Parkin Binds to alpha /beta  Tubulin and Increases their Ubiquitination and Degradation

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The Journal of Neuroscience, April 15, 2003, 23(8):3316

Parkin Binds to $alpha$ / $beta$ Tubulin and Increases their Ubiquitination and Degradation
Yong Ren, Jinghui Zhao, and Jian Feng
Department of Physiology and Biophysics, State University of New York at Buffalo, Buffalo, New York 14214

  ABSTRACT

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

In addition to inhibiting the mitochondrial respiratory chain, toxins known to cause Parkinson's disease (PD), such as 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridineand rotenone, also strongly depolymerize microtubules and increasetubulin degradation. Microtubules are polymers of tubulin $alpha$ / $beta$ heterodimers, whose correct folding requires coordinated actionsof cellular chaperonins and cofactors. Misfolded tubulin monomersare highly toxic and quickly degraded through a hitherto unknownmechanism. Here we report that parkin, a protein-ubiquitin E3ligase linked to PD, was tightly bound to microtubules in taxol-mediatedmicrotubule coassembly assays. In lysates from the rat brain ortransfected human embryonic kidney (HEK) 293 cells, $alpha$ -tubulinand $beta$ -tubulin were strongly coimmunoprecipitated with parkin at4°C in the presence of colchicine, a condition in which tubulinexits as $alpha$ / $beta$ heterodimers. At the subcellular level, parkin exhibitedpunctate immunostaining along microtubules in rat brain sections,cultured primary neurons, glial cells, and cell lines. This patternof subcellular localization was abolished in cells treated withthe microtubule-depolymerizing drug colchicine. The binding betweenparkin and tubulin apparently led to increased ubiquitinationand accelerated degradation of $alpha$ - and $beta$ -tubulins in HEK293 cells.Similarly ubiquitinated tubulins were also observed in rat brainlysates. Furthermore, parkin mutants found in PD patients didnot ubiquitinate or degrade either tubulin. Taken together, ourresults show that parkin is a novel tubulin-binding protein, aswell as a microtubule-associated protein. Its ability to enhancethe ubiquitination and degradation of misfolded tubulins may playa significant role in protecting neurons from toxins that causePD.

Key words: parkin; Parkinson's disease; tubulin; ubiquitination; misfolding; microtubule; dopamine

  Introduction

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Microtubules play critical roles in diverse cellular functions. The polymerization of tubulin $alpha$ / $beta$ heterodimers into microtubulesis a dynamically regulated process that is influenced by manyfactors, among which the concentration of free tubulin heterodimersis the driving force. The synthesis of $alpha$ - and $beta$ -tubulins is coordinatedsuch that excess tubulin monomers are never produced in any significantamount, because the overexpression of either tubulin gene aloneis toxic to the cell (Burke et al., 1989; Weinstein and Solomon,1990). After translation, the correct folding of tubulin monomersand the formation of functional $alpha$ / $beta$ heterodimers require a seriesof coordinated actions of cellular chaperonins and cofactors (forreview, see Lewis et al., 1997).

The complex and reversible nature of the folding process for $alpha$ / $beta$ tubulin heterodimers, in addition to the mechanisms thatregulate the synthesis of tubulin polypeptides, make it unavoidablefor the cell to produce misfolded tubulin monomers, which arequickly degraded through an unknown mechanism to prevent cytotoxicity.Several lines of evidence indicate that misfolded tubulin maybe involved in Parkinson's disease (PD). First, both ubiquitin(Lowe et al., 1988; Mayer et al., 1989) and tubulin (Gallowayet al., 1992) are major components of the Lewy body, suggestingthat ubiquitinated tubulin may be present in this histologicalhallmark of Parkinson's disease. Second, 1-methyl-4-phenylpyridinium(MPP⁺), a neurotoxin that kills dopamine (DA) neurons and induces PD-likesymptoms (Langston et al., 1983; Przedborski and Jackson-Lewis,1998), depolymerizes microtubules in PC12 cells (Cappelletti etal., 1999) as well as in vitro (Cappelletti et al., 2001). Third,the long-term systemic administration of rotenone leads to selectivedegeneration of nigral DA neurons and locomotor problems resemblingPD (Betarbet et al., 2000). In addition to its widely recognizedability to inhibit mitochondrial complex I (Higgins and Greenamyre,1996), rotenone also potently depolymerizes microtubules in vivoand in vitro (Brinkley et al., 1974), by binding to the colchicinesite on tubulin heterodimers (Marshall and Himes, 1978). Becausethe depolymerization of microtubules leads to increased tubulindegradation (Cleveland, 1989), the cellular mechanism for thedegradation of tubulin in response to these neurotoxins may playa role inPD.

Parkin, a gene linked to autosomal recessive juvenile PD (AR-JP) (Kitada et al., 1998) has been found to be a protein-ubiquitinE3 ligase (Shimura et al., 2000). A variety of mutations existin the parkin gene of patients with autosomal recessive (Luckinget al., 2000) or sporadic PD (Scott et al., 2001). Many of themutations appear to be clustered in the ubiquitin-like domainand the RING (Really Interesting New Gene) finger domains (Giassonand Lee, 2001), suggesting that the E3 ligase activity of parkinis crucial for PD. Although previous studies have identified severalsubstrates of parkin in the cell (Zhang et al., 2000; Chung etal., 2001; Imai et al., 2001; Shimura et al., 2001), it is clearthat parkin may have additional substrates that contribute tothe degeneration of nigral DA neurons. Here we report the discoveryof parkin as a novel tubulin-binding protein, as well as an E3ligase for $alpha$ - and $beta$ -tubulins.

