Polymerization of tau peptides into fibrillar structures. The effect of FTDP-17 mutations

The peptides corresponding to the four repeats found in the microtubule binding region of tau protein were synthesized and their ability for self-aggregation in presence of heparin or chondroitin sulfate was measured. Mainly, only the peptide containing the third tau repeat is able to form polymers in a high proportion. Additionally, the peptide containing the second repeat aggregates with a very low efficiency. However, when this peptide contains the mutation (P301L), described in a fronto temporal dementia, it is able to form polymers at a higher extent. Finally, it is suggested to have a role for the first and fourth tau repeats. It could be to decrease the ability of the third tau repeat for self-aggregation in the presence of heparin.     

Tau polymerization: role of the amino terminus

The abnormal polymerization of the tau molecule into insoluble filaments is a seminal event in the neurodegenerative process underlying Alzheimer's disease. Previous experimentation has shown that the microtubule-binding repeat region of the molecule is vital for its ability to polymerize in vitro into filaments similar to those found in Alzheimer's disease. However, it is becoming clear that regions outside the microtubule-binding repeat, such as exons 2 and 3 and the carboxy-terminal tail, can greatly influence its polymerization. Since it has been previously postulated that the amino terminus of tau could be involved in generating pathological conformations in the disease state, its role in the polymerization process was investigated. This report demonstrates that the removal of the amino terminus greatly inhibits the polymerization of the tau molecule, reducing both the rate and extent of polymerization. These results support the hypothesis that the ability of tau to form specific conformations involving the amino terminus is an early event in the formation of tau polymers in the disease state. Furthermore, the mutation of arginine 5 to leucine ((R)5(L)), mimicking an amino-terminal tau mutation found in a single case of FTDP-17, enhances the polymerization of the tau molecule. Therefore, the amino terminus of the tau molecule, while largely overlooked in studies of its polymerization, is a significant contributor to the polymerization process.     

Domains of Neuronal Microtubule-associated Proteins and Flexural Rigidity of Microtubules

Microtubules are flexible polymers whose mechanical properties are an important factor in the determination of cell architecture and function. It has been proposed that the two most prominent neuronal microtubule-associated proteins (MAPs), tau and MAP2, whose microtubule binding regions are largely homologous, make an important contribution to the formation and maintenance of neuronal processes, putatively by increasing the rigidity of microtubules. Using optical tweezers to manipulate single microtubules, we have measured their flexural rigidity in the presence of various constructs of tau and MAP2c. The results show a three- or fourfold increase of microtubule rigidity in the presence of wild-type tau or MAP2c, respectively. Unexpectedly, even low concentrations of MAPs promote a substantial increase in microtubule rigidity. Thus at ~20% saturation with full-length tau, a microtubule exhibits >80% of the rigidity observed at near saturating concentrations. Several different constructs of tau or MAP2 were used to determine the relative contribution of certain subdomains in the microtubule-binding region. All constructs tested increase microtubule rigidity, albeit to different extents. Thus, the repeat domains alone increase microtubule rigidity only marginally, whereas the domains flanking the repeats make a significant contribution. Overall, there is an excellent correlation between the strength of binding of a MAP construct to microtubules (as represented by its dissociation constant K_d) and the increase in microtubule rigidity. These findings demonstrate that neuronal MAPs as well as constructs derived from them increase microtubule rigidity, and that the changes in rigidity observed with different constructs correlate well with other biochemical and physiological parameters.     

Can tau filaments be both physiologically beneficial and toxic?

