S100{beta} Interaction with Tau Is Promoted by Zinc and Inhibited by Hyperphosphorylation in Alzheimer's Disease

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The Journal of Neuroscience, April 1, 2001, 21(7):2240-2246

S100 $beta$ Interaction with Tau Is Promoted by Zinc and Inhibited by Hyperphosphorylation in Alzheimer's Disease
W. Haung Yu¹^,² and Paul E. Fraser¹^,³
¹ Centre for Research in Neurodegenerative Diseases, ² Department of Pharmacology, and ³ Department of Medical Biophysics, University of Toronto, Toronto, Ontario, Canada M5S 3H2

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The zinc-binding protein S100 $beta$ has been identified as an interacting partner with the microtubule-associated protein tau.Both proteins are individually affected in Alzheimer's disease(AD). S100 $beta$ , is overexpressed in the disease, whereas hyperphosphorylatedtau constitutes the primary component of neurofibrillary tangles.In this study, we examine factors that modulate their bindingand the potential role the complex may play in AD pathogenesis.Zinc was identified as a critical component in the binding processand a primary modulator of S100 $beta$ -associated cellular responses.Abnormally phosphorylated tau extracted from AD tissue displayeda dramatically reduced capacity to bind S100 $beta$ , which was restoredby pretreatment with alkaline phosphatase. In differentiated SH-SY5Ycells, exogenous S100 $beta$ was internalized and colocalized with tauconsistent with an intracellular association. This was enhancedby the addition of zinc and eliminated by divalent metal chelators.S100 $beta$ uptake was also accompanied by extensive neurite outgrowththat may be mediated by its interaction with tau. S100 $beta$ -tau bindingmay represent a key pathway for neurite development, possiblythrough S100 $beta$ modulation of tau phosphorylation and/or functionalstabilization of microtubules and process formation. S100 $beta$ -tauinteraction may be disrupted by hyperphosphorylation and/or imbalancesin zinc metabolism, and this may contribute to the neurite dystrophyassociated withAD.

Key words: S100 $beta$ ; tau; Alzheimer's disease; zinc; binding; colocalization; neuronal development

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

S100 $beta$ is a small molecular weight (10 kDa) zinc-calcium binding protein produced by astrocytes (Donato, 1991; Mrak et al.,1995). In addition to metal binding, S100 $beta$ has several functionsthat include a role in the cytokine cycle, inhibition of selectedphosphokinases, including phosphokinase C (PKC), and the stimulationof neurite outgrowth (Kligman and Marshak, 1985; Baudier and Cole,1988; Marshak and Pena 1992; Zimmer et al., 1995; Griffin et al.,1998; Heizmann and Cox, 1998). S100 $beta$ is located on chromosome21 and is increased in Down's syndrome and Alzheimer's disease(by as much as 20-fold) (Griffin et al., 1989, 1998; Marshak etal., 1992; Castets et al., 1997). In AD, the pathology is definedby amyloid plaques and neurofibrillary tangles (NFT) that areaccompanied by neuronal loss and aberrant neuritic sprouting (Masilahet al., 1991). The neuritic response may be induced by the lossof neuronal connections or a cellular reaction to amyloid deposition(Mrak et al., 1996). S100 $beta$ overexpression in AD has been directlycorrelated with plaque-associated dystrophic neurite developmentand the astrocyte activation, as well as S100 $beta$ overproduction,may be a direct effect of the loss of neuronal connections andamyloid- $beta$ deposition (Van Eldik and Griffin, 1994; Mrak et al.,1996; Sheng et al., 2000). S100 $beta$ levels are elevated in brainregions with a direct relationship to the presence of neuriticplaques (Sheng et al., 1994). In addition, astrocyte activationand S100 $beta$ expression may also be correlated with neurofibrillarytangle formation in AD (Sheng et al., 1994).

