SUMO-1 Conjugation in Vivo Requires Both a Consensus Modification Motif and Nuclear Targeting*

Manuel S. Rodriguez, Catherine DargemontDagger , and Ronald T. Hay§

From the School of Biology, Biomolecular Sciences Building, University of St. Andrews, St. Andrews, Fife KY169ST, United Kingdom and the Dagger  Laboratoire de Transport Nucléocytoplasmique, Institut Jacques Monod, CNRS UMR 7592, Tour 43, 2 Place Jussieu, 75251 Paris Cedex 05, France

Received for publication, October 17, 2000, and in revised form, December 13, 2000



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

SUMO-1 is a small ubiquitin-related modifier that is covalently linked to many cellular protein targets. Proteins modified by SUMO-1 and the SUMO-1-activating and -conjugating enzymes are located predominantly in the nucleus. Here we define a transferable sequence containing the Psi KXE motif, where Psi  represents a large hydrophobic amino acid, that confers the ability to be SUMO-1-modified on proteins to which it is linked. Whereas addition of short sequences from p53 and Ikappa Balpha , containing the Psi KXE motif, to a carrier protein is sufficient for modification in vitro, modification in vivo requires the additional presence of a nuclear localization signal. Thus, protein substrates must be targeted to the nucleus to undergo SUMO-1 conjugation.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

SUMO-11 is a small ubiquitin-related modifier (also known as sentrin, GMP1, UBL1, PIC1, or SMT3 in yeast) that has been found covalently conjugated to various cellular proteins (for reviews see Refs. 1-3). Several substrates for SUMO-1 have been reported: the RanGTPase-activating protein (RanGAP1) (4, 5) and Ran-binding protein 2 (6) implicated in nucleocytoplasmic trafficking; the promyelocytic leukemia protein (PML) and Sp100 (7) found in subnuclear structures known as PML oncogenic domains or PODs; the Ikappa Balpha inhibitor of the transcription factor nuclear factor kappa B, implicated in the control of immune and inflammatory responses (8); and the tumor suppressor protein p53 (9, 10). Consequently, "SUMOylation" plays a role in multiple vital cellular processes such as oncogenesis, cell cycle control, apoptosis, and response to virus infection.

SUMO-1 is conjugated to a target protein by a pathway that is distinct from but analogous to ubiquitin conjugation. Like ubiquitin, SUMO-1 is proteolytically processed to expose its mature C terminus by recently described SUMO-1-specific proteases variously called Ulp1 and Ulp2 in yeast (11, 12) or SENP1 and SUSP-1 in vertebrates (13-15). Ulp1, Ulp2, and SENP1, but not SUSP-1, are capable of both deconjugating SUMO-1 from modified proteins and removing four amino acids from the C terminus of the 101-amino acid SUMO-1 precursor to generate the mature 97-amino acid form. SUMO-1 addition is accomplished by a thioester cascade, with SUMO-1 first being activated by a heterodimeric SUMO-1-activating enzyme (SAE) that adenylates the C-terminal glycine of SUMO-1 (16-19) before catalyzing the formation of a thioester bond between the C terminus of SUMO-1 and a cysteine residue in SAE. In a transesterification reaction SUMO-1 is transferred from the SAE to the SUMO-1-conjugating enzyme Ubc9, which catalyzes the formation of an isopeptide bond between the C terminus of SUMO-1 and the epsilon -amino group of a lysine residue of the target protein (6, 20-23). Ubc9 is required for cell cycle progression in yeast (24). Unlike ubiquitin conjugation, SUMO-1 modification of target proteins in vitro is not dependent on the equivalent of an E3 protein ligase (17, 19).