Alzheimer's disease (AD) is a progressive disease of aging primarily characterized at the behavioral level by symptoms of memory loss. The pathological hallmarks of AD are extracellular plaques and intracellular neurofibrillary tangles that are composed of filamentous polymers of beta-amyloid (Abeta) and tau, respectively. Aggregates of filaments are not unique to AD--fibrous polymers are the pathological signatures of many diseases of aging such as Huntington's disease and Parkinson's disease. Whether Abeta or tau filaments cause AD is still an open question, as a wide variety of proteins and pathways have been implicated in the initiation and advancement of the disease--processes such as apoptosis, oxidative stress, and protein degradation. That polymers are the prevalent species observed in aging disorders suggests that this morphology of aggregation represents a significant physiological role. As a consequence of an independent insult or aging itself, the filament shifts from a physiological role to one with pathological implications. The relative importance of Abeta filaments versus tau filaments has also been a focus of significant debate within the research community. Although genetic evidence indicates that Abeta filaments are an integral component in AD, only tau pathology has been found to correlate with symptom presentation in patients. Not only do tau filaments greatly contribute to the systematic loss of neurons and the pathological presentation of memory loss, but they may represent a physiological process whose regulation may be controlled.     

Phosphorylated, but not native, tau protein assembles following reaction with the lipid peroxidation product, 4-hydroxy-2-nonenal

A correlation between hyperphosphorylation of tau protein and its aberrant assembly into paired helical filaments has lead to suggestions that phosphorylation controls assembly, but lacked a mechanistic basic. In this work, we have found that phosphorylated, but not native, tau protein is able to form polymers after the reaction with 4-hydroxy-2-nonenal, a highly toxic product of lipid peroxidation. Phosphorylation of tau by both proline or non-proline directed kinases, was able to assemble it into polymers.     

Quantitation and characterization of tau factor in porcine tissues

Using a monospecific antibody against brain tau factor purified by affinity chromatography, we have studied the distribution of tau factor or related polypeptides in different cells. The presence of tau in all cell types tested was demonstrated by a radioimmunoassay. Tau factor-related proteins were found in liver, spleen, pancreas, kidney and lung, although at much lower levels than that found in neural cells. In all cases, they copolymerized with tubulin and were heat-resistant. When the distribution of tau factor-related proteins was studied by Western blotting, tau factor antiserum reacted against peptides with an electrophoretic mobility that was similar to those of brain tau factor peptides. Immunofluorescence studies have also been performed with the same antibody to determine the distribution of tau factor-related peptides in PK15 cells. Our results indicated that these peptides were associated to the microtubule network.     

Dephosphorylation of Microtubule-Associated Protein 2, τ Factor, and Tubulin by Calcineurin

Calcineurin dephosphorylated microtubule-associated protein 2 (MAP2) and tau factor phosphorylated by cyclic AMP-dependent and Ca2+, calmodulin-dependent protein kinases from the brain. Tubulin, only phosphorylated by the Ca2+, calmodulin-dependent protein kinase, served as substrate for calcineurin. The concentrations of calmodulin required to give half-maximal activation of calcineurin were 21 and 16 nM with MAP2 and tau factor as substrates, respectively. The Km and Vmax values were in ranges of 1-3 microM and 0.4-1.7 mumol/mg/min, respectively, for MAP2 and tau factor. The Km value for tubulin was in a similar range, but the Vmax value was lower. The peptide map analysis revealed that calcineurin dephosphorylated MAP2 and tau factor universally, but not in a site-specific manner. The autophosphorylated Ca2+, calmodulin-dependent protein kinase was not dephosphorylated by calcineurin. These results suggest that calcineurin plays an important role in the functions of microtubules via dephosphorylation.     

Regulation of microtubule protein levels during cellular morphogenesis in nerve growth factor-treated PC12 cells

Nerve growth factor induces neurite process formation in pheochromacytoma (PC12) cells and causes the parallel increase in levels of the microtubule-associated proteins, tau and MAP1, as well as increases in tubulin levels. Mechanisms to insure balanced accumulation of microtubule proteins and make their levels highly responsive to nerve growth factor were investigated. The effects on tau, MAP1, and tubulin are due to changes in protein synthesis rates, which for tau and tubulin we could show are due in part to changes in the mRNA levels. Whereas tubulin shows feedback regulation to modulate synthesis up or down, tau protein synthesis is not affected in a straightforward way by microtubule polymerization and depolymerization. The degradation of tau, MAP1, and both tubulin polypeptides, however, are stimulated by microtubule depolymerization caused by colchicine, or nerve growth factor removal. Combined feedback on synthesis and stability make tubulin levels highly responsive to assembly states. In addition, the linkage of tau and MAP1 turnover with the state of microtubule polymerization amplifies any change in their rate of synthesis, since tau and MAP1 promote microtubule polymerization. This linkage lends itself to rapid changes in the state of the system in response to nerve growth factor.     