This study examines the relationship between tau and S100 $beta$ based on the observation that they are cellular binding partnersand each may therefore regulate specific neurite outgrowth ortau hyperphosphorylation activity (Baudier and Cole, 1988; Sorciet al., 2000). Second, tau is a unique neuronal component thatstabilizes microtubules leading to the formation of axonal processesand, in its hyperphosphorylated state, tau is the major componentof neurofibrillary tangles (Su et al., 1994; Nagy et al., 1995;Ikura et al., 1998; Mailliot et al., 1998). Finally, althoughthe mechanism is unknown, S100 $beta$ can induce a similar neurite outgrowththat may be related to its association with tau. S100 $beta$ has beenshown to directly affect tau, for example, by its ability to blockPKC phosphorylation at specific sites (Ser 262 and 313) (Biernatet al., 1992; Lin et al., 1994; Singh et al., 1996a). This activitymay have a direct consequence for AD because loss of PKC phosphorylationincreases the susceptibility of tau to hyperphosphorylation byGSK-3 $beta$ (Singh et al., 1996b; Tsujo et al., 2000). This AD-relatedphosphorylation is considered to be a major factor in tau depositionand neurofibrillary degeneration (Su et al., 1994; Friedhoff etal., 1998; Ikura et al., 1998; Mailliot et al., 1998).

We have examined S100 $beta$ binding proteins by affinity chromatography and immunoprecipitation to survey the potential involvementof other AD-associated proteins. In addition to tau, S100 $beta$ bindingto the amyloid precursor protein (APP), the amyloid- $beta$ peptide,and the presenilins (PS1 and PS2) were also assessed. Among theproteins we evaluated, tau was the only significant binding proteinand furthermore, based on immunofluorescence studies, colocalizedwith S100 $beta$ after internalization by neuronal cells. Zinc has alsobeen implicated in some aspects of AD pathology, such as promotionof amyloid fibril formation (Bush et al., 1994) and, when examinedin the current system, it significantly affected the relationshipbetween S100 $beta$ and tau. This may be attributable to zinc-inducedconformational changes that result in the exposure of a hydrophobicdomain and could represent a key site for tau binding (Fujii etal., 1986; Baudier and Cole, 1988; Baudier et al., 1992). In addition,changes to tau also regulated this interaction, as shown by thealtered binding of S100 $beta$ to the AD-related hyperphosphorylatedNFT-tau. Based on our observations, S100 $beta$ -tau binding, overexpressionof S100 $beta$ , and tau hyperphosphorylation in Alzheimer's diseasepathology suggest that S100 $beta$ -tau interactions may contribute toneuronal development as well as neuronaldysfunction.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Purification of S100 $beta$ . Extracts containing S100 $beta$ were prepared from fresh bovine brains using the method described by Isobeet al. (1977). A 20% homogenate was made in a potassium phosphatebuffer (0.1 M KPO₄, pH 7.1, 1 mM EDTA, 1 µg/ml aprotinin, 1 µg/mlleupeptin, and 1 mM polymethonyl sulfate) with 2.66 M (or 50%)ammonium sulfate (AmSO₄). Cell debris was removed by centrifugationat 10,000 × g, and the supernatant was adjusted to 85% AmSO₄ atpH 4.2 and incubated at 4°C for 2 hr. Precipitated proteins wererecovered by centrifugation, dialyzed against phosphate buffer,and stored at $-$ 20°C in lyophilized form. From this crude material,S100 $beta$ was purified using a modified method as described by Baudieret al. (1982). Crude extracts were dissolved in the elution buffer(50 mM Tris-Base, pH 7.4) with 1 mM ZnSO₄ and applied to a PhenylSepharose 650 M column (ToyoPearl, Montgomeryville, PA). S100 $beta$ was eluted using a step gradient containing 300 mM NaCl, 0.25mM ZnSO₄, or 2 mM EDTA. Protein purity was assessed by SDS-PAGEwith Coomassie staining and by Western blotting with an S100 $beta$ monoclonal antibody (clone SH-B1; Sigma, St. Louis,MO).

Electrophoresis and Western blotting. S100 $beta$ (1 µg) was dissolved in Laemmli buffer and separated on a 10-20% Tricine gel (Novex,Carlsbad, CA). Gels were either stained with 0.2% Coomassie bluereagent in 5% acetic acid, or transferred to a polyvinylidenedifluoride membrane. The membrane was washed in Tris-bufferedsaline (200 mM Tris-base, pH 7.4, 150 mM NaCl), blocked with skimmilk and incubated overnight with the required antibody. Immunoreactivebands were identified with HRP-conjugated secondary antibodiesand visualized using enhanced chemiluminescence (ECL; AmershamPharmacia Biotech, Arlington Heights, IL) with filmexposure.

