The CUL1 C-Terminal Sequence and ROC1 Are Required for Efficient Nuclear Accumulation, NEDD8 Modification, and Ubiquitin Ligase Activity of CUL1

doi:10.1128/MCB.20.21.8185-8197.2000

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Molecular and Cellular Biology, November 2000, p. 8185-8197, Vol. 20, No. 21
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

The CUL1 C-Terminal Sequence and ROC1 Are Required for Efficient Nuclear Accumulation, NEDD8 Modification, and Ubiquitin Ligase Activity of CUL1

Manabu Furukawa,¹ Yanping Zhang,¹ Joseph McCarville,² Tomohiko Ohta,¹^, and Yue Xiong¹^,²^,³^,^*

Lineberger Comprehensive Cancer Center,¹ Department of Biochemistry and Biophysics,² and Program in Molecular Biology and Biotechnology,³ University of North Carolina at Chapel Hill, Chapel Hill, North Carolina 27599-7295

Received 28 April 2000/Returned for modification 14 June 2000/Accepted 10 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Members of the cullin and RING finger ROC protein families form heterodimeric complexes to constitute a potentially largenumber of distinct E3 ubiquitin ligases. We report here that thehighly conserved C-terminal sequence in CUL1 is dually required,both for nuclear localization and for modification by NEDD8. Disruptionof ROC1 binding impaired nuclear accumulation of CUL1 and decreasedNEDD8 modification in vivo but had no effect on NEDD8 modificationof CUL1 in vitro, suggesting that ROC1 promotes CUL1 nuclear accumulationto facilitate its NEDD8 modification. Disruption of NEDD8 bindinghad no effect on ROC1 binding, nor did it affect nuclear localizationof CUL1, suggesting that nuclear localization and NEDD8 modificationof CUL1 are two separable steps, with nuclear import precedingand required for NEDD8 modification. Disrupting NEDD8 modificationdiminishes the I $kappa$ B $alpha$ ubiquitin ligase activity of CUL1. These resultsidentify a pathway for regulation of CUL1 activity $---$ ROC1 and theCUL1 C-terminal sequence collaboratively mediate nuclear accumulationand NEDD8 modification, facilitating assembly of active CUL1 ubiquitinligase. This pathway may be commonly utilized for the assemblyof other cullinligases.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Ubiquitin-mediated proteolysis plays a key role in regulating the levels of a large number of proteins involved in diversecellular processes. Through a cascade of enzymes involving ubiquitinactivation (E1), conjugation (E2), and ligation (E3), the ubiquitin-dependentprotein degradation pathways catalyze the formation of polyubiquitinchains onto substrate proteins via isopeptide bonds. Polyubiquitinatedsubstrates are then rapidly delivered to and degraded by the 26Sproteasome (6, 7, 12). While E1 and E2 both representstructurally related proteins that are relatively well characterizedbiochemically, the E3 ubiquitin ligases, generally defined ashaving both a ubiquitin ligase activity and a substrate targetingfunction, comprise a potentially large number of diverged multisubunitprotein complexes. Elucidating the molecular nature and regulationof E3s has become critically important to our understanding ofregulated proteolysis and is currently the focus of intensiveinvestigation.

The three best-characterized E3 activities involve HECT (homologous to E6AP carboxy terminus) domain proteins representedby E6-AP (10), the anaphase-promoting complex (APC or cyclosome)that consists of at least 12 subunits and is required for bothentry into anaphase and exit from mitosis (18, 51), and theSCF complexes, which consist of SKP1, CDC53 or its homologue,Cullin-1, and a distinct F box protein (1, 4, 42). A coresubunit of SCF, cullin or CDC53, was first identified, throughgenetic analysis, in Caenorhabditis elegans and yeast as beingencoded by a gene whose functional loss caused defects in G₁ regulation(19, 29, 47). Several CDC53- or CUL1-dependent SCF complexeshave been identified in both yeast and mammalian cells that functionto ubiquitinate many phosphorylated substrate proteins, indicatingthat a similar SCF mechanism is evolutionarily conserved acrossspecies (recently reviewed in references 2, 20, and 36).A subunit of the mitotic APC E3 complex, APC2, was found to containa limited sequence similarity to CDC53 and cullins (50, 52),further underscoring an important and conserved role for cullinproteins in ubiquitin-mediatedproteolysis.

Recently a family of closely related RING finger proteins, represented by ROC1 (regulator of cullins, also known as Rbx1 forRING-box protein, or Hrt1) was identified (reviewed in references2 and 51). ROC1 shares a high degree of sequence similarityto another APC subunit, APC11, and functions as an essential subunitof CUL1 and CDC53 ubiquitin ligases to catalyze ubiquitinationof the phosphorylated inhibitor of the NF- $kappa$ B transcription factor,I $kappa$ B $alpha$ , G₁ cyclin Cln2, and the CDK inhibitor Sic1 (17, 33,41, 43, 45). Deficiency of yeast ROC1 can be functionallyrescued by mammalian ROC1 and ROC2 but not by yeast APC11 (17,33, 41), demonstrating an evolutionary conservation and functionalspecificity for the ROC gene family. ROC1 and ROC2 commonly interactwith all cullins to constitute multiple active ubiquitin ligases,while APC11 specifically interacts and constitutes active ligasewith cullin-related APC2 (33; Ohta et al., unpublished data),suggesting the in vivo existence of a potentially large numberof heterodimeric cullin-ROC ubiquitin ligases. More recently,several large RING finger proteins with otherwise diverse structuresand functions were linked to ubiquitination (14, 26), suggestinga broad and general function of RING fingers in inducing E3 ligaseactivity.

Genetic and biochemical studies with yeast cells have identified a covalent modification of the CDC53 protein by a ubiquitin-likeprotein, RUB1 (related to ubiquitin), via an E1-like bipartiteRUB1-activating enzyme (22, 24). In mammalian cells, catalyzedvia a similar bipartite E1 activity and E2-Ubc12 (34), the RUB1homologue, NEDD8 (neural precursor cell-expressed and developmentallydown-regulated), forms a covalent conjugate with most, if notall, cullins (9, 23, 34). In fact, cullins appear to bethe major cellular substrates of NEDD8 modification (15, 22,24, 34). NEDD8 is a member of a group of ubiquitin-like proteinsthat are covalently linked to their substrates mostly, if notonly, monomerically by E1 activating and E2 conjugating activitiesdistinct from that utilized in ubiquitination (8, 13). Conjugationof the mammalian ubiquitin-related UCRP (ubiquitin cross-reactiveprotein) appears to target conjugates to the cytoskeleton (25),and conjugation of another mammalian ubiquitin-like protein, SUMO-1(small ubiquitin-related modifier, also known as sentrin, PIC1,UBL1, and GMP1), was found to target cytosolic RanGAP1 to thenuclear pore complex (27, 30), to antagonize ubiquitin-mediateddegradation of I $kappa$ B $alpha$ (3), and to activate transcriptional activityof p53 (5, 40). These observations indicate that in contrastto polyubiquitination, covalent modification by these ubiquitin-likeproteins plays regulatory, rather than proteolytic,roles.

