τ Protein from Alzheimer's Disease Patients Is Glycated at Its Tubulin-Binding Domain

Abstract: Glycated residues of τ protein from paired helical filaments isolated from the brains of Alzheimer's disease patients were localized by doing a proteolytic cleavage of the protein, fractionation of the resulting peptides, and identification of those peptides using specific antibodies. The most suitable residues for glycation, lysines, present at the tubulin-binding motif of τ protein, seem to be preferentially modified compared with those lysines present at other regions. Among these modified lysines, those located in the sequence comprising residues 318–336 (in the largest human τ isoform) were found to be glycated, as determined by the reaction with an antibody that recognizes a glycated peptide containing this sequence. Because those lysines are present in a tubulin binding motif of τ protein, its modification could result in a decrease in the interaction of τ with tubulin.     

A τ Fragment Containing a Repetitive Sequence Induces Bundling of Actin Filaments

Abstract: Much indirect evidence suggests that the interconnections of actin microfilaments with the microtubule system are mediated by microtubule-associated proteins (MAPs). In this study we provide new data to support the interaction of a specific tubulin-binding domain on τ with actin in vitro. In actin polymerization assays, the synthetic peptide VRSKIGSTENLKHQPGGG, corresponding to the first repetitive sequence of τ protein, increased turbidity at 320 nm in a dose-dependent fashion. A salient feature of the τ peptide-induced assembly process is the formation of a large amount of actin filament bundles, as revealed by electron microscopic analysis. An increase in the τ peptide concentration resulted in a proportional increase in the bundling of actin filaments. It is interesting that a gradual decrease of pH within the range 7.6–4.7 resulted in a higher effect of τ peptide in promoting bundles of actin filaments. A similar pH-dependent effect was observed for τ protein-induced bundling. An analysis of the mechanisms that operate in the peptide induction of actin filament bundles suggests the involvement of electrostatic forces, because the neutralization of ɛ-aminolysyl residues by selective carbamoylation resulted in a complete loss of the peptide induction of actin bundles. The data suggest that a τ repetitive sequence (also found in MAP-2 and MAP-4) containing a common tubulin binding motif may constitute a functional domain on τ for the dynamics of the interconnections between actin filaments and microtu-bules.     

Amino Acid Residues 226–240 of τ Which Encompass the First Lys-Ser-Pro Site of τ, Are Partially Phosphorylated in Alzheimer Paired Helical Filament-τ

Abstract: A synthetic peptide corresponding to residues 226–240 (E9 peptide) of human τ, which contains an Lys-Ser-Pro motif, was used to raise a polyclonal antibody. The antibody, E9, was 10-fold less reactive with phospho-E9 peptide than with native E9 peptide. E9 antibody was used to study the extent of phosphorylation in a modified form of τ (PHF-τ) that is found in Alzheimer's disease brain and is incorporated into paired helical filaments (PHFs). E9 immunolabeled Alzheimer's disease neurofibrillary tangles and abnormal neurites in brain sections intensely, with increased immunoreactivity detected after pretreatment of sections with phosphatase. On immunoblots and ELISA, E9 reacted with PHF-τ and recombinant human τ but not with the high and middle molecular weight neurofilament proteins. Phosphatase treatment of PHF-τ improved the E9 immunoreactivity by 30–50%. Dephosphorylated high but not middle molecular weight neurofilament protein became reactive with E9. These results indicate that <50% of the PHF-T is phosphorylated in the subregion corresponding to residues 226–240 of τ and suggest that the phosphorylation of this region may not be essential for PHF formation.     

τ Protein Kinase II Is Involved in the Regulation of the Normal Phosphorylation State of τ Protein

Abstract: To study the phosphorylation state of τ in vivo, we have prepared antisera by immunizing rabbits with synthetic phosphopeptides containing phosphoamino acids at specific sites that are potential targets for τ protein kinase II. Immunoblot experiments using these antisera demonstrated that τ in microtubule-associated proteins is phosphorylated at Ser¹⁴⁴ and at Ser³¹⁵. Almost all τ variants separated on two-dimensional gel electrophoresis were phosphorylated at Ser¹⁴⁴ and nearly one-half of them at Ser³¹⁵. Phosphorylation at Ser¹⁴⁴ and at Thr¹⁴⁷ of τ isolated from heat-stable brain extracts was shown to be developmentally regulated, with the highest level of phosphorylation found at postnatal week 1. In vitro phosphorylation of τ by τ protein kinase I, a kinase responsible for abnormal phosphorylation of τ found in paired helical filaments of patients with Alzheimer's disease, was enhanced by prior phosphorylation of τ by τ protein kinase II. Thus, we suggest that τ protein kinase II is indirectly involved, at least in part, in the regulation of the phosphorylation state of τ in neuronal cells.     