  Materials and Methods

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Antibodies and cDNAs. Polyclonal antibodies against parkin (P304 and P124) were generated by immunizing rabbits with KLH-conjugatedpeptides derived from mouse parkin sequence (amino acids 304-322and 124-141, respectively). Antisera were purified by affinitychromatography using the same peptide immobilized on SulfoLinkgel matrix (Pierce, Rockford, IL) according to the manufacturer'sprotocol. Monoclonal antibodies against synaptophysin (SVP-38), $alpha$ -tubulin (DM1A), $beta$ -tubulin (TUB2.1), FLAG (M2), anti-FLAG-conjugated(M2) agarose, and rhodamine-conjugated phalloidin were purchasedfrom Sigma (St. Louis, MO). Anti-ubiquitin, anti-microtubule-associatedprotein 1A (MAP1A), and rhodamine- or FITC-conjugated secondaryantibodies were purchased from Santa Cruz Biotechnology (SantaCruz, CA). Monoclonal anti-hemagglutinin was purchased from Roche(Indianapolis, IN). Monoclonal anti-postsynaptic density 95 (PSD-95)was purchased from Affinity BioReagents (Golden, CO). TO-PRO-3(a DNA-binding dye) was purchased from Molecular Probes (Eugene,OR). Monoclonal anti-MAP2 was purchased from Upstate Biotechnology(Lake Placid, NY). Mouse parkin cDNA was amplified by reversetranscription PCR from brain total RNA. It was completely sequencedto ensure that no mutation was introduced by PCR. The FLAG epitopetag was added to the 5' end by PCR, and the tagged cDNA was subclonedinto pcDNA3.1. The HA-tagged ubiquitin construct was describedpreviously (Wang et al., 2000).

Taxol-mediated microtubule coassembly assay. The experiments were performed according to the protocol of Vallee (1986). Briefly,3-week-old male Sprague Dawley rats were decapitated after beinganesthetized with halothane (Sigma). A whole brain was homogenizedin PEM buffer (0.1 M PIPES, 1 mM EGTA, and 1 mM MgSO₄) on ice,centrifuged at 4°C first at 30,000 × g for 15 min then at 180,000× g for 90 min. The supernatant fraction contained the cytosol(C). Taxol (Sigma) and GTP were added to C to a final concentrationof 20 µM and 1 mM, respectively. The solution was warmed up to37°C and centrifuged through a layer of sucrose. The supernatantfraction was designated S₁, and the pellet was washed with PEMbuffer and resuspended in PEM buffer contain taxol and GTP at37°C (P₁), which was centrifuged again. The supernatant fractionwas designated S₂, and the pellet was washed with PEM buffer andresuspended in PEM buffer containing taxol and GTP at 37°C (P₂),which was separated into three equal portions. Each portion wasmixed with one-tenth, one-third, or one-half volume of MAP dissociationbuffer (PEM + taxol + GTP + 4 M NaCl) at 37°C to elute MAPs at0.36, 1, or 2 M of NaCl, respectively. After the mixtures werecentrifuged, the supernatant fractions were designated S₃, S₄,and S₅, respectively, and pellet fractions were rinsed in PEMbuffer at 37°C and resuspended in PEM buffer at 4°C to depolymerizemicrotubules (P₃, P₄, and P₅, respectively). Equal amounts oftotal proteins (10 µg) from each fraction were boiled and separatedon 7.5% SDS-polyacrylamide gel and analyzed by Western blots withantibodies against MAP1A, MAP2, parkin and $alpha$ -tubulin,respectively.

Transfection, immunoprecipitation, and Western blot. Human embryonic kidney (HEK) 293, SH-SY5Y, and BE(2)C cells were purchasedfrom American Type Culture Collection (Manassas, VA). They weremaintained in DMEM with 10% FCS and antibiotics. Transfectionof various constructs was performed using Fugene 6 (Roche, Indianapolis,IN) according to the manufacturer's protocol. Sixty hours aftertransfection, cells cultured in 10 cm dishes were lysed on icein cold lysis buffer (containing the following: 1% Triton X-100,10 mM Tris pH 7.6, 50 mM NaCl, 30 mM sodium pyrophosphate, 50mM NaF, 5 mM EDTA, and 0.1 mM Na₃VO₄) for 20 min. Lysates werecentrifuged at 4°C at 16,000 × g and supernatant fractions wereincubated with antibody against $alpha$ - or $beta$ -tubulin for 1 hr at 4°C,followed by incubation with protein A/G plus agarose (Santa CruzBiotechnology) at the same condition. Immunoprecipitates werewashed three times with the lysis buffer, then boiled in 2× SDSloading buffer for 5 min and separated on 7.5% SDS-polyacrylamidegel. Half of the immunoprecipitates were for Western blot withanti-HA, and the other half for Western blot with anti- $alpha$ -tubulinor anti- $beta$ -tubulin (loading control). Western blots were carriedout using the ECL method according to the manufacturer's protocol(Amersham Biosciences, Piscataway, NJ). In some experiments, celllysates containing equal amounts of total protein (100 µg) wereboiled in sample buffer, separated on 7.5% SDS-polyacrylamidegel, and analyzed by Western blot with anti-HA or anti-FLAG. Forexperiments using rat brain homogenates, one whole brain was homogenizedin 15 ml of ice-cold lysis buffer on ice in a tissue grinder (FisherScientific, Pittsburgh, PA). The homogenate was centrifuged at16,000 × g for 20 min and ultracentrifuged at 338,000 × g for30 min. The supernatant fraction was used in immunoprecipitationor Western blot as describedabove.

Immunohistochemistry. Adult male Sprague Dawley rats were anesthetized and transcardially perfused with PBS, followed by 4%paraformaldehyde (PFA; Sigma) in PBS. Fixed brain chucks werecut on a cryostat to obtain sagittal sections (14 µm thick), whichwere floated on PBS and picked up with slides precoated with 0.2%polyethylenimine (Sigma). After the sections were air-dried, theywere permeablized in 0.1% Triton X-100 in PBS for 15 min, thenblocked with 3% BSA for 1 hr. This was followed by incubationin primary antibodies (anti-parkin and anti- $beta$ -tubulin) for 1 dat 4°C and secondary antibodies (rhodamine-conjugated goat anti-rabbitIgG and FITC-conjugated goat anti-mouse IgG) for another day at4°C. Slides were counterstained with the DNA-binding dye TO-PRO-3(1:1000 in PBS, emitting fluorescence in the Cy5 range) for 5min, and mounted with VectaShield (Vector Laboratories, Burlingame,CA).

