Peter Filipcik

Truncated tau from sporadic Alzheimer's disease suffices to drive neurofibrillary degeneration in vivo

Truncated tau protein is the characteristic feature of human sporadic Alzheimers disease. We have identified truncated tau proteins conformationally different from normal healthy tau. Subpopulations of these structurally different tau species promoted abnormal microtubule assembly in vitro suggesting toxic gain of function. To validate pathological activity in vivo we expressed active form of human truncated tau protein as transgene, in the rat brain. Its neuronal expression led to the development of the neurofibrillary degeneration of Alzheimers type. Furthermore, biochemical analysis of neurofibrillary changes revealed that massive sarcosyl insoluble tau complexes consisted of human Alzheimers tau and endogenous rat tau in ratio 1:1 including characteristic Alzheimers disease (AD)‐specific proteins (A68). This work represents first insight into the possible causative role of truncated tau in AD neurofibrillary degeneration in vivo.

Mammalian Target of Rapamycin (mTor) Mediates Tau Protein Dyshomeostasis IMPLICATION FOR ALZHEIMER DISEASE

Background: Perturbations of the mammalian target of rapamycin (mTor) signaling pathway are implicated in Alzheimer disease (AD). Results: The activated mTor alters the activity of major tau kinases contributing to the formation of tau dyshomeostasis. Conclusion: We established a cellular system using genetic activation of mTor that developed authentic AD-like changes. Significance: The study provides potential tools for identifying tau-based therapeutics. Previous evidence from post-mortem Alzheimer disease (AD) brains and drug (especially rapamycin)-oriented in vitro and in vivo models implicated an aberrant accumulation of the mammalian target of rapamycin (mTor) in tangle-bearing neurons in AD brains and its role in the formation of abnormally hyperphosphorylated tau. Compelling evidence indicated that the sequential molecular events such as the synthesis and phosphorylation of tau can be regulated through p70 S6 kinase, the well characterized immediate downstream target of mTor. In the present study, we further identified that the active form of mTor per se accumulates in tangle-bearing neurons, particularly those at early stages in AD brains. By using mass spectrometry and Western blotting, we identified three phosphoepitopes of tau directly phosphorylated by mTor. We have developed a variety of stable cell lines with genetic modification of mTor activity using SH-SY5Y neuroblastoma cells as background. In these cellular systems, we not only confirmed the tau phosphorylation sites found in vitro but also found that mTor mediates the synthesis and aggregation of tau, resulting in compromised microtubule stability. Changes of mTor activity cause fluctuation of the level of a battery of tau kinases such as protein kinase A, v-Akt murine thymoma viral oncogene homolog-1, glycogen synthase kinase 3β, cyclin-dependent kinase 5, and tau protein phosphatase 2A. These results implicate mTor in promoting an imbalance of tau homeostasis, a condition required for neurons to maintain physiological function.

Expression of a truncated tau protein induces oxidative stress in a rodent model of tauopathy

Truncation of tau protein and oxidative stress have been implicated as important pathogenetic events in tauopathies including Alzheimers disease (AD). We have generated a transgenic rat model that expresses a human truncated tau protein analogous to a variant form derived from sporadic AD. We employed this model to investigate the relationship between tau protein truncation and oxidative stress. We have found that rat cortical neurons (derived from transgenic animals) that had been cultured in vitro for 16 days showed an increased accumulation of reactive oxygen species (up to 1.4‐fold increase; P < 0.01) when compared to neurons derived from nontransgenic control animals. Transgene‐expressing neurons treated with inducers of oxidative stress, such as glucose oxidase (GO) and buthionine sulfoximine (BSO), displayed dramatically reduced survival (31.4 ± 3.3 and 24.9 ± 3.6%, respectively; both P < 0.001) compared to neurons from control animals (79.9 ± 7.1%, survival following treatment with GO and to 98.2 ± 3.8%, survival following treatment with BSO). The number of mitochondria in processes of neurons from transgenic animals was decreased by about one‐third from that present in neurons from control animals. The results reveal that expression of a human truncated variant form of tau protein leads to the accumulation of reactive oxygen species and sensitizes rat cortical neurons to cell death induced by oxidative stress. This indicates that truncation of tau may precede oxidative stress in the pathogenesis of neurodegenerative diseases such as AD and other tauopathies. These findings may have implications for therapeutic strategies aiming at prevention of neurofibrillary degeneration and cognitive decline, and identify potential new targets for drug development.