The regulation and biochemical significance of cullin-RUB1 or -NEDD8 conjugation are not clear at present. The RUB1 gene andits E1 (ENR2 and UBA3) activating and E2 (UBC12) conjugating genesare not essential for budding yeast growth. The defect in CDC53-RUB1conjugation, however, is synthetically lethal, with a temperature-sensitivemutation of cdc34 that enhances the phenotype of the cdc4, cdc53,and skp1 mutations (22, 24), leading to the suggestion thatRUB1 may play a regulatory role, albeit nonessential, in regulatingROC-cullin ubiquitin ligase activity in budding yeast. Disruptionof NEDD8 modification in both mammalian and fission yeast cells,however, significantly reduced the level of in vitro SCF ubiquitinligase activity of CUL1 and resulted in a cellular lethality (32,35, 37, 39), indicating an essential function of NEDD8 modification.NEDD8 modification of both yeast CDC53 and human CUL2 is dependenton the presence of ROC1 (16). The mechanism by which ROC1 activatesRUB1 and NEDD8 modification of cullins is unclear. In this paper,we report that the highly conserved cullin C-terminal sequenceand binding with ROC1 are both required for efficient nuclearaccumulation of cullin. Blocking of CUL1 nuclear localizationreduced its NEDD8 modification, resulting in a significant lossof I $kappa$ B $alpha$ ubiquitin ligase activity of CUL1 both in vitro and invivo. These results identify a pathway for regulation of CUL1activity $---$ ROC1 binds to CUL1 and probably collaborates with itsC-terminal sequence to promote nuclear localization of CUL1, therebyfacilitating NEDD8 modification and assembly of active CUL1 ubiquitinligase in the nucleus. Three elements involved in the activationof CUL1 ligase activity $---$ ROC1 binding, NEDD8 modification, andthe C-terminal sequence $---$ are shared by or conserved in most, ifnot all, cullins, suggesting that this pathway may be commonlyutilized in the assembly and activation of other cullinligases.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Plasmids. Full-length mammalian cullin cDNAs were described previously (31). Human ROC1 cDNA was described previously (33). Cullinmutations were introduced by site-directed mutagenesis using theQuick-Change kit (Stratagene) and verified by DNA sequencing.Human NEDD8 cDNA (21) was amplified from a HeLa cell cDNA libraryby PCR and subcloned into the pcDNA3 mammalian expression vectorwith a Myc epitopetag.

Cell lines, culture conditions, and cell transfection. Human U2OS and 293T cells used in this study were cultured in Dulbecco modified Eagle medium, supplemented with 10% fetalbovine serum in a 37°C incubator with 5% CO₂. Cell transfectionswere carried out using the Lipofectamine (Gibco-BRL) or Effectene(QIAGEN) transfection reagents according to the manufacturer'sinstructions (Gibco-BRL) (for U2OS cells) or calcium-phosphatebuffer (for 293T cells). For each transfection, 2.5, 5, or 15µg of total plasmid DNA was used for each six-well, 60- or 100-mmdish,respectively.

Antibodies, immunochemistry, and indirect immunofluorescence. Procedures for [³⁵S]methionine metabolic labeling, immunoprecipitation, and immunoblotting have been described previously (11).Indirect immunofluorescence was previously described in detail(54). Antibodies to human CUL1 and SKP1 (31) and to humanROC1 (33) were previously described. Monoclonal antihemagglutinin( $alpha$ -HA) (12CA5; Boehringer-Mannheim), affinity-purified polyclonal $alpha$ -HA (sc-805; Santa Cruz), $alpha$ -Myc (9E10; NeoMarker), $alpha$ -FLAG (cloneM2, F3165; Sigma), $alpha$ -T7 (no. 69522; Novagen), rhodamine red- andfluorescein isothiocyanate-conjugated donkey secondary antibodies(Jackson ImmunoResearch Laboratories), and a rabbit polyclonalantibody to NEDD8 (Catalog no. 210-194; Alexis Biochemicals, SanDiego, Calif.) were purchasedcommercially.

In vitro NEDD8 assays. [³⁵S]methionine-labeled proteins were prepared in vitro with T7 RNA polymerase using a TNT-coupled reticulocyte lysate systemaccording to the manufacturer's recommendation (Promega). Equalamounts of ROC1 and CUL1 plasmid DNA (0.3 µg) were mixed and weretranscribed and translated together. After incubation for 90 minat 30°C, the reaction mixture was aliquoted, diluted with theNP-40 buffer, and immunoprecipitated with either HA or Myc antibody(11). Immunoprecipitates were washed three times with the sameNP-40 buffer, boiled in sodium dodecyl sulfate (SDS) sample buffercontaining 0.1 M dithiothreitol (DTT), and electrophoresed on7.5 to 15% gradient denaturing polyacrylamide gels followed byautoradiography.

In vitro and in vivo ubiquitin ligase activity assays. The procedure for an in vitro assay of the ROC- and cullin-associated ubiquitin ligase activity was essentially the same ashas been previously described (33, 45). Purified rabbit E1ubiquitin-activating enzyme was purchased from Affinity ResearchProducts (Exeter, United Kingdom). His-tagged E2 human UbcH5Cwas purified using nickel beads (QIAGEN). Ub was prepared by subcloningfull-length Ub as a fusion protein with a six-His tag and proteinkinase C recognition site (LRRASV) and was purified with nickelbeads (45). For ubiquitination assays, transfected HA-taggedwild-type or mutant CUL1 immunocomplexes were immunoprecipitatedwith $alpha$ -HA antibody. Immunocomplexes immobilized on protein A agarosebeads were washed and added to a Ub ligation reaction mixture(30 µl) that contained 50 mM Tris-HCl (pH 7.4), 5 mM MgCl₂, 2mM NaF, 10 nM okadaic acid, 2 mM ATP, 0.6 mM DTT, 0.75 µg of Ub,60 ng of E1, 300 ng of E2, and 1.2 µg of phosphorylated glutathioneS-transferase (GST)-I $kappa$ B $alpha$ ^1-54. Reaction mixtures were incubated at 37°C for 60 min, terminatedby adding 30 µl of 2× Laemmli loading buffer and boiling for 4min, and resolved by SDS-polyacrylamide gel electrophoresis (PAGE)followed by autoradiography to visualize the ubiquitinated I $kappa$ B $alpha$ ladders. For substrate preparation, 36 µg of purified glutathioneS-transferase-I $kappa$ B $alpha$ (residues 1 to 54) was phosphorylated withan HA immunocomplex derived from 293T cells transfected with HA-tagged,constitutively active IKK $beta$ ^S177E/S181E kinase. The reaction was carried out in the presence of 20 µCiof [ $gamma$ -³²P]ATP at 37°C for 20 min in a total volume of 60 µl of kinasebuffer (50 mM Tris-HCl [pH 7.4], 5 mM MgCl₂, 5 µM ATP, 2 mM NaF,10 nM okadaic acid, and 0.6 mMDTT).

For the in vivo I $kappa$ B $alpha$ ubiquitination assay, 293T cells on a 100-mm dish were transfected with plasmids expressing HA-CUL1 (5µg), Myc- $beta$ -TrCP (3 µg), Myc-ROC1 (3 µg), SKP1 (5 µg), HA-IKK $beta$ ^S177E/S181E (3 µg), FLAG-I $kappa$ B $alpha$ (1 µg), and HA-Ub (5 µg). The total amountof plasmid DNA in each transfection was adjusted to total 25 µgwith a pcDNA3 empty vector when needed. Twenty hours after transfection,cells were treated with the proteasome inhibitor MG132 (25 µM)for 4 h. Cells were then collected, pelleted by centrifugation,lysed in 200 µl of preboiled SDS-lysis buffer (50 mM Tris-HCl[pH 7.5], 0.5 mM EDTA, 1% SDS, 1 mM DTT), and further boiled foran additional 10 min. Lysates were clarified by centrifugationat 14,000 rpm on a microcentrifuge (5415C; Eppendorf) for 10 min.The supernatant was diluted 10-fold with 0.5% NP-40 buffer andimmunoprecipitated with anti-FLAG antibody (3.6 µg). Immunoprecipitateswere washed three times and resolved on a 7.5 to 15% gradientSDS-PAGE, followed by immunoblotting with anti-HA antibody (1µg/ml) or anti-FLAG antibody (1 µg/ml).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

