Neurofibrillary tangles associated with Alzheimer's disease are composed mainly of paired helical filaments that are formed by the aggregation of abnormally phosphorylated microtubule-associated protein tau. 14-3-3, a highly conserved protein family that exists as seven isoforms and regulates diverse cellular processes is present in neurofibrillary tangles (Layfield, R., Fergusson,
Glial heme oxygenase-1 is over-expressed in the CNS of subjects with Alzheimer disease (AD), Parkinson disease (PD) and multiple sclerosis (MS). Up-regulation of HO-1 in rat astroglia has been shown to facilitate iron sequestration by the mitochondrial compartment. To determine whether HO-1 induction promotes mitochondrial oxidative stress, assays for 8-epiPGF(2alpha) (ELISA), protein carbonyls (ELISA) and 8-OHdG (HPLC-EC) were used to quantify oxidative damage to lipids, proteins, and nucleic acids, respectively, in mitochondrial fractions and whole-cell compartments derived from cultured rat astroglia engineered to over-express human (h) HO-1 by transient transfection. Cell viability was assessed by trypan blue exclusion and the MTT assay, and cell proliferation was determined by [3H] thymidine incorporation and total cell counts. In rat astrocytes, hHO-1 over-expression (x 3 days) resulted in significant oxidative damage to mitochondrial lipids, proteins, and nucleic acids, partial growth arrest, and increased cell death. These effects were attenuated by incubation with 1 microM tin mesoporphyrin, a competitive HO inhibitor, or the iron chelator, deferoxamine. Up-regulation of HO-1 engenders oxidative mitochondrial injury in cultured rat astroglia. Heme-derived ferrous iron and carbon monoxide (CO) may mediate the oxidative modification of mitochondrial lipids, proteins and nucleic acids in these cells. Glial HO-1 hyperactivity may contribute to cellular oxidative stress, pathological iron deposition, and bioenergetic failure characteristic of degenerating and inflamed neural tissues and may constitute a rational target for therapeutic intervention in these conditions.
In Alzheimer's disease, microtubule-associated protein tau is hyperphosphorylated by an unknown mechanism and is aggregated into paired helical filaments. Hyperphosphorylation causes loss of tau function, microtubule instability, and neurodegeneration. Glycogen synthase kinase-3 (GSK3) has been implicated in the phosphorylation of tau in normal and Alzheimer's disease brain. The molecular mechanism of GSK3-tau interaction has not been clarified. In this study, we find that when microtubules are disassembled, microtubuleassociated GSK3 dissociates from microtubules. From a gel filtration column, the dissociated GSK3 elutes as an ϳ400-kDa complex. When fractions containing the ϳ400-kDa complex are chromatographed through an anti-GSK3 immunoaffinity column, tau co-elutes with GSK3. From fractions containing the ϳ400-kDa complex, both tau and GSK3 co-immunoprecipitate with each other. GSK3 binds to nonphosphorylated tau, and the GSK3-binding region is located within the N-terminal projection domain of tau. In vitro, GSK3 associates with microtubules only in the presence of tau. From brain extract, ϳ6-fold more GSK3 co-immunoprecipitates with tau than GSK3␣. These data indicate that, in brain, GSK3 is bound to tau within a ϳ400-kDa microtubule-associated complex, and GSK3 associates with microtubules via tau.