S100 $beta$ affinity chromatography and identification of binding proteins. Purified S100 $beta$ was immobilized on AffiGel-10 (Bio-Rad,Hercules, CA) and equilibrated in 100 mM HEPES with 0.25 mM ZnSO₄.Immobilized S100 $beta$ was incubated with a human brain tissue homogenate(10% w/v), and nonspecific binding proteins were removed by washingwith the initial buffer. A high salt (100 mM HEPES, 1 M NaCl,0.25 mM ZnSO₄) wash was used to elute proteins with weak S100 $beta$ interactions. Zinc-dependent binding proteins were subsequentlyeluted with 1 mM EDTA, and any remaining bound elements were removedwith 1 M urea. All samples were collected and dialyzed then storedat $-$ 20°C in their lyophilized form. Eluted proteins were analyzedon 4-20% Tricine gels (Novex) and examined by silver stainingand by Western blotting. Antibodies corresponding to S100 $beta$ , amyloid- $beta$ (clone 6F/3D; Dako, Carpinteria, CA), tau (Dako), and a presenilinantisera (Yu et al., 1998) were used to determine if they werecapable of binding to S100 $beta$ .

Formation of S100 $beta$ complexes with normal and AD tau. AD and control brain were homogenized (10% w/v) in 0.1 M KH₂PO₄, 2 mMEDTA, 2 mM EGTA, and protease inhibitors. Samples were centrifugedfor 45 min at 20 000 × g, and the supernatant was fractionatedusing 35 and 55% ammonium sulfate to produce a tau-enriched fraction.Crude protein precipitates were resuspended in 20 mM Tris and0.5 M NaCl, pH 7.6, with protease inhibitors. Samples were boiled,centrifuged at 25,000 × g for 30 min, and control aliquots werecollected. To assess the effects of phosphorylation on S100 $beta$ binding,samples were also treated with alkaline phosphatase (Sigma) for30 min at 37°C. Binding of S100 $beta$ with tau from these enrichedsamples was assessed by immunoprecipitation. Aliquots of the brainextracts (50 µg of total protein) were combined with 1 µg of purifiedbovine S100 $beta$ and 10 µl of S100 $beta$ monoclonal antibody. The mixturewas incubated overnight at 4°C and the S100 $beta$ -containing complexeswere recovered by immunoprecipitation by protein-G sepharose.Beads were washed with buffer containing 50 mM Tris with 150 mMNaCl and 0.5% NP-40, and S100 $beta$ with bound proteins eluted with500 mM NaCl with 1 mM EDTA. Samples were collected, dialyzed,and examined by Western blotting using tauantibodies.

S100 $beta$ internalization and subcellular distribution. Bovine S100 $beta$ (final concentration, 5 µg/ml) was added to culture and incubatedfor pulse of 4 or 24 hr. Cells were washed with fresh medium andharvested at 0, 15, 30, or 60 min and 4, 24, or 48 hr. Cells lysateswere examined by immunoblotting to determine cellular uptake ofS100 $beta$ . SH-SY5Y cells were grown in 10% fetal bovine serum/DMEM(Life Technologies, Burlingame, CA) at 37°C under 5% CO₂. Cellswere placed on poly-L-lysine-coated coverslips and differentiatedusing 10 µM trans-retinoic acid. To examine colocalization withtau, S100 $beta$ was preincubated with the cells for 4, 12, and 24 hrunder control conditions or with 50 µM EDTA or 5 µM EGTA for 1hr before addition of S100 $beta$ or with 10 µg/ml ZnSO₄. Cells werefixed with 2% paraformaldehyde and examined by immunofluorescenceusing a Nikon TE300 inverted microscope attached to a Bio-RadRadiance 2000 laser confocalsystem.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Identification and analysis of S100 $beta$ binding proteins