Studies on the physical state of water in living cells and model systems. II. NMR relaxation times of water protons in aqueous solutions of gelatin and oxygen-containing polymers which reduce the solvency of water for NA+, sugars, and free amino acids

This communication reports our study of the NMR relaxation times, T1 and T2 of water protons in aqueous solutions of bovine serum albumin, gelatin, polyvinylpyrrolidone, poly(ethylene oxide), and polyvinylmethylether over a wide concentration range. In contrast to solutions of gelatin and bovine serum albumin, the T1/T2 ratio of the three synthetic polymers are close to unity over the entire range studied. When combined with earlier-reported data of water made "non-solvent" to Na salts, the present data provided the basis for calculating the T1 and T2 as well as the rotational correlation time tau c of the "non-solvent" water. It was shown that only a modest increase by a factor of about 3 of tau c is enough to produce water that is "non-solvent" for Na citrate and sulfate. The new data reconciles NMR data of living cells with the theory of the cell water given in the association-induction hypothesis. The variability of tau c of "non-solvent" water also offers explanations of apparently conflicting conclusions on the physical state of cell water from dielectric measurements.     

Inhibition of protein phosphatase 2A overrides tau protein kinase I/glycogen synthase kinase 3 beta and cyclin-dependent kinase 5 inhibition and results in tau hyperphosphorylation in the hippocampus of starved mouse.

Hyperphosphorylated tau is the major component of paired helical filaments in neurofibrillary tangles found in Alzheimer's disease (AD) brain. Starvation of adult mice induces tau hyperphosphorylation at many paired helical filaments sites and with a similar regional selectivity as those in AD, suggesting that a common mechanism may be mobilized. Here we investigated the mechanism of starvation-induced tau hyperphosphorylation in terms of tau kinases and Ser/Thr protein phosphatases (PP), and the results were compared with those reported in AD brain. During starvation, tau hyperphosphorylation at specific epitopes was accompanied by decreases in tau protein kinase I/glycogen synthase kinase 3 beta (TPKI/GSK3 beta), cyclin-dependent kinase 5 (cdk5), and PP2A activities toward tau. These results demonstrate that the activation of TPKI/GSK3 beta and cdk5 is not necessary to obtain hyperphosphorylated tau in vivo, and indicate that inhibition of PP2A is likely the dominant factor in inducing tau hyperphosphorylation in the starved mouse, overriding the inhibition of key tau kinases such as TPKI/GSK3 beta and cdk5. Furthermore, these data give strong support to the hypothesis that PP2A is important for the regulation of tau phosphorylation in the adult brain, and provide in vivo evidence in support of a central role of PP2A in tau hyperphosphorylation in AD.     

Tubulin, actin, and tau protein interactions and the study of their macromolecular assemblies

The intracellular polymerization of cytoskeletal proteins into their supramolecular assemblies raises many questions regarding the regulatory patterns that control this process. Binding experiments using the ELISA solid phase system, together with protein assembly assays and electron microscopical studies provided clues on the protein-protein associations in the polymerization of tubulin and actin networks. In vitro reconstitution experiments of these cytoskeletal filaments using purified tau, tubulin, and actin proteins were carried out. Tau protein association with tubulin immobilized in a solid phase support system was inhibited by actin monomer, and a higher inhibition was attained in the presence of preassembled actin filaments. Conversely, tubulin and assembled microtubules strongly inhibited tau interaction with actin in the solid phase system. Actin filaments decreased the extent of in vitro tau-induced tubulin assembly. Studies on the morphological aspects of microtubules and actin filaments coexisting in vitro, revealed the association between both cytoskeletal filaments, and in some cases, the presence of fine filamentous structures bridging these polymers. Immunogold studies showed the association of tau along polymerized microtubules and actin filaments, even though a preferential localization of labeled tau with microtubules was revealed. The studies provide further evidence for the involvement of tau protein in modulating the interactions of microtubules and actin polymers in the organization of the cytsokeletal network.     