Embryonic neuronal culture and immunocytochemistry. Primary neuronal cultures were performed with brains from rat embryosat embryonic day 18. The cortex, hippocampus, or midbrain (containingsubstantia nigra) was dissected from each embryo for separatecultures. Minced brain tissue was digested in CGBD buffer (0.2mg/ml DL-cysteine hydrochloride monohydrate, 5 mg/ml glucose,0.2 mg/ml BSA, and 0.01 mg/ml DNaseI in PBS) containing 9 U/mlof papain (Worthington Biochemical, Lakewood, NJ). Dissociatedneurons were plated on coverslips in 12-well plates at a densityof 1 × 10⁵ cells/well in Neurobasal media supplemented with B27 (Invitrogen,Carlsbad, CA). Cytosine arabinoside (1 mM) was added to culturemedia from the fourth day to inhibit glia growth and the mediumwas changed every 4-5 d. Coverslips were precoated with 0.2% polyethyleniminein 0.15 M of sodium borate, pH 8.4. Neurons cultured for 3 weekswere fixed in 4% PFA for 15 min at room temperature or cold methanolfor 20 min at $-$ 20°C. PFA-fixed neurons were permeablized in 0.1%Triton X-100 in PBS for 15 min. Immunostaining was the same asthe procedures described forimmunohistochemistry.

Confocal microscopy and image analysis. Immunofluorescence images were acquired on a confocal microscope from Bio-Rad (Hercules,CA). Monochrome images (512 × 512 pixels) were pseudocolored andmerged with the software Confocal Assistant (freeware by ToddClark Brelje). Colocalization of signals was assessed by the colocalizationanalysis function in the LaserSharp software (Bio-Rad). The degreeof colocalization is expressed in Pearson's correlation coefficient,which calculates, for example, the proportion of all red intensitiesthat have green components among all red intensities (Manderset al., 1993).

  Results

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Parkin coassembles with microtubules

To identify substrates of parkin, we performed yeast two-hybrid screening with a mouse brain cDNA library. MAP1A came up asa positive clone in several independent experiments. However,the binding between parkin and MAP1A in coimmunoprecipitationassays was quite weak and apparently dependent on the temperatureduring immunoprecipitation. The amount of MAP1A coimmunoprecipitatedwith parkin at 37°C was significantly more than that at 4°C (Fengand Lin, 2001). This result hints that parkin may bind to MAP1Aindirectly, through microtubules, because the polymerization ofmicrotubules is temperature-dependent and optimal at 37°C.

To explore this possibility, we carried out taxol-mediated microtubule coassembly experiments using ultracentrifuged rat brainhomogenate (Vallee, 1986). As shown in Figure 1, $alpha$ -tubulin andtwo known MAPs (MAP1A and MAP2) were highly enriched in the pelletfractions containing microtubules (P₁ and P₂), compared with thesoluble fractions (S₁ and S₂). Parkin was found exclusively inthe pellet fractions, indicating that it was bound to microtubulesrather than freely floating in the cytosol. When the pellets inP₂ were incubated at 37°C in MAP dissociation buffer with varyingconcentrations of NaCl, MAP1A and MAP2 were eluted into the supernatantfractions (S₃, S₄, and S₅) at 0.36 M of NaCl or above. In contrast,parkin could not be dissociated from the pellet fractions evenwith 2 M of NaCl (P₅). These results show that parkin binds tomicrotubules much more tightly than MAP1A or MAP2 does, perhapsthrough hydrophobic rather than electrostatic interactions.

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Figure 1. Coassembly of parkin and microtubules. The cytosolic fraction (C) from ultracentrifuged rat brain homogenate was subjected to two cycles of taxol-mediated assembly. Supernatant and pellet fractions from each cycle were designated as S₁, P₁, S₂, and P₂, respectively. The P₂ pellet was resuspended and separated into three equal parts, each incubated at 37°C in MAP dissociation buffer containing 0.36, 1, or 2 M of NaCl, respectively, to release MAPs into the supernatant fractions (S₃, S₄, or S₅, respectively), whereas the pellet fractions (P₃, P₄, or P₅, respectively) contained mostly microtubules. Ten micrograms of total proteins from each fraction were analyzed by Western blots with antibodies against MAP1A, MAP2, $alpha$ -tubulin, or parkin, respectively. Note that parkin was always in the pellet fractions, in which microtubules were enriched. The large space in lane S₅ on $alpha$ -tubulin and parkin blots was attributable to distortion caused by high salt concentration of the samples as they migrate to the bottom. The faint signal of MAP1A in C was attributable to its relatively low abundance in the 10 µg of total cytosolic proteins loaded. The experiment was repeated three times, each with similar results.

To ensure the specificity of the parkin antibody used in our studies, we performed Western blots on lysates from the rat brainand HEK293 cells transfected with or without FLAG-tagged parkin.Of the five antibodies that we generated against peptides derivedfrom different regions of parkin, the P304 antibody recognizedparkin specifically. As shown in Figure 2, this antibody (PK)detected the same 52 kDa band in the samples, without recognizinganything else. The identity of this band was confirmed by thetransfected FLAG-tagged mouse parkin, which migrated at a slightlyhigher position because of the epitope tag. Preincubation of theantibody with its antigenic peptide completely eliminated thesignals, further demonstrating the specificity of this antibody.

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Figure 2. Generation of a monospecific antibody against parkin. Rat brain homogenates (B) and lysates from HEK293 cells transfected without (C) or with (P) FLAG-tagged mouse parkin were Western blotted (WB) with the antibody against parkin, or the same antibody preincubated with the antigenic peptide, or anti-FLAG. m, Prestained molecular weight marker. The amount of total proteins loaded in lanes B and C was 100 µg, whereas that in lane P was 5 µg, because FLAG-parkin was overexpressed. The experiment was repeated three times, each with similar results.