Phosphorylation of tau on S(396) was suggested to be a key step in the development of neurofibrillary pathology in Alzheimer's disease brain [Bramblett, G. T., Goedert, M., Jacks, R., Merrick, S. E., Trojanowski, J. Q., and Lee, V. M.-Y. (1993) Neuron 10, 1089-1099]. GSK3beta phosphorylates Ser(396) of tau in the brain by a mechanism which is not clear. In this study, when HEK-293 cells were cotransfected with tau and GSK3beta, GSK3beta co-immunoprecipitated with tau and phosphorylated tau on S(202), T(231), S(396), and S(400) but not on S(262), S(235), and S(404). Blocking phosphorylation on T(231), S(235), S(396), S(400), or S(404) did not prevent the subsequent phosphorylation on S(202) by GSK3beta. These data suggest that GSK3beta directly phosphorylates tau on S(202) (without requiring prephosphorylation). However, preventing phosphorylation on S(235), S(400), and S(404) prevented GSK3beta-dependent phosphorylation of T(231), S(396), and S(400), respectively. This indicates that phosphorylation of T(231), S(396), and S(400) by GSK3beta depends on a previous phosphorylation of S(235), S(400), and S(404), respectively. To examine S(396) phosphorylation, we analyzed phosphorylation of S(396), S(400), and S(404). Blocking phosphorylation of S(404) prevented the subsequent GSK3beta-dependent phosphorylation of both S(400) and S(396). When phosphorylation of S(404) was allowed but S(400) blocked, GSK3beta failed to phosphorylate S(396). Thus, GSK3beta phosphorylates S(396) by a two-step mechanism. In the first step, GSK3beta phosphorylates S(400) of previously S(404)-phosphorylated tau. This event primes tau for second-step phosphorylation of S(396) by GSK3beta. We conclude that GSK3beta phosphorylates tau directly at S(202) but requires the previous phosphorylation on S(235) to phosphorylate T(231). Phosphorylation of S(396), on the other hand, occurs sequentially. Once a priming kinase phosphorylates S(404), GSK3beta sequentially phosphorylates S(400) and then S(396).
In the preceding paper, we showed that GSK3beta phosphorylates tau at S(202), T(231), S(396), and S(400) in vivo. Phosphorylation of S(202) occurs without priming. Phosphorylation of T(231), on the other hand, requires priming phosphorylation of S(235). Similarly, priming phosphorylation of S(404) is essential for the sequential phosphorylation of S(400) and S(396) by GSK3beta. The priming kinase that phosphorylates tau at S(235) and S(404) in the brain is not known. In this study, we find that in HEK-293 cells cotransfected with tau, GSK3beta, and Cdk5, Cdk5 phosphorylates tau at S(202), S(235), and S(404). S(235) phosphorylation enhances GSK3beta-catalyzed T(231) phosphorylation. Similarly, Cdk5 by phosphorylating S(404) stimulates phosphorylation of S(400) and S(396) by GSK3beta. These data indicate that Cdk5 primes tau for GSK3beta in intact cells. To evaluate if Cdk5 primes tau for GSK3beta in mammalian brain, we examined localizations of Cdk5, tau, and GSK3beta in rat brain. We also analyzed the interaction of Cdk5 with tau and GSK3beta in brain microtubules. We found that Cdk5, GSK3beta, and tau are virtually colocalized in rat brain cortex. When bovine brain microtubules are analyzed by FPLC gel filtration, Cdk5, GSK3beta, and tau coelute within an approximately 450 kDa complex. From the fractions containing the approximately 450 kDa complex, tau, Cdk5, and GSK3beta co-immunoprecipitate with each other. In HEK-293 cells transfected with tau, Cdk5, and GSK3beta in different combinations, tau binds to Cdk5 in a manner independent of GSK3beta and to GSK3beta in a manner independent of Cdk5. However, Cdk5 and GSK3beta bind to each other only in the presence of tau, suggesting that tau connects Cdk5 and GSK3beta. Our results suggest that in the brain, tau, Cdk5, and GSK3beta are components of an approximately 450 kDa complex. Within the complex, Cdk5 phosphorylates tau at S(235) and primes it for phosphorylation of T(231) by GSK3beta. Similarly, Cdk5 by phosphorylating tau at S(404) primes tau for a sequential phosphorylation of S(400) and S(396) by GSK3beta.
