Developmental Changes in τ Phosphorylation: Fetal τ Is Transiently Phosphorylated in a Manner Similar to Paired Helical Filament-τ Characteristic of Alzheimer's Disease

Rat and human fetal brain τ were probed with a panel of monoclonal antibodies (tau-1, AT8, 8D8, RT97, SMI31, SMI34) that distinguish between paired helical filament (PHF)-τ of Alzheimer's disease and normal adult brain τ. These antibodies discriminate between normal and PHF-τ because their epitopes are phosphorylated in PHF-τ. Although only one molecular isoform of τ was shown to be expressed in fetal brain, two fetal τ species could be distinguished on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the slower migrating species was recognized by all of the PHF-τ-specific antibodies. Moreover, this immunoreactivity was shown to be phosphorylation dependent. Our observations suggest that the abnormal phosphorylation of τ in Alzheimer's disease may be the result of reactivation of pathways governing the phosphorylation of τ in the developing brain.     

Mechanism of neurofibrillary degeneration in Alzheimer's disease

Neurofibrillary degeneration associated with the formation of intraneuronal neurofibrillary tangles of paired helical filaments (PHF) and 2.1 nm τ filaments is one of the most characteristic brain lesions of Alzheimer's disease. The major polypeptides of PHF are the microtubule associated protein, τ. τ, in PHF is present in abnormally phosphorylated forms. In addition to the PHF, the abnormal τ is present in soluble non-PHF form in the alzheimer's disease brain. The level of τ in Alzheimer's disease neocortex is severalfold higher than in aged control brain, and this increase is in the form of the abnormally phosphorylated protein. The abnormally phosphorylated τ does not promote the assembly of tubulin into microtubules in vitro, and it inhibits the normal τ-stimulated microtubule assembly. After in vitro dephosphorylation both PHF and non-PHF abnormal τ stimulate the assembly of tubulin into microtubules. The activities of phosphoseryl/phosphothreonyl protein phosphatase 2A and nonreceptor phosphotyrosyl phosphatase(s) are decreased in AD brain. It is suggested that

1. A defect(s) in the protein phosphorylation/dephosphorylation system is one of the early events in the neurofibrillary pathology in AD;
2. A decrease in protein phosphatase, activities, at least in part, allows the hyperphosphorylation of τ; and
3. Abnormal phosphorylation and polymerization of τ into PHF most probably lead to a breakdown of the microtubule system and consequently to neuronal degeneration.

     

In vitro formation of different tubulin polymers from purified tubulin of Ehrlich ascites tumor cells

Preparations of cycled tubulin from Ehrlich ascites tumor cells contain several acessory proteins; once or twice cycled microtubule preparations are usually composed of fibers 10 nm in diameter, but lack vimentin. Highly purified tubulin consists of α- and β-tubulin and a minor component which was identified by peptide mapping as a second β-chain. This pure tubulin is able to form in vitro at low concentrations (1 mg protein/ml) fibers of about 10 nm width, and at higher concentrations (3.5 mg protein/ml) normal microtubules.     

Tubulin from cultured tobacco cells: isolation and identification based on similarities to brain tubulin

The microtubule protein, tubulin, was isolated from most other proteins of cell suspension cultures of Nicotiana tabacum L. by its copolymerization with cow-brain tubulin. Cow-brain tubulin was added to the soluble protein fraction of extract from ³⁵S-labeled tobacco cells and subjected to two cycles of temperature-dependent assembly-disassembly (copolymerization). When analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) about 70% of the radioactivity in the twice copolymerized protein was found in a prominent doublet migrating close to the doublet of brain tubulin. When analyzed by two-dimensional isoelectric-focusing-SDS-PAGE the radioactive doublet behaved like the doublet of brain tubulin. Limited proteolysis of the individual polypeptides of the coublets showed that, while the peptide maps of the leading radioactive band and of the β-subunit of brain tubulin were virtually indistinguishable, the maps of the trailing radioactive band and of the α-subunit of brain tubulin, though similar, were not identical. Most of the copolymerized ³⁵S-labeled protein also behaved like brain tubulin during gel filtration and ion-exchange chromatography. It is concluded that the doublet of radioactive polypeptides isolated by copolymerization with brain tubulin are tobacco tubulin polypeptides that have, in their native as well as denatured forms, properties very similar to, but not identical with, cow brain tubulin. Apparently, tubulin has been highly conserved during evolution.     

