N-Terminal Ubiquitination of Extracellular Signal-Regulated Kinase 3 and p21 Directs Their Degradation by the Proteasome

Extracellular signal-regulated kinase 3 (ERK3) is an unstablemitogen-activated protein kinase homologue that is constitutivelydegraded by the ubiquitin-proteasome pathway in proliferatingcells. Here we show that a lysineless mutant of ERK3 is stillubiquitinated in vivo and requires a functional ubiquitin conjugationpathway for its degradation. Addition of N-terminal sequencetags of increasing size stabilizes ERK3 by preventing its ubiquitination.Importantly, we identified a fusion peptide between the N-terminalmethionine of ERK3 and the C-terminal glycine of ubiquitin invivo by tandem mass spectrometry analysis. These findings demonstratethat ERK3 is conjugated to ubiquitin via its free NH₂ terminus.We found that large N-terminal tags also stabilize the expressionof the cell cycle inhibitor p21 but not that of substrates ubiquitinatedon internal lysine residues. Consistent with this observation,lysineless p21 is ubiquitinated and degraded in a ubiquitin-dependentmanner in intact cells. Our results suggests that N-terminalubiquitination is a more prevalent modification than originallyrecognized.

INTRODUCTION

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Introduction

The ubiquitin/proteasome proteolytic pathway is an evolutionarilyconserved regulatory system that controls a host of cellularprocesses, including transcription, cell cycle progression,differentiation and development, tumor suppression, and immuneresponses (17). Malfunctioning of the system, as a result ofeither loss-of-function mutations or abnormal activity, hasbeen implicated in the pathogenesis of cancer and of many otherhuman diseases (17, 28). Proteins targeted for degradation bythe 26S proteasome are generally tagged with multiple copiesof ubiquitin, which serve as a recognition signal for the 19Sregulatory particle. The formation of ubiquitin conjugates isa highly regulated process that requires the sequential actionof three enzymes (20). The last step, which is catalyzed bya large family of E3 ubiquitin ligases, confers specificityto the reaction.

For most proteins, the first ubiquitin molecule is attachedvia an isopeptide bond formed between its C-terminal glycineresidue and the ${varepsilon}$ -NH₂ group of an internal lysine of the substrate.The polyubiquitin chain is then synthesized by the successiveconjugation of ubiquitin molecules to an internal lysine ofthe previously conjugated ubiquitin. There is no consensus aboutthe positioning of internal lysines that are conjugated to ubiquitin,although a number of studies have highlighted the importanceof specific lysine residues. For example, study of Sic1 ubiquitinationhas revealed that some lysines are more efficiently ubiquitinatedthan others and, most importantly, that only 6 N-terminal lysinesout of 20 support efficient degradation by the 26S proteasome(31). Structural analysis of ß-catenin ubiquitinationby SCF^ß-TrCP has shown that the position of the lysineupstream of the ß-transducin repeat-containing protein(ß-TrCP) binding site greatly influences the rateof ubiquitin ligation (45). The sites of lysine ubiquitinationhave been mapped for some well-characterized protein substrates,such as p53 (34), SOCS3 (36), and I ${kappa}$ B ${alpha}$ (1, 37). Replacement ofthese specific lysines stabilizes the mutant protein, suggestingthat they are at least necessary for degradation. However, forthe majority of proteasome substrates, the precise ubiquitinationsite(s) has not been characterized.

Alternative modes of substrate recognition and targeting havealso been described. In the case of the transcriptional activatorMyoD, the free ${alpha}$ -NH₂ terminus of the protein serves as the conjugationsite for ubiquitin (7). For a small number of proteins, suchas ornithine decarboxylase (13), the cell cycle inhibitor p21(40), and ${alpha}$ -synuclein (41), it has been suggested that degradationby the proteasome occurs in an ubiquitin-independent manner.However, although purified recombinant p21 and ${alpha}$ -synuclein canbe efficiently degraded by the proteasome in vitro (25), itremains unclear if degradation of these substrates in vivo isindependent of a functional ubiquitin system. The observationthat p21-ubiquitin conjugates are formed in vivo is also intriguing(8, 26, 35, 40).

Extracellular signal-regulated kinase 3 (ERK3) is a distantlyrelated member of the mitogen-activated protein (MAP) kinasesuperfamily (30, 43). Although the exact physiological functionsof ERK3 remain to be established, accumulating evidence pointsto a role for the kinase in the control of cell differentiation.ERK3 transcripts are upregulated during differentiation of P19embryonal carcinoma cells into neuronal or muscle cells (6).ERK3 protein also markedly accumulates during differentiationof C2C12 myoblasts into muscle cells, with kinetics parallelto that of p21 (14). Notably, overexpression of ERK3 in fibroblastscauses cell cycle arrest. Unlike conventional MAP kinases, ERK3is a highly unstable protein that is constitutively degradedby the ubiquitin-proteasome pathway in proliferating cells (14).We have identified two degrons in the N-terminal lobe of thekinase domain that are both necessary and sufficient to promoteERK3 degradation.

To further understand the mechanism of ERK3 degradation, wehave mapped the ubiquitination site(s) of the protein. We reporthere that ERK3 is ubiquitinated and degraded by the proteasomein a lysine-independent fashion. We show that addition of N-terminalsequence tags of increasing sizes efficiently inhibits N-terminalbut not lysine-dependent ubiquitination of protein substrates.In the course of these studies, we also found that proteasomedegradation of p21 is independent of the presence of lysineresidues but is dependent on a functional ubiquitination pathway.Our results suggest that N-terminal ubiquitination may be amore widespread phenomenon than originally anticipated.

MATERIALS AND METHODS

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Materials and Methods

Reagents and antibodies. The source of reagents has been described previously (14). Tumornecrosis factor alpha (TNF- ${alpha}$ ) was obtained from R&D Systems.Polyclonal anti-hemagglutinin (HA) antibody was from Santa-CruzBiotechnology. The polyclonal antibody to the C terminus ofERK3 (E3-CTE4) was described previously (14).

