Selective Destruction of Stable Microtubules and Axons by Inhibitors of Protein Serine/Threonine Phosphatases in Cultured Human Neurons (NT2N Cells)

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Volume 17, Number 15, Issue of August 1, 1997 pp. 5726-5737
Copyright ©1997 Society for Neuroscience

Selective Destruction of Stable Microtubules and Axons by Inhibitors of Protein Serine/Threonine Phosphatases in Cultured Human Neurons (NT2N Cells)

Sandra E. Merrick, John Q. Trojanowski, and Virginia M.-Y. Lee
Department of Pathology and Laboratory Medicine, The Center for Neurodegenerative Disease Research, The University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104-4283

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Paired helical filaments (PHFs) in the neurofibrillary tangles (NFTs) in Alzheimer's disease (AD) brains are composed of highlyphosphorylated isoforms of tau (PHFtau) that fail to bind microtubules(MTs), and the levels of MT-binding competent tau are decreasedin AD brains with abundant PHFtau. Because this loss of MT bindingcould compromise the viability of tangle-bearing AD neurons bydestabilizing MTs, we asked whether these events could be initiatedby inhibiting protein phosphatase 1 (PP1) and PP2A in culturedhuman neurons (NT2N cells) using okadaic acid (OK) and calyculin-A(CL-A). The treatment of NT2N cells with OK and CL-A increasedtau phosphorylation, decreased the binding of tau to MTs, andselectively depolymerized the more stable detyrosinated MTs butnot the more labile tyrosinated MTs. Significantly, this led tothe rapid degeneration of axons, which are enriched in the morestable detyrosinated MTs, and PP2A was implicated in the initiationof this cascade of events because PP2A but not PP1 was closelyassociated with MTs in the NT2N cells. These studies imply thatinactivation of PP2A in vulnerable neurons of the AD brain mayplay a mechanistic role in the conversion of normal tau into PHFtau,in the depolymerization of stable MTs, and in the degenerationof axons emanating from tangle-bearing neurons.
Key words: Alzheimer's disease; paired helical filaments; protein phosphatase 1; protein phosphatase 2A; tau; cytoskeleton

INTRODUCTION

Paired helical filaments (PHFs), the dominant structures in the neurofibrillary tangles (NFTs) in the Alzheimer's disease(AD) brain, are composed of hyperphosphorylated isoforms of tauknown as PHFtau (for recent reviews, see Lee and Trojanowski,1995; Trojanowski et al., 1996; Goedert et al., 1997). Tau isa microtubule (MT)-associated protein that binds to and stabilizesMTs in addition to promoting MT assembly (Weingarten et al., 1975;Drubin et al., 1986; Goode and Feinstein, 1994). The binding oftau to MTs is regulated by phosphorylation such that PHFtau bindspoorly to MTs (Lindwall and Cole, 1984; Bramblett et al., 1993;Drewes et al., 1995) and binds to MTs only after enzymatic dephosphorylation(Bramblett et al., 1993). Because the level of MT-binding competenttau is reduced in regions of the AD brain with abundant NFTs andPHFtau (Bramblett et al., 1992), this decrease may lead to thedepolymerization of MTs and may compromise neuronal viabilityin AD by disrupting axonal transport (Lee and Trojanowski, 1995;Trojanowski et al., 1996; Goedert et al., 1997).

Initially, the sites and the extent of the phosphorylation of PHFtau distinguished PHFtau from autopsy-derived normal adultbrain tau (Lee et al., 1991; Hasegawa et al., 1992; Goedert etal., 1993, 1994; Morishima-Kawashima et al., 1995). Although PHFtaucould be generated by overactive kinases, studies of biopsy-derivednormal brain tau implicated inactive phosphatases in the formationof PHFtau (Matsuo et al., 1994). Furthermore, most of the putative"abnormal" phosphorylation sites in PHFtau have been shown nowto be phosphorylated in rapidly processed normal rat and humanbrain tau (Matsuo et al., 1994; Mawal-Dewan et al., 1994). Thus,PHFtau seems to result from the excessive phosphorylation of normalphosphate acceptor residues in tau by overactive kinases and/orby hypoactive phosphatases. However, it is unknown whether thisimbalance of kinase and phosphatase activities has a direct effecton MT stability in neurons of the AD brain.

Previous studies have shown that MT functions require a dynamic equilibrium between polymerized and depolymerized MTs (Saxtonet al., 1984; Schulze et al., 1987; Webster et al., 1987b). Asubset of MTs exhibit long turnover rates (Webster et al., 1987a)and an increased resistance to MT-depolymerizing drugs (Khawajaet al., 1988). This more stable pool of MTs contains detyrosinated $alpha$ -tubulin (Glu-tubulin) that is generated posttranslationallyby the removal of the Tyr residue from the C terminus of the moredynamic form of $alpha$ -tubulin (Tyr-tubulin) (Gundersen and Bulinski,1988; Bulinski and Gundersen, 1991). Significantly, cultured postmitoticsympathetic neurons express much more Glu-MTs than rapidly dividingChinese hamster ovary cells express (50 vs 1-2%; Gundersen etal., 1984; Bass and Black, 1990), and axons contain a higher percentageof stable MTs than dendrites (58 vs 25%; Baas et al., 1991). However,the mechanisms that regulate the dynamic equilibrium between polymerizedand depolymerized MTs in neurons are incompletely understood,and it is unclear how an imbalance of kinases and phosphatasesleads to the formation of PHFtau, perturbs MTs, and contributesto the degeneration of neurons in AD.