Interactions of brain-derived proteins, such as tau, were initially examined by affinity chromatography using immobilizedS100 $beta$ as the primary substrate. A native S100 $beta$ secondary structurewas maintained in the presence of calcium and zinc to obtain physiologicallyrelevant conditions for the evaluation of binding proteins (Baudieret al., 1982). A series of increasing elution stringencies wereused to determine the relative affinities of S100 $beta$ binding proteins.Proteins that failed to bind to the S100 $beta$ substrate were recoveredin the initial wash. This was followed by a high salt elutionto isolate proteins with weak ionic binding properties. High-affinityS100 $beta$ -associated proteins were removed by the addition of zincchelators, which caused a structural rearrangement of S100 $beta$ . Previousstudies have shown that zinc exposes a hydrophobic domain, whichrepresents a potential binding site for its cellular partners(Isobe et al., 1977). Finally, any remaining proteins bound tothe affinity column were removed with a denaturing urea wash,and each of these fractions was examined by direct silver stainingas well as Westernblotting.

Immunoblotting of the various elutions demonstrated that tau constituted a principal S100 $beta$ binding protein. All other AD-relatedproteins such as APP, amyloid- $beta$ , PS1, and PS2 did not show anysignificant S100 $beta$ binding and were recovered in the initial elution.Tau binding was particularly evident in the samples obtained fromcontrol cases in which strong signals were observed for all brainregions (Fig. 1A). The control tau was only eluted after zincchelation with EDTA, suggesting that the observed conformationchanges are important for binding. In contrast, in the comparableelutions, there was a marked decrease in the amount from the ADtau fraction (Fig. 1A). The lack of tau was not attributable toloss of immunoreactivity caused by changes in the AD-related proteinbecause a polyclonal, nonphosphorylation-dependent antibody wasused. To confirm this, additional antisera were used (e.g., phosphorylationepitopes detected by the antibody AT8), which demonstrated a similarlack of tau binding. Examination of the complete range of elutionsrevealed that AD-tau was found in both the flowthrough and saltwashes. Based on this finding, it was determined that tau fromAD samples had a significantly lower affinity for S100 $beta$ .

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Figure 1. Affinity chromatography using immobilized S100 $beta$ for identification of binding proteins (A). Immunoblotting of zinc (lanes 1, 3, 5, 7)- and EDTA (lanes 2, 4, 6, 8)-eluted fractions indicated a significant amount of S100 $beta$ -associated tau in control samples from both frontal (lanes 1, 2) and temporal cortices (lanes 3, 4). Comparable affinity analysis with AD-extracted proteins from frontal (lanes 5, 6) or temporal (lanes 7, 8) cortex indicated only weak tau immunoreactivity consistent with a reduced interaction with S100 $beta$ . Zinc-treated samples did not elute any proteins with tau immunoreactivity. Immunoblotting of total brain homogenates from AD and control indicating the elevated levels of S100 $beta$ , as has been previously demonstrated by Griffin et al. (1989) (B).

To examine potential changes in the S100 $beta$ levels between AD and control cases, Western blotting of comparable tissue sampleswas investigated. In the AD cases that showed the loss of taubinding to S100 $beta$ , appreciable increases in the S100 $beta$ levels wereobserved in all AD brain samples (Fig. 1B). The reason for theincreased expression is unclear but does suggest an imbalancein S100 $beta$ levels that may represent a compensatory mechanism forreduced activity. For example, if S100 $beta$ does modulate tau functionand/or metabolism, then the loss of this interaction in AD mayinduce the elevatedexpression.

Identification of S100 $beta$ and tau complex

To assess further the binding of S100 $beta$ to tau, immunoprecipitation of in vitro complexes was examined using both AD and controlextracted samples. To accomplish this, a tau-enriched fractionwas obtained from the brain homogenates through ammonium sulfateprecipitation and incubated with purified S100 $beta$ . The effects oftau phosphorylation on S100 $beta$ -tau binding were also examined byimmunoprecipitation with untreated extracts as well as after incubationwith alkaline phosphatase. Because AD-tau is heavily phosphorylated,this may be one reason for the observed reduction in its bindingto S100 $beta$ .

