Proline-directed and non-proline-directed phosphorylation of PHF-tau

Inhibition of the Ser-Thr phosphatases PP1 and PP2A by naturally occurring toxins

The okadaic acid class of naturally occurring toxins is a structurally diverse group of molecules that inhibit the protein phosphatases PP1 and PP2A. Studies providing information about the mode of binding between the toxins and the phosphatases contribute to an overall understanding of the signal transduction pathways in which the phosphatases are involved.

Oxidized and phosphorylated synthetic peptides corresponding to the second and third tubulin-binding repeats of the tau protein reveal structural features of paired helical filament assembly

The microtubule-associated protein tau of normal brains is attached to tubulin through its 18-amino-acid repeat units. In the paired helical filaments (PHF) of Alzheimer's disease, however, tau is oligomerized in an abnormally hyperphosphorylated from (PHF-tau). tau contains two cysteine residues in repeat units 2 and 3, but only the R3-R3 homodimer is present in PHF-tau. A serine residue two amino acids downstream of the R3 cysteine is a major phosphate acceptor site for protein kinase C. In the work repeated here, we used synthetic peptides corresponding to R2, R3 and phosphorylated R3 to determine the binding of the tau repeat peptides to a peptide fragment corresponding to the C-terminal domain of beta-tubulin and to study the kinetics of homo- and heterodimer formation. Additionally, we studied two major biochemical properties of the peptides that distinguish between normal tau and PHF-tau: conformation and metabolic stability. All R2 and R3 peptides bound specifically to the tubulin peptide regardless of the state of phosphorylation or dimerization. The reverse-turn conformation of the tau repeat peptides in the presence of the tubulin peptide remained unaffected. Phosphorylation slightly loosened the turn structure of the monomeric and dimeric peptides, and did not univocally affect the serum stability of the peptides or the ability of the peptides to form dimers. The isolated R2 and R3 units formed homodimers approximately in the same rate. When the two peptides were mixed, however, the R2-R3 heterodimer was formed preferentially over the homodimers. The dimers were generally more stable in human serum than the monomers. Our results with the synthetic peptide fragments of tau indicate that neither oxidation nor phosphorylation of the repeat units is able to generate extended structure such as that found in PHF-tau. Additionally, phosphorylation of Ser324 does not appear to modulate the kinetics of oligomerization of tau, and in general biochemistry terms, does not affect disulfide bridge formation nearby. In agreement with studies at the full-protein level, the formation of homodimers of the peptides, a model of the self-association of tau, is not preferred. If the dimers are formed, however, their clearance is considerably slower than that of the monomers, explaining the remarkable protease resistance of PHF-tau in the affected brains.

Lithium inhibits Alzheimer's disease-like tau protein phosphorylation in neurons

In Alzheimer's disease, tau protein becomes hyperphosporylated, which can contribute to neuronal degeneration. However, the implicated protein kinases are still unknown. Now we report that lithium (an inhibitor of glycogen synthase kinase-3) causes tau dephosphorylation at the sites recognized by antibodies Tau-1 and PHF-1 both in cultured neurons and in vivo in rat brain. This is consistent with a major role for glycogen synthase kinase-3 in modifying proline-directed sites on tau protein within living neurons under physiological conditions. Lithium also blocks the Alzheimer's disease-like proline-directed hyperphosphorylation of tau protein which is observed in neurons treated with a phosphatase inhibitor. These data raise the possibility of using lithium to prevent tau hyperphosphorylation in Alzheimer's disease.

Unique Alzheimer's disease paired helical filament specific epitopes involve double phosphorylation at specific sites

Alzheimer's disease (AD) paired helical filaments (PHFs), building blocks of neurofibrillary tangles (NFTs) are composed of hyperphosphorylated forms of the microtubule-associated protein tau (i.e., PHF-tau). Currently, much effort is devoted to the development of diagnostic antibodies specific for PHF-tau since elevated tau levels are found in the cerebral spinal fluid of AD patients. To this end, we have mapped the epitopes of a large panel of monoclonal antibodies (mAbs) that recognized only phosphorylation dependent epitopes on PHF-tau. These mAbs include the PHF-tau specific mAb AT10 and 12 newly developed anti-PHF mAbs that recognize PHF-tau but not autopsy-derived normal adult tau on Western-blot and enzyme-linked immunosorbent assay (ELISA). Epitope analysis, together with data on known binding sites of previously published mAbs, revealed that Ser214, Thr231, and Ser396 are immunodominant phosphorylated amino acids in PHF-tau. Six of the 12 new mAbs recognized one of these three phosphorylated sites. With the exception of AT10 and PHF-27, all the mAbs also labeled fetal tau and biopsy-derived tau. Since mAbs AT10 and PHF-27 had little or no affinity for fetal tau and biopsy tau, they can be considered as the first "true" PHF-specific antibodies capable of distinguishing tau isoforms from normal versus AD subjects, suggesting a possible utility of these mAbs as diagnostic markers. Remarkably, the true PHF-specific antibodies recognized peptide sequences phosphorylated on more than one amino acid residue. The peptide recognition of mAb AT10 required the simultaneous phosphorylation of Thr212 and Ser214, and the peptide recognition of mAb PHF-27 was markedly increased when both the primary site Thr231 and the subsite Ser235 were phosphorylated. Since AT10 and PHF-27 are the only mAbs currently available that bind specifically to PHF-tau, these data suggest that double phosphorylation at Thr212/Ser214 and Thr231/Ser235 may be unique to PHF-tau. These data may facilitate the development of mAbs that can be used as specific diagnostic reagents for the detection of altered tau in cerebrospinal fluid of AD patients.

The heat shock-induced hyperphosphorylation of tau is estrogen-independent and prevented by androgens: implications for Alzheimer disease

We have shown that heat shock induces rapid dephosphorylation of tau in both female and male rats followed by hyperphosphorylation only in female rats. To investigate the role of gonadal hormones, rats were ovariectomized (OVX), orchiectomized (ORX), or sham-gonadectomized and received replacement therapy with estradiol benzoate (EB), testosterone propionate (TP), or sesame oil (SO) vehicle for 2-3 weeks, respectively. At 0, 3, 6, and 12 hr after heat shock, immunoblot analysis of SDS cerebral extracts was performed using phosphate-dependent and -independent anti-tau antibodies. Seven groups of rats were analyzed: (i) sham-OVX + SO; (ii) OVX + SO; (iii) OVX + EB; (iv) sham-ORX + SO; (v) ORX + SO; (vi) ORX + TP; and (vii) ORX. In all seven groups, there was dephosphorylation of tau at 0 hr after heat shock. In all three groups of female rats, there was hyperphosphorylation of tau at 3 hr after heat shock, and its degree and temporal pattern were identical between the OVX + SO and OVX + EB groups. In male rats, there was hyperphosphorylation of tau at 3 hr after heat shock in both ORX + SO and ORX groups, and its degree was reduced in the ORX + TP group. Thus, dephosphorylation of tau is gonadal hormone-independent, but while its hyperphosphorylation is estrogen-independent it is prevented by androgens. Because tau is abnormally hyperphosphorylated in Alzheimer disease, which is more frequent in women than men, these findings suggest that androgens may exert a neuroprotective effect.