α2-Macroglobulin as a β-Amyloid Peptide-Binding Plasma Protein

Abstract: The β-amyloid peptide (Aβ) is a normal proteolytic processing product of the amyloid precursor protein, which is constitutively expressed by many, if not most, cells. For reasons that are still unclear, Aβ is deposited in an aggregated fibrillar form in both diffuse and senile plaques in the brains of patients with Alzheimer's disease (AD). The factor(s) responsible for the clearance of soluble Aβ from biological fluids or tissues are poorly understood. We now report that human α₂-macroglobulin (α₂M), a major circulating endoproteinase inhibitor, which has recently been shown to be present in senile plaques in AD, binds ¹²⁵I-Aβ_(1–42) with high affinity (apparent dissociation constant of 3.8 × 10^?10M). Approximately 1 mol of Aβ is bound per mole of α₂M. Both native and methylamine-activated α₂M bind ¹²⁵I-Aβ_(1–42). The binding of ¹²⁵I-Aβ_(1–42) to α₂M is enhanced by micromolar concentrations of Zn²⁺ (but not Ca²⁺) and is inhibited by noniodinated Aβ_(1–42) and Aβ_(1–40) but not by the reverse peptide Aβ_(40-1) or the cytokines interleukin 1β or interleukin 2. α₁-Antichymotrypsin, another plaque-associated protein, inhibits both the binding of ¹²⁵I-Aβ_(1–42) to α₂M as well as the degradation of ¹²⁵I-Aβ_(1–42) by proteinase-activated α₂M. Moreover, the binding of ¹²⁵I-Aβ_(1–42) to α₂M protects the peptide from proteolysis by exogenous trypsin. These data suggest that α₂M may function as a carrier protein for Aβ and could serve to either facilitate or impede clearance of Aβ from tissues such as the brain.     

Reduced dopamine-beta-hydroxylase activity in Alzheimer's disease

The activity of the noradrenergic marker enzyme dopamine-beta-hydroxylase was measured in brains removed postmortem from control patients and patients with Alzheimer''s disease. Enzyme activity was decreased in the frontal and temporal cortices and hippocampus in patients with Alzheimer''s disease, but was within the normal range in patients with depression, multiinfarct dementia, and terminal coma.The decrease in enzyme activity in Alzheimer''s disease may reflect an abnormality of cortical noradrenergic fibres in some patients with the disease.     

Identification of the major 68,000-dalton protein of microtubule preparations as a 10-nm filament protein and its effects on microtubule assembly in vitro.

The major 68,000-dalton protein present in cycled microtubule preparations from bovine brain can be isolated in a rapidly sedimenting fraction consisting of filaments 10 nm in diameter. This 68,000-dalton protein remains in the filament fraction after gel filtration, phosphocellulose chromatography, or salt extraction of microtubule protein. Microtubule protein devoid of 10-nm filaments contains ring structures under depolymerizing conditions, and it polymerizes into microtubules with a characteristically low critical concentration, although all of the 68,000-dalton protein has been removed from it. When cycled microtubule protein is subjected to chromatography on phosphocellulose, the tubulin fraction (PC-tubulin) assembles into microtubules only at concentrations greater than 2 mg/mL. The other fraction, eluted from phosphocellulose at high ionic strength, contains the major 68,000-dalton protein and can be further resolved into two components by centrifugation. The supernatant, which consists mainly of high molecular weight microtubule-associated proteins, stimulates low concentrations of PC-tubulin to assemble. The pellet contains all of the 68,000-dalton protein, consists of 10-nm filaments, and does not stimulate assembly of PC-tublin. Boiling of purified filaments, however, releases several proteins, including the 68,000-dalton protein, and these released proteins stimulate the assembly of PC-tubulin. The morphology and protein composition of the filaments isolated from microtubule preparations by these techniques are very similar to those of mammalian neurofilaments. These results suggest that the major 68,000-dalton protein in cycled microtubule preparations, which may correspond to tubulin assembly protein [Lockwood, A.H. (1978) Cell 13, 613--627], is a constituent of neurofilaments.     

Association of nucleosidediphosphate kinase with microtubules.

A nucleosidediphosphate kinase activity (EC 2.7.4.6) which phosphorylates GDP to GTP is present in bovine brain microtubule protein prepared by cycles of assembly-disassembly. This activity persists through 5 cycles of assembly-disassembly and sediments with microtubules in sucrose density gradients, but is not associated with the tubulin dimer. It is proposed that the kinase is an integral part of the microtubule and is therefore a microtubule associated protein (MAP). Several isozymes of nucleosidediphosphate kinase exist in our preparations with a pI 7.6 form predominant. It may be speculated that this enzyme affects tubulin assembly $\text{in vivo}$ by modulating the $\text{GTP}\text{GDP}$ ratio in the microtubule environment.     

