Identification of the nuclear localization signals within the ... - CiteSeerX

Journal of General Virology (2004), 85, 165–172

DOI 10.1099/vir.0.19549-0

Identification of the nuclear localization signals within the Epstein–Barr virus EBNA-6 protein Kenia Krauer, Marion Buck, James Flanagan, Deanna Belzer and Tom Sculley Correspondence Tom Sculley

Queensland Institute of Medical Research and ACITHN University of Queensland, 300 Herston Road, Brisbane 4029, Queensland, Australia

[email protected]

Received 5 August 2003 Accepted 1 October 2003

Epstein–Barr virus nuclear antigen (EBNA)-6 is essential for EBV-induced immortalization of primary human B-lymphocytes in vitro. Previous studies have shown that EBNA-6 acts as a transcriptional regulator of viral and cellular genes; however at present, few functional domains of the 140 kDa EBNA-6 protein have been completely characterized. There are five computer-predicted nuclear localization signals (NLS), four monopartite and one bipartite, present in the EBNA-6 amino acid sequence. To identify which of these NLS are functional, fusion proteins between green fluorescent protein and deletion constructs of EBNA-6 were expressed in HeLa cells. Each of the constructs containing at least one of the NLS was targeted to the nucleus of cells whereas a construct lacking all of the NLS was cytoplasmic. Site-directed mutation of these NLS demonstrated that only three of the NLS were functional, one at the N-terminal end (aa 72–80), one in the middle (aa 412–418) and one at the C-terminal end (aa 939–945) of the EBNA-6 protein.

INTRODUCTION Epstein–Barr virus (EBV) is a DNA tumour virus that has the capacity to infect and transform B-lymphocytes. Following infection, the co-ordinate expression of a number of viral nuclear antigens (EBNAs) and membrane proteins (LMP-1 and -2) acts to maintain B-cell growth and transformation (for review see Kieff, 1996). EBNA-6 is essential in the transformation and immortalization process. Analysis of the EBNA-6 amino acid sequence has revealed features common to many viral and cellular transcription factors. These include a region which resembles a basic DNA-binding domain adjacent to a potential leucinezipper motif (b-zip) and a transactivation domain rich in glutamine/proline residues, which has similarities to the mammalian transcription factor Sp1 (Bain et al., 1996; Radkov et al., 1997; Marshall & Sample, 1995). The EBNA6 protein has also been identified as an immortalizing oncoprotein which can cooperate with activated (Ha-)ras in cotransformation assays and can override Rb-mediated pathways (Allday et al., 1993). EBNA-6 is a hydrophilic, proline-rich, charged protein that is targeted exclusively to the cell nucleus, and cellular fractionation experiments have shown that EBNA-6 is associated with the nuclear matrix, and to a lesser extent is present in the nucleoplasm (Petti et al., 1990). Sample & Kieff (1990) showed that EBNA-6 localized to subnuclear granules within the cell nucleus. Subsequent to translation, the fate of a protein depends 0001-9549 G 2004 SGM

Printed in Great Britain

largely on whether its amino acid sequence contains sorting signals directing the protein to specific cellular locations. The active transport of proteins in both directions across the nuclear envelope requires the presence of specific targeting sequences within the protein (Gorlich et al., 1996). There are at least three types of nuclear localization signals (NLS) on proteins and these signals are characteristically rich in the basic amino acids lysine and arginine and usually contain proline (Dingwall & Laskey, 1991). The first type of NLS is a continuous stretch of amino acids, which can be located almost anywhere in the protein sequence. The archetypal NLS is that of the SV40 large tumour antigen (PPKKRKV) (Huber et al., 1996). The second type of NLS is a bipartite sequence, or a signal patch, that consists of a three-dimensional arrangement on the protein surface. An example of this is Xenopus laevis nucleoplasmin, where there are two clusters of basic amino acid residues separated by an intervening 10–12 aa spacer (Dingwall & Laskey, 1992). The third type are less well conserved sequences with few basic residues such as that of the adenovirus E1A (KRPRP) (Lyons et al., 1987). However, nuclear localization signals can be masked by phosphorylation close to or within an NLS. This phosphorylation inactivates the NLS through charge or conformational effects (Hennekes et al., 1993; Ohta et al., 1989). NLS are not cleaved off after transport into the nucleus, which is presumably because nuclear proteins need to be imported repeatedly, once after every cell division (Chaudhary & Courvalin, 1993). Proteins containing NLS are recognized by the transport machinery and are imported through the 165