The C-terminal sequence is required for nuclear localization of CUL1. The carboxyl terminus is the most highly conserved region in cullin family members from different organisms (19) (Fig. 1A).In experiments investigating the functional significance of thishighly conserved domain, we noticed that deletion of the CUL1C terminus resulted in an altered subcellular localization. Subcellularlocalization of wild-type human CUL1 in transfected U2OS cellsexhibited heterogeneous patterns (Fig. 1B), localized predominantlyto the nucleus in most cells (81.9%) (Table 1) and predominantlyto the cytoplasm in a small percentage of cells (6.5%), and equallydistributed in both the nucleus and the cytoplasm in the remainingcells (11.6%). Similar heterogeneous distribution with predominantnuclear localization was also seen for endogenous CUL1 (Fig. 1B,column 5). Whether this heterogeneity reflects a dynamic traffickingof CUL1 protein or a cell cycle-dependent regulation has not beeninvestigated. Deletion of 22 C-terminal amino acid residues (CUL1^C22) significantly impaired the nuclear accumulation of CUL1, resultingin a predominantly cytoplasmic accumulation of CUL1 in most cells(63.2%) and a reduction of predominantly nuclear localizationfrom 81.9 to 14.5% of the cell population (Table 1 and Fig. 1B,column 6). To identify the residues required for CUL1 nuclearaccumulation, we mutated several highly conserved residues andexamined their effect on subcellular localization by indirectimmunofluorescence. Mutation of two adjacent hydrophobic residues,Leu756 and Ile757 (CUL1^L756A/I757A), reduced the nuclear accumulation of CUL1 from 81.9% of cellsto 23.6% and increased the population of cells with predominantlycytoplasmic CUL1 staining from 6.5 to 41.2% (Table 1 and Fig.1B, column 7). These results indicate that mutations at Leu756and Ile757 significantly impaired nuclear accumulation of CUL1but less severely than the C-terminal 22-residue deletion, suggestingthat additional residue(s) in this region may also contributeto nuclear accumulation of CUL1.

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FIG. 1. The C-terminal sequence is required for nuclear localization of CUL1. (A) Amino acid sequence comparison of three functional domains, the ROC1 binding domain, the NEDD8 conjugation site, and the C-terminal sequence involved in both NEDD8 modification and nuclear localization (NEDD8/NL), of six human cullins, human APC2, and CUL1 from eight different organisms. Hs, Homo sapiens (human); Mm, Mus musculus (house mouse); Dm, Drosophila melanogaster (fruit fly); Dd, Dictyostelium discoideum (slime mold); Ce, C. elegans (worm); Sp, Schizosaccharomyces pombe (fission yeast); Le, Lycopersicon esculentum (tomato); At, Arabidopsis thaliana (mouse-ear cress); Sc, Saccharomyces cerevisiae (budding yeast). Shadowed residues denote mutations that were characterized in this study. Asterisks indicate the stop codon. (B) Subcellular localization of the CUL1 protein was examined by indirect immunofluorescence in untransfected U2OS cells or U2OS cells transiently transfected with plasmid DNA expressing HA-tagged wild-type and mutant CUL1. (C) Levels of CUL1 expression for wild-type and mutant proteins were examined by Western blot analysis of transfected U2OS cells.

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TABLE 1. Subcellular localization of CUL1 proteins^a

To determine whether the conserved C termini of other cullins are also required for nuclear localization, we introduced similardouble point mutations at the conserved Leu and Ile residues intohuman CUL2 (CUL2^L725A/I726A), CUL5 (CUL5^L760A/I761A), and mouse CUL4A (mCUL4A^L739A/I740A) and examined their effect on subcellular localization. LikeCUL1, the wild-type CUL2, mCUL4A, and CUL5 are localized predominantlyto the nucleus in most cells and to the cytoplasm in a smallerpopulation (data not shown). Mutations at the adjacent Leu andIle residues reduced nuclear accumulation of all three cullins(data not shown). These results demonstrate that the C-terminalsequence contains an evolutionarily conserved element requiredfor efficient nuclear localization of most, if not all, cullinproteins. Notably, the APC2 protein lacks this sequence, suggestinga distinct mechanism for regulation of APC ligaseactivity.

The transfected cullins described in this study $---$ wild-type CUL1, the CUL1^C22 and CUL1^L756A/I757A mutants, a NEDD8 modification mutant (CUL1^K720A), a ROC1 binding mutant (CUL1^610-615), and a SKP1 binding mutant (CUL1^Y42A/M43A) $---$ were expressed at similar levels as determined by direct immunoblottingof the total cell lysate derived from each transfected cell populationwith anti-HA antibody (Fig. 1C, lanes 1 to 6). These results excludethe possibility that these point mutations or small internal deletionschanged CUL1 protein stability or expression levels, resultingin an altered subcellular localization. From these experiments,we conclude that the C-terminal sequence of human CUL1 containsa signal critically important for CUL1's nuclear accumulation.Notably, a slow-migrating and less intense band was detected incells expressing wild-type CUL1 (Fig. 1C, lane 1) but was notseen or was substantially reduced in all five CUL1 mutants (lanes2 to 6). This band was later confirmed as NEDD8-modified CUL1(see below), suggesting a potential link between CUL1 modificationby NEDD8 and its nuclear import and binding with ROC1 and SKP1.Experiments to investigate these possible links are describedbelow.

Blocking nuclear accumulation of CUL1 reduces its modification by NEDD8. The carboxyl terminus of CDC53 was previously shown to be required for RUB1 modification of yeast CDC53 (22). The NEDD8conjugation site in human CUL2 has been mapped to Lys residue689 (46), corresponding to Lys720 in human CUL1 (Fig. 1A). Thefunction of the C-terminal sequence in promoting nuclear accumulationof cullin, while distinct from the NEDD8 conjugation site, suggeststhat nuclear localization and RUB1 or NEDD8 modification may betwo related events. To test this possibility, we first soughtto confirm the NEDD8 modification site in human CUL1. Transfectedwild-type, HA-tagged CUL1 was resolved into two forms as determinedby coupled immunoprecipitation and immunoblotting (IP-Western)(Fig. 2A, lane 5), likely corresponding to unmodified and NEDD8-conjugatedCUL1, respectively. Coexpression with Myc3-NEDD8 resulted in theappearance of a third, even slower-migrating band (lane 6). Whenthe same $alpha$ -HA precipitate was immunoblotted with $alpha$ -Myc antibody,the slowest-migrating form, but not the other two bands, was detected(lane 3), confirming that it corresponds to Myc3-NEDD8-conjugatedCUL1. Mutation of Lys residue 720 (HA-CUL1^K720A) abolished both slow-migrating forms without affecting the fast-migratingband (lane 9), confirming that the two slow-migrating forms correspondto NEDD8- and Myc3-NEDD8-conjugated CUL1 and that Lys720 is themajor, if not the only, site for modification by NEDD8 in CUL1.

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FIG. 2. The CUL1 C-terminal sequence is required for NEDD8 modification. (A) 293T cells were transiently transfected with plasmid vectors expressing Myc3-NEDD8 and wild-type or mutant CUL1 proteins as indicated. Lysates were prepared 24 h after transfection from each transfected cell population and immunoprecipitated with $alpha$ -HA antibody. The precipitates were separated by SDS-PAGE and immunoblotted with $alpha$ -HA or $alpha$ -Myc antibodies. The asterisk in lane 4 indicates a nonspecific band cross-reacting with the monoclonal HA antibody. A polyclonal $alpha$ -HA antibody that avoids this cross-reacting polypeptide was used in subsequent experiments. (B) 293T cells were transiently transfected with plasmid vectors expressing wild-type or mutant CUL1 proteins as indicated. Lysates were prepared 24 h after transfection from each transfected cell population and immunoprecipitated with $alpha$ -HA antibody. The precipitates were separated by SDS-PAGE and immunoblotted with $alpha$ -NEDD8 antibody (right panel), and then the same filter was stripped and reblotted with $alpha$ -HA antibody. K/LI refers to a triple mutation in CUL1 (K720A/L756A/I757A). ND8, NEDD8.