Zinc-Induced Aggregation of Human and Rat β-Amyloid Peptides In Vitro

Abstract: The major pathological feature of Alzheimer's disease is the presence of a high density of amyloid plaques in the brain tissue of patients. The plaques are predominantly composed of human β-amyloid peptide (Aβ), a 39–43-mer peptide the neurotoxicity of which is related to its aggregation state. Previous work has demonstrated that certain metals that have been implicated as risk factors for Alzheimer's disease (Al, Fe, and Zn) also cause substantial aggregation of Aβ. In particular, we reported that zinc cations at concentrations of >10^?4M dramatically accelerate the rate of Aβ aggregation at physiological peptide concentrations at 37°C in vitro. In the present study, we investigate the effect of Zn²⁺ on aggregation of radiolabeled and unlabeled human and rat Aβ over a wide range of peptide concentrations in the presence and absence of salt and blocking protein. Aggregation was assayed by centrifugation and filtration using amino acid analysis, immunoassay, and γ-counting for quantification over a wide range of concentrations of Zn²⁺ and Aβ above and below physiological values. The results of this study demonstrate the following: (a) Radio-iodinated Aβ accurately tracked unlabeled Aβ, (b) zinc concentrations of at least 10^?4M were required to induce significant aggregation of Aβ, and (c) rat and human Aβ species were cleared from aqueous solutions by similar concentrations of zinc. These results stand in significant quantitative disagreement (～100-fold in zinc concentration) with one previous study that reported significant aggregation of Aβ by <1 µM Zn²⁺. Differences between the present study and the latter study from another laboratory appear to result from inappropriate reliance on optical density to measure Aβ concentrations and nonspecific loss of Aβ to plastic in the absence of blocking protein.     

A Thermodynamic Model of Microtubule Assembly and Disassembly

Microtubules are self-assembling polymers whose dynamics are essential for the normal function of cellular processes including chromosome separation and cytokinesis. Therefore understanding what factors effect microtubule growth is fundamental to our understanding of the control of microtubule based processes. An important factor that determines the status of a microtubule, whether it is growing or shrinking, is the length of the GTP tubulin microtubule cap. Here, we derive a Monte Carlo model of the assembly and disassembly of microtubules. We use thermodynamic laws to reduce the number of parameters of our model and, in particular, we take into account the contribution of water to the entropy of the system. We fit all parameters of the model from published experimental data using the GTP tubulin dimer attachment rate and the lateral and longitudinal binding energies of GTP and GDP tubulin dimers at both ends. Also we calculate and incorporate the GTP hydrolysis rate. We have applied our model and can mimic published experimental data, which formerly suggested a single layer GTP tubulin dimer microtubule cap, to show that these data demonstrate that the GTP cap can fluctuate and can be several microns long.     

Ca2+-Guanine Nucleotide Interactions in Brain Membranes. II. Characteristics of [3H]Guanosine Triphosphate and [3H]β, γ-Imidoguanosine 5'-Triphosphate Binding and Catabolism in the Rat Hippocampus and Striatum

Abstract: With [³H]guanosine triphosphate ([³H]GTP) and [³H]β, γ -imidoguanosine 5′-triphosphate ([³H]GppNHp) as the labelled substrates, both the binding and the catabolism of guanine nucleotides have been studied in various brain membrane preparations. Both labelled nucleotides bound to a single class of noninteracting sites (K_D= 0.1-0.5 μm ) in membranes from various brain regions (hippocampus, striatum, cerebral cortex). Unlabelled GTP, GppNHp, and guanosine diphosphate (GDP) but not guanosine monophosphate (GMP) and guanosine competitively inhibited the specific binding of [³H]guanine nucleotides. Calcium (0.1–5 mm ) partially prevented the binding of [³H]GTP and [³H]GppNHp to hippocampal and striatal membranes. This resulted from both an increased catabolism of [³H]GTP (into [³H]guanosine) and the likely formation of Ca-guanine nucleotide^2- complexes. The blockade of guanine nucleotide catabolism was responsible for the enhanced binding of [³H]GTP to hippocampal membranes in the presence of 0.1 mm -ATP or 0.1 mm -GMP. Striatal lesions with kainic acid produced both a 50% reduction of the number of specific guanine nucleotide binding sites and an acceleration of [³H]GTP and [³H]GppNHp catabolism (into [³H]guanosine) in membranes from the lesioned striatum. This suggests that guanine nucleotide binding sites were associated (at least in part) with intrinsic neurones whereas the catabolising enzyme(s) would be (mainly) located to glial cells (which proliferate after kainic acid lesion). The characteristics of the [³H]guanine nucleotide binding sites strongly suggest that they may correspond to the GTP subunits regulating neurotransmitter receptors including those labelled with [³H]5-hydroxytryptamine ([³H]5-HT) in the rat brain.     

