UNIPROT:P10636 - FACTA Search

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Query: UNIPROT:P10636 (tau protein)
5,110 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A conclusive diagnosis of Alzheimer's disease (AD) can be made only by correlating clinical findings and neuropathological studies of post-mortem tissues. Two leading neuropathological changes correlate with the diagnosis of AD: first, the neurofibrillary tangles (NFTs) which accumulate in neuronal perikarya and are made of paired helical filaments (PHFs) containing the microtubule-associated protein tau; second, extracellular amyloid deposits in the form of diffuse or neuritic senile plaques which contain the amyloid peptide. In AD, NFTs can be easily visualized using antibodies recognizing the microtubule associated protein tau and are composed of bundles of PHFs. In the autopsy-derived AD brain, tau is hyperphosphorylated and more than 30 phosphorylation sites have been identified in PHF-tau proteins. The formation of NFTs is thought to be associated with a collapse of the microtubule network, disturbances of axoplasmic transports, synapse loss, neuritic atrophy, and neuronal death. Senile plaques are extracellular lesions which have been shown by electron micro-scopic studies to contain amyloid fibrils. Fibrils were isolated and a small 4.2 kDa poly-peptide was purified from this material. The amyloid peptide found in amyloid deposits of AD is designated Abeta. Since the Abeta peptide is small and unlikely to be a primary translational product, it was predicted to arise from a larger precursor. In 1987, this amyloid peptide precursor (APP) was characterised from the analysis of a full-length cDNA encoding a primary translational product of 695 residues. This protein is synthetized by neurons as a 100-kDa glycosylated transmembrane protein with a single membrane spanning domain. The use of cellular models has clearly identified two catabolic pathways for APP. A non amyloidogenic pathway, in which APP is cleaved by beta-secretase within the sequence of the amyloid peptide. This cleavage precludes the formation of the full-length Abeta found in the amyloid core of senile plaques. A second catabolic pathway of APP leads to the production of Abeta from its precursor. In this amyloidogenic pathway, APP is cleaved by beta-secretase at the N-terminus of Abeta. The C-terminal fragment of APP thus formed is in turn cleaved by beta-secretase to release the full-length amyloid peptide. In primary cultures of neurons over-expressing APP, the production of intraneuronal Abeta induces neuronal apoptosis. This neurotoxicity, which is not observed in epithelial cells, seems to be related to the formation of intraneuronal aggregates of Abeta 1-42. In AD, the specific inhibition of beta- or beta-secretase activities would decrease the production of Abeta from its precursor, in such a way that its relative concentration could be low enough to avoid the formation of aggregates. Molecules which can interact with Abeta in order to inhibit its aggregation are also being developed. Immunization against Abeta has also been tested in both animal models and clinical studies. Although these clinical studies had to be interrupted due to the development of T-lymphocyte meningoencephalitis in some patients, very preliminary results indicate that antibodies against Abeta slow cognitive decline in AD, and generate areas of neocortex devoid of senile plaques.
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PMID:[Alzheimer disease: cellular and molecular aspects]. 1676 48

The misfolding of proteins into highly ordered fibrils with similar physical properties is a hallmark of many degenerative diseases. Here, we use the microtubule associated protein tau as a model system to investigate the role of amino acid side chains in the formation of such fibrils. We identify a region (positions 272-289) in the tau protein that, in the fibrillar state, either forms part of a core of parallel, in-register, beta-strands, or remains unfolded. Single point mutations are sufficient to control this conformational switch with disease mutants G272V and DeltaK280 (found in familial forms of dementia) inducing a folded state. Through systematic mutagenesis we derive a propensity scale for individual amino acids to form fibrils with parallel, in-register, beta-strands. This scale should not only apply to tau fibrils but generally to all fibrils with same strand arrangement.
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PMID:Side chain-dependent stacking modulates tau filament structure. 1702 23