Plasmid constructs and mutagenesis. Mutations were introduced into human ERK3 (27) and human p21(16) cDNAs by using the Altered Sites In Vitro Mutagenesis system(Promega). pcDNA3-HA-ERK3, HA-ERK3 ${Delta}$ , and HA-ERK1 have alreadybeen described (14). To construct the C-terminal His₆-taggedexpression vectors, two oligonucleotides coding for His₆ tagsequence were inserted into the EcoRI/XbaI sites of pcDNA3-HA.The coding sequences of ERK3 ${Delta}$ , ERK3 ${Delta}$ -0K, p21, and p21-0K weresubcloned in frame into the EcoRI site. To construct the N-terminalHis₆-tagged ERK3, two oligonucleotides encoding the sequenceMRGSHHHHHHGIS were introduced downstream of a Kozak sequence.Myc₆-ERK3 was constructed by first subcloning the Myc₆ tag sequencederived from pCS3MT (a gift from A. J. Waskiewicz) into theBamHI/EcoRI sites of pcDNA3 to yield pcDNA3-Myc₆. The ERK3 codingsequence was then subcloned into pcDNA3-Myc₆. Enhanced greenfluorescent protein (EGFP)-ERK3 was constructed by first insertingthe EGFP sequence (Clontech) into the KpnI/EcoRI sites of pcDNA3.The ERK3 coding sequence was then subcloned into the EcoRI siteof the resulting vector. To construct Myc_n-ERK3 expression vectors,a pair of oligonucleotides coding for a unique Myc epitope wassequentially cloned into the EcoRI/XbaI sites of pcDNA3-Koz,which was designed to contain a Met initiator codon into a consensusKozak sequence. ERK3-EGFP was constructed by first subcloningthe EGFP coding sequence into pcDNA3-Koz. The full-length ERK3was then ligated in frame upstream of EGFP. Glutathione S-transferase(GST)-tagged ERK3-EGFP and EGFP-ERK3 were constructed by subcloningthe GST sequence, derived from pGEX-KG (18), into the EcoRI/XbaIsites of the respective pcDNA3 vectors. To generate the M₅HAexpression vector, the sixth Myc epitope was first replacedby an HA tag by inserting a set of oligonucleotides into theNcoI/EcoRI sites of pCS3MT. The resulting M₅HA tag was thensubcloned into the BamHI/EcoRI sites of pcDNA3 to yield pcDNA3-M₅HA.The coding sequences of hamster ERK1, human ERK3, human SOCS3(gift from A. Yoshimura), human p53 (gift from G. Ferbeyre),human I ${kappa}$ B ${alpha}$ (gift from J. Hiscott), and human p21 were subclonedinto the EcoRI/XbaI sites of pcDNA3-M₅HA. pMT123 vector encodingHA-tagged ubiquitin was kindly provided by Dirk Bohmann (42).All mutations were confirmed by DNA sequencing. Sequence ofthe primers used for PCR and details about the cloning strategiesare available upon request.

Cell culture and transfections. Human embryonic kidney 293 (HEK 293), A31, and ts20 cells werecultured as described previously (14). HEK 293 cells were transfectedby the calcium phosphate coprecipitation method. A31 and ts20cells were transfected with Lipofectamine reagent (Invitrogen).

Protein biochemistry methods and immunofluorescence. Cell lysis, protein precipitation, and immunoblot analysis wereperformed as previously described (14, 39). Protein concentrationswere measured by using the bicinchoninic acid assay (Pierce),and equal amounts of lysate proteins were subjected to sodiumdodecyl sulfate (SDS)-gel electrophoresis. In vivo phosphorylationanalysis and immunofluorescence studies were based on techniquespreviously described (33). In vitro transcription and translationwas carried out using the TNT Coupled Reticulocyte Lysate system(Promega) according to the manufacturer's instructions. Thereaction products were detected by fluorography with Amplify(Amersham).

In vivo ubiquitination assays. HEK 293 cells were cotransfected with the indicated expressionvectors (4 µg) together with HA-tagged ubiquitin (2 µg).After 36 h, the cells were treated with 25 µM MG-132 for12 h. For purification of C-terminal His₆-tagged proteins, thecells were lysed in buffer lacking EDTA and were supplementedwith 20 mM imidazole and 10 mM N-ethyl maleimide (NEM). Celllysates (750 µg of protein) were incubated with 20 µlof Ni-nitrilotriacetic acid agarose beads (QIAGEN) for 2 h at4°C with constant agitation. The beads were washed threetimes with lysis buffer without NEM. Proteins were separatedby SDS-gel electrophoresis and were detected by immunoblottingwith anti-HA monoclonal antibody 12CA5. C-terminal GST-taggedproteins were purified by using glutathione-conjugated agarosebeads (Pharmacia). The cells were lysed in Triton X-100 lysisbuffer supplemented with 10 mM NEM, and the clarified lysateswere further incubated for 10 min with 2.5 mM dithiothreitolto quench free NEM. Cell lysates (750 µg of protein) wereincubated for 2 h at 4°C with 20 µl of glutathione-agaroseresin. The bound proteins were washed four times in lysis bufferand were resolved by SDS-gel electrophoresis.

MS analysis. Twenty 10-cm-diameter culture dishes of HEK 293 cells were transfectedwith expression vectors encoding ERK3 ${Delta}$ or p21 tagged at the Nterminus with HA and tagged at the C terminus with GST. After36 h, the cells were treated with 25 µM MG-132 for 12h. The cells were lysed in NEM-containing buffer, and the transfectedproteins were precipitated with glutathione-agarose beads. Thepurified proteins (4 µg) immobilized on beads were resuspendedin 50 mM ammonium bicarbonate (pH 8.1). Modified trypsin (Promega)was then added at an enzyme:substrate ratio of 1:25, and thesamples were incubated overnight at 37°C. Supernatants werecollected and the beads were washed three times with 100 µlof 50 mM ammonium bicarbonate prior to evaporation in a Speedvac.The protein digests were reconstituted in 40 µl of aqueousformic acid (0.2%) containing 5% acetonitrile, and 10 µlwas loaded on the chromatographic system. All mass spectrometry(MS) analyses were conducted on a Waters CapLC coupled to aQ-TOF Ultima via a nanoLC interface (Waters). The on-line two-dimensionalliquid chromatography-mass spectrometry (LC-MS) chromatographicsystem comprised a homemade strong cation exchange (SCX) column,5 mm by 360 µm (PolyLC), a 300-µm by 5-mm WatersSymmetry C₁₈ precolumn, and a 150-µm by 10-cm homemadeJupiter C₁₈ (Phenomenex) analytical column. After sample injection,peptides were eluted sequentially from the SCX column with 20-µlsalt plugs of ammonium acetate of increasing concentrations,ranging from 0, 60, 70, 80, 100, 150, 200, 400, to 1,000 mMat pH 3.0. Peptides eluted from the SCX column were retainedon the C₁₈ precolumn and subsequently were separated on theanalytical column with a linear gradient (10 to 60%) of 0.2%formic acid in acetonitrile over 63 min. The mass spectrometerwas operated in a data-dependent acquisition mode whereby theinstrument cycled through a survey scan (1s) and a product ionspectrum (2s). Collisional activation of selected precursorswas obtained by using nitrogen as a target gas, with collisionenergies ranging from 30 to 80 eV (laboratory frame of reference)scaled according to m/z and the charge of the precursor ion.Fragment ions formed in the replicative form-only quadrupolewere recorded by a time-of-flight mass analyzer. Mascot (MatrixScience) database searches of the acquired MS-MS spectra wereperformed against the National Center for Biotechnology Informationnonredundant protein database.