K. Krauer and others

nuclear pore complex, whereas proteins lacking NLS remain in the cytoplasm (Moll et al., 1991). EBNA-6 has several localized concentrations of arginine or lysine residues that are potential signatures of nuclear localization and although it is recognized that EBNA-6 is targeted to the nucleus, the NLS responsible have not been identified.

METHODS Construction of GFP-EBNA-6 deletion mutants. The correct

orientation and insertion of fragments in each of the deletion constructs of EBNA-6 were confirmed by DNA sequencing and immunoblotting. pBS-GFP-E6. The EBNA-6 cDNA fragment (B95-8 virus) was excised from vector pGBT9-E6 (Young et al., 1997) using BsrGI and BstEII. The excised fragment was then Klenow treated and ligated into pBS-GFP that had previously been restricted with BsrGI and Klenow treated. (pBS-GFP was a gift from M. Vogel, Medicine, Microbiology and Hygiene, Regensburg University; pBS-GFP-E6 was originally prepared by D. Young, QIMR.) pBS-GFPL. The pBS-GFP plasmid was adapted to include a linker containing the restriction enzyme sites BsrGI, StuI, BamHI, EcoRV, HpaI, XhoI and NotI. This was prepared by annealing 1 mg of two self-complementary 41 base oligomers (Custom-made; Life Technologies, Australia) and then ligating this fragment into pBSGFP that had been restricted with BsrGI and NotI. pBS-GFPL-E6D1–206. Plasmid pBS-GFP-E6 was cut with HpaI and

NotI and the E6 fragment was inserted into pBS-GFPL cut with HpaI and NotI. pBS-GFP-E6D1–395/601–992. The pBS-GFPL-E6D1–206 construct

was digested with ClaI and NarI, resulting in a 618 bp fragment, which was Klenow treated and then ligated to pBSGFPL that had been HpaI restricted. This resulted in a fusion of GFP with aa 396–600 of EBNA-6 containing NLS2–4. pBSGFP-E6D184–992. The vector pBS-GFP-E6 was digested with XbaI, Klenow treated, and then digested with EcoRV and religated resulting in a fusion of GFP with aa 22–183 of EBNA-6 which contained NLS1.

pEBO-GFP-E6D396–625. NLS2–4 were removed from EBNA-6 by

excising a 696 bp fragment from the vector pBSGFP-E6 by restriction with ClaI and NarI. The restricted ends were then Klenow treated and religated. The plasmid was then digested with HindIII and NotI and the EBNA-6 region inserted into EBO-pLPP, restricted with the same enzymes. This resulted in removal of aa 396–625 of EBNA-6. pBS-GFPL-E6D1–206/396–625. The pBSGFPL-E6D396–625 con-