Here, we demonstrate that a short sequence containing the consensus Psi KXE, where Psi  represents a large hydrophobic amino acid, constitutes a transferable signal that confers the ability to be modified with SUMO-1 on proteins to which it is linked. The predominantly nuclear localization of both subunits of the SAE, Ubc9 and SUMO-1, suggest that SUMOylation is a nuclear process. We demonstrate that heterologous proteins carrying the SUMO-1 consensus modification sequences present in Ikappa Balpha and p53 are only conjugated to SUMO-1 in vivo when a nuclear localization signal (NLS) is also present. These data suggest that protein substrates must be targeted to the nucleus to undergo SUMO-1 conjugation and allow us to propose that this modification may be involved in regulating multiple processes in the nucleus.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Cell Culture and Transfections-- HeLa cells were grown in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum. Cells were transfected by electroporation as described previously (25). For immunofluorescence analysis 2 µg of plasmid were transfected in 1 × 106 HeLa cells. For nickel bead purification, 10 µg of each plasmid DNA encoding pyruvate kinase (PK) fusions and His6-SUMO-1 were transfected in 1 × 107 HeLa cells. To increase efficiency of protein expression, no DNA carrier was used in cotransfections. After transfection, cells were seeded in 75 cm2 flasks. One-twentieth of transfected cells were seeded in a separated plate (to control protein input), and incubation was continued for 24 h.

Plasmids and DNA Manipulations-- Plasmids encoding His6-SUMO-1, HA-SUMO-1, SV5-SAE1, HA-SAE2, and SV5-Ubc9 were reported previously (8, 9, 17). pcDNA3 plasmids encoding Myc-tagged PK and NLS-PK were described previously (26). cDNA encoding the 1-26 fragment of Ikappa Balpha was obtained by polymerase chain reaction using as template Ikappa Balpha wild type and Ikappa Balpha K21R,K22R-encoding plasmids (27) to generate PK-Ikappa Balpha -(1-26) and PK-Ikappa Balpha -(1-26)-KR. cDNAs encoding 361-393 and 361-393 KR of p53 were subcloned from previously described constructs (9). Polymerase chain reaction fragments and synthetic oligonuclotides encoding the 381-391 fragment of p53, the 16-26 fragment of Ikappa Balpha , the 519-529 fragment of human RanGAP1, the 99-109 fragment of adenovirus type 2 E1B, and the 485-495 fragment of PML, as well as Lys to Arg versions, were cloned in BamHI and XbaI restriction sites of the PK vector. The same cDNAs were subcloned into BamHI and XbaI restriction sites of the NLS-PK vector that contains a polylinker, KpnI-BamHI-EcoRV-XbaI, to generate NLS-PK versions.

Immunofluorescence Microscopy-- Indirect immunofluorescence analysis was performed as described previously (28). Monoclonal antibodies anti-HA (Babco), anti-SV5 (Dr. R. Randall, University of St. Andrews), and anti-Myc (9E10) were applied for 30 min followed by a 30-min incubation with fluorescein isothiocyanate-conjugated donkey anti-mouse IgG (Jackson). Coverslips were mounted in Mowiol (Hoechst, Frankfurt, Germany). Images were acquired on a DMRB fluorescence microscope (Leica) with a CCD camera (Princeton).

In Vitro SUMO-1 Assay-- In vitro transcription/translation (Promega) and SUMO-1 conjugation assays were performed as reported (8).

Preparation of Cell Extracts and Immunoblotting-- Cells were harvested in 100 µl of lysis buffer for Western blot analysis (8). His6-SUMO-1 conjugates were purified as described (9). Proteins were resolved by electrophoresis in 8.5% polyacrylamide gels containing SDS, transferred to polyvinylidene difluoride membranes (Sigma) by electroblotting, and processed for Western blotting as reported previously (9). Primary monoclonal antibody anti-Myc (9E10) was obtained from Dr. R. E. Randall. Horseradish peroxidase-conjugated anti-mouse IgG was purchased from Amersham Pharmacia Biotech. An enhanced chemiluminescence detection system was used to detect specific antigen-antibody interactions (Amersham Pharmacia Biotech).

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Nuclear Distribution of the SUMO-1 Conjugation Pathway Enzymes-- It has been previously reported that Ubc9 promotes the nuclear localization of a Ubc9-beta -galactosidase fusion protein in Saccharomyces cerevisiae (24). Moreover, Ubc9 has been localized predominantly in the nucleus of T cells (29). To analyze the subcellular distribution of all the components of the SUMO-1 conjugation pathway, we transiently transfected HeLa cells with HA-tagged versions of SUMO-1 and SAE-2 and SV5-tagged versions of Ubc9 and SAE-1 (Fig. 1). As expected, SUMO-1 displayed nuclear distribution and accumulated in nuclear dot-like structures (30) (Fig. 1a). Using paraformaldehyde fixation, Ubc9 was localized mainly in the nucleus but also in the cytoplasm of transfected cells (Fig. 1b). However, when cells were fixed with 1:1 methanol/acetone, Ubc9 immunoreactive material was concentrated at the nuclear envelope (data not shown and Ref. 23). The SAE-1 and SAE-2 (Fig. 1, c and d, respectively) subunits of the SAE presented an exclusively nuclear distribution that was not changed when both subunits were coexpressed or when cells were fixed by different methods (data not shown). Thus, the predominant nuclear localization of enzymes implicated in the SUMO-1 modification pathway suggests that this ubiquitin-like modification may take place in the nucleus.