Neural repetitive firing: modifications of the Hodgkin-Huxley axon suggested by experimental results from crustacean axons.

The Hodgkin-Huxley equations for space-clamped squid axon (18 degrees C) have been modified to approximate voltage clamp data from repetitive-firing crustacean walking leg axons and activity in response to constant current stimulation has been computed. The m infinity and h infinity parameters of the sodium conductance system were shifted along the voltage axis in opposite directions so that their relative overlap was increased approximately 7 mV. Time constants tau m and tau h, were moved in a similar manner. Voltage-dependent parameters of delayed potassium conductance, n infinity and tau n, were shifted 4.3 mV in the positive direction and tau n was uniformly increased by a factor of 2. Leakage conductance and capacitance were unchanged. Repetitive activity of this modified circuit was qualitatively similar to that of the standard model. A fifth branch was added to the circuit representing a transient potassium conductance system present in the repetitive walking leg axons and in other repetitive neurons. This model, with various parameter choices, fired repetitively down to approximately 2 spikes/s and up to 350/s. The frequency vs. stimulus current plot could be fit well by a straight line over a decade of the low frequency range and the general appearance of the spike trains was similar to that of other repetitive neurons. Stimulus intensities were of the same order as those which produce repetitive activity in the standard Hodgkin-Huxley axon. The repetitive firing rate and first spike latency (utilization time) were found to be most strongly influenced by the inactivation time constant of the transient potassium conductance (tau b), the delayed potassium conductance (tau n), and the value of leakage conductance (gL). The model presents a mechanism by which stable low frequency discharge can be generated by millisecond-order membrane conductance changes.     

Changes in conformation of human neuronal tau during denaturation in formaldehyde solution

Human neuronal tau was incubated in formaldehyde solution at low concentrations and the intensity of light scattering of tau-40 solution at 480 nm increased markedly. Then potassium iodide was used to quench the intrinsic fluorescence of tau. The fluorescent quenching constants decreased as formaldehyde concentrations increased. 8-anilino-1-naphthalenesulfonic acid (ANS) binding assay showed that a putative hydrophobic core formed in tau polymers during incubation with formaldehyde. Native tau was hydrolyzed by immobilized earthworm fibrinolytic enzyme-II (EFE-II), producing a digested fragment (36-37 kDa). However, formaldehyde-treated tau could not be digested under the same conditions, suggesting that aggregated protein was relatively rigidly deposited.     

Fluorescence anisotropy studies of molecularly imprinted polymers.

A molecularly imprinted polymer (MIP) is a biomimetic material that can be used as a biochemical sensing element. We studied the steady-state and time-resolved fluorescence and fluorescence anisotropy of anthracene-imprinted polyurethane. We compared MIPs with imprinted analytes present, MIPs with the imprinted analytes extracted, MIPs with rebound analytes, non-imprinted control polymers (non-MIPs) and non-MIPs bound with analytes to understand MIP's binding behaviour. MIPs and non-MIPs had similar steady-state fluorescence anisotropy in the range 0.11-0.24. Anthracene rebound in MIPs and non-MIPs had a fluorescence lifetime of tau = 0.64 ns and a rotational correlation time of phi(F) = 1.2-1.5 ns, both of which were shorter than that of MIPs with imprinted analytes present (tau = 2.03 ns and phi(F) = 2.7 ns). The steady-state anisotropy of polymer solutions increased exponentially with polymerization time and might be used to characterize the polymerization extent in situ.     