In vitro study on the alterations of brain tubulin structure and assembly affected by magnetite nanoparticles

In recent decades, considerable efforts have been made to understand the mechanism of memory, cognition, and relevant neurodegenerative diseases in the human brain. Several studies have shown the importance of microtubule proteins in the memory mechanism and memory dysfunction. Microtubules possess dynamicity, which is essential for functions of neuronal networks. Microtubule-associated proteins, i.e., tau, play vital roles in microtubule stability. On the other hand, the ferromagnetic mineral magnetite (Fe₃O₄) has been detected in the normal human brain, and elevated levels of magnetite are also observed in the brains of Alzheimer’s disease patients. Therefore, we propose that a relationship between microtubule organization in axons and brain magnetite nanoparticles is possible. In this study we found alterations of microtubule polymerization in the presence of increasing concentrations of magnetite through transmission electron microscopy images and a turbidimetry method. Structural changes of microtubule and tau protein, as an essential microtubule-associated protein for tubulin assembly, were detected via circular dichroism spectroscopy, intrinsic fluorescence, and 8-anilino-1-naphthalenesulfonic acid fluorometry. We predicted three possible binding sites on tau protein and one possible binding site on tubulin dimer for magnetite nanoparticles. Magnetite also causes the morphology of PC12 cells to change abnormally and cell viability to decrease. Finally, we suggest that magnetite changes microtubule dynamics and polymerization through two paths: (1) changing the secondary and tertiary structure of tubulin and (2) binding to either tubulin dimer or tau protein and preventing tau–tubulin interaction.     

Calmodulin-binding proteins in brain

It is now widely accepted that actions of intracellular Ca²⁺ are mediated by a four-domain Ca²⁺-binding protein, calmodulin. Brain is especially rich in calmodulin, containing about 400 mg (24 μmol) of EGTA-extractable calmodulin per kg of brain. However, only a fraction of the above amount is required for the calmodulin-activated enzymes and most of the rest may be assigned to calmodulin-binding proteins, proteins which are apparently devoid of enzyme activities but undergo Ca²⁺-dependent associations with calmodulin. Several of such proteins have been recently discovered in brain. These include a heat-labile 80 K phosphodiesterase inhibitor protein (calcineurin), a heat-stable 70 K phosphodiesterase inhibitor protein, a 50 K protein, myelin basic protein, tubulin, microtubule τ (tau) factor, a spectrin-like doublet protein (240 plus 235 K) (calspectin; fodrin) and a particle-associated 155 K protein.Functions of these calmodulin-binding proteins have not been fully elucidated yet. Some proteins may be calmodulin-regulated enzymes catalyzing yet unknown biochemical reactions, e.g. a protein phosphatase activity was found for calcineurin. Some proteins may interact with contractile elements or cytoskeleton of the cell, e.g. τ factor and calspectin interacted with tubulin and F-actin, respectively and tubulin itself is a calmodulin-binding protein. So, interesting possibilities are the regulation of the functions of cytoskeleton by calmodulin through these calmodulin-binding proteins. Regulation of microtubule assembly by Ca²⁺-dependent binding of calmodulin to tubulin and/or τ factor and possible involvement of calspectin in the mechanism regulating axonal transport of neuronal proteins have been suggested. Thus, the exploration of the regulating functions of Ca²⁺/calmodulin in brain depends largely upon the further study of the properties of these calmodulin-binding proteins.     