Using cultured NT2N cells as an in vitro model of human neurons (Pleasure et al., 1992), we showed that the inhibition ofprotein phosphatases such as protein phosphatase 2A (PP2A) couldplay a mechanistic role in the conversion of normal tau into PHFtau,in the disruption of MTs, and in the degeneration of tangle-bearingneurons in AD.

MATERIALS AND METHODS
Cell culture. The NTera-2 (NT2) cells isolated from a human teratocarcinoma-derived embryonal carcinoma cell line (Andrewset al., 1984; Lee and Andrews, 1986) were grown and maintainedas described (Pleasure et al., 1992). NT2 cells were treated withretinoic acid for 5 weeks to induce differentiation into postmitoticneuron-like cells (NT2N cells) and then were replated at a densityof 8.0 × 10⁶ cells per 100 mm² dish coated with poly-D-lysine (10 µg/ml) and Matrigel (CollaborativeResearch, Bedford, MA). The NT2N cells were maintained in DMEMHG with 5% fetal bovine serum (FBS) and with penicillin/streptomycinwith mitotic inhibitors (1 µM cytosine arabinoside, 10 µM fluorodeoxyuridine,and 10 µM uridine) for 4-6 weeks or until ~95% of the cells acquiredthe phenotype of neurons (Pleasure et al., 1992; Pleasure andLee, 1993).

Phosphatase inhibitors. Phosphatase inhibitors were stored at $-$ 70°C in small aliquots as concentrated stock solutions dissolvedin 1% dimethylsulfoxide (DMSO). They included the following aliquots:500 µM okadaic acid (OK), 100 µM calyculin A (CL-A), and 500 µM1-norokadone, an inactive analog of OK (LC Labs, Woburn, MA).The properties of these reagents have been described in severalprevious reports (Bialojan and Takai, 1988; Cohen et al., 1989,1990; Ishihara et al., 1989; Gurland and Gundersen, 1993; Matsuoet al., 1994; Sontag et al., 1995, 1996; Merrick et al., 1996).

Isolation of tubulin and tau from NT2N cells. Total tubulin was extracted from NT2N cultures by scraping the cells in ice-coldreassembly (RA) buffer (0.1 2-[N-morpholino]ethanesulfonic acid,0.5 mM MgSO₄, 1 mM EGTA, and 2 mM dithiothreitol, pH 6.8) containinga mixture of protease inhibitors (2 mM phenylmethylsulfonyl fluoride,20 mM NaF, 0.5 mM sodium orthovanadate, and N-tosyl-L-phenylalaninechloromethyl ketone, N $alpha$ -p-tosyl-L-lysine chloromethyl ketone,leupeptin, pepstatin, and soybean trypsin inhibitor each at 10µg/ml). After incubation on ice for 10 min, the cells were sonicated,and the supernatants were collected after centrifugation at 100,000× g for 20 min at 4°C.

Soluble tubulin and insoluble MT polymers were obtained by scraping the cultures in 1 ml of 37°C MT stabilization buffer,i.e., RA buffer containing 2 mM GTP and 20 µM taxol to stabilizeMTs (Schiff et al., 1979; Vallee, 1982) plus 0.1% (v/v) TritonX-100, 2 mM dithiothreitol, and a mixture of protease and phosphataseinhibitors. Taxol was a gift from Dr. V. Narayanan (Drug Synthesisand Chemistry Branch, Division of Cancer Treatment, National CancerInstitute). This scraped culture material was then homogenizedin a glass homogenizer and centrifuged at 100,000 × g for 20 minat 30°C, generating a supernatant fraction containing solubletubulin and a pellet fraction containing MT polymers.

In a similar manner, tau bound to pelleted MTs was separated from unbound tau that partitioned in the supernatant with solubletubulin. Cultures were scraped into MT stabilization buffer, homogenized,and centrifuged as described above. The supernatant was boiledfor 10 min; the pellet was resuspended in ice-cold RA buffer containing0.75 M NaCl, was sonicated to release the bound tau from the MTs,and then was boiled for 10 min. After both fractions were boiled,the samples were centrifuged again to generate heat-stable tau-enrichedsamples that were then concentrated by centrifugation throughAmicon Microcon-10 spin columns. Finally, fetal human brain tauwas used as a control sample in some of the studies of tau fromthe NT2N cells, and these fetal tau proteins were isolated fromautopsy-derived prenatal human brains as described (Bramblettet al., 1992).

Western blot analysis. Protein samples were separated by SDS-PAGE and then electroblotted onto nitrocellulose membranes forWestern blot studies. Antibody binding was quantified using ¹²⁵I-labeled goat anti-mouse IgG for mouse monoclonal antibodies(mAbs) and ¹²⁵I-labeled protein A for rabbit polyclonal antisera (Bramblettet al., 1992; Matsuo et al., 1994; Mawal-Dewan et al., 1994) andthen exposing the nitrocellulose membranes to PhosphorImager plates.Quantification was performed with the IMAGEQUANT software providedwith the PhosphorImager (Molecular Dynamics, Sunnyvale, CA), andthese experiments were repeated at least three times. Proteinanalysis was performed using Coomassie blue as a dye reagent withbovine serum albumin as the standard (Pierce, Rockford, IL). Fornonquantitative immunoblotting, antibody binding was detectedwith the peroxidase-anti-peroxidase method using diaminobenzadineas a substrate (Lee et al., 1991) or with Enhanced Chemiluminescence(DuPont NEN).