To determine whether nuclear accumulation of CUL1 and its modification by NEDD8 may regulate each other, we examined NEDD8modification of mutant CUL1 defective in nuclear localizationand the subcellular localization of mutant CUL1 lacking the NEDD8modification site. HA-tagged wild-type or mutant CUL1 that wasdefective in nuclear localization (L756A/I757A) or at the NEDD8modification site (K720A), or their combination (referred to asK/LI), was transiently transfected into cultured 293T cells. NEDD8modification of transfected CUL1 was determined by direct immunoblottingof HA immunoprecipitates with either $alpha$ -HA antibody or $alpha$ -NEDD8antibody (Fig. 2B). Mutations in the CUL1 C-terminal sequencethat impaired CUL1 nuclear localization (HA-CUL1^L756A/I757A) consistently caused a considerable decrease, but not disruption,of NEDD8-conjugated CUL1 (Fig. 2B, lanes 2 and 3; Fig. 6A, lanes2 and 6, Fig. 7C, lanes 5 and 6; and Fig. 7D, lanes 3 and4).

NEDD8 modification is not required for CUL1 nuclear localization. We next examined subcellular localization of a mutant CUL1^K720A protein, harboring a mutation at its NEDD8 modification site. Comparedwith wild-type HA-CUL1 transfected in parallel, mutation at theNEDD8 modification site (K720A), in contrast to the mutationsin the C-terminal sequence, had no significant effect on CUL1'snuclear localization (Fig. 3, middle column, and Table 1). CUL1mutated in both the C-terminal and NEDD8 conjugation sites (CUL1^K/LI) was still blocked from accumulating in the nucleus (Fig. 3,right column). Taken together, these observations indicate thatNEDD8 modification is not required for nuclear accumulation ofCUL1.

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FIG. 3. NEDD8 modification is not required for nuclear localization of CUL1. Subcellular localization of proteins was examined in transiently transfected U2OS cells for wild-type CUL1, mutant CUL1 lacking the NEDD8 modification site (K720A), and CUL1 with a mutated NEDD8 modification site and C-terminal residues (K720A/L756A/I757A).

Mapping the ROC1 binding sequence in CUL1. Both endogenously and ectopically expressed ROC1 protein localized mainly to the nucleus, with lower levels present in thecytoplasm (data not shown). We noticed an increase of nuclearaccumulation of cullin proteins when they were cotransfected withROC1 but not with APC11 (data not shown), raising the possibilitythat ROC1 may facilitate or be required for nuclear accumulationof cullins. To test this possibility directly, we first attemptedto map the ROC1 binding sequence in order to identify a ROC1-binding-deficientmutant CUL1. Through a series of deletion analyses, we mappeda sequence in human CUL1, between residues 549 and 650, that issufficient for binding with ROC1 as determined by reciprocal $alpha$ -HA-CUL1and $alpha$ -ROC1-Myc immunoprecipitation (Fig. 4A, lanes 5 to 8). Acomparison of the intensity of coprecipitated ROC1-Myc shows thatthe ROC1 binding affinity of CUL^549-650 is very similar to that of wild-type CUL1 (Fig. 4A, compare lanes5 and 7), indicating that CUL^549-650 contains most, if not all, ROC1 binding activity. As a control,another CUL1 fragment containing residues 350 to 493 exhibitedno detectable binding with cotransfected ROC1-Myc (lanes 9 and10).

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FIG. 4. Mapping the ROC1 binding region in CUL1. 293T cells transiently transfected with the indicated plasmids expressing Myc-tagged ROC1 and two HA-tagged CUL1 fragments or several mutant CUL1s were pulse-labeled with [³⁵S]methionine. Lysates prepared from transfected cells were immunoprecipitated with either $alpha$ -Myc or $alpha$ -HA antibody and resolved by SDS-PAGE, followed by autoradiography. (A) Mapping the ROC1 binding region in CUL1. (B) Characterization of ROC1 binding mutant CUL1s. (C) NEDD8 modification and nuclear localization of CUL1 are not required for CUL1-ROC1 binding.

Further deletion analyses within this region identified two internal deletion mutants, CUL1^606-624 (Fig. 4B, lanes 5 and 11) and CUL1^610-615 (lanes 6 and 12), that significantly reduced but did not completelydisrupt the binding with ROC1 as determined by reciprocal immunoprecipitations.As a control, disruption of SKP1 association by the mutationsat Tyr42 and Met43 (HA-CUL1^Y42A/M43A) did not affect the binding of CUL1 with ROC1, as determinedreciprocally by either anti-HA (Fig. 4B, lane 10) or anti-SKP1(data not shown) immunoprecipitation, consistent with the previousfinding that ROC1 and SKP1 bind independently to two separateregions in CUL1 (33). Six amino acid residues deleted in CUL1(CUL1^610-615), which resulted in a disruption of ROC1 binding, are highlyconserved among members of cullins from different organisms (Fig.1A), suggesting that this sequence may be required for bindingof ROC1 to other cullin proteins aswell.

We also determined the effect of disruption of NEDD8 modification and mutation in the C-terminal sequence of CUL1 on CUL1'sability to bind ROC1 (Fig. 4C). Neither the mutation in the sitefor modification by NEDD8 (CUL1^K720A; Fig. 4C, lanes 2 and 5), the C-terminal mutation (CUL1^L756A/I757A; data not shown), nor their combination (CUL1^K/LI; Fig. 4C, lanes 3 and 6) in CUL1 affects the binding of CUL1with ROC1, indicating that binding of ROC1 to CUL1 is not dependenton CUL1's nuclear localization or NEDD8modification.

ROC1 is required for efficient CUL1 nuclear localization. Mapping of ROC1 binding sequences and identification of ROC1 binding mutants of CUL1 allowed us to determine whether ROC1is involved in nuclear accumulation of CUL1. Both CUL1^610-615 and CUL1^606-624 are severely impaired from entering the nucleus (Fig. 5A). Thepercentage of cells with predominantly nuclear staining was reducedfrom 81.9% for wild-type CUL1 to 7.9% for CUL1^610-615, and predominantly cytoplasmic staining increased from 6.5 to71.5% (Table 1), an even more pronounced disruptive effect thanthat caused by deletion of the C-terminal 22 residues. Since bothCUL1^610-615 and CUL1^606-624 mutants retain a residual low level of ROC1 binding activity(Fig. 4), such a prominent disruptive effect on nuclear accumulationof CUL1 associated with decreased ROC1 binding suggests the possibilitythat ROC1 might not act alone to promote CUL1 nuclear accumulationand that additional unidentified factor(s) may collaborate withROC1 in this process in a way that may or may not act in a stoichiometricmode in promoting nuclear accumulation of CUL1. Disruption ofthe binding of CUL1 with SKP1 (Y42A/M43A), on the other hand,had only a slight effect on CUL1's nuclear accumulation (Fig.5A). The percentage of cells with predominantly nuclear CUL1 stainingwas reduced from 81.9% for the wild type to 73.7% for CUL1^Y42A/M43A (Table 1). Whether this result reflects a minor contributionof SKP1 to the nuclear accumulation of CUL1 has not been determined.Both CUL1^606-624 and CUL1^610-615 still bind with SKP1 as well as wild-type CUL1 does (Fig. 4B,lanes 11 and 12), and both can be modified efficiently by NEDD8in vitro (Fig. 6B), arguing against the possibility that impairmentof nuclear accumulation of CUL1 by mutations at the ROC1 bindingsite is caused by an overt protein conformational change or aggregation,as opposed to a loss of ROC1 binding. These observations suggestthat ROC1 is required for efficient nuclear localization of CUL1.