Characterization of Postmortem Human Brain Proteins by Two-Dimensional Gel Electrophoresis

Abstract: The proteins of membrane and cytosol fractions from frozen human postmortem brain were analyzed by two-dimensional gel electrophoresis (isoelectric range: 5.1–6.0) and both Coomassie-blue and ammoniacal silver staining. Cytosol preparations were analyzed from six different postmortem brains from patients with various neurologic diagnoses and immediate causes of death. Intervals between death and brain freezing (−70^oC) ranged from 2 to 20 h. The vast majority of proteins detected in these cytosol fractions had identical molecular weights and isoelectric points in each of six human brains examined. However, in some tissue samples tubulin was either quantitatively decreased or undetectable. The possibility that this partial or complete depletion of tubulin was related to postmortem interval and/or brain freezing was studied using rat forebrain tissue. Rat brain incubated at room temperature for up to 24 h did not reproduce the changes seen in the region of human cytosol tubulin. However, other changes seen in the two-dimensional electrophoretic pattern of rat cytosol proteins did relate to postmortem interval, brain freezing, or both. Rough endoplasmic reticulum (RER) and smooth endoplasmic reticulum were prepared from three human brains, with highly reproducible two-dimensional patterns. Protein analysis of these membrane fractions revealed that human RER contained significant amounts of tubulin, in contrast to rat RER which contained no detectable tubulin. This discrepancy was elucidated by allowing rat brains to remain at room temperature for 24 h before freezing; gels of rat RER prepared from this tissue showed that tubulin subunits were present.     

Translation of beta-tubulin mRNA in vitro generates multiple molecular forms

We describe the in vitro expression and characterization of the isolated beta-tubulin subunit in rabbit reticulocyte lysates and compare its assembly and chromatographic properties with that of the isolated alpha-subunit and the tubulin heterodimer. The beta-tubulin polypeptides, derived from a single chicken beta-tubulin cDNA, were found in three distinct molecular forms: a multimeric or lysate-associated form, beta I (Mr approximately 180,000); the free beta-subunit beta II (Mr approximately 55,000); and the hybrid heterodimer alpha(rabbit) beta(chick), beta III (Mr approximately 80,000-100,000). The hybrid heterodimers were 100% assembly competent, whereas beta-tubulin in the "associated" beta I and the monomeric beta II forms displayed only approximately 70 +/- 15 and 25 +/- 10% competence, respectively, in coassembly assays with bovine brain tubulin. This reduced functionality was not a consequence of diminished beta-subunit stability or protein denaturation. By comparing the elution positions of the three beta forms, the monomeric alpha-subunit, and tubulin dimer purified from bovine brain, we demonstrate that anion-exchange columns (Mono-Q) interact preferentially with the alpha-subunit and chromatograph tubulin dimer on the basis of alpha-subunit isotype. The rate of exchange of the free beta-subunit into bovine tubulin dimer was followed chromatographically. The exchange was slow at 4 degrees C and rapid at 37 degrees C where it is essentially complete in 40 min in the presence of 2.5 mg/ml bovine microtubule protein. Exogenous GTP, a potent effector of microtubule assembly, binds exchangeably to beta II and enhances the recovery of this form from the Mono-Q column, suggesting that GTP binding may occur at identical sites in the isolated beta-subunit and in the tubulin heterodimer.     

Nine Residues Influence the Binding of α-Bungarotoxin in α-Subunit Region 185–200 of Human Muscle Acetylcholine Receptor

Abstract: Identification of residues in the skeletal muscle nicotinic acetylcholine receptor (AChR) that bind snake venom a-neurotoxin antagonists of acetylcholine [e.g., α-bungarotoxin (α-BTx)] provides structural information about the neurotransmitter binding region of the receptor. Using synthetic peptides of the human AChR α-subunit region 177–208, we previously localized a pharmacologically specific binding site for α-BTx in segment 185–199. To define in more detail the residues that influence the binding of α-BTx to this region, we prepared 16 peptide analogues of the α-subunit segment 185–200, with the amino acid Lalanine sequentially replacing each native amino acid. Circular dichroism spectroscopy did not reveal changes in the secondary structure of the peptides except for the analogue in which Pro¹⁹⁴ was substituted with alanine. This implies that any change in α-BTx binding could be attributed to replacement of the native residue's side chain by alanine's methyl group, rather than to a change in the structure of the peptide. The influence of each substitution with alanine was determined by comparing the analogue to the parental sequence α 185–200 in solution-phase competition with native human AChR for binding of ¹²⁵I-labeled α-BTx. The binding of α-BTx by analogue peptides with alanine substituted for Tyr¹⁹⁰, Cys¹⁹², or Cys¹⁹³ was greatly diminished. Binding of α-BTx to peptides containing alanine replacements at Val¹⁸⁸, Thr¹⁸⁹, Pro¹⁹⁴, Asp¹⁹⁵, or Tyr¹⁹⁸ was also reduced significantly (p < 0.003). An unanticipated finding was that substitution of alanine for Ser¹⁹¹ significantly increased α-BTx binding (p < 0.003). The data imply that these nine amino acids influence the binding of the antagonist, α-BTx, to the nicotinic acetylcholine receptor of human skeletal muscle, and confirm previous reports for certain contact residues for α-BTX that were found in region α181-200 of the Torpedo AChR.     