Phosphorylation of microtubule-associated protein tau by stress-activated protein kinases

The paired helical filament, which comprises the major fibrous element of the neurofibrillary lesions of Alzheimer's disease, is composed of hyperphosphorylated microtubule-associated protein tau. Many of the hyperphosphorylated sites in tau are serine/threonine-prolines. Here we show that the stress-activated protein (SAP) kinases SAPK1gamma (also called JNK1), SAPK2a (also called p38, RK, CSBPs, Mpk2 and Mxi2), SAPK2b (also called p38beta), SAPK3 (also called ERK6 and p38gamma) and SAPK4 phosphorylate tau at many serine/threonine-prolines, as assessed by the generation of the epitopes of phosphorylation-dependent anti-tau antibodies. Based on initial rates of phosphorylation, tau was found to be a good substrate for SAPK4 and SAPK3, a reasonable substrate for SAPK2b and a relatively poor substrate for SAPK2a and SAPK1gamma. Phosphorylation of tau by SAPK3 and SAPK4 resulted in a marked reduction in its ability to promote microtubule assembly. These findings double the number of candidate protein kinases for the hyperphosphorylation of tau in Alzheimer's disease and other neurodegenerative disorders.

Phosphorylation of tau by glycogen synthase kinase 3beta affects the ability of tau to promote microtubule self-assembly

To study the effects of phosphorylation by glycogen synthase kinase-3beta (GSK-3beta) on the ability of the microtubule-associated protein tau to promote microtubule self-assembly, tau isoform 1 (foetal tau) and three mutant forms of this tau isoform were investigated. The three mutant forms of tau had the following serine residues, known to be phosphorylated by GSK-3, replaced with alanine residues so as to preclude their phosphorylation: (1) Ser-199 and Ser-202 (Ser-199/202-->Ala), (2) Ser-235 (Ser-235-->Ala) and (3) Ser-396 and Ser-404 (Ser-396/404-->Ala). Wild-type tau and the mutant forms of tau were phosphorylated with GSK-3beta, and their ability to promote microtubule self-assembly was compared with the corresponding non-phosphorylated tau species. In the non-phosphorylated form, wild-type tau and all of the mutants affected the mean microtubule length and number concentrations of assembled microtubules in a manner consistant with enhanced microtubule nucleation. Phosphorylation of these tau species with GSK-3beta consistently reduced the ability of a given tau species to promote microtubule self-assembly, although the affinity of the tau for the microtubules was not greatly affected by phosphorylation since the tau species remained largely associated with the microtubules. This suggests that the regulation of microtubule assembly can be controlled by phosphorylation of tau at sites accessible to GSK-3beta by a mechanism that does not necessarily involve the dissociation of tau from the microtubules.

Familial multiple system tauopathy with presenile dementia: a disease with abundant neuronal and glial tau filaments

Neurofibrillary lesions made of hyperphosphorylated microtubule-associated protein tau constitute not only one of the defining neuropathological features of Alzheimer disease but also are present in a number of other neurodegenerative diseases with dementia. Here we describe a novel autosomal dominant disease named familial "multiple system tauopathy with presenile dementia," which is characterized by abundant fibrillary deposits of tau protein in both neurons and glial cells. There are no detectable deposits of beta-amyloid. The tau deposits are in the form of twisted filaments that differ in diameter and periodicity from the paired helical filaments of Alzheimer disease. They are stained by both phosphorylation-independent and -dependent anti-tau antibodies. Moreover, tau immunoreactivity coexists with heparan sulfate in affected nerve and glial cells. Tau protein extracted from filaments of familial multiple system tauopathy with presenile dementia shows a minor 72-kDa band and two major bands of 64 and 68 kDa that contain mainly hyperphosphorylated four-repeat tau isoforms of 383 and 412 amino acids.

Conversion of serine to aspartate imitates phosphorylation-induced changes in the structure and function of microtubule-associated protein tau

Microtubule-associated protein tau is a neuronal phosphoprotein that promotes microtubule assembly in vitro and has been shown to play a role in the development of axonal morphology. Tau can be phosphorylated in vitro by several kinases, some of which cause a change in the conformation and activities of tau. Here we report the consequences of converting two of the protein kinase A phosphorylation sites (positions 156 and 327), first to alanine to eliminate phosphorylation, and second to aspartate, to mimic phosphorylation. We show that a serine to aspartate mutation at position 327 results in a conformational change similar to that caused by phosphorylation of this residue. This mutation does not affect the activities of tau in microtubule assembly as compared with wild-type tau. However, an additional mutation at position 156 to aspartate drastically decreases the microtubule nucleation activity of tau but does not affect the activity of tau to promote microtubule growth. All constructs are similarly bound to microtubules and promote process formation when expressed in cytochalasin-treated PC12 cells. We conclude that serine to aspartate mutations provide a useful system for analyzing the effect of individual phosphorylation sites on the conformation and function of tau in vitro and in cells. The results provide evidence that microtubule growth and nucleation can be differentially affected by phosphorylation of individual residues in a region amino-terminally flanking the microtubule binding domain of tau.

Transglutaminase activity is increased in Alzheimer's disease brain

Transglutaminase is a calcium-activated enzyme that crosslinks substrate proteins into insoluble, often filamentous aggregates resistant to proteases. Because the neurofibrillary tangles in Alzheimer's disease have similar characteristics, and because tau protein, the major component of these tangles is an excellent substrate of transglutaminase in vitro, transglutaminase activity and levels were measured in control and Alzheimer's disease brain. Frozen prefrontal cortex and cerebellum samples from Alzheimer's disease and control cases matched for age and postmortem interval were used in the analyses. Total transglutaminase activity was significantly higher in the Alzheimer's disease prefrontal cortex compared to control. In addition the levels of tissue transglutaminase, as determined by quantitative immunoblotting, were elevated approximately 3-fold in Alzheimer's disease prefrontal cortex compared to control. To our knowledge, this is the first demonstration that transglutaminase is increased in Alzheimer's disease brain. There were no significant differences in transglutaminase activity or levels in the cerebellum between control and Alzheimer's disease cases. Because the elevation of transglutaminase in the Alzheimer's disease samples occurred in the prefrontal cortex, where neurofibrillary pathology is usually abundant, and not in the cerebellum, which is usually spared in Alzheimer's disease, it can be suggested that transglutaminase could be a contributing factor in neurofibrillary tangle formation.