Truncated tau expression levels determine life span of a rat model of tauopathy without causing neuronal loss or correlating with terminal neurofibrillary tangle load

We have previously demonstrated in a transgenic rat model of tauopathy that human misfolded truncated tau derived from Alzheimer’s disease suffices to drive neurofibrillary degeneration in vivo. We employed this model to investigate the impact of truncated tau expression levels on life span, neuronal loss and the final load of neurofibrillary tangles (NFTs) in transgenic rats. Two independent transgenic lines (SHR72, SHR318), that display different expression levels of truncated tau, were utilized in this study. We found that transgene expression levels in the brain of SHR72 rats were 44% higher than in SHR318 rats and that truncated tau protein levels determined the survival rate of transgenic rats. The line with higher expression levels of truncated tau (SHR72) showed decreased median survival (222.5 days) when compared with the line with lower expression (SHR318; 294.5 days). Interestingly, NFT loads (total NFT/total neurons) were very similar in terminal stages of disease in both transgenic lines (SHR72 – 10.9%; SHR318 – 11.6%), despite significantly different expression levels of truncated tau. Moreover, mean neuron numbers in the hippocampus (CA1–3) and brain stem (gigantocellular reticular nucleus) in the two transgenic rat strains in the terminal stages of disease were similar, and did not differ significantly from those observed in age‐matched non‐transgenic controls. These findings suggest that the expression levels of misfolded truncated tau determine the life span in a transgenic rat model of tauopathy without causing neuronal loss or correlating with terminal NFT load.

First transgenic rat model developing progressive cortical neurofibrillary tangles.

Neurofibrillary degeneration induced by misfolded protein tau is considered to be one of the key pathological hallmarks of Alzheimers disease (AD). In the present study, we have introduced a novel transgenic rat model expressing a human truncated tau that encompasses 3 microtubule binding domains (3R) and a proline-rich region (3R tau151-391). The transgenic rats developed progressive age-dependent neurofibrillary degeneration in the cortical brain areas. Neurofibrillary tangles (NFTs) satisfied several key histological criteria used to identify neurofibrillary degeneration in human Alzheimers disease including argyrophilia, Congo red birefringence, and Thioflavin S reactivity. Neurofibrillary tangles were also identified with antibodies used to detect pathologic tau in the human brain, including DC11, recognizing an abnormal tau conformation and antibodies that are specific for hyperphosphorylated forms of tau protein. Moreover, neurofibrillary degeneration was characterized by extensive formation of sarkosyl insoluble tau protein complexes consisting of rat endogenous and truncated tau species. Interestingly, the transgenic rats did not show neuronal loss either in the cortex or in the hippocampus. We suggest that novel transgenic rat model for human tauopathy represents a valuable tool in preclinical drug discovery targeting neurofibrillary degeneration of Alzheimers type.

Expression of a Truncated Human Tau Protein Induces Aqueous-Phase Free Radicals in a Rat Model of Tauopathy: Implications for Targeted Antioxidative Therapy

Oxidative stress has been implicated in the pathogenesis of many neurodegenerative diseases including Alzheimers disease (AD). We investigated the effect of a truncated form of the human tau protein in the neurons of transgenic rats. Using electron paramagnetic resonance we observed significantly increased accumulation of ascorbyl free radicals in brains of transgenic animals (up to 1.5-fold increase; P < 0.01). Examination of an in vitro model of cultured rat corticohippocampal neurons revealed that even relatively low level expression of human truncated tau protein (equal to 50% of endogenous tau) induced oxidative stress that resulted in increased depolarization of mitochondria (approximately 1.2-fold above control, P < 0.01) and increases in reactive oxygen species (approximately 1.3-fold above control, P < 0.001). We show that mitochondrial damage-associated oxidative stress is an early event in neurodegeneration. Furthermore, using two common antioxidants (vitamin C and E), we were able significantly eliminate tau-induced elevation of reactive oxygen species. Interestingly, vitamin C was found to be selective in the scavenging activity, suggesting that expression of truncated tau protein preferentially leads to increases in aqueous phase oxidants and free radicals such as hydrogen peroxide and hydroxyl and superoxide radicals. Our results suggest that antioxidant strategies designed to treat AD should focus on elimination of aqueous phase oxidants and free radicals.

Effect of selenite and selenate on rat liver nuclear 3,5,3′-triiodothyronine (T3) receptor

The present study was undertaken to investigate the effects of selenite (SeIV) or selenate (SeVI) on nuclear T3 receptors of rat liver. Selenite at 0.1 μM (p<0.01) inhibited the T3 specific binding to rat liver nuclear receptors. The specific binding of the T3 receptor was fully restored when even 1.0 μM selenite was separated from the T3 receptor by gel filtration. No inhibitory effect of selenite (up to 100 μM) on the T3 binding to nuclear receptor was found in the presence of 1.0 mM dithiothreitol. The rate of dissociation of the T3-nuclear receptor complex was effectively increased by 0.1 μM selenite. Selenate up to 1 mM as well as sulfite or sulfate up to 0.1 mM did not exert an inhibitory effect on T3 receptors. The results based on the in vitro experiments suggest that the selenium in the form of selenite may reversibly affect the T3 binding on the receptor molecule.

Intracellular degradation of misfolded tau protein induced by geldanamycin is associated with activation of proteasome.