Antibodies. The anti-tubulin antibodies used were anti-Glu-tubulin antisera, which was a gift from Drs. C. Bulinski and G.Gundersen (Columbia University) (Gundersen et al., 1984); theanti-Tyr-tubulin antibody known as TUB-1A2 (Kreis, 1987) and theanti-acetylated tubulin antibody known as 6-11b-1 (Piperno andFuller, 1985; Piperno et al., 1987), which were purchased fromSigma (St. Louis, MO); the anti- $alpha$ -tubulin and anti- $beta$ -tubulin mAbs(Blose et al., 1984), which were purchased from Amersham (Boston,MA); and the anti-Tyr-tubulin antibody known as YL1/2 (Kilmartinet al., 1982), which was purchased from Accurate Chemicals (Westbury,NY). Two phosphate-independent anti-tau mAbs used were T14 andT46 (Kosik et al., 1988; Trojanowski et al., 1989), one of which(T46) recognizes an epitope located at the C terminus of tau thatis shared by the microtubule-associated protein (MAP) known asMAP2c (Kosik et al., 1988; Ksiezak-Reding et al., 1990). Two phosphate-dependentanti-tau antibodies that recognize PHFtau also used were the T3Pantiserum (Lee et al., 1991) and the PHF1 mAb, which was kindlyprovided by Dr. P. Davies (Albert Einstein College of Medicine)(Greenberg et al., 1992; Otvos et al., 1994). Other antibodiesused here were the mAb AP14 (Geisert et al., 1990), which is specificfor MAP2 and was donated by Dr. L. Binder; the mAb HO14 (Pleasureet al., 1990), which is specific for highly phosphorylated formsof the midsize neurofilament (NF-M) subunit; the mAb 9-1E10, whichis specific for the growth-associated protein (GAP) known as GAP-43(Goslin and Banker, 1990); an anti-PP2A antibody to the catalyticsubunit of PP2A, which was a gift from Dr. B. Hemmings (MiesscherInstitute, Basel, Switzerland); and an antiserum to the catalyticsubunit of protein phosphatase 1 (PP1), which was purchased fromUpstate Biotechnology (Lake Placid, NY).

Indirect immunofluorescence. For the immunofluorescence studies, NT2N cells were grown on glass coverslips (25 mm in circumference)using the method described by Goslin and Banker (1991) with minorchanges. NT2N cells that were plated on glass coverslips (at adensity of ~0.2 × 10⁶ cells per coverslip) were cocultured with a feeder layer of NT2cells that were plated on the bottom of the well. Three dropsof paraffin were placed at the outer edge of each coverslip (coatedpreviously with poly-D-lysine and Matrigel) to support the coverslipswith the NT2N cells above the feeder layer of NT2 cells at thebottom of the wells during coculture. The NT2N cells were maintainedin culture as described above for 3-4 weeks to allow the establishmentof polarity as monitored by the segregation of MAP2 to the somatodendriticcompartment and of highly phosphorylated NF-M to the axon usingimmunofluorescence methods (Pleasure et al., 1992; Bramblett etal., 1993). Immunofluorescence was performed on cultures thatwere washed with PBS and fixed according to one of two protocols.In the first procedure, cells were fixed with methanol at $-$ 20°Cfor 10 min, allowed to dry at room temperature, and rehydratedin PBS. In the second procedure, cells were fixed with 2% paraformaldehydeand 0.05% gluteraldehyde in PHEM buffer (60 mM 1,4-piperazinediethanesulfonicacid, 20 mM HEPES, 10 mM EGTA, and 1 mM MgSO₄) (Bramblett et al.,1993), rinsed with PBS, extracted with 0.1% Triton X-100 in PHEMbuffer, washed with PBS, rinsed with 0.15 M glycine, pH 7.4, toquench the gluteraldehyde autofluorescence, and washed with PBS.The cultures were then incubated overnight at 4°C with a primaryantibody, and bound antibody was detected with a secondary antibody(donkey anti-mouse, anti-rabbit, or anti-rat) coupled to FITCor to Texas Red (Jackson ImmunoResearch, West Grove, PA).

Transmission and immunoelectron microscopy. Cultures of NT2N cells were either untreated or treated with 50 nM CL-A for 5,15, and 60 min and were prepared for transmission electron microscopy(EM) and immuno-EM as described (Baas and Black, 1990; Baas etal., 1991; Lee et al. 1991). Cultured NT2N cells were washed withPBS at 37°C and were fixed for 1 hr at 37°C in 0.1 M cacodylatebuffer, pH 7.0, containing 2% gluteraldehyde and tannic acid at2 mg/ml. The cultures were rinsed three times with 0.1 M cacodylatebuffer, post-fixed for 30 min in 1% osmium tetroxide, rinsed oncein 0.1 M cacodylate buffer, rinsed three times in 0.05 M maleatebuffer, pH 5.2, stained for 10 min in 1% uranyl acetate in 0.05M maleate buffer, pH 6.0, rinsed three times with 0.05 M maleatebuffer, pH 5.2, dehydrated in an ascending series of ethanols,and embedded in Epon. Embedded samples were stained for 60 minat 60°C with 1% toluidine blue in 1% borax (Baas and Black, 1990)to visualize the axons and to ensure that thin sections were takenfrom areas enriched for axons as confirmed by phase-contrast photosof the trimmed block before sectioning. Thin sections cut parallelto the substratum were stained with uranyl acetate and lead citrate.For the immuno-EM studies, CL-A-treated and untreated NT2N cellswere fixed, extracted with detergent, and incubated with primaryantibodies exactly as described above for indirect immunofluorescence.The bound primary antibody was visualized with a goat anti-rabbitor anti-rat IgG secondary antibody conjugated to 5 nm gold particles(Amersham). The sections were then viewed with a Hitachi H-600electron microscope (Nissei Sangyo America, Gaithersburg, MD).