Regeneration of mirror symmetrical limbs in the axolotl

Measurements of tubulin exchange into and from bovine brain microtubules at steady state in vitro were made with 3H-GTP as a marker for tubulin addition to or loss from microtubules. Tubulin has an exchangeable GTP binding site that becomes nonexchangeable in the microtubule. We found that tubulin addition to and loss from microtubules under steady state conditions occurred at equivalent rates, that loss and gain were linear, and that exchange rates (percentage of total tubulin in microtubules lost or gained per hour) were dependent upon microtubule length. Furthermore, we found that podophyllotoxin blocked steady state assembly, but did not alter the rate of steady state tubulin loss. When the assembling microtubule end was pulsed with 3H-GTP at steady state, the label was almost completely retained during a subsequent chase. We conclude that the microtubule assembly-disassembly "equilibrium" is a steady state summation of two different reactions which occur at opposite ends of the microtubule, and that assembly and disassembly occur predominantly and perhaps exclusively at the opposite ends under steady state conditions in vitro.     

Amyloid β-Peptide Inhibits High-Affinity Choline Uptake and Acetylcholine Release in Rat Hippocampal Slices

Abstract: The characteristic pathological features of the postmortem brain of Alzheimer's disease (AD) patients include, among other features, the presence of neuritic plaques composed of amyloid β-peptide (Aβ) and the loss of basal forebrain cholinergic neurons, which innervate the hippocampus and the cortex. Studies of the pathological changes that characterize AD and several other lines of evidence indicate that Aβ accumulation in vivo may initiate and/or contribute to the process of neurodegeneration and thereby the development of AD. However, the mechanisms by which Aβ peptide influences/causes degeneration of the basal forebrain cholinergic neurons and/or the cognitive impairment characteristic of AD remain obscure. Using in vitro slice preparations, we have recently reported that Aβ-related peptides, under acute conditions, potently inhibit K⁺-evoked endogenous acetylcholine (ACh) release from hippocampus and cortex but not from striatum. In the present study, we have further characterized Aβ-mediated inhibition of ACh release and also measured the effects of these peptides on choline acetyltransferase (ChAT) activity and high-affinity choline uptake (HACU) in hippocampal, cortical, and striatal regions of the rat brain. Aβ_1–40 (10^?8M) potently inhibited veratridine-evoked endogenous ACh release from rat hippocampal slices and also decreased the K⁺-evoked release potentiated by the nitric oxide-generating agent, sodium nitroprusside (SNP). It is interesting that the endogenous cyclic GMP level induced by SNP was found to be unaltered in the presence of Aβ_1–40. The activity of the enzyme ChAT was not altered by Aβ peptides in hippocampus, cortex, or striatum. HACU was reduced significantly by various Aβ peptides (10^?14 to 10^?6M) in hippocampal and cortical synaptosomes. However, the uptake of choline by striatal synaptosomes was altered only at high concentration of Aβ (10^?6M). Taken together, these results indicate that Aβ peptides, under acute conditions, can decrease endogenous ACh release and the uptake of choline but exhibit no effect on ChAT activity. In addition, the evidence that Aβ peptides target primarily the hippocampus and cortex provides a potential mechanistic framework suggesting that the preferential vulnerability of basal forebrain cholinergic neurons and their projections in AD could relate, at least in part, to their sensitivity to Aβ peptides.     

An ATPase activity associated with brain microtubules.

A persistent ATPase/GTPase activity has been found to be associated with highly recycled bovine brain microtubules. A GTP regeneration system was introduced to minimize the inhibitory effects of this hydrolase on microtubule polymerization. The characteristics of the ATPase indicate that it is not involved in GTP-induced mictrotubule polymerization, but is directly involved in ATP-induced polymerization. ATP-induced polymerization was also shown to require stoichiometric amounts of GDP, but higher levels of GDP inhibited both microtubule formation and the ATPase activity. An ammonium sulfate fractionation procedure was devised to separate microtubule protein into an ATPase-rich fraction and a pure tubulin fraction. The pure tubulin fraction polymerized in the presence of GTP, but not in the presence of ATP and GDP. In contrast, the ATPase-rich fraction polymerized with either ATP or GTP. It is still not known whether the microtubule associated ATPase plays a significant role in cellular microtubule function.