Protein kinase C and calcium/calmodulin-dependent protein kinase II phosphorylate three-repeat and four-repeat tau isoforms at different rates

All six isoforms of the microtubule-associated protein tau are present in hyperphosphorylated states in the brains of patients with Alzheimer's disease (AD). It is presently unclear how such hyperphosphorylation of tau is controlled. In a previous study (Singh et al. Arch Biochem Biophys 328: 43-50, 1996) we have shown that three-repeat taus containing two N-terminal inserts were phosphorylated to higher levels and at different sites compared to those either lacking or containing only one such insert. We have extended these observations in this study by comparing the phosphorylation of tau isoforms containing three-repeats (tau 3, tau 3 L) and four-repeats (tau 4, tau 4 L). In the absence of N-terminal inserts in tau structure (tau 3, tau 4) both CaM kinase II and C-kinase phosphorylated four-repeat tau (tau 4) to a higher extent than three-repeat tau (tau 3). When two N-terminal inserts are present in tau structure (tau 3 L, tau 4 L), then three-repeat tau (tau 3 L) is phosphorylated to a higher extent than four-repeat tau (tau 4 L) by these kinases. CK-1 and GSK-3 phosphorylated each of the above pairs of three-repeat and four-repeat taus to the same extents. However, after an initial prephosphorylation of the taus by CaM kinase II, GSK-3 differentially phosphorylated three-repeat and four-repeat taus. Under these conditions thr 231, ser 235, ser 396, and ser 404 were phosphorylated to greater extents in four-repeat tau (tau 4) compared to three-repeat tau (tau 3) in the absence of N-terminal inserts. In the presence of such inserts these sites were phosphorylated to greater extents in three-repeat (tau 3 L) compared to four-repeat (tau 4 L) tau. Our results indicate that the extents to which tau isoforms are phosphorylated in normal and AD brain depends on (a) the number of repeats (3 or 4), (b) the number of N-terminal inserts (0, 1, or 2), and (c) the initial phosphorylation state of tau.

Phosphorylation-dependent monoclonal Tau antibodies do not reliably report phosphorylation by extracellular signal-regulated kinase 2 at specific sites

Analysis of phosphorylation of tau, the microtubule-associated proteins hyperphosphorylated in Alzheimer's disease, is often performed using phosphorylation-sensitive monoclonal antibodies thought to report the presence or absence of one or two specific phosphorylations (cognate sites). Using several such antibodies we found a much more complicated relationship between phosphorylation at specific sites, as monitored by two-dimensional phosphopeptide mapping, and antibody recognition of these sites. Multiple phosphorylation of tau in several stages by the brain extracellular signal-regulated kinase 2 isoform PK40 suggested that phosphorylation at cognate sites is sometimes necessary (but not sufficient) to induce a change of antibody reactivity and in some cases is not even necessary in the background of multiple phosphorylation at other sites. No single phosphorylation site was found to be responsible for any level of gel mobility shift associated with phosphorylation. Tau acquired its maximal gel mobility retardation and final immunochemical profile at substoichiometric phosphorylation of most sites. This suggests that many alternate phosphorylation patterns can produce the same conformational and immunochemical presentation on sodium dodecyl sulfate-gel electrophoresis. Although PK40(erk2) prefers some phosphorylation sites, most notably Ser235, followed by Ser199 or Ser202 and Thr205, the phosphorylation of multiple Ser/Thr-Pro sites is not highly sequential. Ser396 is one of the least preferred sites and seems to require prior phosphorylation at Ser404.

Modulation of phosphorylation of neuronal cytoskeletal proteins by neuronal depolarization

1. The neuronal cytoskeletal protein tau and the carboxy tails of cytoskeletal proteins neurofilament-M (NF-M) and neurofilament-H (NF-H) are phosphorylated on serine residues by the cyclin-dependent kinase cdk-5. 2. In aggregating neuronal-glial cultures we show that veratridine-mediated cation influx causes dephosphorylation of tau, NF-M and NF-H. Dephosphorylation was blocked specifically by cyclosporine A but not by okadiac acid at concentrations up to 200 nM. 3. These results suggest that veratridine-triggered cation influx causes activation of PP-2B (calcineurin) leading to dephosphorylation of these cytoskeletal proteins.

Potentiation of GSK-3-catalyzed Alzheimer-like phosphorylation of human tau by cdk5

Tau protein from Alzheimer disease (AD) brain is hyperphosphorylated by both proline-dependent protein kinases (PDPKs) and non-PDPKs. It is presently unclear how PDPKs and non-PDPKs interact in tau hyperphosphorylation. Previously we have shown that non-PDPKs can positively modulate the activity of a PDPK (GSK-3) in tau phosphorylation (Singh et al. (1995) FEBS Lett. 358, 267-272). In this study we have investigated whether (A) non-PDPKs can also modulate the activity of the PDPK, cdk5, (B) a PDPK can modulate the activities of another PDPK, as well as non-PDPKs. We found that, like GSK-3, the activity of cdk5 is stimulated if tau were first prephosphorylated by any of several non-PDPKs (A-kinase, C-kinase, CK-1, CaM-kinase II). Prephosphorylation of tau by cdk5 stimulated both the rate and extent of a subsequent phosphorylation catalyzed by GSK-3. Under these conditions thr 231 phosphorylation was especially enhanced (9-fold). No significant stimulation of phosphorylation was observed when the order of these kinases was reversed (i.e. GSK-3 followed by cdk5). By contrast, prephosphorylation of tau by cdk5 served to inhibit subsequent phosphorylation catalyzed by C-kinase and CK-1, but not by A-kinase or CaM-kinase II. Our results suggest that in tau hyperphosphorylation in AD brain, cdk5-catalyzed phosphorylation may serve to upregulate the activity of GSK-3 and down-regulate the activities of C-kinase and CK-1.

Total Synthesis of the Serine/Threonine-Specific Protein Phosphatase Inhibitor Tautomycin(1)

A convergent, asymmetric synthesis of the protein phosphatase inhibitor, tautomycin, is described. The natural product was constructed by joining two major fragments of comparable complexity at the C21-C22 bond. Absolute stereochemistry of the C1-C21 ketone originates from (S)-citronellene and (2R,3S)-geraniol epoxide. The anti stereochemical relationships at C6-C7 and C18-C19 were introduced with Duthaler's chiral titanium propionic enolate. Syn stereochemical relationships at C13-C14 and C23-C24 were established using an Evan's oxazolidinone chiral auxiliary. The spiroketal was efficiently constructed via a one-pot double-alkylation-spirocyclization sequence with acetone N,N-dimethylhydrazone serving as the central linchpin. Final coupling of the two halves using a chelation-controlled Mukaiyama aldol addition followed by deprotection yielded synthetic tautomycin that is identical to the natural product.