Parkin binds to $alpha$ / $beta$ tubulin heterodimers

The strong affinity between parkin and microtubules and the fact that very little traditional MAP can remain bound to microtubulesin the presence of 2 M NaCl made us suspect that parkin may bindto tubulin directly. To test this hypothesis, we performed coimmunoprecipitationexperiments in rat brain lysate. Rat brains were homogenized ina lysis buffer containing 1% Triton X-100, without GTP or taxol.After ultracentrifugation, the supernatant factions were incubatedat 4°C in the absence or presence of 25 µM of colchicine for 15min; then they were immunoprecipitated with the parkin antibodypreincubated with or without the antigenic peptide. The immunoprecipitateswere analyzed by Western blots with monoclonal antibodies against $alpha$ - or $beta$ -tubulin, respectively. As shown in Figure 3A, both $alpha$ -and $beta$ -tubulins were strongly coimmunoprecipitated with parkin.The signals were completely eliminated when the parkin antibodywas preincubated with its antigenic peptide, confirming that thecoimmunoprecipitation was indeed caused by parkin. The bindingbetween parkin and $alpha$ - or $beta$ -tubulin was not affected by colchicinetreatment at 4°C, indicating that parkin binds to tubulin $alpha$ / $beta$ heterodimers, which are the predominant form of tubulin at thiscondition.

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Figure 3. The binding between parkin and $alpha$ / $beta$ tubulins. A, Ultracentrifuged rat brain homogenates were incubated in the absence or presence of 25 µM of colchicine at 4°C to ensure the depolymerization of microtubules. They were then immunoprecipitated (IP) with preimmune serum (Pre) or the antibody against parkin (PK) in the absence or presence of the antigenic peptide. The immunoprecipitates and 1% of input (In) were separated by SDS-PAGE, and blotted with antibodies against $alpha$ - or $beta$ -tubulin, respectively. Both tubulins were coimmunoprecipitated with parkin. HC, Heavy chain. B, Cleared lysates from HEK293 cells transfected with or without FLAG-tagged parkin were immunoprecipitated with anti-FLAG. Precipitated proteins and 1% of input were analyzed by Western blotting with antibodies against $alpha$ - or $beta$ -tubulin, respectively. The lysates were also blotted with anti-parkin and anti-FLAG to show the expression level of transfected parkin. All experiments were repeated at least three times.

Similar results were obtained when we transfected FLAG-tagged parkin into HEK293 cells and examined its interaction with endogenous $alpha$ - and $beta$ -tubulins. As shown in Figure 3B, the expression of FLAG-taggedparkin led to a significant increase in its coimmunoprecipitationwith $alpha$ - or $beta$ -tubulin, respectively. The background level of coimmunoprecipitatedtubulins in untransfected cells may be attributable to nonspecificbinding between tubulins and protein A/G-plus agarose used inimmunoprecipitation.

Parkin is localized along microtubules in a punctate manner

The strong binding between parkin and microtubules suggests that they may be colocalized. To test this, we costained rat embryoniccortical neurons cultured for 21 d in vitro with anti-parkin (Fig.4A), anti- $alpha$ -tubulin (Fig. 4B), and the DNA-binding dye TO-PRO-3(merged in Fig. 4C). The punctate subcellular localization ofparkin largely coincided with microtubules, as shown by the strongyellow signals, especially in the processes (Fig. 4C and inset).Colocalization analysis indicated that 98% of the parkin signalscoincided with $alpha$ -tubulin signals, whereas 70% of $alpha$ -tubulin signalscoincided with those of parkin (Fig. 4D). On the other hand, neitherparkin nor $alpha$ -tubulin signals were in the nucleus (colocalizationcoefficient, 0.04) (Fig. 4E,F), which is consistent with theircolocalization and the well-established absence of microtubulesin the nucleus. To ensure the specificity of the parkin antibody,we stained cultured neurons with the primary antibodies preincubatedwith the parkin antigenic peptide and obtained no significantsignal from the rhodamine channel (Fig. 4G), whereas signals fromother channels were intact (data not shown). The cultures thatwe used also contained a small number of glial cells. The subcellularlocalization of parkin in these cells was the same as that inneurons: punctate dots along microtubules (Fig. 4H and inset).In addition, we have cultured neurons from different brain regions,such as the substantia nigra and hippocampus. There was no differencein the subcellular localization of parkin in neurons from differentregions, nor was there any difference between dopaminergic neuronsand nondopaminergic neurons (data not shown). To ascertain whetherwhat we saw in cultured neurons represented the situation in thebrain, we costained adult rat brain sections with anti-parkin(red), anti- $beta$ -tubulin (green), and TO-PRO-3 (blue). As shown inthe merged image in Figure 4I, parkin immunostaining was punctate,decorating along $beta$ -tubulin signals, which were most prominentin the processes. Thus, the subcellular localization of parkinappears very similar in culture and in vivo: punctate dots alongmicrotubules.

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Figure 4. Punctate subcellular localization of parkin along microtubules in rat neurons and glial cells. Cultured rat embryonic cortical neurons were costained with anti-parkin (A), anti- $alpha$ -tubulin (B), and the DNA-binding dye TO-PRO-3. Confocal images from rhodamine channel (parkin, red), FITC channel ( $alpha$ -tubulin, green), and Cy5 channel (DNA, blue) were merged (C). Inset, Enlarged portion of the composite showing punctate staining of parkin along microtubules. D, Fluorogram showing the degree of colocalization between red signals (parkin) and green signals (microtubule). Colocalization coefficients indicate that 98% of the red signals have green components, whereas 70% of the green signals have red components. E, Fluorogram showing the degree of colocalization between green signals ( $alpha$ -tubulin) and blue signals (DNA). The lack of $alpha$ -tubulin in the nucleus is indicated by the small coefficient (0.04). F, Fluorogram showing the degree of colocalization between red signals (parkin) and blue signals (DNA). The lack of parkin in the nucleus is indicated by the small coefficient (0.04). G, No significant signal was observed in the rhodamine channel when the parkin antigenic peptide was mixed with the primary antibodies, demonstrating the specificity of parkin staining. Signals from other channels were unaffected (data not shown). H, Merged images of a glial cell in the same culture showing punctate staining of parkin (red) along microtubules ( $alpha$ -tubulin, green). Inset, Enlarged portion of the composite. I, Merged images of an adult rat brain section showing punctate staining of parkin (red) along microtubules ( $beta$ -tubulin, green). Scale bars, 10 µm. At least 10 sets of images were taken from 5 coverslips, all with similar results.