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FIG. 5. ROC1 is required for nuclear accumulation of CUL1. (A) Subcellular localization of wild-type and mutant CUL1 proteins with disrupted ROC1 binding ( $Delta$ 610-615 and $Delta$ 606-624) or SKP1 binding (Y42A/M43A) was examined in transiently transfected U2OS cells. (B) The CUL1 C-terminal sequence and ROC1 are both required to mediate CUL1 nuclear accumulation. U2OS cells were transiently cotransfected with plasmids expressing HA-ROC1 with either wild-type or C-terminal mutant CUL1. Subcellular localization of both transfected ROC1 and CUL1 protein was examined by indirect immunofluorescence with either $alpha$ -HA or $alpha$ -Myc antibody. Cell nuclei were stained with 4',6'-diamidino-2-phenylindole. Note that overexpression of ROC1 is unable to promote nuclear accumulation of C-terminal mutant CUL1.

Requirement of both ROC1 and C-terminal sequence for nuclear accumulation of CUL1. The finding that mutation of CUL1 either in the ROC1 binding region or in the C-terminal sequence impaired CUL1 nuclear accumulationled us to determine whether these two signals are functionallyredundant or collaborative. In a small fraction of transfectedcells expressing very high levels of cullins, we noticed a cytoplasmicstaining that was more intense than nuclear staining (data notshown). In cells cotransfected with ROC1, however, CUL1 was mainlylocalized to the nucleus even when they were expressed at highlevels (Fig. 5B). These observations are consistent with the findingthat ROC1 promotes, and may even act as a rate-limiting factorfor, nuclear accumulation of cullins. When the C-terminal mutantCUL1 was coexpressed with ROC1, however, it remained localizedpredominantly in the cytoplasm despite high levels of ROC1 expression(Fig. 5B). In most cells examined, we noticed that nuclear stainingof HA-ROC1 appeared to be lower in cells expressing C-terminallymutated cullins than in cells expressing wild-type cullins, suggestingthat mutations in the C-terminal sequence of cullins not onlyimpaired their nuclear accumulation but also resulted in a cytoplasmicretention of their associated ROC1. These results, together withthe observation that the mutant CUL1^610-615 that is deficient in ROC1 binding is impaired from entering thenucleus despite containing an intact C-terminal sequence (Fig.5A), suggest that the cis-acting C-terminal sequence and trans-actingROC1 binding are both needed for nuclear accumulation ofcullin.

ROC1 promotes NEDD8 modification of CUL1 in vivo. The finding that ROC1 promotes cullin nuclear accumulation led us to determine the role of ROC1 in regulating NEDD8 modificationof cullins. HA-tagged wild-type or mutant CUL1 was either singlytransfected or cotransfected with Myc-ROC1 into 293T cells. Similarlevels of Myc-ROC1 protein were expressed in each transfection,as verified by $alpha$ -Myc IP-Western blotting (Fig. 6A, bottom panel).Modification of transfected HA-CUL1 by NEDD8 was determined byimmunoprecipitation with $alpha$ -HA antibody followed by immunoblottingwith either $alpha$ -HA or $alpha$ -NEDD8 antibody. Cotransfection with ROC1increased the levels of NEDD8-conjugated CUL1 (Fig. 6A, comparelanes 2 and 3), indicating that ROC1 can promote modificationof CUL1 by NEDD8 in vivo. More intense NEDD8-conjugated CUL1 wasseen with the $alpha$ -HA antibody than with the $alpha$ -NEDD8 antibody dueto the higher affinity of the HA antibody. Mutation in the ROC1binding region (HA- CUL1^610-615) substantially reduced the levels of NEDD8-conjugated CUL1 (Fig.6A, compare lanes 2 and 4). Consistent with residual ROC1 bindingactivity in the CUL1^610-615 mutant (Fig. 4B), overexpression of ROC1 also exhibited a promotingeffect on NEDD8 modification of CUL1^610-615, but the level of NEDD8-conjugated CUL1^610-615 is substantially lower than that of NEDD8-conjugated wild-typeCUL1 (Fig. 6A, compare lanes 3 and 5). Similarly, overexpressionof ROC1 also increased NEDD8 modification of the CUL1 C-terminalmutant (CUL1^L756A/I757A) (Fig. 6A, compare lanes 6 and 7), but the level of NEDD8-conjugatedCUL1^L756A/I757A is greatly reduced from that of wild-type CUL1, both with orwithout coexpression of ROC1 (Fig. 6A, compare lanes 6 and 7 withlanes 2 and 3). NEDD8 modification was completely abolished bythe mutation at Lys720 (CUL1^K720A) and was not detectably restored by the overexpression of ROC1(lanes 8 and 9). These results demonstrate that ROC1 promotesNEDD8 modification in vivo and are consistent with a recent reportthat RUB1 or NEDD8 modification of both yeast CDC53 and humanCUL2 in yeast or insect cells is dependent on the presence ofROC1 (16).

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FIG. 6. ROC1 promotes NEDD8 modification of CUL1 in vivo but not in vitro. (A) 293T cells were transiently cotransfected with plasmids expressing Myc-tagged ROC1 and HA-tagged wild-type or mutant CUL1 proteins as indicated. Twenty-four hours after transfection, lysates were prepared from each transfected cell population and immunoprecipitated with $alpha$ -HA or $alpha$ -myc antibodies. The $alpha$ -HA precipitates were separated by SDS-PAGE and immunoblotted with $alpha$ -HA antibody, and then the same filter was stripped and reblotted with $alpha$ -NEDD8 antibody. The $alpha$ -Myc precipitates after SDS-PAGE were blotted with $alpha$ -Myc to verify the expression of Myc-ROC1. (B) In vitro assay for modification of CUL1 by NEDD8. Wild-type or mutant CUL1 proteins were synthesized together in vitro with either Myc3-ROC1 or Myc3-NEDD8 through a coupled in vitro transcription and translation system (TNT; Promega) in rabbit reticulocyte lysate in the presence of [³⁵S]methionine. HA-CUL1, Myc3-ROC1, and Myc3-NEDD8 proteins were immunoprecipitated using HA and Myc antibodies, respectively, and resolved by SDS-PAGE. Note that the addition of ROC1 (lane 3) or mutation in the ROC1 binding region of CUL1 ( $Delta$ 610-615 and $Delta$ 606-624, lanes 6 and 7) had no obvious effect on NEDD8 modification of CUL1 in vitro. (C) CUL1-ROC1 binding assay. Wild-type CUL1 and a CUL1 deletion mutant containing the C-terminal 149 residues were cotransfected with ROC1-Myc into 293T cells. CUL1-ROC1 binding was determined reciprocally by immunoprecipitation with either HA or Myc antibodies.

In vitro NEDD8 modification requires the CUL1 C-terminal sequence but not ROC1. Mutations both in the CUL1 C-terminal sequence and in the ROC1 binding region impaired nuclear accumulation of CUL1 and decreasedmodification of CUL1 by NEDD8, suggesting a link between CUL1nuclear accumulation of NEDD8 modification. These findings alsoraised the question of whether the C-terminal sequence and ROC1are involved in two apparently separate events: promoting CUL1nuclear accumulation and promoting NEDD8 modification. To addressthis question, we examined in vitro NEDD8 modification of wild-typeand mutant CUL1 in rabbit reticulocyte lysate. Consistent withprevious reports (23, 34), in vitro synthesized wild-typeHA-CUL1 migrates as two forms: a fast-migrating major band correspondingto unmodified CUL1 and a slow-migrating minor form correspondingto NEDD8-conjugated CUL1 (Fig. 6B, lane 2). Mutation at Lys720abolished the slow-migrating form without affecting the fast-migratingband (lane 5), confirming the NEDD8 modification in this assay.Mutation in the C-terminal sequence of CUL1 (L756A/I757A) greatlyreduced levels of NEDD8-conjugated CUL1 (lane 4), indicating thatthe C-terminal sequence is required for both CUL1 nuclear accumulationand NEDD8modification.