Biochemical and cellular effects of roscovitine, a potent and selective inhibitor of the cyclin-dependent kinases cdc2, cdk2 and cdk5

Cyclin-dependent kinases (cdk) play an essential role in the intracellular control of the cell division cycle (cdc). These kinases and their regulators are frequently deregulated in human tumours. Enzymatic screening has recently led to the discovery of specific inhibitors of cyclin-dependent kinases, such as butyrolactone I, flavopiridol and the purine olomoucine. Among a series of C2, N6, N9-substituted adenines tested on purified cdc2/cyclin B, 2-(1-ethyl-2-hydroxyethylamino)-6-benzylamino-9-isopropylpurine (roscovitine) displays high efficiency and high selectivity towards some cyclin-dependent kinases. The kinase specificity of roscovitine was investigated with 25 highly purified kinases (including protein kinase A, G and C isoforms, myosin light-chain kinase, casein kinase 2, insulin receptor tyrosine kinase, c-src, v-abl). Most kinases are not significantly inhibited by roscovitine. cdc2/cyclin B, cdk2/cyclin A, cdk2/cyclin E and cdk5/p35 only are substantially inhibited (IC50 values of 0.65, 0.7, 0.7 and 0.2 microM, respectively). cdk4/cyclin D1 and cdk6/cyclin D2 are very poorly inhibited by roscovitine (IC50 > 100 microM). Extracellular regulated kinases erk1 and erk2 are inhibited with an IC50 of 34 microM and 14 microM, respectively. Roscovitine reversibly arrests starfish oocytes and sea urchin embryos in late prophase. Roscovitine inhibits in vitro M-phase-promoting factor activity and in vitro DNA synthesis in Xenopus egg extracts. It blocks progesterone-induced oocyte maturation of Xenopus oocytes and in vivo phosphorylation of the elongation factor eEF-1. Roscovitine inhibits the proliferation of mammalian cell lines with an average IC50 of 16 microM. In the presence of roscovitine L1210 cells arrest in G1 and accumulate in G2. In vivo phosphorylation of vimentin on Ser55 by cdc2/cyclin B is inhibited by roscovitine. Through its unique selectivity for some cyclin-dependent kinases, roscovitine provides a useful antimitotic reagent for cell cycle studies and may prove interesting to control cells with deregulated cdc2, cdk2 or cdk5 kinase activities.

Normal and pathological Tau proteins as factors for microtubule assembly

Tau proteins are microtubule-associated proteins. They regulate the dynamics of the microtubule network, especially involved in the axonal transport and neuronal plasticity. Tau proteins belong to a family of developmentally regulated isoforms generated by alternative splicing and phosphorylation. This generates several Tau variants that interact with tubulin and other proteins. Therefore, Tau proteins are influenced by many physiological regulations. Tau proteins are also powerful markers of the neuronal physiological state. Their degree of phosphorylation is a good marker of cell integrity. It is heavily disturbed in numerous neurodegenerative disorders, leading to a collapse of the microtubule network and the presence of intraneuronal lesions resulting from Tau aggregation. However, different biochemical and immunological patterns of pathological Tau proteins found among neurodegenerative disorders are useful markers for the understanding of the role of Tau protein isoforms and the diagnosis of these pathological conditions.

Regulation of the phosphorylation state and microtubule-binding activity of Tau by protein phosphatase 2A

Recently, we reported that a pool of protein phosphatase 2A (PP2A) is associated with microtubules. Here, we demonstrate that specific isoforms of PP2A bind and dephosphorylate the neuronal microtubule-associated protein tau. Coexpression of tau and SV40 small t, a specific inhibitor of PP2A, in CV-1, NIH 3T3, or NT2 cells induced the phosphorylation of tau at multiple sites, including Ser-199, Ser-202, Thr-205, Ser-396, and Ser-404. Immunofluorescent and biochemical analyses revealed that hyperphosphorylation correlated with dissociation of tau from microtubules and a loss of tau-induced microtubule stabilization. Taken together, these results support the hypothesis that PP2A controls the phosphorylation state of tau in vivo.

The microtubule-associated protein tau is extensively modified with O-linked N-acetylglucosamine

Tau is a family of phosphoproteins that are important in modulating microtubule stability in neurons. In Alzheimer's disease tau is abnormally hyperphosphorylated, no longer binds microtubules, and self-assembles to form paired helical filaments that likely contribute to neuron death. Here we demonstrate that normal bovine tau is multiply modified by Ser(Thr)-O-linked N-acetylglucosamine, a dynamic and abundant post-translational modification that is often reciprocal to Ser(Thr)-phosphorylation. O-GlcNAcylation of tau was demonstrated by blotting with succinylated wheat germ agglutinin and by probing with bovine milk beta(1,4)galactosyltransferase. Structural analyses confirm the linkage and the saccharide structure. Tau splicing variants are multiply O-GlcNAcylated at similar sites, with an average stoichiometry of greater than 4 mol of O-linked N-acetylglucosamine/mol of tau. However, the number of sites occupied appears to be greater than 12, suggesting substoichiometric occupancy at any given site. A similar relationship between average stoichiometry and site-occupancy has also been described for the phosphorylation of tau. Site-specific or stoichiometric changes in O-GlcNAcylation may not only modulate tau function but may also play a role in the formation of paired helical filaments.

Local and distant histopathological effects of unilateral amyloid-beta 25-35 injections into the amygdala of young F344 rats

To determine if amyloid-beta (A beta) induces tau-immunoreactivity (IR) and reactive astrocytosis in vivo, we injected A beta 25-35 (5.0 nmol) into the right amygdala of rats. At 8 days postinjection, the peptide induced tau-2 IR in neuronal cell bodies and processes ipsilaterally in the amygdala, cingulate cortex, and hippocampus. At 32 days postinjection, the intensity of tau-2 IR was greater than at 8 days in the amygdala and hippocampus, but not in the cingulate cortex. Induction of Alz-50 IR also was progressive but the morphology and distribution was different from tau-2 IR. Beaded fibers with occasional neuronal perikarya were visualized with Alz-50, and the IR was primarily observed in the ipsilateral amygdala. In addition, amygdaloid injections of A beta 25-35 induced reactive astrocytosis, particularly in the ipsilateral hippocampus at 32 days postoperatively. To our knowledge, this is the first study to show that in vivo injections of A beta 25-35 induce progressive transsynaptic cytoskeletal and astrogliotic reactions, that gradually spread from the area of injection to brain regions that have prominent efferent connections with that area. These findings also suggest a direct association between plaque and tangle formation in Alzheimer's disease.

Immunocytochemistry of tau phosphoserine 413 and tau protein kinase I in Alzheimer pathology

One unique phosphorylation site consistently found in paired helical filament tau, serine 413, is modified by tau protein kinase I/glycogen synthase kinase-3 beta but no other known tau kinase. Here we present immunocytochemistry from Alzheimer's disease brains showing that focal subpopulations of hippocampal CA1 pyramidal neurons and neuritic plaques are strongly reactive for tau protein kinase I/glycogen synthase kinase-3 beta and tau phosphoserine 413 in early stages of pathology. Colocalization of these epitopes suggests that tau protein kinase I/glycogen synthase kinase-3 beta abnormally phosphorylates tau and is in a position to disrupt neuronal metabolism in anatomical areas vulnerable to Alzheimer's disease.