Immunoprecipitation of untreated AD extracts using an anti-S100 $beta$ antibody yielded very low or undetectable levels of associatedtau in all tissues examined (Fig. 2). This finding is consistentwith the affinity chromatography results and suggests an impairedbinding. In contrast, similar immunoprecipitation control samplesproduced a robust level of binding of tau to S100 $beta$ . The high levelof tau immunoreactivity reflects the amount of binding to S100 $beta$ in immunoprecipitation samples relative to the same amount ofprotein used in the AD samples. The formation of the S100 $beta$ -taucomplex in the control extracts was also zinc-dependent. Thisevent was demonstrated by the removal of zinc with EDTA, followedby the subsequent release of tau from immunoprecipitated S100 $beta$ .This observation is consistent with the elution profile from theaffinity column, which facilitated the removal of tau from theimmobilized S100 $beta$ . Dephosphorylation of tau by alkaline phosphataserestored the normal, possibly functional, binding of tau to S100 $beta$ (Fig. 2). In all AD cases, we observed a significantly higherlevel of binding after tau dephosphorylation. There was littleor no change in the amount of tau that could be immunoprecipitatedin the comparable control samples after alkaline phosphatase treatment.Restoration of binding after dephosphorylation of tau indicatesa possible mechanism for the lack of S100 $beta$ -tau interaction inthe AD cases.

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Figure 2. Immunoprecipitation of S100 $beta$ complexed with brain-extracted tau from control and AD cases (3 separate tissue samples). Purified S100 $beta$ incubated with tau-enriched and precipitated with an S100 $beta$ polyclonal antibody indicated significant interacted evidenced by the coprecipitating tau. Untreated AD extracts displayed reduced tau binding to S100 $beta$ under comparable conditions. The association was restored by dephosphorylation of the tau-containing extracts using alkaline phosphatase (Alk-Phos.).

Internalization and subcellular distribution of S100 $beta$ in neuronal cells

S100 $beta$ has a stimulatory activity on neurite outgrowth that may result from metal influx (calcium), cytokine activation, andactivation of phosphokinases to initiate axonal growth or microtubulestabilization (Baudier et al., 1987a, 1988; Baudier and Cole,1988; Lin et al., 1994; Sheu et al., 1994; Mrak et al., 1996;Sheng et al., 1996). One possibility that we explored was thedirect uptake of exogenous S100 $beta$ by neuronal cell lines and theeffects of this internalization on tau. Purified S100 $beta$ was addedto cultures of SH-SY5Y cells and was pulsed for 4 or 24 hr andthen removed from the medium. Examination of cell lysates forS100 $beta$ indicated that after 4 hr of incubation relatively low levelsof the S100 $beta$ dimer were observed (Fig. 3). When examined afterdifferent incubation times (4 and 24 hr), the amount of S100 $beta$ slowly decreased with a significant reduction observed at 4 hrand a complete loss of cell-associated protein at 24 hr. Incubationfor a 24 hr period resulted in substantially greater amounts ofS100 $beta$ in the cell lysates, including both monomeric and dimericforms (Fig. 3). These levels were maintained 4 hr after incubationand were detectable, but at reduced levels, and they were notobserved after a 24 hr clearance period. These observations indicatethat significant quantities of S100 $beta$ associate with the cellsand are maintained over long periods of time.

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Figure 3. Time course of S100 $beta$ internalization and clearance from differentiated SH-SY5Y neuroblastoma cells that were preincubated with S100 $beta$ for 4 or 24 hr. Lysates were examined at different time points (0, 15, 30, and 60 min and 4 and 24 hr) after the removal of S100 $beta$ from the culture medium. Readily detectable S100 $beta$ (monomeric and dimeric forms) were observed after the 24 hr pulse and to a lesser extent after 4 hr preincubation.

It is unclear from the Western blotting data whether the S100 $beta$ merely accumulates via nonspecific binding to the plasma membraneor if the cells are capable of internalizing the exogenous protein.To resolve this issue, retinoic acid differentiated SH-SY5Y cellswere used to produce a neuronal-like phenotype and the distributionof S100 $beta$ examined by immunofluorescence. Cells incubated withpurified bovine S100 $beta$ displayed modest amounts of intracellularS100 $beta$ staining after exposures for 4 and 12 hr (Fig. 4). Consistentwith the Western blotting data, substantial levels of S100 $beta$ werefound after the 24 hr incubation (Fig. 4D). S100 $beta$ immunoreactivitywas distributed within the cell body and extended into the processesbut was absent from the nuclear region.