struct was digested with HpaI and NotI, and the resulting fragment was inserted into pBS-GFPL that had been restricted with HpaI and NotI. This resulted in the expression of a fusion of GFP with EBNA6 aa 207–395 joined with aa 626–992 and contained NLS5. pBS-GFP-E6D1–206/396–625/941–992. The 1?5 kb StuI fragment, excised from pBS-GFPL-E6D1–206/396–625, was then ligated into pBS-GFPL previously restricted with HpaI. This resulted in the expression of a GFP fusion linked to aa 207–395 joined with aa 626–940 of EBNA-6, which lacked all computer-predicted NLS. Site directed mutagenesis. In vitro mutagenesis of doublestranded DNA templates was performed as described in Sambrook & Russell (2001) with some modifications. Briefly, a PCR reaction was performed with 5–50 ng plasmid DNA and 125 ng of each primer using Pfu Turbo polymerase under the following buffer conditions: 20 mM Tris/HCl pH 8?8, 10 mM KCl, 10 mM (NH4)2SO4, 2 mM MgSO4, 0?1 % Triton X-100, 0?1 mg nuclease-free BSA ml21 in a 50 ml reaction. Cycling conditions were as follows: 95 uC 30 s, 55 uC 1 min, 68 uC 2 min per kb of plasmid DNA for 16–18 cycles, followed by 72 uC for 10 min. PCR primers are listed in Table 1. Following the PCR reaction plasmid DNA was digested with 20 U DpnI for 3 h at 37 uC. The PCR mixture (4 ml) was then transformed into E. coli DH5a competent cells by electroporation and the bacteria were then plated onto LB plates containing ampicillin. Resultant bacterial colonies were selected, plasmid DNA was prepared and confirmation of mutagenized bases determined by restriction enzyme digestion and DNA sequencing. A list of the resultant NLS mutations is shown in Table 2. Cell lines, maintenance and DNA transfection. HeLa cells were maintained in RPMI 1640 supplemented with 10 % foetal calf serum, benzylpenicillin (0?7 mg ml21) and streptomycin (1 mg ml21) at 37 uC in a 5 % CO2 atmosphere. HeLa cells were transfected using ExGen 500 (Progen) according to the manufacturer’s protocol. Briefly, cells were plated 24 h prior to transfection at a cell density of 2?46105 cells per well in 3 ml RPMI 1640 containing 10 % FCS. Plasmid DNA (5 mg) was diluted with 300 ml 150 mM NaCl and then 15?5 ml ExGen 500 was added. After vortexing and incubation

Table 1. Primers used for site-directed mutagenesis NLS mutated NLS1a NLS1b NLS2 NLS3 NLS5

166

Primers 59-GCAGCGCATCAGGGCAAGGGCGGCAAGACGGGCTGCCTTG-39 59-CAAGGCAGCCCGTCTTGCCGCCCTTGCCCTGATGCGCTGC-39 59-GCGCATCAGGGCAGCGGCGGCAGCACGGGCTGCC-39 59-GGCAGCCCGTGCTGCCGCCGCTGCCCTGATGCGC-39 59-CGTGTGCCTGCAAAGGCACCGGGGAAACTGCCTTGGCC-39 59-GGCCAAGGCAGTTTCCCCGGTGCCTTTGCAGGCACACG-39 59-CCACCGCCTTCCCGTGCGGCAAGGGGAGCGTGTGTTG-39 59-CAACACACGCTCCCCTTGCCGCACGGGAAGGCGGTGG-39 59-GCCACCACGCCAAAAGGGGCTCGAGTAGAAGAAAGTTCTC-39 59-GAGAACTTTCTTCTACTCGAGCCCCTTTTGGCGTGGTGGC-39

Journal of General Virology 85

NLS in EBNA-6

Table 2. Summary of EBNA-6 NLS mutants Amino acid residues are indicated with the single-letter code. Bold letters indicate the mutated amino acid residues within each NLS. NLS NLS1 NLS1a mut NLS1b mut NLS2 NLS2 mut NLS3 NLS3 mut NLS5 NLS5 mut

Sequence RIRRRRRRR RIRARAARR RIRAAAAAR PAKKPRK PAKAPGK PPPSRRRRG PPPSRAARG PKRPRVE PKGARVE

for 10 min at room temperature, the mixture was added directly to the HeLa cells. The plates were centrifuged at 1200 r.p.m. for 5 min and then placed into an incubator. Cells were analysed for transient gene expression at 24 h after incubation at 37 uC in a 5 % CO2 atmosphere. Direct fluorescence microscopy. HeLa cells expressing GFP-E6

fusion proteins were grown on coverslips and fixed with ice-cold acetone (2 min, 220 uC), and then mounted with Vectashield mounting medium onto glass slides. HeLa cells were scanned using either a Bio-Rad MRC 600 confocal microscope with images acquired using COMOS (Confocal Microscope Operating Software Version 6.03) or a Leica confocal microscope, model TCS SP2 and images recorded using Leica Confocal Software. The acquired images were then analysed and processed for presentation using CAS (Confocal Assistant Software Version 3.10), in which single optical sections are shown.