Studies of the association of PP1 and PP2A with MTs. These studies were performed using rat brain- and NT2N cell-derived MTs.Rat brain MTs were obtained by homogenizing fresh adult rat brainin two volumes of ice-cold RA buffer plus protease inhibitorsin a glass homogenizer and by centrifuging at 10,000 × g for 20min at 4°C. The supernatant was decanted and centrifuged againat 100,000 × g for 60 min at 4°C. The resulting supernatant wasincubated in the presence of 1 mM GTP and 20 µM taxol at 37°Cfor 20 min to promote the assembly of MT polymers. MTs were thenpelleted through a 5% sucrose cushion at 30,000 × g for 30 minat 30°C, and protein concentrations were determined as describedabove. Supernatant and MT pellet fractions were then analyzedfor the presence of MT-associated PP2A and PP1 by Western blottingas described above.

MTs from NT2N cells were obtained by scraping cells from 10-15 100 mm² dishes into 0.5-1.0 ml of ice-cold PHEM buffer plus 0.2% TritonX-100 and protease inhibitors and by homogenizing. The sampleswere centrifuged at 100,000 × g for 60 min at 4°C. The resultinghigh-speed supernatant was incubated with GTP and taxol as describedabove, and the MTs were pelleted by centrifugation as describedabove.

Presentation of results from studies performed using CL-A and OK. In the studies described below, similar or nearly identicalresults were obtained after treatment of the NT2N cells with CL-Aand OK. Hence, for simplicity, only the results obtained witheither CL-A or OK are described in each of the following sections,and in most of the experiments summarized, the results obtainedwith CL-A are described in detail.

RESULTS

Inhibitors of PP2A and PP1 increase tau phosphorylation and decrease the binding of tau to MTs in NT2N cells
To determine the effects of inhibitors of PP2A and PP1 on tau phosphorylation and on the binding of tau to MTs, we treatedNT2N cells with 50 nM CL-A for varying lengths of time. Not surprisingly,low concentrations of CL-A resulted in increased tau phosphorylationas indicated by a retardation in the electrophoretic mobilityof tau (Fig. 1A, compare lane 0S with lanes 15S and 30S) and byan increase in the immunoreactivity of tau detected by phosphorylation-dependentantibodies such as T3P and PHF1 (data not shown) as well as byother phosphorylation-dependent antibodies to PHFtau (Merricket al., 1996). In addition, the binding affinity of tau for MTsprogressively decreased (Fig. 1A, compare S and P lanes) afterlonger exposure to CL-A. Indeed, quantitative immunoblot analysisrevealed that ~40% of tau was recovered in the soluble fractionin control cultures, whereas after 15 min of treatment with CL-A,~90% of the tau protein is located in the soluble fraction (Fig.1A,B). Because similar results were obtained with OK, these dataindicate that treatment of NT2N cells with inhibitors of PP2Aand PP1 increases the phosphorylation state of tau and decreasesthe binding of tau to MTs.
Fig. 1. A, Effects of CL-A on tau phosphorylation and on MT binding in NT2N cells. NT2N neurons were treated with 50 nM CL-A for thetimes (in minutes) indicated below each lane and were processedto detect unbound tau in the supernatant (S) and tau bound toMTs in the pellet (P). S and P fractions of treated and untreatedNT2N cells were analyzed in Western blots using a mixture of twoanti-tau (T14, T46) mAbs. B, Tau distribution between supernatants(Sup) and pellets. The levels of tau in the supernatants and pelletswere quantified, and the values are expressed as the percentageof the total tau level for each time point. Data represent mean± SEM (n = 5).
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Preferential destruction of axons in NT2N neurons treated with phosphatase inhibitors
During the course of treatment of NT2N neurons with CL-A, we noted that a subset of neuronal processes were rapidly and selectivelydestroyed. Because NT2N cells develop a large number of polarizedprocesses that exhibit the morphological and molecular propertiesof either axons or dendrites (Pleasure et al., 1992), we soughtto determine whether axons or dendrites were selectively vulnerableto CL-A-induced degeneration. To do this, we used data from previousstudies showing that the somatodendritic domain of neurons isrich in MAP2 (Bernhardt and Matus, 1984; Pleasure et al., 1992),whereas axons are rich in highly phosphorylated neurofilamentproteins (Pleasure et al., 1992). Thus, we performed single anddouble label indirect immunofluorescence studies using the AP14mAb to MAP2 and the HO14 mAb to highly phosphorylated NF-M todemonstrate that the NT2N cells extended highly polarized dendritesand axons, respectively (Fig. 2A1,A2). When similar studies wereperformed on the NT2N cells treated with CL-A, HO14 mAb confirmedthat axons rapidly degenerated (Fig. 2A3). Although the numberof MAP2-positive dendrites seemed to diminish, many remained smoothand undisrupted (Fig. 2A4).
Fig. 2. Double-label immunofluorescence of CL-A-treated NT2N cells. Pairs of antibodies were used to double-label untreated (A1, A2,B1, B2) and CL-A-treated (50 nM for 60 min; A3, A4, B3, B4) cultures.Cultures were double-labeled with HO14 mAb to highly phosphorylatedNF-M in axons (A1, A3) and with AP14 mAb to MAP2 in perikaryaand dendrites (A2, A4). Arrows point to axons, whereas arrowheadsidentify dendrites. Note that all axons are destroyed in treatedcultures, whereas some dendrites remain intact. Similar cultureswere stained with HO14 mAb (B1, B3) and with 9-1E10 mAb, whichrecognizes GAP-43 (B2, B4). Again, note the preferential degenerationof axons. Scale bar, 100 µm.
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To confirm and extend these observations, we double labeled the NT2N cells before and after treatment with CL-A using HO14mAb and an antibody to GAP-43, a protein that is expressed inaxons during periods of active growth and is found in associationwith vesicular transport. In untreated cells, the anti-GAP-43antibody stained axons like the HO14 mAb but displayed a punctatepattern of immunoreactivity [compare HO14 staining (Fig. 2B1)with GAP-43 staining (Fig. 2B2)]. However, after treatment withCL-A, both the HO14 and GAP-43 positive axons of the NT2N cellsrapidly degenerated (Fig. 2B3,B4).