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Figure 4. Immunofluorescence of SH-SY5Y cells that were preincubated with S100 $beta$ for various lengths of time. Untreated cells displayed very low levels of S100 $beta$ (A), which were increased after addition of S100 $beta$ to the medium and incubations for 4 (B) and 12 hr (C). The S100 $beta$ levels were significantly increased after 24 hr of incubation (D). S100 $beta$ was distributed within the cell body and processes consistent with the internalization of the protein rather than cell surface association. Scale bar, 10 µm.

The degree of S100 $beta$ internalization was also affected by zinc, as shown by the increased level of staining within cells, ascompared with control, when zinc was added to the medium and coincubatedfor 24 hr (Fig. 5). The effect of zinc (and possibly other divalentmetals) was supported by EDTA treatment that has a higher affinityfor the metal as compared with S100 $beta$ . Under these metal-depletedconditions, the level of S100 $beta$ was markedly reduced in the SH-SY5Ycultures as compared with controls (Fig. 5C). To examine the effectsof other divalent cations, the calcium-specific chelator EGTAwas added to our cultures to block free and extracellular calcium.Low EGTA concentrations were used because they were not toxicand do not block neuritic sprouting but were sufficient to binda significant proportion of free calcium. EGTA-treated cells exhibitedcomparable S100 $beta$ staining, providing additional support for thespecific role of zinc (data not shown). Cumulatively, the Westernblotting and immunofluorescence studies suggest that S100 $beta$ isactively internalized by the cells as opposed to surface association.This uptake has a number of implications for the mechanism ofS100 $beta$ activity in neuronal systems and its possible relationshipto tau function.

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Figure 5. Immunofluorescence of differentiated SH-SY5Y cells demonstrating the effects of zinc on S100 $beta$ internalization. Samples exposed to untreated S100 $beta$ showed an easily detectable level of protein uptake at 24 hr (A). Elevation of the culture medium zinc concentration to 10 µM resulted in a substantial increase in the intracellular S100 $beta$ levels (B). This zinc-induced enhancement of S100 $beta$ internalization could be reversed with addition of metal chelators such as EDTA (C). Scale bar, 10 µm.

Colocalization of S100 $beta$ with tau and enhanced neurite outgrowth

To investigate the relationship between S100 $beta$ -tau binding and neurite outgrowth, differentiated SH-SY5Y cells were allowedto internalize S100 $beta$ , and its subcellular distribution with respectto tau was examined by immunofluorescence. Under control conditions,S100 $beta$ was broadly distributed within the cell body and some processes.Furthermore, in the double-labeled cells, the staining overlapsto some degree with tau (Fig. 6A). However, a zinc-induced increasein the level of S100 $beta$ within the cell produced a much more definedcolocalization with tau. This is particularly evident within theprocesses in which the S100 $beta$ and tau coincided as punctate stainingthat was observed in virtually all neurites (Fig. 6B, arrows).Colocalization of S100 $beta$ was also time-dependent because 24 hrof incubation produced higher levels of overlapping signals whencompared with the 4 or 12 hr samples. To ensure that there wereno significant changes in tau, the S100 $beta$ -treated cells were alsoanalyzed for changes in phosphorylation using the paired helicalfilament (PHF)-tau AT8 antibody. AT8 immunoreactivity was notdetected in any of the treated cells, at any time points (datanot shown). The effects of zinc and the enhanced colocalizationmay reflect simply an increased cellular uptake of S100 $beta$ , or metalbinding may promote a preferred conformation that facilitatestau binding. This latter possibility would be consistent withour affinity chromatography and immunoprecipitation results. Thesefindings suggest that internalized S100 $beta$ may be associated withtau and thereby affect tau function and/or metabolic events suchas phosphorylation.