RESULTS Nuclear localization signals in EBNA-6 Five potential NLS, as defined by either the bipartite consensus (Robbins & McMichael, 1991) or the Nakai consensus (Nakai & Kanehisa, 1992), were identified within the EBNA-6 protein sequence using PSORT (Pedro’s BioMolecular Research Tools – http://www.public.iastate. edu/~pedro/rt_1.html). NLS1, which comprises multiple overlapping pattern 4 sequences, is located within the N-terminal region of EBNA-6, aa 72–80 (RIRRRRRRR). The second NLS, aa 412–418 (KKPRK), has overlapping pattern 4 and pattern 7 sequences as has the third NLS (NLS3) at aa 494–500 (PPSRRRR). A bipartite NLS (NLS4) is located at aa 533–549 (RKHQDGFQRSGRRQKRAA). The fifth NLS, which has overlapping pattern 4 and pattern 7 sequences, is located at the C-terminal end of the protein (NLS5) and encompasses aa 939–945 (PKKRPRVE). Constructs of EBNA-6, linked to GFP, were prepared such that they contained at least one of these NLS, as well as one construct which lacked all of the computer-predicted NLS, to determine whether other previously unrecognized NLS http://vir.sgmjournals.org

were present in the protein. The integrity of the constructs was determined by DNA sequencing and immunoblotting. To ensure easy visualization of both the nucleus and cytoplasm the constructs were transfected into HeLa cells. All of the constructs were transiently expressed in HeLa cells and the cellular location of the fusion proteins was determined by confocal microscopy. In contrast to GFP alone, which was distributed diffusely in both the cytoplasm and the nucleus, each of the constructs containing a predicted NLS localized to the nucleus of cells. However, the fusion protein in which all computer-predicted NLS were removed (GFP-E6D1–206/396–625/941–992), was present only in the cytoplasm of cells (Fig. 1). These results indicated that the predicted NLS present in EBNA-6 were likely to be functional and that there were unlikely to be any additional NLS present within the EBNA-6 coding region (at least within the sequence included in GFPE6D1–206/396–625/941–992). Mutagenesis of the EBNA-6 NLS To determine if the predicted NLS within each of the GFP-EBNA-6 constructs was responsible for their nuclear localization, site-directed mutants in the basic residues within each of the predicted NLS were generated. The mutations generated within each of the NLS are shown in Table 2. Because of the number of consecutive arginine residues present in NLS1 two mutants were generated, one with three of the arginine residues replaced with alanine residues and the second mutant with five of the arginine residues replaced with alanine residues. Each of the mutagenized constructs was transiently transfected into HeLa cells and the cellular localization of the mutant proteins was determined by confocal microscopy (Fig. 2). Substitution of the arginine residues at position 75, 77 and 78 by alanine residues (NLS1a mut) had no effect upon nuclear localization and additional substitutions of arginine residues 76 and 79 (NLS1b mut) was required to abrogate the nuclear localization of the GFP-E6aa184–992 protein. Mutation of NLS3 had no effect upon the nuclear localization of the GFP-E6aa396–600 protein whereas substitution of lysine residue 414 and arginine residue 416 within NLS2 by alanine and glycine residues, respectively, was sufficient to abrogate the nuclear localization of the GFP-E6aa396–600 protein. This result confirmed that the sequence KKPRK was a functional NLS and that NLS3 and NLS4 were nonfunctional. Substitution of arginine residue 941 by glycine and proline residue 942 by alanine was sufficient to destroy NLS5 and prevent the nuclear localization of the GFP-E6aa643–992 protein.