AD2, a phosphorylation-dependent monoclonal antibody directed against tau proteins found in Alzheimer's disease

Alzheimer's disease is characterized by an intraneuronal aggregation of hyperphosphorylated tau proteins into paired helical filaments. The hyperphosphorylation of tau proteins induces a decrease in their electrophoretic mobility, resulting in a pathological tau triplet referred to as tau 55, 64 and 69 or tau-PHF. We have developed monoclonal antibodies directed against this pathological tau triplet. In the present article, we report the properties of antibody AD2, which detects the hyperphosphorylated tau proteins forming paired helical filaments during Alzheimer's disease. Using immunoblotting, AD2 exclusively labeled the tau triplet, while normal tau proteins from control cases were not immunodetected. Furthermore, AD2 is highly specific in that it was able to detect the triplet not only in tau preparations but also in total brain homogenates from Alzheimer's disease patients. The binding of this monoclonal antibody to tau proteins is phosphorylation dependent. Characterization of this antibody allowed us to identify its epitope as containing phosphorylated Ser-396 with the participation of phosphorylated Ser-404. AD2 was also shown to label normal tau proteins from rapidly processed brain tissues, but its epitope is rapidly dephosphorylated during postmortem intervals. However, in autopsic brains, AD2 still represents a valuable tool to investigate neurofibrillary degeneration at the biochemical and immunocytochemical levels.

Calcium/calmodulin-dependent protein kinase II phosphorylates tau at Ser-262 but only partially inhibits its binding to microtubules

PHF-tau, which is phosphorylated at 10 Ser/Thr-Pro and 11 non-Ser/Thr-Pro sites, is unable to promote microtubule assembly. Phosphorylation of the non-Ser/Thr-Pro site, Ser-262, is reported to be primarily responsible for this. The identities of kinase(s) responsible for Ser-262 phosphorylation are still to be clarified. In this study we have used the monoclonal antibody 12E8, which recognizes P-Ser-262 and P-Ser-356 on tau, to survey different kinases for their abilities to phosphorylate Ser-262 on human tau 3L (tau410). In decreasing order of effectiveness we found that Ser-262 and Ser-356 phosphorylation can be catalyzed by CaM kinase II >> C-kinase >> GSK-3 approximately = A-kinase >> CK-1. CaM kinase II and C-kinase were shown to phosphorylate both Ser-262 and Ser-356. The binding of tau to taxol-stabilized microtubules was decreased by 35 and 42% after phosphorylation by CaM kinase II and C-kinase, respectively. Of the fraction of tau that bound to microtubules, about 50% was phosphorylated at Ser-262 and Ser-356. These results suggest that Ser-262 and Ser-356 are very good substrates for CaM kinase II but their phosphorylations are not sufficient to achieve maximal inhibition of tau binding to microtubules.

Restoration of biological activity of Alzheimer abnormally phosphorylated tau by dephosphorylation with protein phosphatase-2A, -2B and -1

Microtubule associated protein tau promotes the assembly of microtubules by binding to microtubules and stabilizing their structure. In Alzheimer disease brain, tau is abnormally hyperphosphorylated and the altered tau is unable to promote the in vitro assembly of microtubules. In the present study, we found that dephosphorylation of abnormally phosphorylated tau by protein phosphatase-2A1, -2B or -1 restored its biological activity both in the nucleation and in the assembly of microtubules. Both the amount of phosphate released and the rate of restoration of microtubule assembly promoting activity of the abnormal tau were greater on dephosphorylation by protein phosphatase-2A1 than -2B or -1. During 90 min incubation at 37 degrees C protein phosphatase-2A1, -2B and -1 released respectively approximately 57%, approximately 36% and approximately 30% of tau phosphate. Association of the restoration of the biological activity of the abnormal tau dephosphorylated by different phosphatases and the immunochemical identification of the dephosphorylated sites revealed that Ser-235 is not critical in tau function, and that the Thr-231 is probably involved in the regulation of the nucleation and not the assembly of microtubules. These studies indicate that the phosphorylation of tau in situ might be regulated by protein phosphatase-2A, -2B and -1 and activation of these enzyme activities might arrest the Alzheimer neurofibrillary degeneration.

Tau protein is phosphorylated by cyclic AMP-dependent protein kinase and calcium/calmodulin-dependent protein kinase II within its microtubule-binding domains at Ser-262 and Ser-356

Phosphorylation of tau protein at Ser-262 has been shown to diminish its ability to bind to taxol-stabilized microtubules. The paired helical filaments (PHFs) found in Alzheimer's disease brain are composed of PHF-tau, which is hyperphosphorylated at multiple sites including Ser-262. However, protein kinase(s) able to phosphorylate this site are still under investigation. In this study, the ability of cyclic AMP-dependent protein kinase (cAMP-PK) and calcium/calmodulin-dependent protein kinase II (CaMKII) to phosphorylate tau at Ser-262, as well as Ser-356, is demonstrated by use of a monoclonal antibody (12E8) which has been shown to recognize tau when these sites are phosphorylated. Cleavage of cAMP-PK-phosphorylated tau at cysteine residues by 2-nitro-5-thiocyanobenzoic acid, which cuts the protein into essentially two fragments and separates Ser-262 from Ser-356, revealed that cAMP-PK phosphorylates both Ser-262 and Ser-356. In addition, phosphorylation with cAMP-PK or CaMKII of recombinant tau in which Ser-262, Ser-356 or both had been mutated to alanines, clearly demonstrated that cAMP-PK and CaMKII were able to phosphorylate both sites. Mitogen-activated protein kinase or protein kinase C did not phosphorylate tau at Ser-262 and/or Ser-356. Finally, evidence is presented that phosphorylation of both these sites occurs in cultured nerve cells under certain conditions, indicating their potential physiological relevance.

The pool of map kinase associated with microtubules is small but constitutively active

Mitogen-activated protein kinase (MAPK) is activated by many kinds of stimuli and plays an important role in integrating signal transduction cascades. MAPK is present abundantly in brain, where we have studied its association with microtubules. Immunofluorescence of primary hippocampal neurons revealed that MAPK staining co-localized with microtubules and biochemical analyses showed that MAPK co-purified with microtubules. Approximately 4% of MAPK in cytosolic extracts was associated with microtubules, where it was associated with both tubulin and microtubule-associated proteins (MAPs) fractions. Further fractionation of MAPs suggested that a portion of MAPK is associated with MAP2. An association with MAP2 was also demonstrated by co-immunoprecipitation and in vitro binding experiments. A similar association was shown for the juvenile MAP2 isoform, MAP2C. The pool of MAPK associated with microtubules had a higher activity relative to the nonassociated pool in both brain and proliferating PC12 cells. Although MAPK was activated by nerve growth factor in PC12 cells, the activity of microtubule-associated MAPK did not further increase. These results raise the possibility that microtubule-associated MAPK operates through constitutive phosphorylation activity to regulate microtubule function in neurons.