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Figure 6. Colocalization of internalized S100 $beta$ with tau in differentiated neuroblastoma cells. Under control conditions, S100 $beta$ (red) that was taken up by the cells showed partial overlap with tau (green), suggesting a possible intracellular association (A). The colocalization was more pronounced with the addition of zinc to the culture medium (B). Zinc elevated levels of S100 $beta$ resulted in increased neurite outgrowth and frequent overlap of S100 $beta$ with tau in these processes, which appear as discrete, punctate staining within the cell processes (B). Addition of EDTA to the culture medium before incubation of the cells with S100 $beta$ eliminated the tau colocalization pattern caused by reduced protein uptake (C). Scale bar, 10 µm.

Tau is one of the key elements that control axonal growth and may be modulated, to some degree, by interactions with S100 $beta$ .This hypothesis is supported in our experimental system by theresponse of the SH-SY5Y cells to S100 $beta$ and zinc. Even with retinoicacid differentiation, SH-SY5Y cells do not produce extensive processformation and have a predominantly "spindle-type" morphology (Fig.7A). With the addition of S100 $beta$ , a greater number of neuriteswere observed when visualized using an antibody staining for cadherinson the cell surface (Fig. 7B). Neurite outgrowth was even morepronounced in the presence of zinc in which enhanced S100 $beta$ uptakeresulted in increased number of neurites with extensive outgrowththat produced both longer networks of processes (Fig. 7C). Underthese conditions, abnormal neuritic sprouting was also observedwith processes emanating from the cell body. Stimulation of neuritesand colocalization of S100 $beta$ with tau provides additional evidencefor a physiological role for their interaction.

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Figure 7. Stimulation of neurite outgrowth in SH-SY5Y cells after S100 $beta$ internalization. Retinoic acid differentiated cells displayed a neuron-like morphology but with only a limited number of extensions (A, arrow). With the addition of untreated S100 $beta$ , the number and length of the processes were enhanced (B). Addition of zinc to the medium and the accompanying increase in S100 $beta$ uptake resulted in widespread increase in neurite outgrowth, leading to the formation of dense networks of cell processes (C). Cells and processes were visualized by immunofluorescence staining of the cell surface cadherins. Scale bar, 10 µm.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

These studies were performed to establish the binding of S100 $beta$ to tau and the chemical properties involved, as well as identifyits relevance to Alzheimer's disease. Our findings demonstratethat S100 $beta$ binds to tau. In addition, this interaction is enhancedby zinc and inhibited by tau hyperphosphorylation. The functionalaspects of S100 $beta$ -tau binding may impact on several different pathwaysthat are regulated by the two proteins. For example, S100 $beta$ mayprovide a scaffolding structure for tau to stabilize microtubulesand possibly contribute to the abnormal neuritic dystrophy thatis observed in AD (Baudier and Cole, 1988; Tam, 1990; Azmitiaet al., 1995). This is illustrated by our observation that nonphysiologicalsprouting of processes are from the cell body, which is not normallyseen in differentiated neuronal cultures. The second possibilityis that S100 $beta$ is a modulator of tau phosphorylation and that anychanges in their interaction could be a factor in the AD-relatedhyperphosphorylation, as has been previously suggested (Baudieret al., 1987a; Sorci et al., 2000). Furthermore, the ability ofS100 $beta$ to inhibit PKC may potentiate the aberrant phosphorylationat key sites [e.g., residues 262 and 313 (Correas et al., 1992;Singh et al., 1996b)]. However, in our in vitro studies, S100 $beta$ did not appear to promote aberrant phosphorylation, as indicatedby the lack of AT8 staining that identifies PHF-tau related phosphorylatedepitopes (Biernat et al., 1992). Neuritic development, althoughbeneficial in the short term to rejuvenate lost neuronal connections,can also be detrimental in the chronic stages of AD because itincreases cellular metabolic requirements and exposes the neuronsto externalinsults.