To confirm that parkin puncta are indeed localized on microtubules, we treated rat neuronal cultures (Fig. 5A,B), human neuroblastomacell line SH-SY5Y (Fig. 5C,D), and mouse fibroblast cell lineNIH 3T3 (Fig. 5E,F) with or without the microtubule-depolymerizingdrug colchicine (25 µM for 12 hr). The treatment changed the subcellularlocalization of parkin from puncta along microtubules (Fig. 5A,C,E)to diffusely cytosolic (Fig. 5B,D,F). Taken together with otherlines of evidence described above, it demonstrates that parkinpuncta are indeed associated with microtubules. The data alsoshow that the microtubule-associated, punctate subcellular localizationof parkin is a general phenomenon in a variety of cell types,including neurons, glial cells (Fig. 5A), and drastically differentcell lines (Fig. 5C,E), despite the varying level of its expression.

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Figure 5. Disruption of the punctate subcellular localization of parkin by colchicine. Primary rat neuronal cultures (A, B), human neuroblastoma cell line SH-SY5Y (C, D) and mouse fibroblast cell line NIH 3T3 were treated with (+Col, B, D, F) or without ( $-$ Col, A, C, E) colchicine, and costained with anti-parkin (red), anti- $alpha$ -tubulin (green) and TO-PRO-3 (blue). Colchicine depolymerized microtubules and changed the localization pattern of parkin from punctate to diffusely cytosolic. Insets, Enlarged portion of the main image showing punctate localization of parkin along microtubules. Scale bar, 10 µm.

A previous report (Fallon et al., 2002) showed that parkin was colocalized with calmodulin-sensitive kinase in a punctatemanner in postsynaptic densities (PSDs). To ascertain whetherthe punctate staining pattern of parkin that we saw was PSD ornot, we costained rat cortical neurons with antibodies againstparkin and PSD-95 (a marker for PSD). As shown in Figure 6A, thesubcellular localization of parkin and PSD95 appeared to be separated,with almost no yellow spots. Furthermore, using our parkin antibody(P304) in Western blots, we saw that the majority of parkin wasin the Triton X-100-soluble fraction, rather than the pellet fraction,which contains PSD. To provide more evidence, we costained cultureneurons with rhodamine-conjugated phalloidin and anti-parkin.In mature neurons, the actin-binding compound phalloidin recognizesdendritic spines, where most PSDs are localized. The lack of overlappingbetween phalloidin puncta and parkin staining in Figure 6B showedthat parkin was not colocalized with PSD. These results, combinedwith the same pattern of the subcellular localization of parkinin non-neuronal cells which do not have PSD (Fig. 5C,E), demonstratethat parkin puncta are not in the PSD. Costaining of parkin andsynaptophysin showed that parkin was not colocalized with presynapticterminals either (Fig. 6C), which is consistent with previousreports (Fallon et al., 2002).

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Figure 6. Parkin is not colocalized with PSDs or presynaptic terminals. A, Cultured rat cortical neurons were stained with antibodies against parkin (PKN) and PSD95. Confocal images from rhodamine channel (parkin, red) and FITC channel (PSD95, green) were pseudocolored and merged. B, Cultured rat cortical neurons were stained with rhodamine-conjugated phalloidin (Pha) and anti-parkin (PKN). Confocal images from the rhodamine channel (staining actin in spines, red) and FITC channel (parkin, green) were pseudocolored and merged. C, Cultured rat cortical neurons were stained with antibodies against parkin and synaptophysin (SYN). Confocal images from the rhodamine channel (parkin, red) and FITC channel (synaptophysin, green) were pseudocolored and merged. Insets, Enlarged portions of the main pictures showing lack of colocalization of signals.

In addition to the monospecific antibody against parkin (P304), we also used another antibody, P124, which recognized parkinas a major band and a few minor bands as well on Western blots.Nevertheless, the P124 antibody gave similar results with regardto the subcellular localization of parkin, coassembly with microtubulesand binding to tubulin heterodimers, albeit with higher backgroundnoise (data notshown).

Parkin enhances ubiquitination of $alpha$ - and $beta$ -tubulins

The above results show that parkin binds to microtubules and tubulin and is localized in a punctate manner along microtubules.Because parkin is an E3 protein-ubiquitin ligase, it is possiblethat parkin may enhance the ubiquitination of tubulin. To investigatethis possibility, we cotransfected HA-tagged ubiquitin withoutor with FLAG-tagged parkin into HEK293 cells. Cell lysates wereimmunoprecipitated with antibodies against $alpha$ -tubulin (Fig. 7A)or $beta$ -tubulin (Fig. 7C). Precipitated proteins were Western-blottedwith anti-HA to examine the ubiquitination of endogenous $alpha$ - or $beta$ -tubulin. As shown in Figure 7A, the overexpression of parkinled to an increased amount of polyubiquitinated $alpha$ -tubulin. Whenthe cells were treated with lactacystin (1 µM for 12 hr), whichspecifically inhibits proteases in the 26S proteasome (Fenteanyand Schreiber, 1998), an additional increase in the amount ofpolyubiquitinated $alpha$ -tubulin was observed. Lactacystin treatmentalone (lane 5) did not cause any significant increase over thebasal level of polyubiquitinated $alpha$ -tubulin (lane 2), which maybe produced by either endogenous parkin or other E3 ligases inHEK293 cells. Similar effects were observed for $beta$ -tubulin in Figure7C. The same set of $alpha$ - or $beta$ -tubulin immunoprecipitates were alsoseparated side by side with cell lysate and blotted with antibodiesagainst $alpha$ -tubulin (Fig. 7B) or $beta$ -tubulin (Fig. 7D). The amountof $alpha$ - or $beta$ -tubulins immunoprecipitated were the same across thelanes, respectively. These results show that parkin enhances theubiquitination of $alpha$ - and $beta$ -tubulins in HEK293 cells. To understandthe full extent of the E3 ligase activity of parkin, Western blotsusing anti-HA were performed on total cell lysates from the sameset of samples. As shown in Figure 7E, parkin enhanced the ubiquitinationof many proteins in HEK293 cells (lane 3 vs lane 2). An equalexpression level of transfected parkin was shown in the anti-FLAGblot in Figure 7F.