RESULTS

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Results

In vivo degradation of ERK3 by the proteasome is independent of lysines. To further characterize the mechanism of ERK3 ubiquitinationand to possibly obtain stable mutants, we decided to map theubiquitination site(s) of the kinase. It was previously shownthat ERK3 ubiquitination is confined within the first 365 aminoacids of the protein (14). We therefore used this truncatedERK3 mutant (ERK3 ${Delta}$ ) as a backbone to replace the 16 lysines residueswith arginine (Fig. 1A). The effect of the mutations on thestability of ERK3 was estimated from the steady-state levelsof the ectopically expressed protein. An initial series of ninedouble, triple, or quadruple lysine mutants of ERK3 ${Delta}$ was transientlytransfected in HEK 293 cells and was analyzed by immunoblotting.All these constructs were expressed at levels similar to thatof the wild-type protein, suggesting that none of the individuallysines is absolutely essential for ERK3 ubiquitination in vivo(data not shown). To test the possible redundancy of these lysines,we then analyzed the different mutants in combination. The progressiveelimination of up to 14 of the 16 putative lysine ubiquitinationsites had no significant effect on ERK3 steady-state levels(data not shown). We finally constructed a lysineless (0K) mutantof ERK3 ${Delta}$ in an attempt to completely abolish ubiquitination.Surprisingly, we observed that ERK3 ${Delta}$ -0K was expressed at a levelcomparable to that of wild-type ERK3, which is much lower thanthat of the stable ERK1 protein (Fig. 1B). All three constructswere translated with similar efficiency in vitro (Fig. 1B, lowerpanel). To determine whether the weak expression of ERK3 ${Delta}$ andERK3 ${Delta}$ -0K was due to rapid turnover of the proteins, we measuredtheir half-lives by cycloheximide chase experiments (Fig. 1C).We found that both ERK3 ${Delta}$ and ERK3 ${Delta}$ -0K are rapidly degraded, withhalf-lives of approximately 45 min in exponentially proliferatingcells, a value similar to the half-life of the full-length ERK3protein (14).

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FIG. 1. A lysineless mutant of ERK3 is unstable. (A) Schematic representation of ERK3 ${Delta}$ constructs showing the position of lysines mutated in this study. (B) HEK 293 cells were transfected with the indicated constructs. After 48 h, cell lysates were analyzed by immunoblotting with anti-HA antibody. Two different exposures of the gel are shown (upper two panels). The same constructs were translated in vitro in the presence of ³⁵S-labeled amino acids and were analyzed by fluorography (lower panel). (C) HEK 293 cells transfected with the different ERK3 constructs were treated with cycloheximide (100 µg/ml) for the indicated times. Ectopically expressed ERK3 was detected by HA immunoblotting. (D) HEK 293 cells were transfected with Myc₆-tagged ERK3 ${Delta}$ , ERK3 ${Delta}$ kinase dead (KD), ERK3 ${Delta}$ Ser189Ala (S189A), ERK3 ${Delta}$ -0K, or ERK3 ${Delta}$ _1-296. The cells were metabolically labeled with ³²P, and the transfected ERK3 proteins were immunoprecipitated with anti-Myc antibody. Phosphorylation was revealed by autoradiography (upper panel). Aliquots of cell lysates were analyzed by immunoblotting to monitor expression of the ectopic proteins (lower panel). exp., exposure; IB, immunoblot; IP, immunoprecipitation.

To exclude the possibility that the rapid degradation of ERK3 ${Delta}$ -0Kis due to misfolding of the mutated protein, we compared thein vivo phosphorylation status of wild-type ERK3 ${Delta}$ with that ofvarious mutants. ERK3 has been previously shown to be phosphorylatedon the activation loop Ser-189 in intact cells (9, 14). Metaboliclabeling experiments confirmed that the truncated ERK3 ${Delta}$ is alsophosphorylated in vivo (Fig. 1D). Replacement of Ser-189 byalanine almost completely suppressed ³²P incorporation, indicatingthat Ser-189 is the major phosphorylation site of ERK3. Thecatalytically inactive mutant ERK3 ${Delta}$ -KD was phosphorylated tothe same extent as the wild-type protein, consistent with theidea that phosphorylation of Ser-189 is executed by a cellularERK3 kinase (10). MAP kinase kinases are remarkably specificenzymes that recognize their targets only in the native conformation(38). In agreement with this, deletion of the extreme C-terminalend of the ERK3 kinase domain (ERK3 ${Delta}$ _1-296) is sufficient to abolishits phosphorylation by ERK3 kinase (Fig. 1D). Importantly, weobserved that ERK3 ${Delta}$ -0K is phosphorylated in vivo, albeit to alesser extent than the wild-type protein (Fig. 1D). We concludefrom these results that the ERK3 ${Delta}$ -0K mutant is correctly folded.

As previously reported for the native ERK3 protein (14), treatmentwith the structurally unrelated proteasome inhibitors MG-132and lactacystin ß-lactone induced the accumulationof both ERK3 ${Delta}$ and the lysineless mutant (Fig. 2A). Cycloheximidechase experiments further confirmed that incubation with MG-132strongly stabilizes ERK3 ${Delta}$ and ERK3 ${Delta}$ -0K proteins (Fig. 2B). Theseresults indicate that ERK3 is actively degraded by the proteasomein vivo in the complete absence of lysine residues.