Alzheimer's Disease Abnormally Phosphorylated τ Is Dephosphorylated by Protein Phosphatase-2B (Calcineurin)

Abstract: Abnormally hyperphosphorylated τ is the major protein subunit of paired helical filaments in Alzheimer brains. We have examined its site-specific dephosphorylation by different protein phosphatases. Dephosphorylation of τ was monitored by its interaction with several phosphorylation-dependent antibodies. Alzheimer τ was dephosphorylated by brain protein phosphatase-2B at the abnormally phosphorylated sites Ser⁴⁶, Ser¹⁹⁹, Ser²⁰², Ser²³⁵, Ser³⁹⁶, and Ser⁴⁰⁴, and its relative mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis shifted to that of normal τ. Protein phosphatases-1 and -2A could dephosphorylate only some of the above six phosphorylation sites. These results indicate that protein phosphatase-2B might be involved in hyperphosphorylation of τ in Alzheimer's disease.     

Oxidative Stress Induces Dephosphorylation of τ in Rat Brain Primary Neuronal Cultures

Abstract: Oxidative stress and free radical damage have been implicated in the neurodegenerative changes characteristic of several neurodegenerative diseases, including Alzheimer's disease. There is experimental evidence that the neurotoxicity of β-amyloid is mediated via free radicals, and as the deposition of β-amyloid apparently precedes the formation of paired helical filaments (PHF) in Alzheimer's disease, we have investigated whether subjecting primary neuronal cultures to oxidative stress induces changes in the phosphorylation state of the principal PHF protein τ that resemble those found in PHF-τ. Contrary to causing an increase in τ phosphorylation, treatment of neurones with hydrogen peroxide caused a dephosphorylation of τ and so we conclude that oxidative stress is not the direct cause of τ hyperphosphorylation and hence of PHF formation.     

The τ Protein in Human Cerebrospinal Fluid in Alzheimer's Disease Consists of Proteolytically Derived Fragments

Abstract: Previous studies have shown that the levels of the microtubule-associated protein τ in the CSF of patients with Alzheimer's disease (AD) are elevated compared with age-matched controls. In spite of these findings, the nature of τ in CSF has not been well documented. In the present study, τ was immunoprecipitated from CSF of patients with AD or acute stroke, as well as normal elderly controls, followed by immunoblot analysis. In all cases, CSF τ consisted primarily of a band migrating at 26–28 kDa. In AD and stroke patients, several smaller τ fragments were also detected. No intact τ was detected in any of the CSF samples examined. Further immunoprecipitation studies showed that the majority of the τ fragments contained the amino terminus of the molecule. Treatment of CSF τ with alkaline phosphatase did not alter the electrophoretic properties of the fragments. These studies clearly demonstrate that CSF τ is truncated rather than intact.     

Reactivating Kinase/p38 Phosphorylates τ Protein In Vitro

Abstract: Neurofibrillary tangles, one of the major pathological hallmarks of Alzheimer-diseased brains, consist primarily of aggregated paired helical filaments (PHFs) of hyperphosphorylated τ protein. τ from normal brain and especially from foetal brain is also phosphorylated on some of the sites phosphorylated in PHFs, mainly at serines or threonines followed by prolines. A number of protein kinases can phosphorylate τ in vitro; those that require or accept prolines include GSK3 and members of the mitogen-activated protein (MAP) kinase family, ERK1, ERK2, and SAP kinase-β/JNK. In this report, we show that another member of the MAP kinase family, the stress-activated kinase p38/RK, can phosphorylate τ in vitro. Western blots with phosphorylation-sensitive antibodies showed that p38, like ERK2 and SAP kinase-β/JNK, phosphorylated τ at sites found phosphorylated physiologically (Thr¹⁸¹, Ser²⁰², Thr²⁰⁵, and Ser³⁹⁶) and also at Ser⁴²², which is phosphorylated in neurofibrillary tangles but not in normal adult or foetal brain. These findings support the possibility that cellular stress might contribute to τ hyperphosphorylation during the formation of PHFs, and hence, to the development of τ pathology.     