In contrast, mutations in the ROC1 binding region, both CUL1^610-615 (Fig. 6B, lane 6) and CUL1^606-624 (lane 7), had no detectable effect on NEDD8 modification, nordid addition of ROC1 have any visible effect on the levels ofCUL1-NEDD8 conjugates (lane 3). Introduction of a mutation atthe NEDD8 conjugation site, Lys720, into the ROC1-binding mutantCUL1^606-624 (CUL1^{606-624/K720A}) completely abolished modification by NEDD8 (lane 8), confirmingNEDD8 modification on the CUL1^606-624 mutant. To further confirm ROC1-independent NEDD8 modificationof CUL1 in vitro, we examined in vitro NEDD8 modification of adeletion mutant CUL1 containing only the C-terminal 149 residues(CUL1^C149), which exhibits undetectable ROC1 binding activity (Fig. 6C).In vitro-translated HA-CUL1^C149 migrates as two bands, a major 22-kDa form and a less intense30-kDa form (Fig. 6B, lane 9). Introduction of the K720A (HA-CUL1^C149/K720A) mutation abolished the 30-kDa form without affecting the 22-kDaband, indicating that the 30-kDa form corresponded to NEDD8-modifiedHA-CUL1^C149 (Fig. 6B, lane10).

In vitro-translated CUL1 was also modified by similarly in vitro-translated NEDD8, as seen by the appearance of a third slow-migratingHA-CUL1 band after mixing of in vitro-translated Myc3-NEDD8 withwild-type HA-CUL1 (Fig. 6B, lane 11) but not with the HA-CUL1^K720A mutant (lane 12). In vitro-translated Myc3-NEDD8 was efficientlyconjugated with the ROC1-binding-deficient HA-CUL1^606-624 mutant (Fig. 6B, lane 14) but not with a double HA-CUL1^{606-624/K720A} mutant (lane 15), further confirming ROC1-independent NEDD8 modificationof CUL1 in vitro. As in the maturation and conjugation of ubiquitin,the C terminus of newly synthesized human NEDD8 contains fiveadditional residues, Gly-Gly-Leu-Arg-Glu, following the conservedGly76, that are cleaved during maturation in order to expose theGly76 for conjugation. It was shown previously that Gly76 of NEDD8is necessary for conjugation to other proteins (15). MutatingNEDD8 Gly76 to alanine (Myc3-NEDD8^G76A) completely abolished the conjugation of NEDD8 with both wild-typeCUL1 (lane 13) and the ROC1-binding-deficient CUL1^606-624 mutant (lane 16) without any detectable effect on the conjugationof both CUL1 proteins with the wild-type NEDD8 present in thereticulocyte lysate. From these results, we conclude that ROC1is not required for NEDD8 modification invitro.

NEDD8 modification is required for efficient CUL1 ubiquitin ligase activity. To determine the functional consequence of CUL1 nuclear accumulation and NEDD8 modification, we examined in vitro ubiquitinligase activity of mutant CUL1 mutated in the C-terminal sequence,in the NEDD8 modification site, and in ROC1 binding using I $kappa$ B $alpha$ as a substrate. HA-tagged wild-type or mutant CUL1 was cotransfectedwith SKP1 and the I $kappa$ B $alpha$ -targeting F box protein $beta$ -TrCP. The ubiquitinligase activity of CUL1 was precipitated with an $alpha$ -HA antibodyand assayed using phosphorylated I $kappa$ B $alpha$ as a substrate. As previouslyreported (33, 45), the wild-type CUL1 immunocomplex exhibitedhigh levels of I $kappa$ B $alpha$ ubiquitination activity that is dependenton both E1 and E2-Ubc5 (Fig. 7A, lanes 1 to 3). Mutations in theC-terminal sequence (L756A/I757A) (lane 5), at the NEDD8 modificationsite of CUL1 (K720A) (lane 4), or their combination (K/LI) (lane6) substantially reduced the ubiquitin ligase activity of CUL1.A substantial decrease, but not complete abolition, of ligaseactivity by the disruption of NEDD8 modification indicates thatNEDD8 modification is important, but not absolutely required,for CUL1 ubiquitin ligase activity. A mutation in the ROC1 bindingregion ( $Delta$ 610-615) almost completely abrogated the ligase activityof CUL1 (Fig. 7A, lane 7). The more disruptive effect on the ligaseactivity by the mutation in the ROC1 binding sequence than bythe mutation at the NEDD8 modification site indicates that inaddition to promoting nuclear accumulation and NEDD8 modification,ROC1 also has an additional function in activating CUL1 ligaseactivity.

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FIG. 7. NEDD8 modification is required for I $kappa$ B $alpha$ ubiquitin ligase activity of CUL1. (A) In vitro I $kappa$ B $alpha$ ubiquitination. Purified I $kappa$ B $alpha$ was phosphorylated with IKK $beta$ and incubated with $alpha$ -HA immunocomplexes derived from 293T cells cotransfected with plasmids expressing SKP1, FLAG-tagged $beta$ -TrCP, and HA-tagged wild-type or various mutant CUL1 proteins as indicated. Reactions were incubated at 37°C for 60 min, terminated by adding 30 µl of 2× Laemmli loading buffer, boiled for 4 min, and resolved by SDS-PAGE followed by autoradiography to visualize the ubiquitinated I $kappa$ B $alpha$ ladders. (B) In vivo I $kappa$ B $alpha$ ubiquitination. 293T cells were transfected with the indicated plasmids, including constitutively active IKK $beta$ ^S177E/S181E. Twenty hours after transfection, cells were treated with the proteasome inhibitor MG132 for 4 h prior to cell lysis. Cells were lysed into a 1% SDS-containing buffer and boiled for 10 min. Lysates were then diluted to 0.1% SDS and immunoprecipitated with anti-FLAG antibody, and washed immunoprecipitates were resolved by SDS-PAGE, followed by immunoblotting with anti-HA or anti-FLAG antibodies. Exposure time was 1 min. The asterisk indicates a nonspecific protein precipitated by the anti-FLAG antibody. (C) The levels of ectopically expressed SKP1, Myc-ROC1, HA-CUL1, and NEDD8 modification were examined by IP-Western blotting. Because the HA-Ub plasmid was included in the transfection, the level of ectopically expressed HA-CUL1 was determined by immunoprecipitation with an $alpha$ -CUL1 antibody that detected both endogenous CUL1 and CUL1-NEDD8 conjugates, as well as transfected HA-CUL1 and HA-CUL1-NEDD8 conjugates. (D) Interaction of SKP1 and I $kappa$ B $alpha$ with wild-type and mutant CUL1s. 293T cells were transfected with the indicated plasmids. Whole cell lysates were prepared using NP-40 lysis buffer and immunoprecipitated with the indicated antibodies, followed by SDS-PAGE and immunoblotting.