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FIG. 2. ERK3 is degraded by the proteasome in a lysine-independent manner. (A) HEK 293 cells were transfected with HA-tagged ERK3 ${Delta}$ or ERK3 ${Delta}$ -0K constructs. After 36 h, the cells were treated for 12 h with the protease inhibitors MG-132 (25 µM), E-64 (25 µM), lactacystin ß-lactone (20 µM), or vehicle (0.1% dimethyl sulfoxide [DMSO]). Ectopically expressed ERK3 was detected by HA immunoblotting. (B) HEK 293 cells were transfected as described for panel A. After 44 h, the cells were pretreated with dimethyl sulfoxide or MG-132 for 30 min. Cycloheximide was then added for a period of 4 h. Cell lysates were analyzed by HA immunoblotting. IB, immunoblot.

Lysineless ERK3 is ubiquitinated and requires a functional ubiquitin pathway for its efficient degradation in vivo. Because previous reports have suggested that some proteins maybe targeted to the proteasome without ubiquitination (44), wesought to evaluate the role of the ubiquitin pathway in ERK3 ${Delta}$ -0Kturnover. To this end we measured the steady-state levels ofERK3 ${Delta}$ and ERK3 ${Delta}$ -0K in the ts20 cell line that harbors a temperature-sensitiveubiquitin-activating enzyme, E1 (11). As shown in Fig. 3A, bothERK3 ${Delta}$ and ERK3 ${Delta}$ -0K accumulated when ts20 cells were shifted tothe restrictive temperature (39°C). No change in expressionwas observed in parental A31 cells. Thus, degradation of a lysinelessmutant of ERK3 is still dependent on a functional ubiquitinconjugation pathway.

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FIG. 3. Lysineless ERK3 is ubiquitinated in vivo and requires a functional ubiquitin conjugation pathway for its efficient degradation. (A) Parental BALB/c 3T3 (A31) and E1-thermosensitive mutant (ts20) cells were transfected with the indicated ERK3 constructs or empty vector (V). After 24 h, the cells were maintained at the permissive temperature (34°C) or shifted to the restrictive temperature (39°C) for the indicated times. Ectopically expressed ERK3 was detected by HA immunoblotting. (B) HEK 293 cells were cotransfected with expression vectors encoding ERK1, ERK3 ${Delta}$ , or ERK3 ${Delta}$ -0K together with HA-tagged ubiquitin. The protein kinase constructs contain an N-terminal HA tag and a C-terminal His₆ affinity tag. After 36 h, the cells were treated with MG-132 for 12 h. His₆-tagged proteins were purified from cell lysates with nickel-agarose beads and were analyzed by immunoblotting with anti-HA antibody (upper panel). Asterisks mark nonspecific bands. Total cell lysates were analyzed for global ubiquitination activity by HA immunoblotting (lower panel). IB, immunoblot.

The above findings prompted us to ask whether ERK3 ${Delta}$ -0K is ubiquitinatedin vivo. To address this question, C-terminal His₆-tagged constructsof ERK3 were cotransfected with HA-tagged ubiquitin and thekinase was purified from cell lysates with Ni-agarose beads.Ubiquitination was monitored by immunoblotting with anti-HAantibody. A ladder of high-molecular-size bands correspondingto polyubiquitinated species of ERK3 was clearly detected forboth ERK3 ${Delta}$ and the lysineless ERK3 ${Delta}$ -0K mutant (Fig. 3B). ERK1was used as a negative control and shows no specific polyubiquitinadducts under these conditions.

Addition of large N-terminal sequence tags stabilizes ERK3 through inhibition of N-terminal ubiquitination. With the exception of E1, E2, and HECT-type E3 enzymes thattransiently become conjugated to monoubiquitin via an internalcysteine residue, ubiquitination of substrates absolutely requiresan acceptor amino group (17, 20, 32). Moreover, the thiol esterbond formed between ubiquitin and cysteine is labile and highlysensitive to the reducing conditions of Laemmli's sample buffer(15, 21). Thus, the only possible conjugation site of ERK3 ${Delta}$ -0Kto ubiquitin is the free N-terminal NH₂ of the kinase. In thecase of MyoD, it was clearly shown that chemical blocking ofthe ${alpha}$ -NH₂ group completely stabilizes the protein in an in vitrodegradation assay (7). Notably, these authors reported thataddition of a Myc₆ epitope tag at the N terminus of MyoD alsoresults in the stabilization of the protein by a poorly understoodmechanism. To further test this idea, we generated a seriesof constructs of the full-length ERK3 (containing all 45 lysineresidues) containing different tags at their N termini. As waspreviously observed (14), addition of small ( $≤$ 1.5 kDa) epitopetags does not influence ERK3 expression. The His₆ (10 residues)-and HA (13 residues)-tagged ERK3 constructs were expressed atlevels similar to that of the untagged ectopic protein (Fig.4A). Note that in these experimental conditions, these shortepitope-tagged proteins are expressed at levels comparable tothat of the endogenous ERK3 protein. Interestingly, additionof a Myc₆ epitope or EGFP (yielding fusion proteins of 120 and130 kDa, respectively) dramatically enhanced ERK3 expression(Fig. 4A, upper panel) without influencing the rate of in vitrotranslation (lower panel). This result suggested that the observeddifferences in steady-state levels likely reflect changes inthe half-lives of the protein constructs. Indeed, cycloheximidechase experiments confirmed that EGFP-ERK3 is at least 10 timesmore stable than His₆-ERK3 (Fig. 4B). Treatment with MG-132induced a marked accumulation of His₆-ERK3, whereas it had littleeffect on the expression of EGFP-ERK3 (Fig. 4C). Because Myc₆and EGFP do not show significant sequence homology, the similareffect of the two tags suggests that the size of the sequencetag influences ERK3 protein stability. To directly test thisidea, we constructed ERK3 versions containing 1, 3, 5, or 7Myc epitope tags tandemly arrayed at the N terminus. Resultsof this experiment confirmed that the size of the tag has astrong influence on ERK3 accumulation; addition of three repeatsof the Myc epitope was sufficient to increase the expressionof the kinase (Fig. 4D). Cycloheximide chase experiments clearlyshowed that these differences in steady-state expression resultfrom changes in protein turnover (Fig. 4E). We conclude thataddition of large N-terminal tags (larger than 5 kDa) is sufficientto stabilize ERK3. The presence of a large N-terminal tag alsostabilized the lysineless mutant of ERK3 (Fig. 4F), furthersubstantiating the idea that N-terminal ubiquitination of ERK3 ${Delta}$ -0Kis necessary for its degradation by the proteasome. The stabilizationof ERK3 ${Delta}$ -0K by the Myc₆ tag provides additional evidence thatthis mutant is properly folded in vivo.