τ Regulation of Microtubule-Microtubule Spacing and Bundling

Abstract: τ proteins are microtubule-associated proteins that promote microtubule polymerization in vitro and in vivo. They are a family of neuronal proteins with apparent molecular weights in the range 50,000–68,000 determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Recently, a new member of this family has been described and its cDNA has been cloned. It has an apparent molecular weight of 116,000 and has been called high-molecular-weight τ (HMW τ). All the τ proteins are encoded by a single gene, which undergoes complex alternative splicing. In the present study, we have cloned into the baculovirus a cDNA fully encoding HMW τ as well as a truncated cDNA encoding a protein beginning 13 amino acids in front of the τ microtubule-binding domain. HMW τ-recombinant-virus-infected Sf9 cells overexpressed HMW τ, which induced the polymerization of microtubules and the formation of long cellular processes similar to those induced by low-molecular-weight τ (LMW τ) overexpression. Process cross sections revealed a larger spacing (≈35 nm) between microtubules when induced by HMW τ than when induced by LMW τ (≈20 nm). The truncated construct also induces processes, where microtubules were packed far more closely together (≈10 nm). Although branching did not occur in processes induced by intact τs, 10% of the processes induced by the truncated τ protein branched.     

Transglutaminase Cross-Linking of the τ Protein

Abstract: Tissue transglutaminase (EC 2.3.2.13) is a calcium-activated enzyme that cross-links specific substrate proteins into insoluble, protease-resistant, high molecular weight complexes. Because the neurofibrillary tangles in Alzheimer disease have similar biochemical characteristics, and because the microtubule-associated protein τ is the predominant component of these structures, the substrate properties of τ with respect to transglutaminase were investigated. Bovine τ and recombinant human τ isoforms rapidly form high molecular weight, cross-linked polymers on incubation with transglutaminase. Polyamine incorporation assays indicate that bovine τ is an excellent substrate of transglutaminase, with a K _m of 10.4 ± 2.2 µ M and a V _max of 40.9 ± 4.5 nmol/mg of enzyme/min. Individual recombinant human τ isoforms are not equivalent with respect to transglutaminase, as the smallest isoform T3 (352 amino acids) is not as good a substrate as the larger isoforms T4 (383 amino acids) and T4L (441 amino acids). To determine which segments of the τ protein are susceptible to modification by transglutaminase, τ was labeled with [³H]putrescine by transglutaminase and proteolyzed with α-chymotrypsin, and the breakdown products were analyzed. These experiments demonstrate that the enzyme modifies τ at only one or a few discrete sites, primarily in the carboxyl half of the molecule. Thus, the reaction is specific for only a small number of the many glutamine residues in τ. Furthermore, a τ deletion construct (T264) containing a portion of the microtubule-binding domains, which is a substrate of transglutaminase, cannot be cross-linked by the enzyme. This provides evidence that the cross-linking reaction is specific, and requires that the substrates be appropriately associated for cross-linking to occur.     

Neurofilament Monoclonal Antibodies RT97 and 8D8 Recognize Different Modified Epitopes in Paired Helical Filament-τ in Alzheimer's Disease

Abstract: Neurofibrillary tangles in Alzheimer's disease have been previously found to be labeled by some neurofilament antibodies that also recognize τ proteins. We have studied the reactivity of two such monoclonal antibodies, RT97 and 8D8, and of an anti-ubiquitin serum with the abnormal paired helical filaments (PHF)-τ (A68) polypeptides known to be the main component of the PHFs constituting the neurofibrillary tangles. 8D8 recognized the three major PHF-τ polypeptides, but RT97 reacted only with the two larger PHF-τ species. PHF-τ polypeptides were labeled by 8D8 and RT97 much more strongly than normal human τ and this labeling was decreased after alkaline phosphatase treatment. Anti-ubiquitin and anti-phosphotyrosine antibodies did not label PHF-τ polypeptides. The immunoreactivity of proteolytic fragments of PHF-τ polypeptides was studied with RT97, 8D8, and a panel of τ antibodies. The epitope for 8D8 on PHF-τ was localized between amino acids 222 and 427 in the carboxyl half of τ. The RT97 epitope on PHF-τ was localized in the amino domain of τ, probably in the 29-amino-acid insertion (insert 1) found towards the amino terminus of some τ isoforms. These results show that the basis for the labeling of neurofibrillary tangles by antibodies 8D8 and RT97 to neurofilament is their ability to react with PHF-τ polypeptides by recognizing sites specifically modified on PHF-τ, including a site specific to some τ isoforms.     