Phosphatase inhibitors decrease Glu-tubulin levels and increase Tyr-tubulin levels in NT2N cells
We examined phosphatase inhibitor-induced changes in the different posttranslationally modified forms of MTs by treating NT2Ncultures with 100 nM OK for up to 4 hr. These studies showed thatthe levels of Glu-tubulin and acetylated-tubulin (Ac-tubulin)in the more stable pool of MTs were dramatically reduced withprogressively longer treatment times (Fig. 3A,C, compare lane1 with lane 5). Quantitative analysis of Western blots revealedthat after 4 hr of treatment, Glu-tubulin immunoreactivity wasonly 20% relative to untreated cultures, indicating that the levelof stable MTs had been reduced by 80%. The levels of Tyr-tubulinconcomitantly increased (Fig. 3B, compare lane 1 with lanes 4and 5) by 55% after 4 hr of treatment. However, we cannot directlycompare the changes detected by one antibody with the changesobserved for the other because of the different affinities ofthese antibodies. Because acetylation is another posttranslationalmodification of $alpha$ -tubulin that correlates with the stabilizationof MTs, it was not surprising that OK treatment of the NT2N cellsfor 4 hr resulted in a 40% decrease in Ac-tubulin levels (Fig.3C). Because the levels of tubulin did not change in these experiments(as monitored with the anti- $beta$ -tubulin antibody), it is unlikelythat tubulin synthesis and turnover were altered significantlyby OK treatment (Fig. 3D). To validate the effects of OK further,we treated NT2N cultures with 1-norokadone, an inactive analogof OK, but this analog did not reduce the levels of Glu-tubulinin the NT2N cells. Taken together, these findings indicate thatinhibitors of PP2A and PP1 induce a decrease in the pool of stableMTs followed by a rapid retyrosination of Glu-tubulin resultingin an increase in the more labile Tyr-tubulin.
Fig. 3. The time course of the effects of OK treatment on Glu- and Tyr-tubulin levels in NT2N neurons. NT2N cultures were treatedwith 100 nM OK for up to 4 hr and analyzed by quantitative Westernblotting using antibodies specific for modified $alpha$ -tubulin: A,Glu-tubulin; B, Tyr-tubulin; C, Ac-tubulin; D, $beta$ -tubulin. OK decreasedGlu- and Ac-tubulin levels and increased Tyr-tubulin levels. Notethat the $beta$ -tubulin immunoreactivity is constant indicating thattotal tubulin levels are unaffected. Values for each time pointwere calculated as the percentage of untreated cultures and illustratedin the bar graphs below each set of Western blots. Data representmean ± SEM (n = 4; asterisks indicate significance, *p < 0.005and **p < 0.05; Student's t test, independent pairs).
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Phosphatase inhibitors depolymerize Glu-MTs but not Tyr-MTs
To determine whether the reduction in Glu-tubulin levels was caused by a selective reduction in Glu-MTs, we treated NT2N cellswith CL-A and processed the cultures to analyze soluble and insolublecytoskeletal proteins in the NT2N cells and to monitor changesin the distribution of tubulin between protomers and MT polymers.Inhibition of protein phosphatases resulted in decreased Glu-MTsin the insoluble cytoskeletal fraction, consistent with a breakdownor disassembly of the stable pool of MTs (Fig. 4A, compare lanes1 and 2 with lanes 11 and 12). Furthermore, quantitative analysisindicated that in untreated cultures 86% of Glu-tubulin was presentas Glu-MTs and that after 4 hr of treatment with CL-A only 34%of Glu-MTs remained in the insoluble cytoskeletal fraction (Fig.4E,G). Notably, this decrease in Glu-MTs is not compensated forby an increase in the soluble Glu-tubulin. Instead, there is adecrease in soluble Glu-tubulin, and this indicates that whenGlu-MTs depolymerize, the Glu-tubulin released from these polymersis rapidly retyrosinated (see below and Fig. 4B). Thus, thesedata suggest that inhibition of PP1 and PP2A induces a depolymerizationof stable Glu-MTs and that the tubulin subunits released fromthese polymers quickly undergo retyrosination.
Fig. 4. Effect of CL-A treatment on MT polymer levels in NT2N cells. NT2N cultures were treated with 50 nM CL-A for up to 4 hr, processedfor soluble tubulin (S) and MT polymers (P), and analyzed by quantitativeWestern blotting: A, Glu-tubulin; B, Tyr-tubulin; C, Ac-tubulin;D, $alpha$ -tubulin. E, F, Bar graphs demonstrating the loss of stableGlu-MTs and the decrease of $alpha$ -MTs, respectively, from the pellets(P) after treatment of NT2N cells with CL-A for the indicatedtimes. The decrease in MTs was calculated as the amount of tubulinimmunoreactivity in the pellet divided by total tubulin immunoreactivityin untreated NT2N cells. G, Bar graph showing the soluble tubulinremaining in the supernatant (S) and the MT polymers recoveredin the pellets (P) for Glu-tubulin, Tyr-tubulin, Ac- tubulin,and $alpha$ -tubulin in untreated cultures and cultures treated withCL-A for 4 hr. Data represent mean ± SEM (n = 4; asterisks inbar graphs indicate significance, *p < 0.005; Student's t test,independent pairs).
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Consistent with this view, Figure 4B shows that Tyr-tubulin immunoreactivity increases in the supernatant fractions (Fig.4B, compare lane 1 with lanes 9 and 11) of CL-A-treated NT2N cells,and that the Tyr-tubulin immunoreactivity in the pellet fractionremains approximately the same for each time point (Fig. 4B, comparelane 2 with lanes 10 and 12). Furthermore, quantitative analysisshowed that in control cultures 60% of Tyr-tubulin was solubleand 40% was polymerized into MTs (Fig. 4B). However, after 4 hrof CL-A treatment, total Tyr-tubulin immunoreactivity (Fig. 4B,S plus P) is increased, as reflected by a dramatic increase (~193%)in soluble Tyr-tubulin monomers (Fig. 4G). Significantly, thereis no change in Tyr-MTs in the pellet fraction.