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FIG. 4. Addition of large N-terminal tags stabilizes ERK3 expression. (A) HEK 293 cells were transfected with the indicated constructs. After 48 h, endogenous and ectopic ERK3 were detected by immunoblotting with antibody E3-CTD4, which specifically recognizes the ERK3 C terminus (upper panel). The asterisk marks a nonspecific band. The same constructs were translated in vitro in the presence of ³⁵S-labeled amino acids and were analyzed by fluorography (lower panel). (B) HEK 293 cells were transfected with ERK3 constructs or empty vector (V). After 48 h, the cells were treated with cycloheximide for the indicated times. His₆-ERK3 was purified from cell lysates with nickel-agarose beads and detected by immunoblotting with antibody E3-CTD4 (upper panel). EGFP-ERK3 was analyzed by immunoblotting using anti-GFP antibody (lower panel). (C) HEK 293 cells were transfected as described for panel B and were treated with MG-132 (25 µM) for 12 h. (D) N-terminal tags larger than $~$ 5 kDa enhance ERK3 expression. HEK 293 cells were transfected with ERK3 constructs tagged at their N termini with an increasing number of copies of the Myc epitope. After 48 h, endogenous and transfected ERK3 was detected by immunoblotting with E3-CTD4 antibody (upper panel). The same constructs were in vitro translated and detected by fluorography (lower panel). (E) The half-lives of ectopically expressed Myc₁-ERK3 (upper panel) and Myc₃-ERK3 (lower panel) were evaluated by cycloheximide chase. (F) The half-lives of Myc₆-ERK3 ${Delta}$ (upper panel) and Myc₆-ERK3 ${Delta}$ -0K (lower panel) were evaluated as described for panel E. IB, immunoblot; IP, immunoprecipitation.

To better understand the mechanism by which fusion of largesequence tags stabilizes ERK3 protein, we tested whether theposition of the tag is important. We found that addition ofEGFP to the C terminus of ERK3 is completely inefficient instabilizing the protein, again highlighting the importance ofthe N-terminal domain in the regulation of ERK3 degradation(Fig. 5A). We also compared the ubiquitination status of thetwo fusion proteins made between ERK3 and EGFP. Addition ofEGFP to the N terminus of ERK3 drastically inhibited the ubiquitinationof the kinase (Fig. 5B), suggesting that the stabilizing effectof large N-terminal tags results in part from their abilityto interfere with N-terminal ubiquitination.

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FIG. 5. The presence of a large N-terminal tag inhibits ERK3 ubiquitination. (A) HEK 293 cells were transfected with ERK3 constructs fused to the EGFP sequence at the N-terminal or C-terminal extremity. The transfected proteins were detected by immunoblotting with anti-GFP antibody (upper panel). The same constructs were in vitro translated and detected by fluorography (lower panel). (B) HEK 293 cells were cotransfected with the indicated ERK3-EGFP fusion constructs together with HA-ubiquitin. The ERK3 constructs contain the GST sequence at the C terminus to allow for specific and quantitative recovery of the transfected proteins. After 36 h, the cells were treated with MG-132 for 12 h. Transfected proteins were purified from cell lysates with glutathione-agarose beads, and comparable amounts of ERK3-EGFP fusion proteins were analyzed. Ubiquitin conjugates were detected by anti-HA immunoblotting (upper panel). The membrane was reprobed with anti-EGFP antibody to confirm that an equivalent amount of ERK3 fusion proteins was loaded on the gel (middle panel). Total cell lysates were analyzed for global ubiquitination activity by HA immunoblotting (lower panel). IB, immunoblot.

The stabilizing effect of large N-terminal tags is specific to N-terminal ubiquitinated proteins. We next wanted to determine if the addition of large N-terminaltags specifically stabilizes N-terminal ubiquitinated proteinsor also affects proteins ubiquitinated on internal lysine residues.To this end, we constructed a dual set of tagged vectors: onevector expresses the target protein with a single HA epitopetag at the N terminus, while the second vector contains a largertag of Myc₅ epitopes placed upstream of the HA epitope sequence(Fig. 6A). Transfection of cells with each of the two vectors,followed by simple HA immunoblot analysis, will reflect thesteady-state levels of the tagged proteins and should revealwhether addition of a larger N-terminal tag has a stabilizingeffect. We first validated our assay by using the stable ERK1protein and ERK3. ERK1, which is not ubiquitinated under theseconditions, was expressed to the same extent with both vectors(Fig. 6B). In contrast, expression of ERK3 was greatly augmentedby addition of the larger N-terminal tag (Fig. 6C).

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FIG. 6. Addition of large N-terminal tags stabilizes expression of ERK3 and p21 but not that of proteins ubiquitinated on internal lysine residues. (A) Schematic representation of the constructs used in these experiments. Note that proteins expressed from these two vectors are tagged with a single HA epitope. (B to E) HEK 293 cells were transfected with empty vector or with either HA- or Myc₅-HA (M₅HA)-tagged expression vectors encoding ERK1 (B), ERK3 (C), SOCS3 (D), and p53 (E). After 48 h, the HA-tagged proteins were detected by immunoblotting with anti-HA antibody (upper panel). An asterisk denotes a nonspecific band. The same constructs were translated in vitro (IVT) and were analyzed by anti-HA immunoblotting (lower panel). (F) HEK 293 cells were transfected with the same vectors encoding I ${kappa}$ B ${alpha}$ . After 24 h, the cells were serum starved for 24 h and then left untreated or treated with TNF- ${alpha}$ (50 ng/ml) for 30 min in the presence of cycloheximide. HA-tagged proteins were detected as described for panel B. (G) HEK 293 cells were transfected with HA- or M₅HA-tagged p21. After 48 h, the expression of ectopic p21 was monitored by HA immunoblotting. (H) HEK 293 cells transfected with p21 expression vectors were treated with cycloheximide for the indicated times. HA-tagged proteins were detected as described for panel B. ORF, open reading frame; IB, immunoblot.