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Figure 7. Parkin enhances the ubiquitination of $alpha$ - and $beta$ -tubulins in HEK293 cells. HEK293 cells were transfected without or with HA-tagged ubiquitin (HA-Ub) and Flag-tagged parkin (F-PKN), and were treated without or with 1 µM lactacystin (Lac) for 12 hr. Cleared cell lysates were immunoprecipitated with antibodies against $alpha$ -tubulin (A, B) or $beta$ -tubulin (C, D). Half of the precipitates were blotted with anti-HA (A, C), whereas the other half were blotted with anti- $alpha$ -tubulin (B) or anti- $beta$ -tubulin (D). Cell lysates (10 µg total proteins, lane 6 in B and D) were loaded next to the lanes containing tubulin immunoprecipitates to indicate the position of $alpha$ - or $beta$ -tubulin (arrow). Ubiquitinated tubulin proteins are marked with a bracket. *IgG heavy chain. The same set of cell lysates (100 µg total proteins in each lane) were also blotted with anti-HA (E) to show ubiquitinated proteins, or with anti-FLAG (F) to show the expression level of transfected parkin; #, nonspecific bands recognized by anti-HA in total cell lysates.

To ascertain whether the ubiquitination of $alpha$ - and $beta$ -tubulin observed in HEK293 cells occurs under normal physiological conditionsin the brain, we immunoprecipitated $alpha$ - or $beta$ -tubulin from ultracentrifugedrat brain lysates and analyzed the precipitated proteins by Westernblotting with anti-ubiquitin. As shown in the left panel of Figure8, the $alpha$ -tubulin antibody immunoprecipitated two proteins (bandsa and c) that can be recognized by both anti-ubiquitin and anti- $alpha$ -tubulin.The size of the two bands suggests that a is probably penta-ubiquitinated $alpha$ -tubulin and c is probably partially degraded ubiquitinated $alpha$ -tubulin.The ability of the $alpha$ -tubulin antibody to immunoprecipitate $alpha$ -tubulinitself was demonstrated by the presence of band b in the $alpha$ -tubulinblot, which migrated at the same size as the band recognized bythe Western blot of the rat brain lysate. Similar results wereobtained for $beta$ -tubulin in Figure 8 (right). Distinct bands ofpolyubiquitinated $beta$ -tubulin were recognized by both anti-ubiquitinand anti- $beta$ -tubulin (bands d), whereas bands f probably representedpartially degraded ubiquitinated $beta$ -tubulin. The ability of the $beta$ -tubulin antibody to immunoprecipitate the protein itself wasconfirmed by the presence of band e, which was a little smallerin molecular weight than $alpha$ -tubulin (band b). The tight bindingbetween $alpha$ - and $beta$ -tubulins means that either antibody would pulldown $alpha$ / $beta$ tubulin heterodimers. The specificity of these well establishedantibodies and their recognition of the same bands seen in ubiquitinblots indicate that both tubulins are ubiquitinated in vivo. Thesizes of the largest ubiquitinated $alpha$ - and $beta$ -tubulin species inFigure 8 are very similar to those ~100 kDa bands in Figure 7,A and B, which suggests that the situation in transfected HEK293cells largely mimics the conditions in the rat brain. The high-molecular-weightspecies of ubiquitinated tubulins (Fig. 7A,B, 200-300 kDa bands)were not observed in rat brain lysate. They are perhaps additionallyubiquitinated products of the ~100 kDa species by parkin overexpressedin HEK293 cells.

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Figure 8. Ubiquitinated $alpha$ - and $beta$ -tubulin in rat brain lysate. Ultracentrifuged rat brain lysates were immunoprecipitated with an irrelevant polyclonal antibody (anti-neurabin, n), anti- $alpha$ -tubulin ( $alpha$ ) or anti- $beta$ -tubulin ( $beta$ ). Immunoprecipitates were analyzed by Western blotting with anti-ubiquitin (Ub), anti- $alpha$ -tubulin or anti- $beta$ -tubulin. Rat brain lysates (5 µg total proteins, $-$ ) were loaded next to the lanes containing tubulin immunoprecipitates to indicate the position of $alpha$ - or $beta$ -tubulin. Bands: a, d, ubiquitinated $alpha$ - or $beta$ -tubulin; b, e, $alpha$ - or $beta$ -tubulin; c, f, partially degraded ubiquitinated $alpha$ - or $beta$ -tubulin; HC, IgG heavy chain; LC, IgG light chain.

Parkin mutants found in PD patients do not ubiquitinate $alpha$ - or $beta$ -tubulin

To provide more evidence that parkin is an E3 ligase for tubulin and to test whether such enzymatic activity is affected bymutations found in PD patients, we transfected HEK293 cells withFLAG-tagged human wild-type parkin or three point mutants (K161N,T240R, and C431F) (Fig. 9A) that are linked to AR-JP (Giassonand Lee, 2001) along with HA-tagged ubiquitin. After the celllysates were immunoprecipitated with antibodies against $alpha$ - or $beta$ -tubulin, respectively, precipitated proteins were analyzed byWestern blotting with anti-HA. As shown in Figure 9B, only wild-typeparkin caused a significant increase in the ubiquitination of $alpha$ - and $beta$ -tubulins, and none of the mutants were capable of ubiquitinatingeither tubulin. When we analyzed the cell lysates by HA Westernblot, it was clear that these mutants did not have any significantE3 ligase activity over the background level caused by other E3ligases in the cell (Fig. 9C). This is consistent with previousstudies using these mutants (Giasson and Lee, 2001). The expressionlevels of wild-type and mutant parkin constructs were comparablein these experiments (Fig. 9D).

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Figure 9. Parkin mutants found in PD patients cannot ubiquitinate $alpha$ - and $beta$ -tubulin. A, Diagram showing the location of three point mutations found in PD patients. U, Ubiquitin-like domain; R, RING finger domain; I, in-between RING finger domain. B, HEK293 cells were transfected with FLAG-tagged human wild-type (w) or mutant (a, b, or c as shown in A) parkin- and HA-tagged ubiquitin. Cell lysates were immunoprecipitated with antibodies against $alpha$ -tubulin (left) or $beta$ -tubulin (right). Precipitated proteins were blotted with anti-HA to show the ubiquitination of either tubulin (indicated by the bracket). *IgG heavy chain. The same set of cell lysates was also blotted with anti-HA to show the E3 ligase activity of wild-type and mutant parkin (C) or anti-FLAG to show the expression level of these parkin constructs (D). #, Nonspecific bands recognized by anti-HA in HEK293 cell lysates. All experiments were repeated at least three times, each with similar results.