Alois Alzheimer couldn't have chosen a name more appropriate than neurofibrillary tangles when one hundred years ago (Alzheimer, 1906) he presented this histopathological hallmark of the progressive dementing disorder, which got named after him as Alzheimer disease. Both, the structure and as well as the molecular composition of neurofibrillary tangles have baffled neuroscientists for many years. It was not till 1963 when with the help of the electron microscope the tangles were found to be made up of paired helical filaments (PHF). It took another 23 years before microtubule associated protein tau was immunohistochemically identified as the part of neurofibrillary tangles (Grundke-lqbal, 1986 a). The same year it was shown that tau protein in Alzheimer disease brain was abnormally hyperphosphorylated (Grundke-Iqbal, 1986 b). In 1988 Michal Novak, Cesar Milstein and Claude Wischik produced monoclonal antibody that was able to recognize then unknown protein in PHF. The antibody (MN423) allowed its isolation and let to full molecular characterization as protein tau. These studies provided molecular proof that tau protein was the major and an integral component of the PHF (Wischik et al, 1988 a, b, Goedert et al, 1988, Novak et al, 1989, 1991). Over the years the significance of tau pathology for the neurodegenerative diseases was discussed and often questioned. However, detailed studies of the maturation and distribution of NFTs, showing correlation with degree of cognitive decline and memory impairment in Alzheimer's disease (Braak and Braak, 1991), together with discovery of tau gene mutations causing fronto-temporal dementia in many families (Hutton et al, 1998) promoted tau as the major pathogenic force in neurodegenerative cascade. Further studies focused on tau dysfunctions revealed truncation and phosphorylation as two major posttranslational modifications responsible for toxic gain of function as an underlying cause of tauopathies including Alzheimer's disease (Alonso et al, 1996, Novak et al, 1989, 1991, 1993, Avila et al, 2006). Recently, in vivo experiments using transgenic expression of conformationally modified truncated tau showed that truncation is able to drive neurofibrillary pathology ofAlzheimer's type (Zilka et al, 2006). Finally, after one hundred years the exact nature of the neurofibrillary tangles and their role in neurodegeneration is beginning to be unraveled.
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PMID:From tangles to tau protein. 1726 84

Tau, an important microtubule associated protein, has been found to bind to DNA, and to be localized in the nuclei of both neurons and some non-neuronal cells. Here, using electrophoretic mobility shifting assay (EMSA) in the presence of DNA with different chain-lengths, we observed that tau protein favored binding to a 13 bp or a longer polynucleotide. The results from atomic force microscopy also showed that tau protein preferred a 13 bp polynucleotide to a 12 bp or shorter polynucleotide. In a competitive assay, a minor groove binder distamycin A was able to replace the bound tau from the DNA double helix, indicating that tau protein binds to the minor groove. Tau protein was able to protect the double-strand from digestion in the presence of DNase I that was bound to the minor groove. On the other hand, a major groove binder methyl green as a negative competitor exhibited little effect on the retardation of tau-DNA complex in EMSA. This further indicates the DNA minor groove as the binding site for tau protein. EMSA with truncated tau proteins showed that both the proline-rich domain (PRD) and the microtubule-binding domain (MTBD) contributed to the interaction with DNA; that is to say, both PRD and MTBD bound to the minor groove of DNA and bent the double-strand, as observed by electron microscopy. To investigate whether tau protein is able to prevent DNA from the impairment by hydroxyl free radical, the chemiluminescence emitted by the phen-Cu/H(2)O(2)/ascorbate was measured. The emission intensity of the luminescence was markedly decreased when tau protein was present, suggesting a significant protection of DNA from the damage in the presence of hydroxyl free radical.
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PMID:Binding to the minor groove of the double-strand, tau protein prevents DNA from damage by peroxidation. 1859 78

Neurofibrillary tangles are a pathological phenotype in Alzheimer's disease (AD) and are caused by the hyperphosphorylation of the microtubule associated protein tau. In mouse models of AD, decreasing tau protein expression limits the severity of symptoms and inhibits progression of AD. We now report that the 5' leader in the human tau mRNA contains an internal ribosomal entry site (IRES) and that IRES-dependent translation plays a role in the synthesis of tau protein. Consequently, targeting the tau IRES provides a novel target for regulating tau expression in AD and other tauopathies.
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PMID:Translation initiation of the human tau mRNA through an internal ribosomal entry site. 1922 16

The purpose of this work is to review the changes that take place in the microtubule associated protein tau during neuronal development, aging and neurodegeneration. Human tau protein is expressed from a single gene located on chromosome 17. The DNA is transcribed into nuclear RNA and this RNA, by alternative splicing, yields different mRNA species which are developmentally regulated. In aging, or in neurodegenerative disorders, post translational modifications of tau, such as phosphorylation, could take place, and new tau isoforms may appear. Thus, tau isoforms can be used as markers to follow neuronal development, aging or neurodegeneration.
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PMID:Tau as a molecular marker of development, aging and neurodegenerative disorders. 2002 73

Neurodegenerative diseases caused by abnormal accumulation of the microtubule associated protein tau (MAPT, tau) are collectively called tauopathies. The most devastating tau related disorder is Alzheimer's disease (AD). Molecular chaperones such as heat shock proteins (Hsp) have emerged as critical regulators of tau stability. Several studies from our group and others have shown that the chaperone network can be targeted for the development of therapeutic strategies for AD and other neurodegenerative diseases. Here we will discuss a recent paper and current work from our laboratory where we have manipulated the ATPase activity of the 70-kDa heat shock protein (Hsp70) to regulate tau turnover. A high-throughput screening assay revealed several compounds that activated or inhibited Hsp70's ATPase activity. Inhibitors dramatically and rapidly reduced tau levels, whereas activators stabilized tau, both in cells and brain tissue. Moreover, increased levels of Hsp70 improved ATPase inhibitor efficacy, suggesting that therapies aimed at inducing Hsp70 levels followed by inhibition of its ATPase activity may be a very effective strategy to treat AD. These findings demonstrate that Hsp70 ATPase activity can be targeted to modify the pathologies of AD and other tauopathies.
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PMID:Hsp70 ATPase Modulators as Therapeutics for Alzheimer's and other Neurodegenerative Diseases. 2052 17