We next tested our approach on additional substrates known tobe ubiquitinated on internal lysines: p53, SOCS3, and I ${kappa}$ B ${alpha}$ . p53is ubiquitinated by MDM2 on C-terminal lysines, notably lysines370, 372, 373, 381, 382, and 386 (34). SOCS3 and I ${kappa}$ B ${alpha}$ are ubiquitinatedon lysine 6 and on lysines 21 and 22, respectively (1, 36, 37).Mutation of these specific lysines is sufficient to stabilizethe corresponding protein. Both SOCS3 and p53 are constitutivelyubiquitinated in exponentially proliferating cells (26, 36).Addition of a large N-terminal tag did not result in the accumulationof either protein under these conditions (Fig. 6D and E). Inthe case of I ${kappa}$ B ${alpha}$ , degradation of the protein is induced by proinflammatorystimuli like TNF- ${alpha}$ (2). We found that TNF- ${alpha}$ induces the degradationof both HA- and Myc₅-HA-tagged I ${kappa}$ B ${alpha}$ to a similar extent (Fig.6F). In all of these examples, the proteins were in vitro translatedwith similar efficiency regardless of the N-terminal tag (Fig.6B to F, lower panels). Importantly, the subcellular localizationof the proteins tested was not affected by the nature of thetag (data not shown). These results suggest that stability ofproteins ubiquitinated on lysine residues is not affected bythe presence of large N-terminal tags.

We made the hypothesis that this assay could be used as a meanto identify proteins ubiquitinated on the N terminus. As mentionedabove, the cyclin-dependent kinase inhibitor p21, like MyoDand ERK3, is degraded by the proteasome in a lysine-independentmanner (40). The precise ubiquitination site of the proteinhas not been characterized, despite the fact that p21 is knownto be polyubiquitinated in vivo. We recently observed that differentiationof C2C12 myoblasts into muscle cells is accompanied by a time-dependentaccumulation of ERK3, which results in large part from the stabilizationof the protein (14). Interestingly, the upregulation of ERK3shows a striking parallel to that of p21, a known marker ofmuscle differentiation (19, 29). These observations promptedus to test the effect of adding a large N-terminal tag on theexpression of p21. Immunoblot analysis revealed that Myc₅-HA-taggedp21 is expressed at levels at least 10 times higher than thatof HA-p21 (Fig. 6G). Cycloheximide chase experiments confirmedthat the accumulation of p21 upon addition of the large N-terminaltag results from stabilization of the protein (Fig. 6H). Theseresults suggest that p21 is ubiquitinated on the NH₂ terminusin vivo and that this site is important for its efficient degradation.

N-terminal ubiquitination of p21 is necessary for its degradation in vivo. To investigate the role of the ubiquitin pathway in the proteasome-mediateddegradation of p21 in vivo, we monitored by immunoblot analysisthe steady-state levels of endogenous p21 in ts20 and parentalA31 cells. We found that p21 accumulates to very high levelswhen ts20 cells are grown at the restrictive temperature (Fig.7A). Because p21 is a direct transcriptional target of p53,the upregulation of p21 may be a consequence of the accumulationof p53 in ts20 cells as previously documented (11). To directlytest the importance of ubiquitination in regulating the turnoverof p21, we measured the half-life of the protein by cycloheximidechase experiments in ts20 cells grown at the permissive or restrictivetemperature. Inactivation of the E1 enzyme clearly stabilizedthe endogenous p21 protein (Fig. 7B). The half-life of p21 is $~$ 15 to 30 min in exponentially proliferating ts20 cells culturedat 34°C and increases to more than 4 h when the temperatureis shifted to 39°C. The ectopically expressed p21 proteinalso accumulated at the restrictive temperature in ts20 cells(Fig. 7C). These results indicate that degradation of p21 isdependent on a functional ubiquitin conjugation pathway.

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FIG. 7. Degradation of lysineless p21 is dependent on a functional ubiquitin conjugation pathway. (A) Parental A31 and E1-mutant ts20 cells were cultured at 34 or 39°C for the indicated times. Expression of endogenous p21 was monitored by immunoblotting with anti-p21 antibody. (B) Half-life of endogenous p21 was measured by cycloheximide chase experiments in ts20 cells grown for 12 h at the permissive or restrictive temperature. (C) A31 or ts20 cells were transfected with the indicated p21 constructs or empty vector (V). The p21 constructs contain an N-terminal HA tag and a C-terminal His₆ tag. After 24 h, the cells were maintained at 34 or 39°C for the indicated times. Ectopically expressed p21 proteins were purified from cell lysates with nickel-agarose beads and were analyzed by immunoblotting with anti-HA antibody. (D) HEK 293 cells were cotransfected with the indicated p21 expression vectors together with HA-tagged ubiquitin. After 36 h, the cells were treated with MG-132 for 12 h. His₆-tagged proteins were purified from cell lysates with nickel-agarose beads. Half of the purified material was separated on a 7.5% gel (upper panel), while the other half was loaded on a 12% gel (middle panel). Ubiquitin conjugates were detected by HA immunoblotting. The arrow indicates the position of the nonubiquitinated p21 protein. An asterisk marks a nonspecific band. Total cell lysates were analyzed for global ubiquitination activity by HA immunoblotting (lower panel). IB, immunoblot.

Results presented in Fig. 6 suggest that p21 might be ubiquitinatedon its N terminus in intact cells. If this is indeed the case,a lysineless version of p21 should accumulate to the same extentas the wild-type protein in ts20 cells grown at 39°C. Wetherefore constructed a lysineless mutant of p21 by replacingall six lysines with arginine residues. In A31 and HEK 293 cells,p21-0K was expressed at steady-state levels comparable to thatof the wild-type protein (Fig. 7C and D). Moreover, the p21-0Kmutant similarly accumulated to high levels in ts20 cells grownat the restrictive temperature (Fig. 7C), thereby indicatingthat degradation of lysineless p21 is also dependent on ubiquitination.We next sought to determine if p21 is ubiquitinated in a lysine-independentfashion in vivo. Cotransfection experiments with HA-ubiquitinconfirmed previous observations (26, 40) that p21 is polyubiquitinatedin intact cells (Fig. 7D). Importantly, we also detected thepresence of high-molecular-mass immunoreactive species ( $~$ 66 to200 kDa) of p21-0K, indicative of polyubiquitin conjugates.Together, our results are consistent with the idea that N-terminalubiquitination of p21 targets the protein for proteasomal degradation.