The fluorescent characterization of the polymerized microtubule-associated protein Tau

A new fluorescence formed while microtubule-associated protein tau was incubated at 25 and 37C for hours, with its maximum excitation at 230 and 280 nm, respectively. The fluorescence completely formed after tau was incubated in phosphate buffer and Tris-HCl buffer for approximately 20 h, with a relaxation phase about 2-4 h. The light scattering of the sample solution improved during formation of the fluorescence when tau was incubated. Both the fluorescence and tau oligomers did not form when tau was incubated in the buffers containing DTT. On the other hand, heparin improved both tau aggregation and the fluorescence formation. It suggests that the fluorescence comes from tau polymerization, which may follow the mechanism of tyrosine-tyrosinate emission for a protein not containing any tryptophan residues. This new fluorescence could be used as a probe to tau polymers.     

Differential Association of Tau With Subsets of Microtubules Containing Posttranslationally-Modified Tubulin Variants in Neuroblastoma Cells

Neuronal cells display different subsets of dynamic microtubules. In axons and extending neurites, this intrinsic dynamics is modulated by the microtubule-associated protein tau. Moreover, posttranslational modifications of tubulin, namely acetylation, tyrosination or glutamylation are directly involved in determining the stability of neuronal microtubules. Studies were carried out to analyze the interaction patterns of tau with subsets of microtubules in N2A neuroblastoma cells, which can differentiate in the presence of dibutyryl cAMP. Double labeling studies showed a differential pattern of tau association with microtubules containing acetylated and tyrosinated tubulin. Furthermore, studies using depolymerizing drugs revealed a selectivity in the association of tau with microtubular polymers and microfilaments, within the organization of the neuronal cytoskeleton. In order to study the association of specific tau isoforms with microtubules containing modified tubulin variants, immunoprecipitation studies were carried out. The coimmunoprecipitation data indicated a selective binding of specific tau isoforms to either modified tubulin variant. To assess the hypothesis on the roles of tau isoforms in the stabilization of microtubules containing modified tubulins, the association of those variants with tau isoforms was analyzed in overlay experiments. A preferential binding of acetylated tubulin from undifferentiated N2A cell extracts, to at least one slow-migrating tau isoform was revealed. However, acetylated tubulin from N2A cells containing long neurites displayed a preferential association with two isoforms of tau. On the other hand, tyrosinated tubulin from N2A extracts bound to the entire set of neuronal tau isoforms. These studies, along with the tau association with microtubules with different stability, indicate that tau segregates into subsets of microtubules in the axonal processes. The studies also suggest that these interactions may respond to a functional versatility of these polymers in differentiating neurons.     

Isoforms of tau protein from mammalian brain and avian erythrocytes: Structure, self-assembly, and elasticity

Previous studies on tau protein showed that the protein forms paracrystals which are unusually elastic. The paracrystals were obtained from a mixture of isoforms prepared from brain tissue, and the protein was in a mixed state of phosphorylation. Subsequently we showed that the structure and elasticity was related to the state of phosphorylation. However, this left open the possibility that the isotype composition played a role as well. We have now addressed this question by separating the individual isoforms and analyzing their structure. The paracrystals from all isoforms are similar to one another and to those of the native mixture; the same holds for the elasticity. Thus the tendency to self-associate, the apparent structure, and the elasticity are determined by those regions of tau which all isoforms have in common. In addition we compare tau paracrystals from three different sources. Apart from the porcine brain tau described earlier we have prepared paracrystals from bovine brain tau because its sequence is now known (Himmler et al., 1989). The structure and elasticity is indistinguishable from porcine tau. Second, we have prepared tau from avian erythrocytes where it is found in the membrane-associated marginal band microtubules ( Murphy and Wallis, 1985). Its isoform composition differs from mammalian brain tau, but again the structural properties are similar. A notable difference is that the shift in electrophoretic mobility induced by phosphorylation with CaM kinase, typical of all brain tau isotypes, is not found in the marginal band tau. Tau shows a strong tendency of longitudinal self-association which is apparent not only in the crystallization buffer but also in standard microtubule reassembly buffer. This leads to rod-like tau oligomers, fibers, and three-dimensional networks. This property, coupled with tau's elasticity, suggests a role in the organization of the cytoplasm beyond the stabilization of microtubules.     