Because OK and CL-A treatment leads to the selective disassembly of stable MTs in the NT2N cells, this should result in adecrease in the levels of total $alpha$ -tubulin-containing MTs in thepellet fraction with a concomitant increase in $alpha$ -tubulin in thesoluble fraction, and this is illustrated in Figure 4D (comparelane 2 with lanes 10 and 12 and lane 1 with lanes 9 and 11). Thepercentage of $alpha$ -tubulin-containing MTs decreased from 80% forcontrol cultures to 20% for cultures treated with CL-A for 4 hr(Fig. 4F,G). However, the total signal of the soluble plus thecytoskeletal fractions for each time point showed no significantchange, indicating that, as the amount of MTs in the pellet decreases,the soluble fraction of tubulin protomers increases, which isconsistent with the notion that the decrease in MT polymer wasnot caused by the degradation of tubulin (also see Fig. 3D). Significantly,the effect of CL-A on Glu-tubulin and tau seems to follow a similartime course (Figs. 1, 4). Finally, if the inhibition of phosphatasesinduces the depolymerization of stable MTs, then the levels ofAc-tubulin (which also serves as a marker of stable MTs) shoulddecrease as a result of CL-A treatment, and this finding is demonstratedin Figure 4C (compare lane 2 with lanes 10 and 12). Because noAc-tubulin is detected in the soluble fractions, deacetylationmust be very rapid.

Taken together, these data indicate that inhibition of PP1 and PP2A results in the depolymerization of MTs and that this depolymerizationis selective for the more stable pool of MTs. Furthermore, thesedata also suggest that the tubulin subunits released from theCL-A-induced depolymerization of Glu-MTs are rapidly retyrosinatedand/or deacetylated, and that the rate-limiting step in this processis the depolymerization of the more stable MTs that are rich inGlu-tubulin.

Phosphatase inhibitors induce rapid and selective destruction of axonal MTs
To investigate the ultrastructural effects of phosphatase inhibitors on the NT2N cells, we used transmission EM to study CL-A-treatedNT2N cells. To do this, we focused our EM studies on areas ofthe cultures that were the farthest away from cell body clumpsin which axons are most abundant (Pleasure et al., 1992) (Fig.2). The axons of untreated NT2N cells contained many long, uninterruptedMTs that were oriented parallel to the axolemma (Fig. 5A,B). However,after 5 min of treatment with CL-A, short fragments of MTs appearedthat were oriented at various angles to the long axis of the axon,but the axolemma seemed to remain intact (Fig. 5C). Longer treatmentwith CL-A resulted in the degeneration of many of the axons. However,in those axons remaining, we observed an increase in the abundanceof short MT fragments, a reduction in the number of intact MTs,and accumulations of amorphous material in the axoplasm (Fig.5D). Thus, these data are consistent with the view that CL-A inducesthe breakdown of axonal Glu-rich MTs and that this breakdown mayaccount for the preferential destruction of axons by CL-A describedabove.
Fig. 5. Electron micrographs of axonal MTs treated with CL-A. NT2N cultures were treated with 50 nM CL-A for 0 min (A, B), 5 min (C),or 60 min (D) and analyzed by EM. Control cultures contain long,continuous MTs (arrows) of uniform orientation, and treated culturescontain many short MT fragments (arrowheads) oriented at variousangles to the long axis of the axon. Scale bar, 100 nm.
[View Larger Version of this Image (95K GIF file)]