Immunohistochemical examination of phosphorylated tau in granulovacuolar degeneration granules

Granulovacuolar degeneration (GVD) and neurofibrillary tangles (NFT) are neuropathological features in Alzheimer's disease (AD). The molecular mechanism of GVD formation remains unknown. Recent immunohistochemical investigations suggested a potential link of NFT to GVD formation. Enzyme histochemical studies and electronmicroscopic findings suggested that GVD is formed through lysosomal autophagy of intraneuronal substances. We recently demonstrated that in non-demented cases NFT was phosphorylated at serines 199, 202 and 422 in paired helical filament (PHF)-tau more than in serine 396, while NFT in AD cases was similarly phosphorylated at these four sites in tau. In this study, we demonstrated immunohistochemically a similar phosphorylation state of tau in GVD granules to that in NFT in both non-demented cases and AD patients by using a mouse monoclonal anti-tau antibody and three phosphorylation site-specific antibodies for PHF-tau, indicating that GVD granules and NFT are composed of similar phosphorylated-tau. However, we could not detect PHF structures within any GVD using electronmicroscopy, indicating that PHF itself is not phagocytized by lysosomes during GVD formation. Therefore, the source of GVD granules might be phosphorylated pre-PHF-tau.

Biochemical and cognitive studies of apolipoprotein-E-deficient mice

Apolipoprotein-E-deficient mice provide a useful model system for studying the role of apolipoprotein E (apoE) in brain function. In the present study, we characterized the cholinergic function of these mice and the extent of phosphorylation of their cytoskeletal protein tau. Morris water maze tasks revealed deficits in working memory that were accompanied by a specific decrease in hippocampal and cortical choline acetyltransferase activities. Immunoblot experiments utilizing native and dephosphorylated tau and antibodies directed against specific phosphorylated and unphosphorylated tau epitopes revealed that tau of the apoE-deficient mice is hyperphosphorylated. These results show that apoE-deficient mice have cognitive cholinergic and cytoskeletal derangements and point out the importance of this model for studying the role of apoE in neuronal function.

Characterization of mAb AP422, a novel phosphorylation-dependent monoclonal antibody against tau protein

A monoclonal antibody (AP422) specific for phosphoserine 422 in microtubule-associated protein tau has been produced. It strongly labels paired helical filament (PHF) tau from Alzheimer's disease brain in a phosphorylation-dependent manner. By contrast, AP422 only labels a small fraction of fetal tau and a very small fraction of tau from adult brain. The amount of tau phosphorylated at Ser-422 in normal brain is minor relative to that phosphorylated at sites recognized by other phosphorylation-dependent anti-tau antibodies of known epitope. It follows that AP422 is the most specific anti-tau antibody available for detecting the neurofibrillary lesions of Alzheimer's disease. We also show that Ser-422 in tau is a good in vitro substrate for mitogen-activated protein kinase, but not for glycogen synthase kinase-3 or neuronal cdc2-like kinase.

Dephosphorylation studies of SKNSH-SY 5Y cell Tau proteins by endogenous phosphatase activity

Recent data have shown that the microtubule-associated Tau proteins are phosphorylated but to a lesser extent than PHF-Tau proteins which are the major components of Alzheimer's disease paired helical filaments. These normal Tau proteins are highly sensitive to the endogenous phosphatase activity during post-mortem delay. In order to understand the basic equilibrium between phosphatase and kinase activities, phosphorylation and dephosphorylation mechanisms of Tau proteins were studied in neuroblastoma cells. The present results demonstrate that an endogenous phosphatase activity is present and directed on Tau proteins in the SKNSH-SY 5Y cell extracts. Interestingly, the okadaic acid-induced hyperphosphorylated Tau proteins are more resistant to the phosphatase activity than the control Tau proteins. Our data emphasize the value of this in vitro cellular model for the study of biological conditions that control Tau protein phosphorylation levels.

Site-specific dephosphorylation of tau protein at Ser202/Thr205 in response to microtubule depolymerization in cultured human neurons involves protein phosphatase 2A

Tau proteins isolated from paired helical filaments, the major building blocks of Alzheimer's disease neurofibrillary tangle, are abnormally phosphorylated and unable to bind microtubules. To examine the dynamics of tau phosphorylation and to identify specific tau phosphorylation sites involved in the stabilization of microtubules, we treated cultured postmitotic neuron-like cells (NT2N) derived from a human teratocarcinoma cell line (NTera2/D1) with drugs that depolymerize microtubules (i.e. colchicine or nocodazole). This led to the recovery of dephosphorylated tau from the NT2N cells as monitored by a relative increase in the electrophoretic mobility of tau and an increase in the turnover of [32P]PO4-labeled tau. However, not all phosphorylation sites on tau are affected by colchicine or nocodazole. Ser202/Thr205 appears to be completely and specifically dephosphorylated by protein phosphatase 2A since this dephosphorylation was blocked by inhibitors of protein phosphatase 2A but not by inhibitors of protein phosphatase 2B. These findings, together with the recent observation that protein phosphatase 2A is normally bound to microtubules in intact cells, suggest that the polymerization state of microtubules could modulate the phosphorylation state of tau at specific sites in the normal and Alzheimer's disease brain.

Distribution of isoforms of the microtubule-associated protein tau in grey and white matter areas of human brain: a two-dimensional gelelectrophoretic analysis

The microtubule-associated protein tau in human brain consists of six molecular isoforms derived from a single gene by alternative mRNA-splicing and further modified by posttranslational processing. In the present study, the distribution of tau isoforms in grey and white matter of human temporal cortex was investigated by two-dimensional gelelectrophoresis. More than 80 isoforms were detected. The pattern of isoforms obtained after treatment with alkaline phosphatase was still more complex than those of recombinant tau, indicating that posttranslational modifications other than phosphorylation contribute to the molecular heterogeneity of tau. The tau isoform D according to Goedert containing four tubulin-binding regions shown to promote tubulin polymerisation most efficiently was present in higher amounts in white as compared to grey matter. The pattern of isoform distribution was not significantly altered in Alzheimer's disease. It is concluded that molecular isoforms that differ in their tubulin-binding characteristics are differentially distributed in subcellular neuronal compartments and/or neuronal types.

Non-proline-dependent protein kinases phosphorylate several sites found in tau from Alzheimer disease brain

Of 21 phosphorylation sites identified in PHF-tau 11 are on ser/thr-X motifs and are probably phosphorylated by non-proline-dependent protein kinases (non-PDPKs). The identities of the non-PDPKs and how they interact to hyperphosphorylate PHF-tau are still unclear. In a previous study we have shown that the rate of phosphorylation of human tau 39 by a PDPK (GSK-3) was increased several fold if tau were first prephosphorylated by non-PDPKs (Singh et al., FEBS Lett 358: 267-272, 1995). In this study we have examined how the specificity of a non-PDPK for different sites on human tau 39 is modulated when tau is prephosphorylated by other non-PDPKs (A-kinase, C-kinase, CK-1, CaM kinase II) as well as a PDPK (GSK-3). We found that the rate of phosphorylation of tau 39 by a non-PDPK can be stimulated if tau were first prephosphorylated by other non-PDPKs. Of the four non-PDPKs only CK-1 can phosphorylate sites (thr 231, ser 396, ser 404) known to be present in PHF-tau. Further, these sites were phosphorylated more rapidly and to a greater extent by CK-1 if tau 39 were first prephosphorylated by A-kinase, CaM kinase II or GSK-3. These results suggest that the site specificities of the non-PDPKs that participate in PHF-tau hyperphosphorylation can be modulated at the substrate level by the phosphorylation state of tau.