Parkin, but not its mutants linked to PD, accelerates degradation of $alpha$ - and $beta$ -tubulins

Because parkin enhanced the ubiquitination of $alpha$ - and $beta$ -tubulins, it should also facilitate their degradation by the 26S proteasome.To test this, we transfected HEK293 cells with or without parkinand treated the cells with the protein synthesis inhibitor puromycin(100 µM) for various durations. We also transfected cells withthe three point mutants that did not ubiquitinate $alpha$ - or $beta$ -tubulin(Fig. 9) to see if these PD-linked mutations affect the abilityof parkin to degrade tubulins. Equal fractions (1%) of total celllysates were separated on SDS-PAGE and analyzed by Western blotswith antibodies against $alpha$ -tubulin, $beta$ -tubulin, or parkin, respectively.Without synthesis of new proteins, the level of $alpha$ - or $beta$ -tubulinin these cells should reflect their rates of degradation. As shownin Figure 10A, the amount of $alpha$ -tubulin decreased much faster inHEK293 cells transfected with wild-type parkin, compared withcells untransfected or transfected with any one of the three pointmutants. Similar effects were observed for $beta$ -tubulin degradation.The amount of endogenous parkin in untransfected cells was significantlyreduced at 12 and 24 hr of puromycin treatment. However, the levelof transfected wild-type or mutant parkin was not significantlyaffected by the puromycin treatment, perhaps because of the overexpressionof the constructs.

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Figure 10. Parkin, but not its mutant-linked PD, accelerates the degradation of $alpha$ - and $beta$ -tubulin. HEK293 cells were transfected without or with various parkin constructs [wild-type (WT), K161N, T240R, or C431F mutant] and treated with puromycin (100 µM) for different duration. Equal fractions (1%) of total cell lysates were Western-blotted with anti- $alpha$ -tubulin, anti- $beta$ -tubulin, or anti-parkin (A). Only wild-type parkin significantly accelerated the degradation of $alpha$ - and $beta$ -tubulin at 12 and 24 hr of treatment, compared with cells untransfected or transfected with any one of the point mutants. Expression levels of transfected parkin constructs were not significantly affected by puromycin treatment. Results from four experiments were quantified and normalized against the amount of $alpha$ -tubulin (B) or $beta$ -tubulin (C) at 0 hr of treatment. *p < 0.05, paired t test, compared with no parkin transfection at 12 or 24 hr of puromycin treatment.

A significant difference was found in the level of $alpha$ - or $beta$ -tubulin between untransfected cells and cells transfected withwild-type parkin at 12 and 24 hr of puromycin treatment (p < 0.05,n = 4 experiments, paired t test) (Fig. 10B,C). Tubulin degradationrates were not significantly different between cells untransfectedor transfected with any one of the three mutants (p > 0.05) (Fig.10B,C). The much faster rate for the degradation of $alpha$ - and $beta$ -tubulinin the presence of parkin, but not its mutants that lack E3 ligaseactivity, shows that parkin enhances the turnover of both tubulins,most likely through increasing theirubiquitination.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

In this report, we describe the strong binding and colocalization between parkin and microtubules. In contrast to typicalMAPs, which bind to microtubules primarily through electrostaticinteractions, parkin cannot be dissociated from microtubules with2 M of NaCl. It suggests that this interaction is mostly hydrophobicin nature. The strong binding appears to be caused by direct interactionsbetween parkin and tubulin $alpha$ / $beta$ heterodimers, the building blocksof microtubules. In our coimmunoprecipitation experiment (Fig.3), we pretreated ultracentrifuged brain lysates with colchicineat 4°C to ensure that microtubules were completely depolymerizedinto tubulin heterodimers. The large amount of $alpha$ - and $beta$ -tubulinscoimmunoprecipitated with parkin at this condition suggests thatparkin binds to tubulin $alpha$ / $beta$ heterodimers with high affinity. Evenin high salt conditions, the coimmunoprecipitation could not bedisrupted (data not shown), which is consistent with the tightbinding between parkin and microtubules. Additional studies arenecessary to purify parkin from tubulins and measure the dissociationconstant and stoichiometry of the interaction between parkin andtubulin heterodimers, as well as that between parkin and puremicrotubules. It would also be interesting to investigate therole of parkin in microtubule assembly, stability, and dynamicproperties.

The interaction between parkin and $alpha$ / $beta$ tubulin apparently enhances the ubiquitination and degradation of both tubulins. Theexpression of transfected parkin in HEK293 cells significantlyincreased the ubiquitination of $alpha$ - and $beta$ -tubulins (Fig. 7A,C).This effect was shown to be dependent on the E3 ligase activityof parkin. Three point mutations found in PD patients (K161N,T240R, C431F) abolished the E3 ligase activity of parkin towardtubulins (Fig. 9B) and other substrates (Fig. 9C) in the cell.These data indicate that parkin is a protein-ubiquitin E3 ligasefor $alpha$ - and $beta$ -tubulin. This is confirmed by the results that parkin,but not its PD-linked mutants that lack E3 ligase activity, acceleratedthe degradation of both $alpha$ - and $beta$ -tubulins (Fig. 10).

To ensure that what we saw in HEK293 cells was not an artifact attributable to the overexpression of parkin, we examined theubiquitination of tubulins in the rat brain. Indeed, similarlyubiquitinated $alpha$ - and $beta$ -tubulins (Figs. 7A,C, 8, ~100 kDa bands)were observed in both systems, suggesting that a fraction of $alpha$ -and $beta$ -tubulins are in fact ubiquitinated in vivo under normalconditions. The size of these bands indicates that they are probablypenta-ubiquitinated tubulins. The minimal length of polyubiquitinchain that can be efficiently recognized by the 26S proteasomeis generally believed to be 4-5 ubiquitin molecules (Hershko andCiechanover, 1998). This might be why we saw distinct bands ofpenta-ubiquitinated tubulins in the brain; additional ubiquitinationof these products would promote their rapid degradation. In transfectedHEK293 cells, the overexpression of parkin would produce the wholerange of polyubiquitinated tubulins in addition to the penta-ubiquitinatedspecies. The balance between ubiquitination enzymes and de-ubiquitinationenzymes, as well as activity of the 26S proteasomes ultimatelydetermines the steady-state distribution of various polyubiquitinatedspecies. Regardless of the details of how parkin ubiquitinates $alpha$ - and $beta$ -tubulin, the expression of transfected parkin in HEK293cells accelerated the degradation of both tubulins, which furthercorroborates that parkin is an E3 ligase for $alpha$ - and $beta$ -tubulins.