Identification of N-terminal ubiquitin conjugates of ERK3 and p21 by MS. To unequivocally demonstrate that ERK3 and p21 are ubiquitinatedat the N terminus, we analyzed whole tryptic digests of purifiedHA-ERK3 ${Delta}$ -GST and HA-p21-GST fusion proteins (Fig. 8A) by tandemMS. A two-dimensional separation approach using on-line SCXand reverse-phase chromatography was devised in order to simplifythe peptide distribution obtained from the nanoLC-MS analyses.Approximately 3,500 MS-MS spectra were acquired for each setof the nine SCX salt fractions. These MS-MS analyses enabledthe identification of ERK3 ${Delta}$ and p21 fusion proteins with sequencecoverage of 37 and 42%, respectively. Both proteins comprisedan N-terminal HA peptide sequence that could not be identifieddirectly from the database search. Rather, manual identificationof the peptide bearing the desired HA sequence was facilitatedby searching the list of MS-MS spectra for characteristic y-typefragment ion series. More specifically, the presence of twoprolines in the expected HA-containing tryptic peptide MYDVPDYASLPGNYRgave rise to abundant y5 and y9 fragment ions at m/z 606.3 and1,252.6, respectively. The search of all MS-MS spectra containingthese characteristic ions revealed several peptide candidates,all comprising the N-terminal methionine residue. Importantly,the tryptic HA peptide was detected under three distinct forms:unmodified free amine (1,759.6 Da), N ${alpha}$ -acetylated (1,801.6 Da),and conjugated to a short Gly-Gly ubiquitin tag (1,855.6 Da)at the N terminus. The latter peptide corresponded to a dehydratedform whereby the amine of the terminal glycine is cyclized tothe carboxylic group of the neighboring aspartate residue. Thiscondensation is possibly a reaction by-product of the trypticdigestion, during which the free amine of the diglycine ubiquitintag is formed. This assignment was supported by the MS-MS spectrumof the doubly charged precursor ion at m/z 928.8, where a distinctb5 ion at m/z 506.1 was assigned to the cyclized GG-MYD fragmention (Fig. 8B). It is noteworthy that this ion was unique tothe cyclized diglycine HA peptide and was not observed for eitherthe N ${alpha}$ -acetylated or the free amine form of the same peptide(data not shown). Rationalization of the MS-MS spectrum of thecyclized diglycine HA peptide is shown in Fig. 8B along withthe y-type fragment ion series. Essentially the same spectrawere obtained for ERK3 and p21. These data provide the firstdirect evidence for N-terminal ubiquitination of a protein substrate.

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FIG. 8. Identification of N-terminally ubiquitinated ERK3 and p21 by MS-MS. (A) Schematic representation of the constructs used in this study. The ERK3 ${Delta}$ and p21 fusion proteins are tagged with an N-terminal HA peptide, which upon tryptic digestion releases the sequence MYDVPDYASLPGNYR (boldface characters identify the HA peptide) together with an extra diglycine derived from the C terminus of ubiquitin. (B) HEK 293 cells were transfected with the indicated constructs and treated for 12 h with MG-132. The transfected proteins were purified from cell lysates with glutathione-agarose beads and were analyzed by LC-MS-MS. The fragmentation pattern of the ubiquitinated N-terminal HA peptide is shown. The tandem mass spectrum of the doubly protonated precursor ion at m/z 928.8 shows a series of y-type fragment ions arising from peptide cleavage with charge retention at the C terminus, thus confirming the expected HA peptide sequence containing the methionine residue. The cyclization of the amine of the terminal glycine to the neighboring aspartate residue is supported by a characteristic b5 fragment ion at m/z 506.1, corresponding to the cleavage of the amide bond with charge retention at the N terminus.

DISCUSSION

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Discussion

We demonstrate that the atypical MAP kinase homologue ERK3 andthe cyclin-dependent kinase inhibitor p21 are ubiquitinatedon their NH₂ termini. With the transcriptional activator MyoD(7), ERK3 and p21 are the second and third examples of mammalianproteins ubiquitinated in that fashion. This conclusion is basedon the following evidence. First, lysineless versions of bothproteins are degraded by the proteasome with kinetics similarto that of the wild-type protein in vivo. In contrast, lysinelessmutants of cyclin E (12) or Sic1 (31) are very stable in vivo,indicating that these proteins require an internal lysine(s)for efficient ubiquitination and degradation. Second, in vivodegradation of ERK3 and p21 lysineless mutants is absolutelydependent on a functional ubiquitin conjugation pathway. Third,we clearly detected polyubiquitin conjugates of lysineless ERK3and p21 proteins. Fourth, we showed that addition of N-terminaltags of increasing size stabilizes ERK3 and p21 by specificallyinterfering with their ubiquitination. Finally, and most importantly,we demonstrated the existence of a fusion peptide between theN-terminal methionine of ERK3 and p21 constructs and the C-terminalglycine of ubiquitin in intact cells.

Recent studies have shown that positioning of the ubiquitinattachment site is critical for efficient polyubiquitinationand proteasome recognition. Petroski and Deshaies have shownthat the context of the ubiquitin acceptor site in Sic1 affectsthe targeting property of the polyubiquitin chain (31). Ubiquitinationof C-terminal Sic1 lysines occurs slowly, while producing substratespoorly recognized by the 26S proteasome. In contrast, the sixN-terminal lysine residues are more efficiently ubiquitinatedin vitro and assemble ubiquitin chains that are more competentfor degradation by the proteasome. Interestingly, these authorsalso showed that a single polyubiquitin chain can support efficientproteasomal degradation in vitro. The results presented heresuggest that the N-terminal amine of ERK3 and p21 is both necessaryand sufficient to sustain efficient degradation by the proteasomein intact cells. Accordingly, lysineless mutants of ERK3 andp21 have half-lives similar to those of their wild-type counterparts.Our findings further substantiate the idea that a single ubiquitinchain is sufficient to efficiently target a protein substrateto the proteasome in vivo.

A recent structural study has also highlighted the importanceof ubiquitin acceptor site positioning. The X-ray structureof the ternary complex Skp1/ß-trcp1/ß-cateninhas revealed that the amino group, provided by a lysine in thiscase, must be properly placed to be efficiently ubiquitinatedby SCF^ß-trcp1 (45). For example, displacing the lysineacceptor by 19 residues can decrease the apparent in vitro ubiquitinationrate by a factor of 3. Here we show that addition of sequencetags at the N terminus greatly affects the ubiquitination statusand stability of ERK3 and p21 in vivo. Most importantly, weshow that the size of the tag and not its primary sequence isimportant for this effect. Small tags comprising less than 13residues have a minimal effect, whereas tags larger than 5 kDavery efficiently inhibit protein ubiquitination and degradation.The observation that three Myc epitopes are sufficient to stabilizeERK3 is in good agreement with the results of Sheaff et al.(40), who showed that addition of Myc₃ tag stabilizes expressionof p21 by about threefold. Thus, our results support the notionthat the E3 ligase active site has a limited range of actionand that displacing the NH₂ acceptor site can greatly influencethe rate of catalysis. Alternatively, the presence of largeN-terminal tags may sterically interfere with the binding ofthe E3 to the substrate. More detailed in vitro studies withpurified E3 ligases will allow for discrimination between thesepossibilities.