The Endogenous and Cell Cycle-dependent Phosphorylation of tau Protein in Living Cells: Implications for Alzheimer’s Disease

In Alzheimer’s disease the neuronal microtubule-associated protein tau becomes highly phosphorylated, loses its binding properties, and aggregates into paired helical filaments. There is increasing evidence that the events leading to this hyperphosphorylation are related to mitotic mechanisms. Hence, we have analyzed the physiological phosphorylation of endogenous tau protein in metabolically labeled human neuroblastoma cells and in Chinese hamster ovary cells stably transfected with tau. In nonsynchronized cultures the phosphorylation pattern was remarkably similar in both cell lines, suggesting a similar balance of kinases and phosphatases with respect to tau. Using phosphopeptide mapping and sequencing we identified 17 phosphorylation sites comprising 80–90% of the total phosphate incorporated. Most of these are in SP or TP motifs, except S214 and S262. Since phosphorylation of microtubule-associated proteins increases during mitosis, concomitant with increased microtubule dynamics, we analyzed cells mitotically arrested with nocodazole. This revealed that S214 is a prominent phosphorylation site in metaphase, but not in interphase. Phosphorylation of this residue strongly decreases the tau–microtubule interaction in vitro, suppresses microtubule assembly, and may be a key factor in the observed detachment of tau from microtubules during mitosis. Since S214 is also phosphorylated in Alzheimer’s disease tau, our results support the view that reactivation of the cell cycle machinery is involved in tau hyperphosphorylation.     

The microtubule-associated protein tau forms a triple-stranded left-hand helical polymer

High resolution transmission electron microscopy (TEM) has shown that bovine tau are 2.1 +/- 0.2-nm diameter filaments which are triple-stranded left-hand helical structures composed of three 1.0 +/- 0.2-nm strands. The reported amino acid sequence of human and bovine tau have been computer processed to predict secondary structure. Within the constraints imposed by the images, the secondary structure models and other structural information have been used to calculate tau's maximum and minimum length. The length calculations and secondary structure form the basis for image interpretation. This work indicates that each approximately 1.0-nm strand is a tau polypeptide chain and that the approximately 2.1-nm filament is composed of three separate tau chains (tau3). Bovine tau length measurements indicate that tau trimer filaments are generally longer than a fully extended tau monomer. These measurements indicate that each trimer, tau3, is joined with other trimers to form long tau polymers, (tau3)n. An inverse temperature transition has been found in the circular dichroism spectrum of tau indicating that its structure is less ordered below 20 degrees C and more ordered at 37 degrees C. The implications of this phenomenon with respect to tau's temperature-dependent ability to reconstitute microtubules is discussed and a mechanism for the possible abnormal aggregation of tau into neurofibrillary tangles in Alzheimer's disease is proposed.     

Molecular cloning and functional characterization of chicken brain tau: isoforms with up to five tandem repeats

Tau is a major microtubule-associated protein in mammalian brain, where it exists as multiple isoforms that are produced from a single gene by alternative mRNA splicing. Here we present the first report on the structure and function of tau protein from a nonmammalian vertebrate. In the adult chicken brain, five main tau isoforms are expressed. One isoform has three tandem repeats, two isoforms have four repeats each, and two isoforms have five repeats each. Similar to mammalian tau, some chicken tau isoforms contain an amino-terminal insert of 53 amino acids. Unlike mammalian tau, a 34 amino acid insert in the proline-rich region upstream of the repeats is alternatively spliced in chicken tau. It is preceded by a constitutively expressed sequence of 17 amino acids that is absent in tau from human and rodent brains. The expression of chicken tau isoforms and their phosphorylation are developmentally regulated, similar to what has been described in mammalian brain. Functionally, chicken tau isoforms with five repeats have the greatest ability to promote microtubule assembly, followed by isoforms with four and three repeats, respectively. The 34 amino acid insert positively influences both the rate and the extent of microtubule assembly, whereas the 53 amino acid insert only influences the extent of assembly.