DISCUSSION EBNA-6 is required for the transformation of B-lymphocytes and is likely to function as a transcriptional regulator as sequence analysis revealed a region homologous to the basic leucine-zipper motif that is found in many mammalian transcription factors. Studies have shown changes in 167

K. Krauer and others

Fig. 1. Schematic representation of the full-length EBNA-6 and a series of EBNA-6 deletions fused to GFP and their subcellular localization. The locations of computer-predicted NLS are indicated. HeLa cells were transiently transfected with constructs expressing the fusion proteins and were analysed 24 h post-transfection by confocal fluorescence microscopy.

Fig. 2. Cellular localization of GFP-EBNA-6 deletions following mutation of NLS sequences. HeLa cells were transiently transfected with plasmids expressing each of the EBNA-6 constructs and 24 h post-transfection the subcellular localization of each of the fusion proteins was determined by confocal fluorescence microscopy. 168

Journal of General Virology 85

NLS in EBNA-6

http://vir.sgmjournals.org

169

K. Krauer and others

viral and cellular genes, such as IL-1b (Krauer et al., 1998), pleckstrin (Kienzle et al., 1996), LMP1 and CD21, a B-cell activation antigen (Sample et al., 1994), following expression of the EBNA-3 family proteins. EBNA-6 has also been shown to interact with a variety of cellular proteins, including the human metastatic suppressor protein Nm23H1, a 152 aa 17 kDa nuclear protein highly conserved in eukaryotes (Subramanian et al., 2001), histone deacetylase through the N terminus of EBNA-6 (Radkov et al., 1999), RBP-Jk/2N (Robertson et al., 1995) and prothymosin alpha (ProTa), which is a small non-histone highly acidic nuclear protein that localizes to regions of the nucleus that are involved in transcription (Subramanian & Robertson, 2002). EBNA-6 can activate the human B-myb promoter through the E2F response element, can co-operate with (Ha-)ras in co-transformation assays and can override a pRb-mediated pathway that inhibits proliferation. EBNA-6 also plays a role in the disruption of cell-cycle checkpoints (Parker et al., 1996). The EBNA-6 protein is targeted exclusively to the cell nucleus, and cellular fractionation experiments have shown that it is present in the nucleoplasm and associates with the nuclear matrix while localization studies demonstrate that it localizes to discrete subnuclear granules within the cell nucleus (Petti et al., 1990; Sample & Kieff, 1990). There are five potential NLS containing arginine and lysine residues within EBNA-6. The data presented here show that NLS1, NLS2 and NLS5 are all independently capable of targeting protein to the nucleus. The pattern 4 C-terminal NLS5 sequence (KRPR) is the shortest known nuclear targeting signal, and is also found in EBNA-1, EBNA-2, and in adenovirus E1A (Lyons et al., 1987; Ambinder et al., 1991; Le Roux et al., 1993). The removal of all NLS (pGFPE6D1–206/396–625/941–992) resulted in the truncated EBNA-6 protein being present solely throughout the cytoplasm, indicating that there are no additional functional NLS within residues 207–395 or 626–940 (Fig. 1). In addition, mutation of NLS1, NLS2 and NLS5 resulted in GFP-EBNA-6 fusion proteins being cytoplasmic, indicating that no additional functional NLS were present in sequences 22–183, 396–600 or 941–992 (Fig. 2). Taken together the results revealed that, other than NLS1, NLS2 and NLS5, it is unlikely that EBNA-6 contains any other functional NLS. Two types of EBV exist (type-I or type-II) which show sequence divergence within the genes encoding the EBNALP, -2, -3, -4 and -6 gene products (Adldinger et al., 1985; Dambaugh et al., 1984; Sample et al., 1986; Sculley et al., 1989). Since EBNA-6 is a nuclear protein it might be expected that there would be conservation of the functional NLS between the two virus types. Computer analysis of the Ag-876 type-II EBNA-6 protein sequence showed conservation of NLS1–4 but not NLS5 (Fig. 3), suggesting that the type-II EBNA-6 protein probably only has two functional NLS (NLS1 and NLS2). Intriguingly, the sequences for the two nonfunctional NLS (NLS3 and NLS4) 170