Tau protein and the neurofibrillary pathology of Alzheimer's disease

Abundant neurofibrillary tangles, neuropil threads and senile plaque neurites constitute the neurofibrillary pathology of Alzheimer's disease. They form in the nerve cells that undergo degeneration in the disease, in which their regional distribution correlates with the degree of dementia. Each lesion contains the paired helical filament (PHF) as its major component. PHFs are composed of the microtubule-associated protein tau in a hyperphosphorylated state. PHF-tau is hyperphosphorylated on all six adult brain isoforms. As a consequence, tau is unable to bind to microtubules and is believed to self-assemble into the PHF. Several candidate protein kinases and protein phosphatases have been identified through in vitro experiments.

Analysis of phosphorylation of tau with antibodies specific for phosphorylation sites

Previously, we determined sites of tau protein phosphorylation by tau protein kinase (TPK) I/glycogen synthase kinase 3 beta (GSK-3 beta) and TPKII/(cyclin-dependent kinase 5 (CDK5) + p23). We prepared antibodies specific for these sites of tau phosphorylated by TPKI and TPKII, using chemically synthesized phosphopeptides as antigens. Each antibody specifically reacts with each phosphorylation site. With these antibodies, it was confirmed that TPKI and TPKII are responsible for these phosphorylation sites, as reported previously, except that Ser404 is also weakly phosphorylated by TPKI alone. It was also observed that TPKII-phosphorylation enhances TPKI-phosphorylation. These results indicate that these antibodies are useful tools for investigation of the phosphorylation of tau by TPKI and TPKII.

In situ dephosphorylation of tau by protein phosphatase 2A and 2B in fetal rat primary cultured neurons

Using antibodies recognizing the phosphorylation state of specific sites, phosphorylation states of tau were monitored in fetal rat primary cultured neurons. When cultured neurons were treated with okadaic acid (OA) or calyculin A (CalA) at concentrations sufficient to inhibit protein phosphatase 2A (PP2A), phosphorylation of Ser-199/Ser-202 (numbered according to the human tau 441) and Ser-235 increased. On the other hand, treatment with Ca2+ ionophore, A23187, induced dephosphorylation of Ser-199/Ser-202, Thr-205, Ser-396 and Ser-404, and this dephosphorylation was repressed by inhibitors of protein phosphatase 2B (PP2B), cyclosporin A and FK506. These results indicate that PP2A and PP2B are differentially involved in dephosphorylation of tau in neurons.

Tau protein in cerebrospinal fluid: a biochemical marker for axonal degeneration in Alzheimer disease?

Cerebrospinal fluid (CSF) biochemical markers for Alzheimer disease (AD) would be of great value to improve the clinical diagnostic accuracy of the disorder. As abnormally phosphorylated forms of the microtubule-associated protein tau have been consistently found in the brains of AD patients, and since tau can be detected in CSF, two assays based on several well-defined monoclonal tau antibodies were used to study these proteins in CSF. One assay detects most normal and abnormal forms of tau (CSF-tau), while the other is highly specific for phosphorylated tau (CSF-PHFtau). A marked increase in CSF-PHFtau was found in AD (2230 +/- 930 pg/mL), as compared with controls (640 +/- 230 pg/mL; p < 0.0001), vascular dementia, VAD (1610 +/- 840 pg/mL; p < 0.05), frontal lobe dementia, FLD (1530 +/- 1000 pg/mL; p < 0.05), Parkinson disease, PD (720 +/- 590 pg/mL; p < 0.0001), and patients with major depression (230 +/- 130 pg/mL; p < 0.0001). Parallel results were obtained for CSF-tau. No less than 35/40 (88%) of AD patients had a CSF-PHFtau value higher than the cutoff level of 1140 pg/mL in controls. The present study demonstrates that elevated tau/PHFtau levels are consistently found in CSF of AD patients. However, a considerable overlap is still present with other forms of dementia, both VAD and FLD. CSF-tau and CSF-PHFtau may therefore be useful as a positive biochemical marker, to discriminate AD from normal aging, PD, and depressive pseudodementia. Further studies are needed to clarify the sensitivity and specificity of these assays, including follow-up studies with neuropathological examinations.

Tau isoform expression and phosphorylation state during differentiation of cultured neuronal cells

The axonal microtubule-associated protein, tau, is thought to play an important role in axonal growth and in the establishment of neuronal polarity. In adult human brain there are six alternatively spliced tau isoforms, which have different microtubule binding affinities in vitro. The tubulin-tau interaction is further modified by phosphorylation of tau and, compared to adult brain tau, both foetal brain tau and paired helical filament (PHF) tau, characteristic of Alzheimer's disease, are hyperphosphorylated. In vivo both the expression of tau isoforms and their phosphorylation states are developmentally regulated. In order to establish the correlation between the expression of tau isoforms and their pattern of phosphorylation, we have characterised these two features in several in vitro models of neuronal differentiation, including the human neuroblastoma cell lines, SK-N-SH, SH-SY5Y and IMR32 cells, rat PC12 cells and primary rat cortical neurones. Sensitive RT-PCR analysis revealed a different complement of tau isoforms in the different cell lines and neuritogenesis was associated mainly with an increase in the overall tau protein level with no apparent phosphorylation changes. A switch in tau isoform expression occurred only at the terminal stages of neuronal development, when it may be important in reinforcing the previously established axonal cytoarchitecture.

Tau protein immunoreactivity in muscle fibers with rimmed vacuoles differs from that in regenerating muscle fibers

To determine whether tau protein found in muscle fibers with rimmed vacuoles and in regenerating fibers was phosphorylated, we examined eight muscle biopsy samples containing rimmed vacuoles (from five patients with distal myopathy with rimmed vacuole formation and three patients with inclusion body myositis) and three muscle biopsy samples from patients with Duchenne muscular dystrophy containing numerous regenerating fibers. Although both rimmed vacuolated and regenerating fibers had increased immunoreactivity against tubulin and tau protein, tau protein in the former was more highly phosphorylated than that in the latter. While very few microtubules in muscle fibers with rimmed vacuoles were recognizable by electron microscopy, regenerating fibers, especially immature ones, contained numerous microtubules. Since tau protein found in vacuolated fibers is hyperphosphorylated, it can be considered to have reduced ability to bind tubulin molecules. Thus, the tau protein cannot stabilize microtubules, resulting in their depolymerization even in the presence of tubulin molecules.

Phosphorylation of tau in apolipoprotein E-deficient mice

It has been suggested that the deleterious effects of the allele E4 of apolipoprotein E (apoE) in Alzheimer's disease (AD) are related to its inability to interact with the microtubule associated protein tau and to thereby prevent its hyperphosphorylation. In the present study we investigated the effects of apoE on tau phosphorylation by immunoblot analysis of the levels and extents of phosphorylation of tau of apoE-deficient mice. This revealed that mAb AT8, which is directed against a phosphorylated tau epitope, labels tau of the apoE-deficient mice more intensely than that of control mice and that the opposite occurs with mAb Tau1, which is directed against dephosphorylated tau epitopes. mAb ALZ50 also labeled the tau enriched preparations of the apoE-deficient mice more intensely than those of the controls, whereas the extents of their labeling by the phosphorylation insensitive anti-tau mAb 134 were similar. These results suggest that tau of apoE-deficient mice is hyperphosphorylated.