In Alzheimer's disease, the microtubule-associated protein tau forms paired helical filaments (PHFs) that are the major structural component of neurofibrillary tangles. Although tau isolated from PHFs (PHF-tau) is abnormally phosphorylated, the role of this abnormal phosphorylation in PHF assembly is not known. Previously, neuronal cdc2-like protein kinase (NCLK) was shown to phosphorylate tau on sites that are abnormally phosphorylated in PHF-tau (Paudel, H. K., Lew, J., Ali, Z., and Wang, J. H. (1993) J. Biol. Chem. 268, 23512-23518). In this study, phosphorylation by NCLK was found to promote dimerization of recombinant human tau (R-tau) and brain tau (B-tau) purified from brain extract. Chemical cross-linking by disuccinimidyl suberate (DSS), a homobifunctional chemical cross-linker that specifically cross-linked R-tau dimers, and a Superose 12 gel filtration chromatography revealed that R-tau preparations contain mixtures of monomeric and dimeric R-tau species. When the structure of NCLK-phosphorylated R-tau was studied by a similar approach, DSS preferentially cross-linked the phosphorylated Rtau over the nonphosphorylated R-tau, and the phosphorylated R-tau eluted as a dimeric species from the gel filtration column. Phosphorylated R-tau became resistant to DSS upon dephosphorylation and was recovered as a monomeric species from the gel filtration column. In the presence of a low concentration of dithiothreitol (1.65 M), R-tau formed disulfide crosslinked R-tau dimers. When compared, phosphorylated R-tau formed more disulfide cross-linked dimers than the nonphosphorylated R-tau. B-tau also was specifically cross-linked to dimers by DSS. When B-tau and NCLK-phosphorylated B-tau were treated with DSS, phosphorylated B-tau was preferentially cross-linked over nonphosphorylated counterpart. Taken together, these results suggest that phosphorylation by NCLK promotes dimerization and formation of disulfide crosslinked tau dimers, which is suggested to be the key step leading to PHF assembly (Schweers, O., Mandelkow, E.-M., Biernat, J., and Mandelkow, E. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 8463-8467).
Neuronal Cdc2-like protein kinase (NCLK), a ϳ58-kDa heterodimer, was isolated from neuronal microtubules (Ishiguro, K., Takamatsu, M., Tomizawa, K., Omori, A., Takahashi, M., Arioka, M., Uchida, T. and Imahori, K. (1992) J. Biol. Chem. 267, 10897-10901). The biochemical nature of NCLK-microtubule association is not known. In this study we found that NCLK is released from microtubules upon microtubule disassembly as a 450-kDa species. The 450-kDa species is an NCLK⅐tau complex, and NCLK-bound tau is in a nonphosphorylated state. Tau phosphorylation causes NCLK⅐tau complex dissociation, and phosphorylated tau does not bind to NCLK. In vitro, the Cdk5 subunit of NCLK binds to the microtubule-binding region of tau and NCLK associates with microtubules only in the presence of tau. Our data indicate that in brain extract NCLK is complexed with tau in a tau phosphorylation-dependent manner and that tau anchors NCLK to microtubules. Recently NCLK has been suggested to be aberrantly activated and to hyperphosphorylate tau in Alzheimer's disease brain (Patrick, G. N., Zukerberg, L., Nikolic, M., de la Monte, S., Dikkes, P, and Tsai, L.-H. (1999) Nature 402, 615-622). Our findings may explain why in Alzheimer's disease NCLK specifically hyperphosphorylates tau, although this kinase has a number of protein substrates in the brain.The neuronal Cdc2-like protein kinase (NCLK) 1 (also known as tau kinase II and brain proline-directed protein kinase) is a heterodimer of cyclin-dependent kinase 5 (Cdk5) and a neuronal-specific activator p25 subunit (reviewed in Ref. 1). The p25 subunit is a proteolytic fragment of a 35-kDa protein, p35 (1, 2). Targeted disruption of the cdk5 gene in mice results in unique lesions in the central nervous system, lack of cortical laminar structure, as well as cerebellar foliate and prenatal death (3). In differentiating neurons, neurite outgrowth is inhibited by the introduction of a dominant negative Cdk5 mutant and is enhanced by Cdk5 and p35 overexpression (4). Similarly, mice lacking p35 do not show NCLK activity and display cortical lamination defects, seizures, and adult lethality (5). These observations indicate that NCLK plays an important role in brain development, neuronal differentiation, and neurite outgrowth. In neurons NCLK phosphorylates inhibitor 1 (6) and DARPP-32 (7), the two inhibitory proteins that upon phosphorylation suppress phosphoprotein phosphatase 1 activity. Munc18 (8) and synapsin (9), which respectively regulate synaptic vesicle exocytosis and neurotransmitter release, are phosphorylated by NCLK. NCLK also phosphorylates the microtubule-associated protein tau (10, 11) and neurofilaments (12,13). These data indicate that NCLK regulates neural signaling, vesicular exocytosis, neurotransmitter release, and microtubule dynamics.
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