Fig. 3. Comparison of EBNA-6 NLS in Type I and II isolates of EBV. Amino acid residues are indicated with the singleletter code. Bold letters indicate differences in sequence between each NLS. Underline indicates that this NLS was not computer-predicted.

were almost perfectly conserved in the type-II EBNA-6 protein, raising the possibility that they may serve another function. NLS3 is contained within the repression domain of EBNA-6, while NLS4 is within the DP-103 interaction domain and these sequences may play crucial roles within each of these domains rather than functioning as NLS. It is not understood why a single protein contains multiple NLS. However, it has been suggested that multiple NLS may function more efficiently (Roberts et al., 1987; Knauf et al., 1996), or that different NLS may have different specificities in different cell types (Liu et al., 1998). Alternatively, some NLS can also function under different conditions, such as one of the multiple NLS in XPG nuclease (Xeroderma pigmentosum type G), which can regulate the localization of the protein to the nucleus following UV irradiation (Knauf et al., 1996). Proteins with multiple NLS include the tumour suppressor menin (Guru et al., 1998), the high-mobility group transcription factors SRY and SOX9 (Sudbeck & Scherer, 1997), the proto-oncogene c-Abl (transforming gene of Abelson murine leukaemia virus) (Wen et al., 1996), tumour suppressor p53 (Shaulsky et al., 1990) and human c-Myc, which contains one strong and one weak NLS (Dang & Lee, 1988). The presence of multiple NLS in EBNA-6 could be needed if, prior to transport into the nucleus, EBNA-6 interacts with proteins in the cytoplasm or if EBNA-6 is modulated by phosphorylation, either of which could mask one or more of the NLS. Other possible reasons for multiple NLS could involve differential cellular regulation, or simply enhancement of nuclear accumulation (Roberts et al., 1987). Journal of General Virology 85

NLS in EBNA-6

ACKNOWLEDGEMENTS

efficient nuclear targeting of the Epstein–Barr virus nuclear antigen 3A. J Virol 67, 1716–1720.

The authors would like to acknowledge Paula Hall and Grace Chowjnowski, Queensland Institute of Medical Research, for assistance with confocal microscopy. This work was supported by grants from the NHMRC, Australia.

Liu, K. D., Gaffen, S. L. & Goldsmith, M. A. (1998). JAK/STAT

REFERENCES

Marshall, D. & Sample, C. (1995). Epstein–Barr virus nuclear antigen

Adldinger, H. K., Delius, H., Freese, U. K., Clarke, J. & Bornkamm, G. W. (1985). A putative transforming gene of Jijoye virus differs

Moll, T., Tebb, G., Surana, U., Robitsch, H. & Nasmyth, K. (1991).

from that of Epstein–Barr virus prototypes. Virology 141, 221–234. Allday, M. J., Crawford, D. H. & Thomas, J. A. (1993). Epstein–Barr

signaling by cytokine receptors. Curr Opin Immunol 10, 271–278. Lyons, R. H., Ferguson, B. Q. & Rosenberg, M. (1987). Penta-

peptide nuclear localization signal in adenovirus E1a. Mol Cell Biol 7, 2451–2456. 3C is a transcriptional regulator. J Virol 69, 3624–3630. The role of phosphorylation and the CDC28 protein kinase in cell cycle-regulated nuclear import of the S. cerevisiae transcription factor SWI5. Cell 66, 743–758.

virus (EBV) nuclear antigen 6 induces expression of the EBV latent membrane protein and an activated phenotype in Raji cells. J Gen Virol 74, 361–369.