Cell cycle-dependent phosphorylation and microtubule binding of tau protein stably transfected into Chinese hamster ovary cells

Tau protein, a neuronal microtubule-associated protein, is phosphorylated in situ and hyperphosphorylated when aggregated into the paired helical filaments of Alzheimer's disease. To study the phosphorylation of tau protein in vivo, we have stably transfected htau40, the largest human tau isoform, into Chinese hamster ovary cells. The distribution and phosphorylation of tau was monitored by gel shift, autoradiography, immunofluorescence, and immunoblotting, using the antibodies Tau-1, AT8, AT180, and PHF-1, which are sensitive to the phosphorylation of Ser202, Thr205, Thr231, Ser235, Ser396, and Ser404 and are used in the diagnosis of Alzheimer tau. In interphase cells, tau becomes phosphorylated to some extent, partly at these sites; most of the tau is associated with microtubules. In mitosis, the above Ser/Thr-Pro sites become almost completely phosphorylated, causing a pronounced shift in M(r) and an antibody reactivity similar to that of Alzheimer tau. Moreover, a substantial fraction of tau is found in the cytoplasm detached from microtubules. Autoradiographs of metabolically labeled Chinese hamster ovary cells in interphase and mitosis confirmed that tau protein is more highly phosphorylated during mitosis. The understanding of tau phosphorylation under physiological conditions might help elucidate possible mechanisms for the hyperphosphorylation in Alzheimer's disease.

Disruption of the cytoskeleton in Alzheimer's disease

Paired helical filaments (PHFs) in Alzheimer's disease are formed from hyperphosphorylated brain tau known as PHF-tau. Many sites of phosphorylation that were thought to be present only in PHF-tau are now known to be normal phosphate acceptor sites in both fetal and rapidly processed adult brain tau. The rapid dephosphorylation of normal brain tau by protein phosphatases 2A and 2B provides an explanation for the apparent absence of phosphates at these sites in the normal adult brain tau obtained postmortem. Although the functional significance of each of these normal phosphate acceptor sites is unknown at this time, emerging evidence suggests that the binding of tau to microtubules is regulated by the simultaneous phosphorylation and dephosphorylation of tau at multiple sites.

Glycogen synthase kinase 3 phosphorylates recombinant human tau protein at serine-262 in the presence of heparin (or tubulin)

Tau protein, the major component of the aberrant structures termed paired helical filaments (PHFs) present in the brain of Alzheimer's disease patients, is pathologically phosphorylated in sites in and around the tubulin-binding sites. A single protein kinase, glycogen synthase kinase 3 (GSK 3), is able to phosphorylate tau at the flanking regions and, additionally, at the tubulin-binding motifs if heparin or tubulin is present. Serines-262 and -324 have been found to be modified at the tubulin-binding region of tau protein by GSK 3 in the presence of heparin or tubulin.

A novel tau-tubulin kinase from bovine brain

During purification of tau protein kinase I and II from the bovine brain extract, a new tau protein kinase was detected and purified with phosphocellulose, gel filtration, S-Sepharose and AF-Heparin column chromatography. The molecular mass of the enzyme was determined to be 32 kDa by gel filtration and activity staining on SDS-PAGE. The enzyme is a Ser/Thr protein kinase phosphorylating tau, beta-tubulin, MAP2 and alpha-casein. Employing many synthetic peptides, the recognition site of this enzyme appears to be -SR-. The enzyme requires no second messenger and is inhibited with high concentration of heparin, but not by inhibitors of CKI. These results indicate that this enzyme, tau-tubulin kinase is novel and distinct from TPKI, II and CKI, II.

Detection of phosphorylated Ser262 in fetal tau, adult tau, and paired helical filament tau

Paired helical filaments (PHFs) are the major structural elements of Alzheimer's disease neurofibrillary lesions, and these filaments are formed from hyperphosphorylated brain tau known as PHF-tau. Recent studies showed that many previously identified phosphorylated residues in PHF-tau also are phosphate acceptor sites in fetal and rapidly processed adult brain tau. However, Ser262 has been suggested to be uniquely phosphorylated in PHF-tau and a key regulator of the binding of tau to microtubules. For these reasons, we generated a monoclonal antibody (12E8) specific for phosphorylated Ser262 and showed that 12E8 binds to PHF-tau, rat and human fetal brain tau, as well as to rapidly processed adult rat and biopsy-derived human brain tau. Further, phosphorylation Ser262 was developmentally regulated, and endogenous brain phosphatases rapidly dephosphorylated Ser262 in biopsy-derived brain tau isolates. Finally, the phosphorylation of Ser262 did not eliminate the binding of tau to microtubules. Thus, we speculate that the binding of tau to microtubules is regulated by phosphorylation at multiple sites and that the generation of PHF-tau in Alzheimer's disease results from the reduced efficiency of phosphatases leading to the incremental accumulation of hyperphosphorylated tau.

Differential sensitivity to proteolysis by brain calpain of adult human tau, fetal human tau and PHF-tau

Reduced turn-over of tau by calpains is a possible mechanism to facilitate the incorporation into paired helical filaments (PHFs) in Alzheimer's disease. The present study shows that the differently phosphorylated fetal tau isoforms are all rapidly proteolysed to an equal extent by human brain m-calpain. This result argues against the hypothesis that this type of fetal phosphorylation is involved in reducing tau turn-over by calpain in Alzheimer's disease. Adult and fetal tau fragments in vitro generated by m-calpain, but not trypsin, cathepsin D or chymotrypsin resemble the post-mortem in situ degradation patterns, suggesting a possible role for calpains in tau metabolism in vivo. Tau incorporated into PHFs was considerably more resistant to proteolysis by calpain which can help to explain the persistence of these structures in Alzheimer's disease.

Hyperphosphorylation of tau in PHF

Tau in PHF is known to be highly phosphorylated and immunochemical study has indicated the similarity of the phosphorylation between PHF-tau and fetal tau. We have determined the exact phosphorylation sites in both PHF-tau and fetal rat tau by ion-spray mass spectrometry and sequencing of ethanethiol-modified peptides. In PHF-tau, 19 sites have been identified; all the phosphorylation sites except for Ser-262 are localized to the amino- and carboxyl-terminal flanking regions of the microtubule-binding domain. Half of them are shared by fetal tau. Thus, PHF-tau is much more phosphorylated. Whereas most of the sites in fetal tau are proline-directed, half of them in PHF-tau are nonproline-directed. Overall, the hyperphosphorylation of PHF-tau can be considered to consist of fetal-type phosphorylation and additional proline-directed and nonproline-directed phosphorylation. This extraphosphorylation may provide PHF-tau with the unusual characteristics including assembly incompetence.