Benoit Lechat

AAV-Tau Mediates Pyramidal Neurodegeneration by Cell-Cycle Re-Entry without Neurofibrillary Tangle Formation in Wild-Type Mice

In Alzheimers disease tauopathy is considered secondary to amyloid, and the duality obscures their relation and the definition of their respective contributions. Transgenic mouse models do not resolve this problem conclusively, i.e. the relative hierarchy of amyloid and tau pathology depends on the actual model and the genes expressed or inactivated. Here, we approached the problem in non-transgenic models by intracerebral injection of adeno-associated viral vectors to express protein tau or amyloid precursor protein in the hippocampus in vivo. AAV-APP mutant caused neuronal accumulation of amyloid peptides, and eventually amyloid plaques at 6 months post-injection, but with only marginal hippocampal cell-death. In contrast, AAV-Tau, either wild-type or mutant P301L, provoked dramatic degeneration of pyramidal neurons in CA1/2 and cortex within weeks. Tau-mediated neurodegeneration proceeded without formation of large fibrillar tau-aggregates or tangles, but with increased expression of cell-cycle markers. We present novel AAV-based models, which demonstrate that protein tau mediates pyramidal neurodegeneration in vivo. The data firmly support the unifying hypothesis that post-mitotic neurons are forced to re-enter the cell-cycle in primary and secondary tauopathies, including Alzheimers disease.

GSK-3α/β kinases and amyloid production in vivo.

Arising from C. J. Phiel, C. A. Wilson, V. M.-Y. Lee & P. S. Klein 423, 435–439 (2003)10.1038/nature01640A major unresolved issue in Alzheimer’s disease is identifying the mechanisms that regulate proteolytic processing of amyloid precursor protein (APP)—glycogen synthase kinase-3 (GSK-3) isozymes are thought to be important in this regulation. Phiel et al. proposed that GSK-3α, but not GSK-3β, controls production of amyloid. We analysed the proteolytic processing of mouse and human APP in mouse brain in vivo in five different genetic and viral models. Our data do not yield evidence for either GSK-3α-mediated or GSK-3β-mediated control of APP processing in brain in vivo.

Neurological characterization of mice deficient in GSK3α highlight pleiotropic physiological functions in cognition and pathological activity as Tau kinase

BackgroundGSK3β is involved in a wide range of physiological functions, and is presumed to act in the pathogenesis of neurological diseases, from bipolar disorder to Alzheimer’s disease (AD). In contrast, the GSK3α isozyme remained largely ignored with respect to both aspects.ResultsWe generated and characterized two mouse strains with neuron-specific or with total GSK3α deficiency. Behavioral and electrophysiological analysis demonstrated the physiological importance of neuronal GSK3α, with GSK3β not compensating for impaired cognition and reduced LTP. Interestingly, the passive inhibitory avoidance task proved to modulate the phosphorylation status of both GSK3 isozymes in wild-type mice, further implying both to function in cognition. Moreover, GSK3α contributed to the neuronal architecture of the hippocampal CA1 sub-region that is most vulnerable in AD. Consequently, practically all parameters and characteristics indicated that both GSK3 isoforms were regulated independently, but that they acted on the same physiological functions in learning and memory, in mobility and in behavior.ConclusionsGSK3α proved to be regulated independently from GSK3β, and to exert non-redundant physiological neurological functions in general behavior and in cognition. Moreover, GSK3α contributes to the pathological phosphorylation of protein Tau.

Early Structural and Functional Defects in Synapses and Myelinated Axons in Stratum Lacunosum Moleculare in Two Preclinical Models for Tauopathy

The stratum lacunosum moleculare (SLM) is the connection hub between entorhinal cortex and hippocampus, two brain regions that are most vulnerable in Alzheimer’s disease. We recently identified a specific synaptic deficit of Nectin-3 in transgenic models for tauopathy. Here we defined cognitive impairment and electrophysiological problems in the SLM of Tau.P301L mice, which corroborated the structural defects in synapses and dendritic spines. Reduced diffusion of DiI from the ERC to the hippocampus indicated defective myelinated axonal pathways. Ultrastructurally, myelinated axons in the temporoammonic pathway (TA) that connects ERC to CA1 were damaged in Tau.P301L mice at young age. Unexpectedly, the myelin defects were even more severe in bigenic biGT mice that co-express GSK3β with Tau.P301L in neurons. Combined, our data demonstrate that neuronal expression of protein Tau profoundly affected the functional and structural organization of the entorhinal-hippocampal complex, in particular synapses and myelinated axons in the SLM. White matter pathology deserves further attention in patients suffering from tauopathy and Alzheimer’s disease.