Phosphatase inhibitors reduce the abundance of Glu-MTs in axons
To explore the basis of this axonal pathology in greater detail, we undertook immuno-EM studies to determine whether Glu-MTsin the axons of NT2N cells were affected by CL-A treatment. Inuntreated cultures, immunoreactive Glu-MTs were far more numerousthan Tyr-MTs in axons (Fig. 6A,B), whereas the abundance of Glu-MTsand Tyr-MTs was similar in cell bodies (Fig. 6E,F) and dendrites(data not shown). Varying the concentrations of the primary antibodiesto Glu-tubulin and to Tyr-tubulin did not alter the distributionof the labeled MTs in axons. Specifically, the relative abundanceof Glu-MTs remained far greater than that of Tyr-MTs (data notshown), and we never observed Glu-MT-rich segments existing incontinuity with Tyr-MT-rich segments in individual MTs. Instead,immunogold particles demonstrated Glu-MTs over the entire lengthof individual MTs within the main shaft of axons. After treatmentof the NT2N cells with CL-A, there was a reduction in the totalnumber of axonal MTs, especially Glu-MTs, the most abundant poolof MTs in these axons (Fig. 6, compare A,B with C,D). Given thesimilar abundance of Glu-MTs and Tyr-MTs in cell bodies and dendrites,the loss of Glu-MTs is not as apparent in cell bodies (Fig. 6,compare E,F with G,H). Thus, the selective degeneration of axonsafter treatment with CL-A may reflect the greater abundance ofGlu-MTs in the axons of the NT2N cells.
Fig. 6. Immuno-EM of axonal and perikarya Glu-MTs and Tyr-MTs after treatment with CL-A. NT2N cells were treated with 50 nM CL-A for0 min (A, B, E, F) or for 15 min (C, D, G, H). A, C, E, G, Cellsfirst immunolabeled with the anti-Glu-tubulin antibody and thenwith 5 nm gold-conjugated goat anti-rabbit IgG. B, D, F, H, Cellsfirst incubated with the anti-Tyr-tubulin antibody and then with5 nm gold-conjugated rabbit anti-rat IgG. AX( $-$ ) and AX(+) denoteimmunolabeling of untreated and CL-A-treated axonal MTs, whereasCB( $-$ ) and CB(+) represent immunolabeling of untreated and CL-A-treatedMTs in neuronal perikarya. Scale bar, 100 nm.
[View Larger Version of this Image (132K GIF file)]

PP2A is associated with MTs in the NT2N cells
Because CL-A and OK inhibit both PP1 and PP2A, we sought to determine which of these enzymes might be responsible for thedecrease in Glu-MT levels described above by determining whetherone or both of these phosphatases was closely associated withMTs in the NT2N cells. To address this question, we incubatedhigh-speed supernatants from rat brain homogenates and from NT2Ncells with taxol at 37°C, and the MTs were pelleted by centrifugation.Consistent with the results of Sontag et al. (1995), we detectedPP2A in association with pelleted MTs (Fig. 7A,C), whereas PP1was recovered only in the soluble fraction (Fig. 7B,D). Thus,these observations suggest that the inhibition of PP2A by thephosphatase inhibitors used here accounts for the alterationsin tau and MTs described above.
Fig. 7. Association of PP2A but not PP1 with MTs. MTs were reassembled from either rat brain homogenates or homogenates of NT2N cells,and the association of PP1 and PP2A with MTs was examined by immunoblottingusing antibodies to the catalytic subunit of PP2A (A, C) or ofPP1 (B, D). In A-D, lane 1 contains soluble protein (S), and lane2 contains MT-associated proteins after taxol-driven polymerization(P). Lane 3 in A and B and lane 4 in C and D contain total (Tot)rat brain homogenates. Lane 3 in C contains purified recombinantPP2A catalytic subunits and in D contains rabbit muscle lysatesenriched in PP1 as standards (Std). Note that a fraction of thePP2A catalytic subunit associates with MTs, whereas PP1 catalyticsubunits are recovered only in the soluble fraction. Molecularweight markers (in kDa) are indicated on the right. The lanesin A were loaded with 20 µg of protein, and the lanes in B andD were loaded with 100 µg. Finally in C, lane 1 = 25 µg, lane2 = 50 µg, lane 3 = 0.5 µg, and lane 4 = 20 µg.
[View Larger Version of this Image (25K GIF file)]

DISCUSSION
In the studies reported here, we show that inhibition of PP1 and PP2A in cultured human neuron-like NT2N cells by OK and CL-Aresults in (1) the hyperphosphorylation of tau, (2) the decreasedbinding of tau to MTs, (3) the selective depolymerization of themore stable Glu-MTs, especially in axons, and (4) the rapid degenerationof axons. Furthermore, we also show that axons of NT2N cells containmore Glu-MTs than cell bodies and dendrites, which suggests thatthe abundance of Glu-MTs in axons may render these processes morevulnerable to rapid degeneration after treatment with OK and CL-A.However, we cannot rule out the possibility that phosphatase inhibitorsmay have a direct effect on axons. Although the precise sequenceof events leading to these abnormalities remains to be elucidated,the demonstration here that PP2A (but not PP1) is closely associatedwith MTs in the NT2N cells leads us to infer that OK and CL-Ainduce the alterations described above by inhibiting a pool ofMT-associated PP2A. Although the relevance of these findings toAD must be explored further, our data are consistent with growingevidence implicating the inactivation of PP2A in the formationof NFTs and in the degeneration of neurons in the AD brain (Goedertet al., 1992; Matsuo et al., 1994; Sontag et al., 1995, 1996).

The selective destruction of Glu-MTs (but not Tyr-MTs) in NT2N cells by OK or CL-A is in agreement with a previously publishedreport demonstrating a complete breakdown of Glu-MTs in fibroblastsand in epithelial cells after treatment with the same inhibitors(Gurland and Gundersen, 1993). However, it was postulated by Gurlandand Gundersen that PP1 but not PP2A is the phosphatase that regulatesthe stability of Glu-MTs. This hypothesis is based on the observationthat CL-A (which is a more potent inhibitor of PP1 than is OK)is more effective in inducing the depolymerization of Glu-MTs.However, it is well known that the concentration of inhibitorsneeded to inhibit a specific phosphatase in intact cells dependson the actual concentration of the phosphatase in these differentcell types. Often, high concentrations (micromolar) of these inhibitorsare required for complete inhibition (Cohen et al., 1990). Thus,it may be difficult to identify definitively the specific phosphatasethat is responsible for the observed effects based on pharmacologicalmanipulation alone. Recently, PP2A has been shown to be capableof binding to MTs (Sontag et al., 1995). Our finding that thecatalytic subunit of PP2A but not PP1 can be recovered bound toMTs in high-speed supernatants obtained from rat brain and NT2Ncells suggests that the species of PP2A associated with MTs maybe in a position to regulate the stability of MTs directly. However,it should be pointed out that a lack of association of PP1 doesnot mean that PP1 cannot regulate Glu-MT stability. Future studiesusing specific inhibitors of PP1 or PP2A could help resolve thisissue.