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Fig. 1.   Nuclear distribution of SUMO-1 and the SUMO-1 conjugation pathway enzymes. HeLa cells were transfected with plasmids encoding HA-SUMO-1 (a), SV5-Ubc9 (b), SV5-SAE1 (c), and HA-SAE2 (d). Indirect immunofluorescence was carried out with monoclonal antibodies recognizing HA and SV5 tags followed by fluorescein isothiocyanate-conjugated anti-mouse IgG.

Sequence Requirement for SUMO-1 Modification-- To test the proposition that SUMO-1 modification takes place in the nucleus, we designed an experiment strategy in which a minimal SUMO-1 modification site, fused to a heterologous protein, is located in either the nucleus or the cytoplasm by virtue of the presence or absence of an NLS. Constructs were designed such that these could be tested for SUMO-1 conjugation in vitro, where there is no influence of compartmentalization, or expressed in vivo either in the nucleus or the cytoplasm. Analysis of the sequence of SUMO-1 conjugation sites in multiple proteins indicates that a short motif Psi KXE represents the primary site of SUMO-1 modification (8, 9, 31-33). To further define the sequence required for conjugation with SUMO-1, we designed a series of constructs containing Ikappa Balpha N-terminal and p53 C-terminal modification sites fused to the C terminus of either a Myc-tagged version of PK or an equivalent construct containing the SV40 NLS (NLS-PK) (Fig. 2). [35S]Met-labeled PK and NLS-PK fusions generated by in vitro transcription and translation were assayed for SUMO-1 conjugation in vitro using the previously described assay (8). PK and NLS-PK fused to amino acids 1-26 and 16-26 of Ikappa Balpha or amino acids 361-393 and 381-391 of p53 were conjugated with SUMO-1, whereas PK or NLS-PK alone were not (Fig. 2, A and B). When lysine residues 21 of Ikappa Balpha and 386 of p53 were changed to arginine (KR constructs), SUMO-1-modified forms of PK-Ikappa Balpha -KR and PK-p53-KR fusions were not detected, indicating that SUMO-1 was conjugated specifically to the previously described lysine residues (8-10). To determine whether the 11-amino acid sequence required for conjugation with SUMO-1 could be further reduced, a series of synthetic oligonucleotides that specifies the human RanGAP1 519-529 (11 amino acids), 520-528 (9 amino acids), 521-527 (7 amino acids), and 522-526 (5 amino acids) amino acid sequences was fused to the C terminus of PK to generate the corresponding PK-RanGAP1 constructs (Figs. 2C and 4A). Efficient SUMO-1 conjugation was observed with PK fusion encoding 11, 9, and 7 amino acids, whereas the efficiency of conjugation was reduced but still detectable with only 5 amino acids (Fig. 2C). Thus, SUMO-1 modification requires a core recognition motif of five amino acids, although flanking residues influence the efficiency of conjugation.


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Fig. 2.   Sequence requirement for SUMO-1 modification. In vitro expressed 35S-labeled PK or NLS-PK constructs containing 1-26, 1-26KR, 16-26, and 16-26KR sequences of Ikappa Balpha (A) or 361-393, 361-393KR, and 381-391 sequences of p53 (B) were tested for substrate activity in an in vitro SUMO-1 conjugation assay. Reaction products were fractionated by SDS-polyacrylamide gel electrophoresis, and the dried gel was analyzed by phosphorimaging. SUMO-1-conjugated forms are indicated by an asterisk. C, in vitro SUMO-1 conjugation of 35S-labeled PK constructs containing amino acids 519-529, 520-528, 521-527, or 522-526 of human RanGAP1. Reaction products were processed as above.