It has been previously reported that the cell cycle inhibitorp21 is degraded by the proteasome in a ubiquitin-independentmanner (3, 23, 40). This conclusion was based mainly on twosets of arguments. First is the apparent lack of involvementof the ubiquitin conjugation pathway in regulating p21 turnoverbased on the fact that a lysineless mutant of p21 was degradedat the same rate as wild-type p21 in intact cells. In addition,Sheaff et al. (40) reported that overexpression of a ubiquitinmutant (UbR7) that stabilizes cyclin E expression had no apparenteffect on the steady-state levels of p21. However, the half-lifeof p21 was not measured in UbR7-transfected cells and it isnot known if this mutant ubiquitin is used by all classes ofE3 ligases with similar efficiency in vivo. Here we used a robustgenetic approach with an E1 temperature-sensitive cell lineto evaluate the importance of the ubiquitin conjugation pathwayin the in vivo degradation of p21. We unambiguously demonstratethat both endogenous and ectopically expressed wild-type orlysineless p21 is degraded in a ubiquitin-dependent manner.The second piece of evidence for ubiquitin-independent degradationof p21 was the inability to detect ubiquitin conjugates of alysineless p21 mutant in vivo. In contrast to these studies,we clearly detected polyubiquitin conjugates of this mutant.Why was polyubiquitination of p21-0K not detected earlier? Ourresults reveal the presence of two apparent populations of ubiquitinatedspecies of ERK3 and p21 with high- and low-molecular-size ubiquitinadducts (Fig. 3 and 7). However, we noticed the absence of low-molecular-sizeubiquitin conjugates for both the ERK3-0K and p21-0K mutants,whereas higher-molecular-size adducts are detected. Thus, thelack of detection of low-molecular-size ubiquitination speciescould lead to the wrong conclusion that a lysineless mutantis not ubiquitinated in vivo (for example, see Fig. 7D, middlepanel).

The physiological significance of N-terminal ubiquitinationremains to be established. In the case of ERK3, accumulatingevidence suggests that N-terminal ubiquitination plays a criticalrole in regulating the effect of the kinase on cell proliferation.In a recent study, it was shown that expression of stable ERK3chimeras (in which ERK3 degrons were replaced by analogous ERK1sequences) strongly inhibits S-phase entry in fibroblasts (14).In contrast, expression of unstable wild-type ERK3 protein hadno significant effect on cell cycle progression. Notably, itwas observed that ectopic expression of Myc₆-ERK3 also potentlyinhibits entry of cells into S phase (24). These observations,together with the findings reported here, suggest that N-terminalubiquitination is essential to repress the negative regulatoryeffect of ERK3 on cell cycle progression. However, our resultsdo not exclude the possibility that ubiquitination of internallysine residues may contribute in some way to the regulationof ERK3 or p21. Indeed, the absence of low-molecular-size ubiquitinadducts in lysineless mutants suggests that these ubiquitinchains are normally conjugated to internal lysine residues.Based on their apparent size, these conjugates may contain oneto five ubiquitin molecules, although it is not known if theseadducts occur on one or multiple lysine(s). Based on the factthat lysineless mutants of ERK3 and p21 have half-lives verysimilar to that of the wild-type protein, we conclude that theselow-molecular-size ubiquitin conjugates play a minor role, ifany, in proteasomal targeting. Modification by mono- or shortubiquitin species may serve functions other than proteolysis,such as regulation of subcellular localization (22).

During the course of this work, Bloom and coworkers (4) haveindependently shown that p21 is ubiquitinated on its NH₂ terminusin vivo. In agreement with the findings reported here, theseauthors have shown that p21 degradation is dependent on a functionalubiquitin system and that addition of a Myc₆ tag stabilizesthe protein. However, contrary to what we observed for ERK3,they suggested that the stabilization effect of the Myc₆ tagdoes not result from inhibition of p21 ubiquitination. Thisdiscrepancy may be intrinsic to the studied proteins or mayresult from differences in experimental procedures. The identificationof additional proteins ubiquitinated on the NH₂ terminus willhelp clarify this issue.

One of the key issues that needs to be addressed is the identityof the ubiquitin ligase(s) responsible for the polyubiquitinationof ERK3 and p21. In the case of p21, different E3 ligases havebeen implicated in the regulation of its degradation. The SCF^Skp2ligase was found to catalyze the ubiquitination of p21 in vitroand to participate in the degradation of p21 specifically duringS phase of the cell cycle (5). SCF^Skp2 was also implicated inthe rapid degradation of p21 in response to low doses of UVlight (3). Consistent with these findings, treatment of cellswith antisense oligonucleotides to Cul1, Skp1, or Skp2 leadsto the accumulation of p21 (46), and physical complexes of Skp2and p21 can be found in intact cells (3). However, p21 half-lifeis unchanged in asynchronous Skp2^–/– mouse embryonicfibroblasts (3), and the inhibitor is also unstable in postmitoticcells in the absence of Skp2 expression. These observationsargue that additional ubiquitin ligases contribute to the proteasomaldegradation of p21 that may be specific to the cell cycle phaseor cellular context. The ring finger MDM2 is another E3 ligasethat binds to p21 and has been shown to promote its degradationby the proteasome (23).

ACKNOWLEDGMENTS

We thank D. Bohmann, G. Ferbeyre, J. Hiscott, H. Ozer, B. Vogelstein,A. J. Waskiewicz, and A. Yoshimura for reagents.

This work was supported by grants from the Canadian Institutesfor Health Research. P.C. is the recipient of a studentshipfrom the National Cancer Institute of Canada. G.R. is the recipientof the Anna D. Barker Fellowship of the American Associationfor Cancer Research. S.M. holds a Canada Research Chair in CellularSignaling.

FOOTNOTES

* Corresponding author. Mailing address: Institut de recherche en immunovirologie et cancérologie, Université de Montréal, C.P. 6128, Succ. Centre-ville, Montreal, Quebec, Canada H3C 3J7. Phone: (514) 343-6966. Fax: (514) 343-6954. E-mail: sylvain.meloche{at}umontreal.ca.

REFERENCES

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