Previous studies have demonstrated that the distribution of Glu-MTs varies for different cell types. For example, fibroblastsand epithelial cells exhibit a subpopulation of stable MTs thatcomprises exclusively Glu-MTs (Schulze, 1987). By contrast, individualMTs in the main shafts of axons of sympathetic neurons are composedof a Glu-MT-rich segment located proximal to and in direct continuitywith a Tyr-MT-rich domain such that stable and labile regionsin the axon exist as distinct domains on individual MTs (Baasand Black, 1990). Our immuno-EM analysis of the organization ofGlu-MTs and Tyr-MTs in individual MTs in the main axonal shaftsof NT2N cells suggests a third arrangement. Unlike those observedfor non-neuronal cells and for sympathetic neurons, individualaxonal MTs in NT2N neurons comprise predominantly Glu-MTs witha small amount of Tyr-MTs interdispersed along the entire lengthsof these very long MTs. The discrepancy between the distributionof Glu- and Tyr-MTs in axonal MTs in sympathetic neurons versusNT2N neurons is unclear. It is possible that the distributionof axonal Glu-MTs and Tyr-MTs in the NT2N cells represents a moremature and stable MT in contrast to the sympathetic neuronal culturesused in previous studies (Baas and Black, 1990).

We have demonstrated here that treatment of NT2N cells with inhibitors of PP2A and PP1 results in the preferential destructionof axons, and we speculate that this is likely the consequenceof multiple downstream signaling events regulated by PP2A andPP1. The present study also shows that the depolymerization ofstable Glu-MTs, the hyperphosphorylation of tau, and the reducedbinding of tau to MTs are among the critical events that are linkedto the destruction of the axon. Other components of the neuronalcytoskeleton such as the neurofilament triplet proteins may alsocontribute to the degeneration of the axon induced by inhibitorsof PP2A and PP1. Indeed, recent in vitro studies have shown thatthe inhibition of PP2A leads to the increased phosphorylationof neurofilament triplet proteins at specific sites, resultingin the disassembly of neurofilaments (Saito et al., 1995). Becauseone of the functions of neurofilaments is to stabilize the axon,the dissolution of the neurofilament network also could contributeto the destruction of the axon. Alternatively, the effects ofPP2A and PP1 inhibitors on axons could be mediated by changesin the activities of a number of kinases such as MAP kinase andglycogen synthase kinase 3, because the activities of these kinaseshave been shown to be regulated by phosphatases (Gotoh et al.,1991; Cross et al., 1994). Thus, these and other phosphorylation-dependentenzymes may directly or indirectly regulate the stability of theneuronal cytoskeleton including MTs (Felix et al., 1990; Gotohet al., 1991; Faruki et al., 1992). Although a number of othermechanisms could be implicated in the OK- and CL-A-induced destructionof axons in the NT2N cells, more detailed information on neuronalphosphatases is needed to test hypotheses about the nature ofthese mechanisms. For example, additional studies are needed toconfirm whether PP2A is the only phosphatase that mediates theOK- and CL-A-induced destabilization of MTs in the NT2N cells.Furthermore, the precise subunit composition of PP2A isoformsin neurons must be determined. Although we provide circumstantialevidence to implicate PP2A in the destabilization of MTs by OKand CL-A in the NT2N cells, and this is consistent with the recentstudies of PP2A in non-neuronal cells (Sontag et al., 1995, 1996),alternative experimental strategies and further research on neuronalMTs and phosphatases are needed to assess the validity of ourinterpretation of the data reported here.

These uncertainties notwithstanding, the results presented here suggest that the downregulation of phosphatases such as PP2Aand PP1 may be sufficient to set off a cascade of events thatleads to the genesis of neurofibrillary lesions. This cascadeincludes the selective depolymerization of the more stable Glu-MTs,as well as an increase in the phosphorylation of tau, and theinability of this hyperphosphorylated tau to bind and stabilizeMTs, i.e., abnormalities that distinguish PHFtau from normal tau.We speculate that these events lead to the dissolution of theMT network, the dying back of the axon, and the degeneration oftangle-bearing neurons in AD (Bramblett et al., 1993; Lee andTrojanowski, 1995; Trojanowski et al., 1996; Goedert et al., 1997).Further studies of these events may provide insights into therole of neurofibrillary lesions in the degeneration of neuronsin AD.

FOOTNOTES

Received April 11, 1997; revised May 8, 1997; accepted May 13, 1997.

This work was supported by grants from the National Institute on Aging of the National Institutes of Health. We gratefullyacknowledge Dr. M. Black for thoughtful discussions, and we alsothank Ms. C. Page, Mr. T.-H. Chiu, and Mr. Lew Johns for theirassistance with tissue culture, photography, and immunoelectronmicroscopy, respectively. Drs. L. Binder, G. Gundersen, C. Bulinski,P. Davies, and B. Hemmings are thanked for contributing antibodiesto this study.

Correspondence should be addressed to Dr. Virginia M.-Y. Lee, Department of Pathology and Laboratory Medicine, The Centerfor Neurodegenerative Disease Research, The University of PennsylvaniaSchool of Medicine, Maloney 3, HUP, Philadelphia, PA 19104-4283.

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