SUMO-1 Conjugation in Vivo Requires Nuclear Targeting-- In most cells, SUMO-1 is found in conjugates with target proteins, and as such the pool of free SUMO-1 is limiting (8). At present, most cellular substrates reported to be conjugated with SUMO-1 show a nuclear distribution (PML, Sp100, and p53), shuttle between the nucleus and the cytoplasm (Ikappa Balpha ) (34, 35), or are associated to the nuclear pore complex (RanGAP1 and Ran-binding protein 2) (4-6). Cell fractionation analysis indicates that 80-90% of endogenous SUMO-1-conjugated proteins have a nuclear distribution (7, 36, and data not shown). To determine whether SUMO-1 conjugation requires nuclear targeting, the PK-Ikappa Balpha and PK-p53 constructs were compared with NLS-PK-Ikappa Balpha and NLS-PK-p53 constructs for SUMO-1 conjugation in vivo. The ability of the NLS-PK constructs to be conjugated with SUMO-1 in vitro is identical to the PK fusion counterpart (Fig. 2, A and B). As expected, all PK constructs were localized in the cytoplasm, and all NLS-PK constructs were localized in the nucleus of transfected cells (Fig. 3A). To detect forms of PK and NLS-PK modified by SUMO-1 in vivo, constructs specifying these proteins were cotransfected into HeLa cells with an expression plasmid for His6-SUMO-1 (9). His6-SUMO-1-conjugated proteins were isolated on nickel beads, and eluted proteins were analyzed by Western blotting with a monoclonal antibody recognizing the Myc tag. NLS-PK-Ikappa Balpha -(1-26) and -(16-26) as well as NLS-PK-p53-(361-393) and -(381-391) are efficiently conjugated with SUMO-1 (Fig. 3, B and C, top). Under the same conditions, KR mutants were not modified. In contrast to NLS-PK constructs, PK counterparts were not modified. These results clearly indicate that nuclear localization is required for conjugation of proteins with SUMO-1.


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Fig. 3.   SUMO-1 conjugation in vivo requires nuclear targeting. A, HeLa cells were transfected with Myc-tagged PK (a-e) or NLS-PK (f-j) constructs containing no insert (a and f), Ikappa Balpha -(1-26) (b and g), Ikappa Balpha -(16-26) (c and h), p53-(361-393) (d and i), and p53-(381-391) (e and j). Indirect immunofluorescence analysis was carried out with a monoclonal antibody recognizing the Myc tag followed by fluorescein isothiocyanate-conjugated anti-mouse IgG. B and C, HeLa cells were cotransfected with plasmids encoding His6-SUMO-1 and Myc-tagged PK or NLS-PK constructs containing Ikappa Balpha -(1-26), Ikappa Balpha -(1-26)-KR, Ikappa Balpha -(16-26), and Ikappa Balpha -(16-26)-KR (B) or p53-(361-393), p53-(361-393)-KR, and p53-(381-391) (C). After 24 h of expression, cells were lysed in buffer containing guanidinium-HCl. Proteins linked to His6-SUMO-1 were purified by nickel beads, and, after being washed, were eluted with 200 mM imidazole. Eluted proteins were fractionated by SDS-polyacrylamide gel electrophoresis and transferred to a polyvinylidene difluoride membrane. His6-SUMO-1 conjugates were detected by Western blotting using the 9E10 anti-Myc monoclonal antibody. To control protein input, a fraction of each lot of transfected cells was lysed in buffer containing SDS and analyzed as above.