Phosphorylation of τ In Situ: Inhibition of Calcium-Dependent Proteolysis

Abstract: In this study, the in situ phosphorylation and subsequent calcium-activated proteolysis of τ protein were examined in human neuroblastoma (LA-N-5) cells, which were differentiated into a neuronal phenotype. The phosphorylation of τ was increased by treating the cells with forskolin and rolipram, which elevate cyclic AMP levels, by treating with the phosphatase inhibitor okadaic acid, or by treating with a combination of both treatments. Phosphorylated τ migrated slightly slower on sodium dodecyl sulfate-polyacrylamide gels than τ from untreated cells. Immunostaining with the phosphate-sensitive monoclonal antibody Tau-1 was also decreased in cells treated with okadaic acid, indicating an increase in the phosphorylation of specific Ser-Pro motifs within the molecule. Calcium-dependent, in situ proteolysis of τ protein was induced by treating the cells with the calcium ionophore A23187. τ protein was proteolyzed to a significantly lesser extent in cells treated with forskolin and rolipram, okadaic acid, or both than in cells in which phosphorylation was not increased. Partially purified τ protein from cells treated with a combination of forskolin, rolipram, and okadaic acid was also more resistant to proteolysis by calpain in vitro compared with τ isolated from control cells. These data suggest a possible role for phosphorylation in the regulation of τ metabolism and in pathological conditions in which the balance between protein kinases and phosphatases is disrupted.     

Phosphatase Activity Toward Abnormally Phosphorylated τ: Decrease in Alzheimer Disease Brain

Abstract: Microtubule-associated protein τ is abnormally hyperphosphorylated and aggregated in affected neurons of Alzheimer disease brain. This hyperphosphorylated τ can be dephosphorylated at some of the abnormal phosphorylated sites by purified protein phosphatase-1, 2A, and 2B in vitro. In the present study, we have developed an assay to measure protein phosphatase activity toward τ-1 sites (Ser¹⁹⁹/Ser²⁰²) using the hyperphosphorylated τ isolated from Alzheimer disease brain as substrate. Using this assay, we have identified that in normal brain, protein phosphatase-2A and 2B and, to a lesser extent, 1 are involved in the dephosphorylation of τ. The K _m values of dephosphorylation of the hyperphosphorylated τ by protein phosphatase-2A and 2B are similar. The τ phosphatase activity is decreased by ∼30% in brain of Alzheimer disease patients compared with those of age-matched controls. These findings suggest that a defect of protein phosphatase could be the cause of the abnormal hyperphosphorylation of τ in Alzheimer disease.     

τ Self-Association: Stabilization with a Chemical Cross-Linker and Modulation by Phosphorylation and Oxidation State

Abstract: τ is a major component of paired helical filaments found in the neurofibrillary tangles of Alzheimer's diseased brain. However, the mechanism or mechanisms responsible for the association of τ to form these aggregates remains unknown. In this study, the role of intermolecular disulfide bonds in the formation of higher order oligomers of bovine τ and the human recombinant τ isoform T3 was examined using the chemical cross-linking agent disuccinimidylsuberate (DSS). In addition, the role of phosphorylation and oxidation state on the in vitro self-association of τ was studied using this experimental model. Stabilization of τ-τ interactions with DSS indicated that intermolecular disulfide bonds probably play a predominant role in dimer formation, but the formation of higher order oligomers of τ cannot be attributed to these bonds alone. τ-τ interactions were significantly decreased either by blocking Cys residues or by exposing the τ to a reducing (nitrogen and dithiothreitol), instead of an oxidizing, environment. τ self-association was also significantly decreased by prior phosphorylation with calcium/calmodulin-dependent protein kinase II. Phosphorylation by cyclic AMP-dependent protein kinase or dephosphorylation by alkaline phosphatase did not alter τ self-assembly. These data suggest a role for several factors that may modulate τ self-association in vivo.     

τ Phosphorylation in Human, Primate, and Rat Brain: Evidence that a Pool of τ Is Highly Phosphorylated In Vivo and Is Rapidly Dephosphorylated In Vitro

Abstract: The extent of τ phosphorylation is thought to regulate the binding of τ to microtubules: Highly phosphorylated τ does not bind to tubules, whereas dephosphorylated τ can bind to microtubules. It is interesting that the extent of τ phosphorylation in vivo has not been accurately determined. τ was rapidly isolated from human temporal neocortex and hippocampus, rhesus monkey temporal neocortex, and rat temporal neocortex and hippocampus under conditions that minimized dephosphorylation. In brain slices, we observed that τ isolated under such conditions largely existed in several phosphorylated states, including a pool that was highly phosphorylated; this was determined using epitope-specific monoclonal and polyclonal antibodies. This highly phosphorylated τ was dephosphorylated during a 120-min time course in vitro, presumably as a result of neuronal phosphatase activity. The slow-mobility forms of τ were shifted to faster-mobility forms following in vitro incubation with alkaline phosphatase. Laser densitometry was used to estimate the percent of τ in slow-mobility, highly phosphorylated forms. Approximately 25% of immunoreactive τ was present as slow-mobility (66- and 68-kDa) forms of τ. The percentage of immunoreactive τ in faster-mobility pools (42–54 kDa) increased in proportion to the decrease in content of 66–68-kDa τ as a function of neuronal phosphatases or alkaline phosphatase treatment. These data suggest that the turnover of phosphorylated sites on τ is rapid and depends on neuronal phosphatases. Furthermore, τ is highly phosphorylated in normal-appearing human, primate, and rodent brain. The presence of a highly phosphorylated pool of τ in adult brain may modify the present hypotheses on how paired helical filaments of Alzheimer's disease are formed.     