To further confirm the reduction of ubiquitin ligase activity by the mutations affecting CUL1's nuclear accumulation and modificationby NEDD8, we established a condition to assay in vivo I $kappa$ B $alpha$ ubiquitinationby CUL1 and determined the in vivo I $kappa$ B $alpha$ ubiquitin ligase activityof wild-type and mutant CUL1. FLAG-I $kappa$ B $alpha$ was cotransfected witha constitutively active mutant I $kappa$ B $alpha$ kinase (IKK $beta$ ^S177E/S181E), $beta$ -TrCP, ROC1 and SKP1, CUL1, and HA-tagged ubiquitin. Twentyhours after transfection, cells were treated with the proteasomeinhibitor MG132, lysed in a preboiled SDS (1%) lysis buffer, andboiled for another 10 min. Whole cell lysate was then dilutedwith NP-40 buffer to reach a final concentration of 0.1% SDS,immunoprecipitated with $alpha$ -FLAG antibody, resolved by SDS-PAGE,and immunoblotted with $alpha$ -HA or with $alpha$ -FLAG antibodies. A high-molecular-weightsmear characteristic of ubiquitination was detected on both immunoblots(Fig. 7B, lane 5) but was not detected when HA-Ub (lane 2) orFLAG-I $kappa$ B $alpha$ (lane 3) was omitted from transfection, indicating thatthe high-molecular-weight smear corresponds to in vivo ubiquitinatedI $kappa$ B $alpha$ . The appearance of ubiquitinated I $kappa$ B $alpha$ was not seen when CUL1, $beta$ -TrCP, ROC1, and SKP1 were omitted (lane 1), confirming an SCF^-TrCP-dependent ubiquitination (44, 48, 49). Dropout of IKK $beta$ from transfection substantially reduced the level of phosphorylatedI $kappa$ B $alpha$ (Fig. 7B, right panel, compare lane 4 with lanes 2 and 5to 7) and the level of ubiquitination of I $kappa$ B $alpha$ (lane 4), confirmingthe dependency of I $kappa$ B $alpha$ ubiquitination on its phosphorylation byIKK $beta$ (28, 53). A low level of I $kappa$ B $alpha$ ubiquitination was stillvisible when IKK $beta$ was omitted from transfection, which is probablyattributable to a residual level of endogenous IKK $beta$ . The levelsof ectopically expressed SKP1, ROC1, and CUL1, the reduction ofNEDD8 modification by the L756A/I757A mutation, and the disruptionof NEDD8 modification by the K720A mutation were confirmed bysequential immunoprecipitation and immunoblotting (Fig. 7C).

Consistent with the in vitro assay, the in vivo I $kappa$ B $alpha$ ubiquitin ligase activity of CUL1 was reduced by both the L756A/I757A(Fig. 7B, lane 6) and the K720A (lane 7) mutations. In contrastto the in vitro assay in which the CUL1^L756A/I757A and the CUL1^K720A mutants exhibited similarly reduced levels of ligase activity,we have consistently observed a more pronounced effect of theK720A mutation than of the L756A/I757A mutation on the in vivoI $kappa$ B $alpha$ ubiquitin ligase activity of CUL1. In fact, under this invivo assay condition, the level of ubiquitinated I $kappa$ B $alpha$ with NEDD8-deficientCUL1^K720A is close to that seen in transfection without the IKK $beta$ kinase(comparing lanes 4 and 7). The basis for this difference betweenin vivo and in vitro assays has not been determined, but it couldbe caused by the higher levels of the substrate (phosphorylatedI $kappa$ B $alpha$ ) in vivo than in vitro. This observation also suggests thatthe in vivo assay may be more sensitive than the in vitro assayin detecting the change of CUL1 ubiquitin ligaseactivity.

Modification by NEDD8 is not required for the assembly of the SCF complex. Diminishing of CUL1 ubiquitin ligase activity by mutations disrupting NEDD8 modification led us to ask whether a deficiencyin NEDD8 modification impairs the assembly of the SCF complexor impedes interaction of ligase with the substrate. HA-taggedwild-type or mutant CUL1 was cotransfected with SKP1, ROC1, $beta$ -TrCP,and I $kappa$ B $alpha$ . Interaction of CUL1 with SKP1 and I $kappa$ B $alpha$ was examinedby IP-Western blotting (Fig. 7D). The wild type and both the L756A/I757Aand K720A mutants of CUL1 coimmunoprecipitated similar amountsof SKP1. SKP1 bound to both NEDD8-modified and unmodified formsof CUL1. The ratio of these two forms of CUL1 present in SKP1immunocomplexes was similar to that seen in CUL1 immunocomplexes,suggesting that SKP1 does not preferentially associate with eitherform of CUL1. Consistently, SKP1 immunocomplexes derived fromcells transfected with wild-type and mutant CUL1 contained similaramounts of CUL1. These results indicate that disruption of NEDD8modification did not affect CUL1-SKP1 interaction. Likewise, thewild type and both the L756A/I757A and K720A mutants of CUL1 coimmunoprecipitatedsimilar amounts of I $kappa$ B $alpha$ , and reciprocally, I $kappa$ B $alpha$ immunocomplexescontained perhaps even higher levels of mutant CUL1^K720A than wild-type CUL1. These results indicate that a deficiencyof NEDD8 modification did not affect the assembly of SCF complexes,nor did it impede the interaction of SCF complexes with thesubstrate.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this report we present evidence suggesting a novel pathway for regulation of CUL1 ubiquitin ligase $---$ ROC1 and the CUL1 C-terminalsequence mediate CUL1 nuclear accumulation, promoting CUL1 modificationby NEDD8 and ligase activation (Fig. 8). This pathway containsfour previously unrecognized features. First, the CUL1 C-terminalsequence is required for both nuclear accumulation and NEDD8 modification.Second, ROC1 binding per se is not required for CUL1 modificationby NEDD8, but it indirectly promotes NEDD8 modification by promotingCUL1 nuclear accumulation. Third, CUL1 nuclear accumulation facilitatesits modification by NEDD8. Last, NEDD8 modification is importantfor efficient CUL1 ubiquitin ligase activity in vivo.

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FIG. 8. A model for cullin ubiquitin ligase activation. Cytoplasmically located CUL1 associates with ROC1 and is promoted to enter into and accumulate in the nucleus. CUL1 nuclear accumulation also requires a C-terminal sequence in CUL1 through an unknown mechanism (represented by a question mark). Once inside the nucleus, CUL1 becomes covalently modified with NEDD8 (ND8), resulting in efficient CUL1 ubiquitin ligase activity. NEDD8 modification is presumed to induce a conformational change in CUL1 to facilitate or stabilize CUL1-ROC1-E2 binding.

Dual function of the CUL1 C-terminal sequence in nuclear accumulation and NEDD8 modification. The site for NEDD8 modification has been mapped to Lys689 in human CUL2 (46), corresponding to Lys720 in human CUL1 or Lys760in yeast CDC53. Deletion of the C-terminal 21 residues (794 to814) from yeast CDC53, downstream of Lys760, abrogates RUB1 modification(22). In agreement with these reports, we have confirmed thata mutation at Lys720 of human CUL1 abolished its NEDD8 modification(Fig. 2A) and found that deletion of or mutation in the C-terminal22 residues (Fig. 1, 2, and 6) of human CUL1 severely reducedNEDD8 modification. Hence, the very C-terminal sequence does notcontain the site of, but may play a regulatory role for, NEDD8modification of CUL1 orCDC53.

Unexpectedly, we found that deletion of the C-terminal 22 residues or mutations at two conserved amino acids in this 22-residueregion impaired nuclear accumulation of CUL1. The mechanism underlyingthe function of the C-terminal sequence in mediating CUL1 nuclearaccumulation is unknown at present. This sequence has not beendetermined to be involved in the interaction with any known cullin-interactingproteins, such as SKP1, ROC1, or CDC34. The C-terminal sequencesof different cullins are highly conserved and do not resemblethe classical nuclear localization signal (NLS), which is characterizedby a cluster of basic residues, as exemplified by the NLS of theSV40 large T antigen (PKKKRKV). The C-terminal 22-amino-acid sequenceof CUL1 has an acidic pI of 4.2 and contains only three scatteredbasic residues, K759, R764, and a nonconserved K769. On the otherhand, there are eight hydrophobic residues that are highly conservedin other cullins (Fig. 1A), and mutation of two of these conservedhydrophobic residues blocks nuclear accumulation of CUL1 and threeother cullins examined (data not shown). Although it is formallypossible that the cullin C-terminal sequence contains a nonclassicalautonomous NLS to mediate import of cullin into the nucleus, thisseems to be unlikely, given that mutant CUL1s defective in ROC1binding, while retaining the intact C-terminal sequence, are impededfrom nuclearaccumulation.