Initially, our finding that S100 $beta$ failed to bind AD-derived tau was attributed to the reduced number of neurons, which isassociated with the progression of AD. This did not appear tobe the case because the normal binding could be restored afteralkaline phosphatase treatments. Although this may suggest thatall phosphate groups on tau hinder S100 $beta$ binding, this is notevident because tau is naturally phosphorylated, and this doesnot affect binding of the control sample tau to S100 $beta$ . In thesestudies, it is only with abnormal hyperphosphorylation of taupresent in AD that prevents S100 $beta$ -tau binding activity. Our studyhas also demonstrated that zinc is important factor in the internalizationof S100 $beta$ into neurons and enhances tau binding. In addition, weobserved an increase in neuritic sprouting in SH-SY5Y cells treatedwith S100 $beta$ and zinc, which suggests that metal binding may becritical to this outgrowthactivity.

S100 $beta$ has been demonstrated to have several biological functions in AD. This is reflected by its ability to bind zinc andcalcium, as well as inhibit certain phosphorylation pathways.In addition, S100 $beta$ has been shown to activate the complement pathwaythrough interleukin-6 activation (Stanley et al., 1994; Mrak etal., 1995; Sheng et al., 1996a,b; Hays, 1998). S100 $beta$ itself isactivated by interleukin-1 and may also participate in a positivefeedback loop, thereby inducing its own production through thepromotion of astrocytic activity (Mrak et al., 1995). In AD, theobserved increase in S100 $beta$ production appears to be related tosome of the physiological changes associated with interleukinsand to the increase in neuritic sprouting. The uptake of S100 $beta$ may represent a key role in its ability to alter the neuronalactivity. Our immunofluorescence data suggests that S100 $beta$ uptakeby cells is enhanced by the addition of zinc. As stated previously,zinc causes S100 $beta$ to undergo a conformational change, exposinga hydrophobic domain that facilitates neuronal internalization.Within the cell, S100 $beta$ may alter many cellular processes, includingbinding totau.

The metal-binding capacity of S100 $beta$ appears to be a crucial functional element and may have some bearing on other diseasepathways. S100 $beta$ -calcium effects have been extensively examinedby Baudier and Cole (1987a,b, 1988), in which they found evidenceof S100 $beta$ -calcium binding to microtubule-associated proteins, includingtau, and calcium-calmodulin-dependent protein kinase II. Calciumis also thought to be excitotoxic in AD (Kim et al., 2000). InAD, both calcium and zinc have been implicated in the amyloidtoxicity pathway. Zinc, as well as copper, is believed to acceleratethe formation of amyloid fibrils (Bush et al., 1994; Yang et al.,2000). Amyloid is implicated as a potential membrane protein thatmay promote the influx of calcium across the plasma membrane.The increase of S100 $beta$ in AD may contribute to the shuttle of thesemetals to points of interaction, thereby accelerating the pathogenicprocess.

Zinc does not normally appear in the cell as a free, or unbound, form. It is believed to be toxic in this state. This maybe related to the ability of free zinc to enter via AMPA channels(Sensi et al., 1997, 1999; Yin et al., 1998), promoting excitotoxicity.Proteins such as metallothionein and S100 $beta$ are induced by astrocytesto compensate for the extrusion of zinc into the extracellularspace to block its toxic effects. In the case of S100 $beta$ , the effectmay detrimentally alter the diseaseprocess.

The role of zinc in AD has generated several interesting and pathogenically significant hypotheses. The potential role thatit may play with S100 $beta$ on the effect on neuritic sprouting isanother important addition to this metals role in the diseaseprocess. Finally, our observations suggest that, in addition toits activation of cytokines, S100 $beta$ may also play a more directrole in tau-related pathways that are associated with neurodegenerationin Alzheimer'sdisease.

  FOOTNOTES

Received Nov. 15, 2000; revised Jan. 11, 2001; accepted Jan. 18, 2001.

This work was supported by the Medical Research Council of Canada, Ontario Mental Health Foundation, and the Alzheimer Societyof Ontario. W.H.Y. is supported by an Alzheimer's Society of CanadaDoctoralAward.
Correspondence should be addressed to Haung Yu, Centre for Research in Neurodegenerative Diseases, 6 Queen's Park CrescentWest, University of Toronto, Toronto, Ontario, Canada M5S 3H2.E-mail: haung.yu{at}utoronto.ca.

  REFERENCES

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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