Intrinsic Substrate Activity of SUMO-1 Modification Motifs-- Although a short motif can direct SUMO-1 modification when transferred to a heterologous protein, the efficiency of SUMO-1 modification will be a combination of the intrinsic substrate activity of the motif and the environment of the motif in the native protein. To investigate the intrinsic substrate activity of a range of SUMO-1 modification motifs, we generated additional PK constructs (Fig. 4A) encoding amino acids 485-495 of PML (31, 37) and amino acids 99-109 of the human adenoviral protein E1B,2 which contain the lysine residue that is the site of SUMO-1 conjugation (Fig. 4A). 35S-labeled PK-RanGAP1-(519-529), PK-p53-(381-391), PK-Ikappa Balpha -(16-26), PK-AdE1B-(99-109), and PK-PML-(485-495) were used as substrates for SUMO-1 conjugation in vitro (Fig. 4B). A range of substrate activities is evident (Fig. 4B), with PK-AdE1B and PK-PML being modified efficiently, PK-Ikappa Balpha and PK-p53 being modified less efficiently, and PK-RanGAP1 being modified poorly. Those differences were also observed in vivo when comparing NLS-PK fusions encoding PML, Ikappa Balpha , and p53 sequences (Fig. 4C) in conditions where PK counterparts were poorly modified or not modified at all (data not shown). The differences observed in the conjugation of SUMO-1 to this range of substrates indicates that the precise sequence of the SUMO-1 modification motif, when isolated from its native environment, defines the efficiency of SUMO-1 conjugation.


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Fig. 4.   Intrinsic substrate activity of SUMO-1 modification motifs. 35S-labeled PK-RanGAP1-(519-529), PK-p53-(381-391), PK-Ikappa Balpha -(16-26), PK-AdE1B-(99-109), and PK-PML-(485-495) (A) were tested as substrates for SUMO-1 conjugation in vitro (B). Reaction products were fractionated by SDS-polyacrylamide gel electrophoresis, and the dried gel was analyzed by phosphorimaging. Different levels of conjugation with SUMO-1 are indicated in A. We arbitrarily considered PK-PML conjugation as 100%. +++, 100-67%; ++, 66-33%; and +, <33%. C, HeLa cells were cotransfected with plasmids encoding His6-SUMO-1 and NLS-PK or NLS-PK constructs encoding PML-(485-495), Ikappa Balpha -(16-26), and p53-(381-391) amino acid sequences. Transfected cells were processed as in Fig. 3. Purified His6-SUMO-1 conjugates and protein input were detected by Western blotting using an anti-Myc antibody.

Mutational Analysis of the Psi KXE Motif-- To evaluate the role of each amino acid within the Psi KXE motif in SUMO-1 conjugation, a series of PK constructs encoding alanine mutations in the FKTE sequence of p53 were generated (9). Mutations of the X residue T did not affect conjugation with SUMO-1 (Fig. 5A). When residue Psi  was changed to alanine, conjugation with SUMO-1 was reduced (Fig. 5A). As expected, mutation of the strictly conserved Lys and Glu residues abrogates conjugation with SUMO-1 (Fig. 5A). These results confirm that Lys and Glu are the most important residues of the consensus and suggest that the Psi  and X residues may influence the efficiency of SUMO-1 conjugation. To investigate this point, a series of PK-RanGAP1 molecules was generated in which the Psi  residue (Leu) of the poorly modified PK-RanGAP1 was changed to each of the possible hydrophobic residues, and the efficiency of conjugation was determined in vitro. Whereas changing the Leu to either Ile or Val increased the efficiency of SUMO-1 conjugation, changes to Ala, Pro, or Trp substantially reduced the efficiency of conjugation. Substitutions of Leu with Phe or Met did not alter the efficiency of conjugation (Fig. 5B). To evaluate the role of the X amino acid, the Met residue at this position in PK-PML was changed to either Ala, Lys, Ile, Ser, or Asp. Whereas substitution of Met with Asp caused a small decrease in substrate activity, all of the other modifications at this position were without consequence. Although most described modification sites in naturally occurring proteins contain the sequence Psi KXE, it was of interest to determine whether a Glu residue was absolutely required for activity. The conservative Glu to Asp change was therefore made within the context of the PK-PML construct, and the substrate activity was determined. The altered substrate is modified very poorly when compared with a substrate containing the wild type motif (Fig. 5B). Thus, SUMO-1 modification is directed by a Psi KXE motif, where the nature of the hydrophobic amino acid preceding the acceptor lysine residue has a major influence on the efficiency with which SUMO-1 is conjugated to the target protein.