Blocking nuclear accumulation of CUL1, by mutations either in the C-terminal region of CUL1 or in the ROC1 binding region,is associated with defective NEDD8 modification of CUL1. Althoughblocking of CUL1 nuclear accumulation could sufficiently explainthe severe reduction of NEDD8 modification by the deletion ofor mutation in the C-terminal sequence, our in vitro assay suggeststhat the CUL1 C-terminal sequence additionally contains anotheryet-to-be-identified activity required for NEDD8 modification.Mutations in the C-terminal sequence of CUL1 substantially reducedits conjugation by NEDD8 in vitro in a rabbit reticulocyte lysate(Fig. 6B). That the mutation at the NEDD8 modification site (CUL1^K720A) has no detectable effect on CUL1 nuclear accumulation arguesagainst the possibility that NEDD8 modification plays any significantrole in CUL1 nuclear accumulation. We speculate that a NEDD8 conjugationactivity binds to the C-terminal sequence of CUL1 and may actto retain CUL1 in the nucleus. Mutation in the CUL1 C-terminalsequence, but not the mutation at the NEDD8 modification site,disrupts this binding, resulting in a defect in both NEDD8 modificationand nuclear retention. Clearly, the function of the cullin C-terminalsequence, including the binding with additional yet-to-be-identifiedcullin-interacting protein(s), needs to be furtherinvestigated.

ROC1 promotes NEDD8 modification by facilitating nuclear accumulation of CUL1. Overexpression of ROC1 increased the levels of NEDD8-conjugated CUL1, and conversely, mutations in the ROC1 binding regionsubstantially reduced the levels of NEDD8-CUL1 conjugates (Fig.6A). These results indicate a function of ROC1 in promoting NEDD8modification of CUL1 and are consistent with and provide additionalsupport for a recent report that reached a similar conclusion(16). Kamura et al. demonstrated that in vitro conjugation ofyeast CDC53 with yeast glutathione S-transferase-RUB1 dependson the coexpression of Rbx1 (ROC1) with CDC53. The mechanism bywhich ROC1 promotes RUB1 or NEDD8 modification of cullins wasunclear, but it was suggested that ROC1 may recruit the RUB1-,NEDD8-conjugating enzyme E2-Ubc12 to cullins or induce conformationalchanges in cullins to allow the access of Ubc12 to the RUB1 orNEDD8 modification site (16). Our results suggest that ROC1promotes NEDD8 modification of CUL1 by promoting CUL1 nuclearaccumulation, but ROC1 per se is not required for NEDD8 modification.Four lines of evidence collaboratively support this conclusion.First, mutation in the CUL1 C-terminal sequence that impairedits nuclear accumulation had no detectable effect on CUL1-ROC1association (Fig. 4C), suggesting that ROC1 can form a complexwith CUL1 in the cytoplasm. Second, overexpression of ROC1 increasedCUL1 nuclear accumulation and NEDD8 modification (Fig. 6A). Third,mutations in CUL1 disrupting ROC1 binding resulted in a decreasednuclear accumulation and NEDD8 modification of CUL1. Last, invitro modification of CUL1 by NEDD8 was not affected by the additionof ROC1 or by mutations in CUL1 disrupting ROC1 binding (Fig.6B) and can occur efficiently using a 149-residue C-terminal CUL1fragment devoid of ROC1 binding capability (Fig. 6B and C). Fromthese results, we conclude that ROC1 is not required for NEDD8modification invitro.

How ROC1 promotes CUL1 nuclear accumulation is not clear. Nuclear accumulation of a protein is the result of several regulatedprocesses, including nuclear import, retention, and export. Thereis the possibility that ROC1 could bind to CUL1 in the cytoplasmand escort CUL1 into the nucleus. Alternatively, ROC1 could actas a nuclear retention factor for nuclear localization of CUL1.ROC1 alone, however, is not sufficient to localize CUL1 in thenucleus. Nuclear accumulation of mutant CUL1 that is defectivein the C-terminal sequence, while retaining the intact ROC1 bindingactivity, is impaired (Fig. 3) and cannot be restored by the overexpressionof ROC1 (Fig. 5B). These observations suggest that nuclear accumulationof cullin involves at least two separate signals: a cis-actingC-terminal sequence and a trans-acting ROC1 factor. Whether thesetwo signals function collaboratively (e.g., one promotes nuclearimport and one functions in nuclear retention) or in a regulatorymanner (e.g., ROC1 may facilitate the binding of an importin receptorto the C-terminal sequence of CUL1) remains to be determined.It also should be pointed out that our results do not suggestthat promoting nuclear accumulation and NEDD8 modification ofcullin are the main functions of ROC1 as an essential subunitof cullin ligases. This is made evident by the observation thatmutant CUL1 that is defective in ROC1 binding (CUL1^610-615) loses virtually all its I $kappa$ B $alpha$ ubiquitin ligase activity, whereasmutant CUL1 that is defective in nuclear accumulation and/or NEDD8modification retains a considerably higher amount of ligase activity(Fig. 7).

Regulation of cullin ligase activity by nuclear localization and NEDD8 modification. Deficiency in NEDD8 modification results in a significant reduction of CUL1 ubiquitin ligase activity (32, 35, 37, 39)(Fig. 7). It is not entirely clear how nuclear accumulation ofCUL1 facilitates its modification by NEDD8 and how NEDD8 modificationresults in activation of CUL1 ubiquitin ligase. Both the NEDD8-activatingE1 protein AXR1 (38) and NEDD8 itself (15) are localized primarilyin the nucleus, suggesting the possibility that nuclear accumulationmay provide CUL1 with access to a NEDD8 conjugating activity.ROC1 promotes association of CDC34 with CDC53/CUL1 when coexpressedin insect cells (43), and CDC34 is localized predominantly inthe nucleus (Y.Z. and Y.X, unpublished observation), suggestingthe possibility that ROC1-promoted nuclear accumulation and NEDD8modification may facilitate or stabilize the binding of E2 withCUL1 in the nucleus, leading to the assembly of active CUL1 ubiquitinligase. The requirement of nuclear accumulation and NEDD8 modificationfor optimal CUL1 ligase activity toward I $kappa$ B $alpha$ , a cytoplasmic protein,argues against the idea that nuclear accumulation and NEDD8 modificationplay a role in substrate targeting. We suggest that the assemblyof active CUL1 ligase is not coupled with and is likely separatedfrom the access to its substrate. Our results demonstrate thatactivation of CUL1 ligase requires a nuclear event and impliesa requirement for, and potentially a regulatory step associatedwith, nuclear export of activated CUL1 ubiquitinligase.

Notably, three elements involved in the regulation of CUL1 nuclear localization and ligase activation $---$ ROC1 binding, NEDD8modification, and the requirement of the C-terminal sequence $---$ areshared by or highly conserved in most, if not all, cullins. Wesuggest that this pathway may be commonly utilized in the assemblyand activation of other cullinligases.

	ACKNOWLEDGMENTS

We thank Al Baldwin for providing the GST-I $kappa$ B $alpha$ expression vector, Zhen-Qiang Pan for providing the HA-IKK $beta$ kinase expressionvector, and Jen Michel for helpful discussion during the courseof this work and critical reading of themanuscript.

T.O. is supported in part by the First Department of Surgery, St. Marianna University School of Medicine, Kawasaki, Japan.Y.X. is a recipient of the American Cancer Society Junior FacultyAward and is a Pew Scholar in Biomedical Science. This study wassupported by Public Health Service grants CA65572 and CA68377to Y.X.

	FOOTNOTES

^* Corresponding author. Mailing address: 22-012 Lineberger Comprehensive Cancer Center, Campus Box 7295, University of NorthCarolina at Chapel Hill, Chapel Hill, NC 27599-7295. Phone: (919)962-2142. Fax: (919) 966-8799. E-mail: yxiong{at}emailunc.edu.

Permanent address: Department of Surgery, St. Marianna University School of Medicine, Kawasaki 216,Japan.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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