Because tubulin can exist stably in the cell only as heterodimers or as polymers of the heterodimers (i.e., microtubules),the most likely source of ubiquitinated tubulin may be misfoldedtubulin. Indeed, the correct folding of each monomer and the formationof functional heterodimers require coordinated actions of a seriesof cellular chaperonins and tubulin-specific folding cofactors(for review, see Lewis et al., 1997). The complex and reversiblenature of the folding process would inevitably result in the productionof misfolded intermediates, which were believed to be quicklydegraded through an unknown mechanism. Our results indicate thatparkin may be responsible for the ubiquitination of misfolded $alpha$ - and $beta$ -tubulin. Once tubulins are ubiquitinated, they are apparentlyrecognized and degraded by the 26S proteasome, because our datashowed that parkin also accelerated the turnover rate of bothtubulins (Fig. 10).

In addition to the folding process, which would inherently produce a small amount of misfolded tubulin, sudden depolymerizationof microtubules, e.g., by colchicine, results in increased ubiquitinationand degradation of tubulin (Y.R. and J.F., unpublished observations).When the concentration of tubulin heterodimers is too high, thecell shuts down tubulin synthesis by degrading its mRNA beingtranslated on polysomes (Pachter et al., 1987). However, this"autoregulation" mechanism may not be able to reduce the freetubulin concentration quickly if microtubules are suddenly depolymerizedby drugs like colchicine. In such a case, parkin may play a criticalrole in ubiquitinating excess tubulin heterodimers so that theycan be efficiently degraded by the 26S proteasome. However, itis unclear whether the E3 ligase activity of parkin has any preferencetoward misfolded tubulin polypeptides or properly folded heterodimers.Additional studies are necessary to resolve thisissue.

MPP⁺ and rotenone are two neurotoxins that cause the selective death of DA neurons and PD-like symptoms in human subjects oranimals (Langston et al., 1983; Betarbet et al., 2000). In additionto their widely recognized ability to inhibit complex I of themitochondrial respiratory chain (Mizuno et al., 1987; Higginsand Greenamyre, 1996), they also strongly induce the depolymerizationof microtubules in vivo and in vitro (Brinkley et al., 1974; Marshalland Himes, 1978; Cappelletti et al., 1999, 2001). On the otherhand, the inhibition of complex I by either toxin leads to overproductionof reactive oxygen species, which covalently modify many cellularproteins and increase their misfolding. The combination of thetwo activities of these toxins would produce a significant amountof misfolded tubulin in the cell, which may be toxic (Burke etal., 1989; Weinstein and Solomon, 1990). Thus, the ability ofparkin to ubiquitinate misfolded tubulin and accelerate its degradationmay be crucial to the survival of any cell affected by MPP⁺ or rotenone. In the case of MPP⁺, its selective uptake by DA neurons through the DA transporterrenders these cells particularly vulnerable (Przedborski and Jackson-Lewis,1998). Although rotenone is nonselectively absorbed by many typesof tissues because of its hydrophobicity, it appears to causespecific degeneration of nigral DA neurons (Betarbet et al., 2000),which suggests that these cells are particularly vulnerable torotenone-inducedtoxicity.

Because microtubules play obligatory functions in the maintenance of cellular morphology and intracellular transport, theirdepolymerization by either toxin would cause significant damageto the cell, especially for long projection neurons such as DAcells on the nigrostriatal pathway. Among the many things thatcould be affected by microtubule depolymerization, the lack ofsufficient transport of DA vesicles to the terminal would directlyreduce DA release in the striatum. Thus, the microtubule-depolymerizingactivity of MPP⁺ and rotenone may significantly affect the normal functions ofnigral DA neurons. Parkin, through its ability to ubiquitinateand degrade misfolded tubulin, may protect neurons from the toxicaccumulation of misfolded tubulin, particularly when the cellsare exposed to neurotoxins such as MPP⁺ androtenone.

Although it is not clear whether AR-JP patients with parkin mutations exhibit microtubule abnormalities, future studies arewarranted to examine the ubiquitination of tubulins in these brains.In the rotenone model of PD, the degeneration of dopamine neuronsappears to be more prominent at neuronal terminals and processescompared with the cell bodies (Betarbet et al., 2000). The lowlevel of rotenone used in those studies (30 nM in the rat brain)may cause only a small amount of microtubule depolymerization.This may cause more harm to the terminals and processes than tothe cell bodies, because tubulin synthesis can rapidly replenishdamaged microtubules in the cell bodies, but not those in theterminals and distal processes, because newly formed microtubulesneed to be transported along old microtubules to these places(Baas, 1997, 2002).

In summary, our results show that parkin strongly binds to microtubules and tubulin $alpha$ / $beta$ heterodimers. It also enhances theubiquitination and degradation of $alpha$ - and $beta$ -tubulin. This E3 ligaseactivity of parkin may play an important role in handling misfoldedtubulins produced during their complex and reversible foldingprocesses, as well as those produced by microtubule-depolymerizingactivities of drugs that causePD.

  FOOTNOTES

Received Nov. 15, 2002; revised Jan. 10, 2003; accepted Jan. 29, 2003.

This work is supported by National Institutes of Health Grant NS41722 (J.F.) and Howard Hughes Medical Institute BiomedicalResearch Support Program Grant 53000261 (State University of NewYork atBuffalo).

Correspondence should be addressed to Dr. Jian Feng, Department of Physiology and Biophysics, State University of New Yorkat Buffalo, 124 Sherman Hall, Buffalo, NY 14214. E-mail: jianfeng{at}buffalo.edu.

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Materials and Methods
Results
Discussion
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Parkin Binds to / Tubulin and Increases their Ubiquitination and Degradation

Parkin Binds to $alpha$ / $beta$ Tubulin and Increases their Ubiquitination and Degradation