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Fig. 5.   Mutational analysis of the Psi KXE motif. A, the in vitro SUMO-1 conjugation assay was performed with 35S-labeled PK-p53-(381-391) (WT), PK-p53-(381-391) (K386A), PK-p53-(381-391) (E386A), PK-p53-(381-391) (T387A), and PK-p53-(381-391) (F385A). Asterisks indicate SUMO-1-conjugated forms. B, 35S-labeled PK-RanGAP1-(519-529)-wild type (L), PK-PML-(485-495)-wild type (M), and indicated mutants were tested as substrates for SUMO-1 conjugation in vitro. Different levels of conjugation with SUMO-1 are indicated.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Post-translational protein modifications modulate protein function by altering protein activity or the ability to interact with ligands or by changing subcellular localization of the modified protein. Conjugation with SUMO-1 has been proposed to regulate protein function through all these mechanisms. Identification of a short amino acid sequence motif required for the transfer of the capacity to be conjugated with SUMO-1 to a heterologous protein indicates that this motif is necessary for recognition by the SUMO-1 modification enzymes. Most of the targets for SUMO-1 modification are Ubc9-interacting proteins, and it is likely that substrate specificity is achieved by Ubc9. The C-terminal region of Ubc9, which is thought to be involved in substrate binding, lies close to the catalytic site and favors the direct transfer of SUMO-1 to substrate proteins (38). The most important amino acids in the consensus sequences are Lys and Glu. Whereas the acceptor Lys residue cannot be substituted, Glu can be replaced by Asp to generate a recognition motif that, although functional, is poorly conjugated with SUMO-1 (Fig. 4). To date, the only reported modification site containing Asp rather than Glu in a natural protein is in the yeast septin Cdc3, although it was not clear how efficiently this site was utilized for modification (32). In addition to the Lys and Glu residues, the large hydrophobic residue contributes substantially to the efficiency of SUMO-1 modification. Short transferable sequences from various protein substrates modified with SUMO-1 show different capacities to be conjugated with SUMO-1. The best conjugated short sequence contains the sequence IKME from PML, whereas the sequence that is least efficiently modified contains the sequence LKSE from RanGAP1. Surprisingly, RanGAP1 is one of the best cellular substrates for conjugation with SUMO-1 (4, 5), suggesting that other cis or trans factors may influence its efficiency of conjugation. When fused to the C terminus of a heterologous protein, the 7-amino acid sequence containing the Psi KXE motif acts as an efficient substrate for SUMO-1 modification in vitro. However, when an amino acid is removed from each end of this sequence to generate a five-amino acid sequence containing the Psi KXE motif, its substrate activity is reduced. Although the shortest transferable sequence we have tested contains five amino acids, extensive additional mutagenesis failed to identify any elements outside the Psi KXE motif that contributed to substrate activity. It is likely that the seven-amino acid sequence is a more efficient substrate than the five-amino acid sequence, because the sequences were added to the C-terminal end of a carrier protein such that the Glu in the Psi KXE motif is now the C terminus of the protein. Thus the Psi KXE motif needs to be flanked by at least one additional C-terminal amino acid for optimal recognition by the SUMO-1 modification machinery. One important factor is how the recognition motif is presented to the surface of the protein. If it is located in an exposed loop, then it may be highly accessible to the modification machinery. Mutational analysis of RanGAP1 indicates that sequences flanking the domain containing the acceptor lysine (Lys-526) are required for efficient SUMO-1 modification in vitro, although the function of these additional domains has yet to be defined (35). Alternatively, additional binding sites for Ubc9 in the target protein may result in tighter binding of Ubc9 to the protein substrate, with a consequent increase in the efficiency of conjugation. This may be the case with PML, in which the RING finger is required for interaction with Ubc9 in a yeast two-hybrid analysis. PML proteins containing mutations that disrupt the RING finger are poorly modified in vivo but efficiently modified in vitro (31). Whereas SUMO-1 conjugation of RanGAP1 and Ikappa Balpha can be catalyzed in vitro simply with SAE and Ubc9 (17, 19), it is possible that additional protein factors may influence the efficiency of conjugation. The importance of how the modification motif is presented is exemplified by the case of the splicing protein p32, which contains a perfect match to the consensus recognition site for SUMO-1 modification and yet is not modified by SUMO-1 in vitro.3 Moreover, inspection of the structure of p32 (39) reveals that the recognition motif is not surface-exposed and would not be accessible to the modification machinery.