Tauopathy Differentially Affects Cell Adhesion Molecules in Mouse Brain: Early Down-Regulation of Nectin-3 in Stratum Lacunosum Moleculare

Cell adhesion molecules are important structural substrates, required for synaptic plasticity and synaptogenesis. CAMs differ widely in their expression throughout different brain regions and their specific structural and functional roles in the brain remain to be elucidated. Here, we investigated selected cell adhesion molecules for alterations in expression levels and neuronal localization in validated mouse models for Alzheimers disease that mimic the age-related progression of amyloid accumulation and tauopathy. Among the cell adhesion molecules analyzed, Nectin-3 expression was affected most and specifically in all mouse models with tauopathy. In particular was Nectin-3 depleted from the specific region of the hippocampus, known as the stratum lacunosum and moleculare, in mice that express wild-type or mutant human protein Tau, either chronically or sub-acutely. Tauopathy progresses from the entorhinal cortex to the hippocampus by unknown mechanisms that could involve transport by the myelinated axons of the temporoammonic and perforant pathways. The decreased expression of Nectin-3 in the stratum lacunosum moleculare is an early marker of impaired transport, and eventual synaptic problems, caused by beginning tauopathy.

GSK-3β and MMP-9 Cooperate in the Control of Dendritic Spine Morphology

Changes in the morphology of dendritic spines are prominent during learning and in different neurological and neuropsychiatric diseases, including those in which glycogen synthase kinase-3β (GSK-3β) has been implicated. Despite much evidence of the involvement of GSK-3β in functional synaptic plasticity, it is unclear how GSK-3β controls structural synaptic plasticity (i.e., the number and shape of dendritic spines). In the present study, we used two mouse models overexpressing and lacking GSK-3β in neurons to investigate how GSK-3β affects the structural plasticity of dendritic spines. Following visualization of dendritic spines with DiI dye, we found that increasing GSK-3β activity increased the number of thin spines, whereas lacking GSK-3β increased the number of stubby spines in the dentate gyrus. Under conditions of neuronal excitation, increasing GSK-3β activity caused higher activity of extracellularly acting matrix metalloproteinase-9 (MMP-9), and MMP inhibition normalized thin spines in GSK-3β overexpressing mice. Administration of the nonspecific GSK-3β inhibitor lithium in animals with active MMP-9 and animals lacking MMP-9 revealed that GSK-3β and MMP-9 act in concert to control dendritic spine morphology. Altogether, our data demonstrate that the dysregulation of GSK-3β activity has dramatic consequences on dendritic spine morphology, implicating MMP-9 as a mediator of GSK-3β-induced synaptic alterations.

Phosphorylation of protein Tau by GSK3β prolongs survival of bigenic Tau.P301L × GSK3β mice by delaying brainstem tauopathy

Tau.P301L transgenic mice suffer precocious mortality between ages 8 and 11 months, resulting from upper airway defects caused by tauopathy in autonomic brainstem circuits that control breathing (Dutschmann et al., 2010). In individual mice, the clinical phenotype evolves progressively and rapidly (3-6weeks) from clasping, over general motor impairment to severe reduction in body-weight into the terminal phase that announces imminent death (<3days). Surprisingly, co-expression of GSK3β with Tau.P301L significantly prolonged survival of bigenic biGT mice (Terwel et al., 2008), which we here assign to delayed development of brainstem tauopathy. Eventually, brainstem tauopathy became as prominent in old biGT mice in the specified brainstem nuclei as in the parental Tau.P301L mice, resulting in similar clinical deterioration and terminal phase preceding death, although at later age. Biochemically, in both genotypes the pathway to neurofibrillary tangles and neuropil threads was similar: phosphorylation of protein Tau and formation of soluble oligomers and insoluble aggregates, ending in the typical tangles and threads of tauopathy. The extra GSK3β activity led to expected increased phosphorylation of protein Tau, particularly at residues S262 and S396, which we must conclude to delay the aggregation of protein Tau in the brainstem of aging biGT mice. The unexpected, paradoxical alleviation of the brainstem problems in biGT mice allowed them to grow older and thereby develop more severe tauopathy in forebrain than Tau.P301L mice, which succumb at younger age.

