models in recapitulating the complex pathogenesis of tauopathies will be discussed.

Changes in neurogenesis in dementia and Alzheimer mouse models: are they functionally relevant?

Alzheimer's disease and related dementias are devastating disorders that lead to the progressive decline of cognitive functions. Characteristic features are severe brain atrophy, paralleled by accumulation of beta amyloid and neurofibrillary tangles. With the discovery of neurogenesis in the adult brain, the hopes have risen that these neurodegenerative conditions could be overcome, or at least ameliorated, by the generation of new neurons. The location of the adult neurogenic zones in the hippocampus and the lateral ventricle wall, close to corpus callosum and neocortex, indicates strategic positions for potential repair processes. However, we also need to consider that the generation of new neurons is possibly involved in cognitive functions and could, therefore, be influenced by disease pathology. Moreover, aberrant neurogenic mechanisms could even be a part of the pathological events of neurodegenerative diseases. It is the scope of this review to summarize and analyze the recent data from neurogenesis research with respect to Alzheimer's disease and its animal models.