Misfolded, N- and C-terminally truncated tau protein is the primary constituent of neurofibrillary tangles in brains of patients afflicted with Alzheimers disease (AD). Intracellular accumulation of misfolded and truncated tau leads to generation of cytotoxic intermediates; transgenic expression of truncated tau leads to neurological deficits, neurofibrillary degeneration, and premature death of animals. Since no cure for AD or other tauopathies is available yet, we tested the possibility for prevention of pathogenic events elicited by tau, via inhibition of its intracellular accumulation. Using a cell model conditionally expressing truncated and misfolding-prone tau protein, we showed that pathogenic forms of tau are degraded via the proteasome. We have also observed that chymotrypsin-like activity of the proteasome was significantly suppressed (a decrease of ∼29.12% in comparison to control cells; p < 0.001) as a consequence of truncated tau expression. Interestingly, the activity of the proteasome was enhanced by geldanamycin, a natural inhibitor of Hsp90. This activation resulted in accelerated degradation of misfolded tau. We suggest that non-toxic inhibitors of Hsp90, especially those which can activate the proteasome, are good candidates for the development of molecules that efficiently counteract the damaging effects of pathologically misfolded proteins.

A novel monoclonal antibody DC63 reveals that inhibitor 1 of protein phosphatase 2A is preferentially nuclearly localised in human brain

Abnormal phosphorylation of tau protein represents one of the major candidate pathological mechanisms leading to Alzheimers disease (AD) and related tauopathies. Altered phosphorylation status of neuronal tau protein may result from upregulation of tau‐specific kinases or from inhibition of tau‐specific phosphatases. Increased expression of the protein inhibitor 1 of protein phosphatase 2A (I1PP2A) could therefore indirectly regulate the phosphorylation status of tau. As an important step towards elucidation of the role of I1PP2A in the physiology and pathology of tau phosphorylation, we developed a novel monoclonal antibody, DC63, which recognizes I1PP2A. Specificity of the antibody was examined by mass spectrometry and Western blot. This analysis supports the conclusion that the antibody does not recognize any of the other proteins of the 9‐member leucine‐rich acidic nuclear phosphoprotein family to which I1PP2A belongs. Immunoblot detection revealed that the inhibitor I1PP2A is expressed throughout the brain, including the hippocampus, temporal cortex, parietal cortex, subcortical nuclei and brain stem. The cerebellum displayed significantly higher levels of expression of I1PP2A than was seen elsewhere in the brain. Imunohistochemical analysis of normal human brain showed that I1PP2A is expressed in both neurons and glial cells and that the protein is preferentially localized to the nucleus. We conclude that the novel monoclonal antibody DC63 could be successfully employed as a mass spectrometry‐validated molecular probe that may be used for in vitro and in vivo qualitative and quantitative studies of physiological and pathological pathways involving I1PP2A.

Tauopathy in transgenic (SHR72) rats impairs function of central noradrenergic system and promotes neuroinflammation.

BackgroundBrain norepinephrine (NE) plays an important role in the modulation of stress response and neuroinflammation. Recent studies indicate that in Alzheimer’s disease (AD), the tau neuropathology begins in the locus coeruleus (LC) which is the main source of brain NE. Therefore, we investigated the changes in brain NE system and also the immune status under basal and stress conditions in transgenic rats over-expressing the human truncated tau protein.MethodsBrainstem catecholaminergic cell groups (LC, A1, and A2) and forebrain subcortical (nucleus basalis of Meynert), hippocampal (cornu ammonis, dentate gyrus), and neocortical areas (frontal and temporal association cortices) were analyzed for NE and interleukin 6 (IL-6) mRNA levels in unstressed rats and also in rats exposed to single or repeated immobilization. Moreover, gene expression of NE-biosynthetic enzyme, tyrosine hydroxylase (TH), and several pro- and anti-inflammatory mediators were determined in the LC.ResultsIt was found that tauopathy reduced basal NE levels in forebrain areas, while the gene expression of IL-6 was increased in all selected areas at the same time. The differences between wild-type and transgenic rats in brain NE and IL-6 mRNA levels were observed in stressed animals as well. Tauopathy increased also the gene expression of TH in the LC. In addition, the LC exhibited exaggerated expression of pro- and anti-inflammatory mediators (IL-6, TNFα, inducible nitric oxide synthases 2 (iNOS2), and interleukin 10 (IL-10)) in transgenic rats suggesting that tauopathy affects also the immune background in LC. Positive correlation between NE and IL-6 mRNA levels in cornu ammonis in stressed transgenic animals indicated the reduction of anti-inflammatory effect of NE.ConclusionsOur data thus showed that tauopathy alters the functions of LC further leading to the reduction of NE levels and exaggeration of neuroinflammation in forebrain. These findings support the assumption that tau-related dysfunction of LC activates the vicious circle perpetuating neurodegeneration leading to the development of AD.