Stress-Activated Protein Kinase/c-Jun N-Terminal Kinase Phosphorylates τ Protein

Abstract: A proportion of the neuronal microtubule-associated protein (MAP) τ is highly phosphorylated in foetal and adult brain, whereas the majority of τ in the neurofibrillary tangles of Alzheimer's patients is hyperphosphorylated; many of the phosphorylation sites are serines or threonines followed by prolines. Several kinases phosphorylate τ at such sites in vitro. We have now shown that purified recombinant stress-activated protein kinase/c-Jun N-terminal kinase, a proline-directed kinase of the MAP kinase extended family, phosphorylates recombinant τ in vitro on threonine and serine residues. Western blots using antibodies to phosphorylation-dependent τ epitopes demonstrated that phosphorylation occurs in both of the main phosphorylated regions of τ protein. Unlike glycogen synthase kinase-3, the c-Jun N-terminal kinase readily phosphorylates Thr²⁰⁵ and Ser⁴²², which are more highly phosphorylated in Alzheimer τ than in foetal or adult τ. Glycogen synthase kinase-3 may preferentially phosphorylate the sites found physiologically, in foetal and to a smaller extent in adult τ, whereas stress-activated/c-Jun N-terminal kinase and/or other members of the extended MAP kinase family may be responsible for pathological proline-directed phosphorylations. Inflammatory processes in Alzheimer brain might therefore contribute directly to the pathological formation of the hyperphosphorylated τ found in neurofibrillary tangles.     

Cytosolic Proteolysis of τ by Cathepsin D in Hippocampus Following Suppression of Cathepsins B and L

Abstract: Incubation of cultured hippocampal slices with an inhibitor [ N -CBZ- l -phenylalanyl- l -alanine-diazomethyl ketone (ZPAD)] of cathepsins B and L resulted in the degradation of high molecular weight isoforms of τ protein and the production of a 29-kDa τ fragment (τ₂₉). A τ antibody that is sensitive to the phosphorylated state of its epitopes did not recognize τ proteins or the τ₂₉ fragment in slices that had been treated with a protein phosphatase inhibitor. This strongly suggests that the τ fragment was located in an extralysosomal compartment accessible to kinases and phosphatases. τ₂₉ exhibited a significant capacity for binding to microtubules and thus has the potential for interfering with normal τ-tubulin interactions. Three lines of evidence indicated that ZPAD-induced τ proteolysis was mediated by cathepsin D: (a) slices treated with the inhibitor had markedly elevated levels of cathepsin D in both lysosomal and extralysosomal compartments; (b) co-incubation of cathepsin D and τ at neutral pH resulted in a loss of intact τ proteins and production of a 29-kDa fragment; and (c) the lysosomotropic drug chloroquine blocked ZPAD-induced increases in mature cathepsin D, and this was accompanied by a suppression of ZPAD-induced τ proteolysis. Changes in lysosomal hydrolases and cytoskeletal perturbations occur during brain aging. The present results suggest that the enzymatic and structural effects are related and, more specifically, are linked by alterations in the concentration and localization of cathepsin D. The τ fragments with microtubule binding capacity generated by cathepsin D could also be a source for the small polypeptides found in association with age-related pathological features.     

Characterization of Two Distinct Monoclonal Antibodies to Paired Helical Filaments: Further Evidence for Fetal-Type Phosphorylation of the τ in Paired Helical Filaments

Abstract: Two monoclonal antibodies C5 and M4 raised against Sarkosyl-insoluble paired helical filaments (PHF) specifically labeled fetal τ, but hardly labeled normal adult τ. C5 immunoreactivity was eliminated by alkaline phosphatase treatment at 37°C, whereas M4 reactivity could be removed only by the treatment at 67°C. Epitope analysis showed that C5 and M4 recognition sites are in residues 386–406 and 198–250, respectively, according to the numbering of the longest human τ isoform. Thus, the phosphorylation sites are located in the amino- and carboxyl-terminal portions of the microtubule-binding region. These two well-characterized monoclonals should be valuable in the identification of a protein kinase(s) that converts normal τ into PHF-τ.