Glycogen synthase kinase-3beta affects size of dentate gyrus and species-typical behavioral tasks in transgenic and knockout mice

Glycogen synthase kinase-3 (GSK-3), a multifunctional serine-threonine kinase, is an important regulator in numerous signaling pathways and processes including adult brain neurogenesis. GSK-3 (mal)functioning was implicated in many diseases, in particular neurological and behavioral disorders. We investigated the impact of altered levels of the GSK-3β isoform on hippocampal size, number of doublecortin-positive cells, and hippocampal-dependent behaviors. Both GSK-3β transgenic mice (GSK-3β[S9A] mice) and GSK-3β neuron-specific knockout (GSK-3β(n-/-)) mice, showed reduced size of the dentate gyrus (DG) and were impaired in three hippocampal-dependent, species-typical behavioral tasks: digging, marble burying and nest building. We further demonstrate that the number of differentiating, doublecortin-positive new neurons is reduced in GSK-3β[S9A] mice, but not in GSK-3β(n-/-) mice. We conclude that GSK-3β activity must be critically controlled to allow wild type-like volume of the dentate gyrus and for normal execution of hippocampal-dependent, species-typical behavior.

Glycogen synthase kinase-3β (GSK3β) expression in a mouse model of Alzheimer's disease: A light and electron microscopy study

Glycogen synthase kinase‐3β (GSK3β) activity has been previously linked to Alzheimers disease (AD) by its phosphorylation of tau and activation by amyloid. GSK3β intracellular distribution is important in regulating its activity by restricting access to compartment‐specific substrates. This study investigated regional and intracellular distribution of GSK3β in a mouse model of AD, a bigenic mouse with combined amyloid and tau pathology (BiAT), and controls (FVB). At two different ages, the entire rostrocaudal extent of each brain was examined. Young (6‐months‐old) FVB and BiAT mice did not differ in GSK3β expression and localization. In old (13‐month‐old) BiAT mice, neurons showed increased GSK3β expression only in AD‐relevant brain regions as compared with modest staining in region‐ and age‐matched controls. Two regions with the most robust changes between FVB and BiAT mice, the amygdala and piriform cortex, were quantified at the light microscopic level. In both regions, the density of darkly labeled neurons was significantly greater in the old BiAT mice vs. the old FVB mice. Electron microscopy of the piriform cortex showed neuronal GSK3β labeling in the rough endoplasmic reticulum, on ribosomes, and on microtubules in dendrites in both strains of mice. In old BiAT mice, GSK3β labeling was qualitatively more robust compared to age‐matched controls, and GSK3β also appeared in neurofibrillary tangles. In conclusion, GSK3β expression was increased in specific intracellular locations and was found in tangles in old BiAT mice, suggesting that GSK3β overexpression in specific brain areas may be intrinsic to AD pathology. Synapse, 2013.

Terminal hypothermic Tau.P301L mice have increased Tau phosphorylation independently of glycogen synthase kinase 3α/β

The microtubule‐associated protein Tau is responsible for a large group of neurodegenerative disorders, known as tauopathies, including Alzheimers disease. Tauopathy result from augmented and/or aberrant phosphorylation of Tau. Besides aging and various genetic and epigenetic defects that remain largely unknown, an important non‐genetic agent that contributes is hypothermia, eventually caused by anesthesia. Remarkably, tauopathy in brains of hibernating mammals is not pathogenic, and, because it is fully reversible, is even considered to be neuroprotective. Here, we assessed the terminal phase of Tau.P301L mice and bigenic crosses with mice lacking glycogen synthase kinase 3 (GSK3)α completely, or GSK3β specifically in neurons. We also analysed biGT bigenic mice that co‐express Tau.P301L with GSK3β.S9A and develop severe forebrain tauopathy with age. We found that the precocious mortality of Tau.P301L mice was typified by hypothermia that aggravated Tau phosphorylation, but, surprisingly, independently of GSK3α/β. The important contribution of hypothermia at the time of death of mice with tauopathy suggests that body temperature should be included as a parameter in the analysis of pre‐clinical models, and, by extension, in patients suffering from tauopathy.