The observed predominant nuclear distribution of SUMO-1, SAE, and Ubc9, as well as the exclusive SUMO-1 modification of NLS-PK substrates, indicates that SUMO-1 modification requires nuclear targeting. However, because Ubc9 is concentrated at the nuclear envelope, we cannot determine whether SUMO-1 modification with SUMO-1 takes place after transport of substrates into the nucleus or whether modification occurs during docking at the nuclear envelope and/or translocation into the nucleus. It has previously been noted that mutations or deletions of the nuclear localization signals of PML, RanGAP1, and Sp100 that resulted in cytoplasmic accumulation of these proteins also resulted in loss of SUMO-1 modification in vivo (31, 33, 35). In addition, a 97-kDa isoform of PML, which, for unknown reasons, is located in the cytoplasm, also fails to undergo SUMO-1 modification in vivo. The same protein, however, is efficiently modified by SUMO-1 in vitro (31).

Thus, newly synthesized unmodified substrates would be targeted to the nucleus, where they would be modified by the combination of SAE1, SAE2, and Ubc9. Once modified, these proteins may be incorporated into subnuclear structures such as PODs. In particular, SUMO-1 modification of the POD component PML is required for both formation of the PODs (40) and for recruitment of other proteins such as Daxx into the PODs (41). Alternatively, newly SUMO-1-modified proteins could, as in the case of RanGAP1, be targeted to the nuclear pore complex (4, 5) or shuttle between the nucleus and the cytoplasm like Ikappa Balpha and p53, although there is as yet no data indicating whether this is the case for the SUMO-1-modified form of these proteins (8-10).

Although nuclear targeting appears to be required for SUMO-1 modification of most substrates, we cannot rule out the possibility that some proteins may be modified in other cellular compartments. This may be the case for the glucose transporters GLUT1 and GLUT4, which are targeted to the cell membrane and yet appear to be SUMO-1-modified (42). One possibility is that newly synthesized SAE and Ubc9 are recruited to a cytoplasmic complex containing GLUT1 and GLUT4, where modification takes place. This is consistent with the observation that GLUT1 and GLUT4 both interact directly with Ubc9. If the NLSs of SAE and Ubc9 are occluded in this complex, then this would allow a small proportion of the predominantly nuclear SAE and Ubc9 to remain in the cytoplasm tightly associated with their substrate.

The two recently described SMT3-specific proteases Ulp1 and Ulp2 (11, 12) accumulate a different pattern of SMT3-conjugated proteins in their mutants, indicating that deconjugation of substrates can be achieved and regulated by multiple SMT3 proteases with different specificities. Because SUMO-1 is a limiting factor for conjugation of substrates, deconjugation of SUMO-1 may be a dual mechanism to decrease (or increase) protein activity of a deconjugated protein and increase (or decrease) the activity of a newly conjugated target, when released SUMO-1 is available. However the cellular sites at which this process takes place are not known, because the cellular localization of endogenous SUMO-1-specific proteases has yet to be determined. Thus SUMO-1 modification of most proteins appears to be regulated by the requirement of the substrate to be targeted to the nucleus and by the possession of a SUMO-1 recognition motif displayed on the surface of the target protein. It is likely that SUMO-1 modification emerges as an important control mechanism that regulates the activity of many nuclear proteins.

    ACKNOWLEDGEMENTS

We thank Alex Houston, University of St. Andrews, for DNA sequencing. We thank Joana Desterro, Ellis Jaffray, and Magali Prigent for technical advice and support.

    FOOTNOTES

* This work was supported by the Medical Research Council, the Biotechnology and Biology Research Council, and the Fondation pour la Recherche Medicale.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ To whom correspondence should be addressed. Tel.: 44-1334-463396; Fax: 44-1334-462595; E-mail: rth@st-and.ac.uk.

Published, JBC Papers in Press, December 21, 2000, DOI 10.1074/jbc.M009476200

2 A. Errico and R. T. Hay, unpublished data.

3 R. T. Hay, unpublished observation.

    ABBREVIATIONS

The abbreviations used are: SUMO-1, small ubiquitin-like modifier 1; RanGAP, RanGTPase-activating protein; PML, promyelocytic leukemia protein; POD, PML oncogenic domain; Ikappa Balpha , inhibitor of (nuclear factor) kappa Balpha ; SAE, SUMO-1-activating enzyme; NLS, nuclear localization signal; PK, pyruvate kinase; HA, hemagglutinin; SV5, simian virus type 5.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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