Microtubule-associated protein tau has long been known for its ability to promote microtubule assembly. A less known feature of tau is its existence as a non-microtubule associated protein. Here we review the interactions of tau with other proteins, some of which interact with the microtubule binding repeat region of tau. The tau interactions with Fyn and with Pin1 have attracted the most attention and both interactions have been thought to have a role in Alzheimer's disease. The fact that tau has unknown cellular functions is further evidenced by its involvement in cell cycle activated neurodegeneration. One possible route for additional investigations stems from the presence of tau in non-neuronal cells where its characteristics have been largely unknown, although there has been a correlation between tau levels and the response of some cancer cells to microtubule-targeting chemotherapy drugs. Our studies of prostate cancer cells indicate that these cells can provide a system with phosphorylated adult tau for functional studies. In fact, structural similarities exist between Alzheimer's disease tau and prostate cancer cell tau, raising the possibility that new tau functions uncovered in prostate cancer cells will have relevance to Alzheimer's disease.
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PMID:Tubulin-independent tau in Alzheimer's disease and cancer: implications for disease pathogenesis and treatment. 2067 73

Tau is the major microtubule associated protein (MAP) of a mature neuron. The other two neuronal MAPs are MAP1 and MAP2. An established function of MAPs is their interaction with tubulin and promotion of its assembly into microtubules and stabilization of the microtubule network. The microtubule assembly promoting activity of tau, a phosphoprotein, is regulated by its degree of phosphorylation. Normal adult human brain tau contains 2-3 moles phosphate/mole of tau protein. Hyperphosphorylation of tau depresses this biological activity of tau. In Alzheimer disease (AD) brain tau is ~three to four-fold more hyperphosphorylated than the normal adult brain tau and in this hyperphosphorylated state it is polymerized into paired helical filaments ([PHF) admixed with straight filaments (SF) forming neurofibrillary tangles. Tau is transiently hyperphosphorylated during development and during anesthesia and hypothermia but not to the same state as in AD brain. The abnormally hyperphosphorylated tau in AD brain is distinguished from transiently hyperphosphorylated tau by its ability (1) to sequester normal tau, MAP1 and MAP2 and disrupt microtubules, and (2) to self-assemble into PHF/SF. The cytosolic abnormally hyperphosphorylated tau, because of oligomerization, unlike normal tau, is sedimentable and on self-assembly into PHF/SF, loses its ability to sequester normal MAPs. Some of the tau in AD brain is truncated which also promotes its self-assembly. Tau mutations found in frontotemporal dementia apparently promote its abnormal hyperphosphorylation. Thus, the AD abnormally hyperphosphorylated tau (1) is distinguishable from both normal and transiently hyperphosphorylated taus, and (2) is inhibitory when in a cytosolic/oligomeric state but not when it is self-assembled into PHF/SF. Inhibition of abnormal hyperphosphorylation of tau offers a promising therapeutic target for AD and related tauopathies.
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PMID:Tau in Alzheimer disease and related tauopathies. 2067 74

Alzheimer's disease (AD) is the main cause of dementia in our increasingly aging population. The debilitating cognitive and behavioral symptoms characteristic of AD make it an extremely distressing illness for patients and carers. Although drugs have been developed to treat AD symptoms and to slow disease progression, there is currently no cure. The incidence of AD is predicted to increase to over one hundred million by 2050, placing a heavy burden on communities and economies, and making the development of effective therapies an urgent priority. Two proteins are thought to have major contributory roles in AD: the microtubule associated protein tau, also known as MAPT; and the amyloid-beta peptide (A-beta), a cleavage product of amyloid precursor protein (APP). Oxidative stress is also implicated in AD pathology from an early stage. By targeting eIF4A, an RNA helicase involved in translation initiation, the synthesis of APP and tau, but not neuroprotective proteins, can be simultaneously and specifically reduced, representing a novel avenue for AD intervention. We also show that protection from oxidative stress is increased upon eIF4A inhibition. We demonstrate that the reduction of these proteins is not due to changes in mRNA levels or increased protein degradation, but is a consequence of translational repression conferred by inhibition of the helicase activity of eIF4A. Inhibition of eIF4A selectively and simultaneously modulates the synthesis of proteins involved in Alzheimer's disease: reducing A-beta and tau synthesis, while increasing proteins predicted to be neuroprotective.
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PMID:eIF4A inhibition allows translational regulation of mRNAs encoding proteins involved in Alzheimer's disease. 2092 85

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