Nakai, K. & Kanehisa, M. (1992). A knowledge base for predicting

Ambinder, R. F., Mullen, M. A., Chang, Y. N., Hayward, G. S. & Hayward, S. D. (1991). Functional domains of Epstein–Barr virus

rylation of cofilin accompanies heat shock-induced nuclear accumulation of cofilin. J Biol Chem 264, 16143–16148.

nuclear antigen EBNA-1. J Virol 65, 1466–1478.

protein localization sites in eukaryotic cells. Genomics 14, 897–911. Ohta, Y., Nishida, E., Sakai, H. & Miyamoto, E. (1989). Dephospho-

Bain, M., Watson, R. J., Farrell, P. J. & Allday, M. J. (1996). Epstein–

Parker, G. A., Crook, T., Bain, M., Sara, E. A., Farrell, P. J. & Allday, M. J. (1996). Epstein–Barr virus nuclear antigen (EBNA)3C is an

Barr virus nuclear antigen 3c is a powerful repressor of transcription when tethered to DNA. J Virol 70, 2481–2489.

immortalizing oncoprotein with similar properties to adenovirus E1A and papillomavirus E7. Oncogene 13, 2541–2549.

Chaudhary, N. & Courvalin, J. C. (1993). Stepwise reassembly of the

Petti, L., Sample, C. & Kieff, E. (1990). Subnuclear localization and

nuclear envelope at the end of mitosis. J Cell Biol 122, 295–306. Dambaugh, T., Hennessy, K., Chamnankit, L. & Kieff, E. (1984). U2

phosphorylation of Epstein–Barr virus latent infection nuclear proteins. Virology 176, 563–574.

region of Epstein–Barr virus DNA may encode Epstein–Barr nuclear antigen 2. Proc Natl Acad Sci U S A 81, 7632–7636.

Radkov, S. A., Bain, M., Farrell, P. J., West, M., Rowe, M. & Allday, M. J. (1997). Epstein–Barr virus EBNA3C represses Cp, the major

Dang, C. V. & Lee, W. M. (1988). Identification of the human c-Myc

promoter for EBNA expression, but has no effect on the promoter of the cell gene CD21. J Virol 71, 8552–8562.

protein nuclear translocation signal. Mol Cell Biol 8, 4048–4054. Dingwall, C. & Laskey, R. A. (1991). Nuclear targeting sequences – a

consensus? Trends Biochem Sci 16, 478–481. Dingwall, C. & Laskey, R. (1992). The nuclear membrane. Science

258, 942–947. Gorlich, D., Kraft, R., Kostka, S., Vogel, F., Hartmann, E., Laskey, R. A., Mattaj, I. W. & Izaurraide, E. (1996). Importin provides a link

between nuclear protein import and U snRNA export. Cell 87, 21–32. Guru, S. C., Goldsmith, P. K., Burns, A. L., Marx, S. J., Spiegel, A. M., Collins, F. S. & Chandrasekharappa, S. C. (1998). Menin, the

product of the MEN1 gene, is a nuclear protein. Proc Natl Acad Sci U S A 95, 1630–1634.

Radkov, S. A., Touitou, R., Brehm, A., Rowe, M., West, M., Kouzarides, T. & Allday, M. J. (1999). Epstein–Barr virus nuclear

antigen 3C interacts with histone deacetylase to repress transcription. J Virol 73, 5688–5697. Robbins, P. A. & McMichael, A. J. (1991). Immune recognition of

HLA molecules downmodulates CD8 expression on cytotoxic T lymphocytes. J Exp Med 173, 221–230. Roberts, B. L., Richardson, W. D. & Smith, A. E. (1987). The

effect of protein context on nuclear location signal function. Cell 50, 465–475.

Hennekes, H., Peter, M., Weber, K. & Nigg, E. A. (1993).

Robertson, E. S., Grossman, S., Johannsen, E., Miller, C., Lin, J., Tomkinson, B. & Kieff, E. (1995). Epstein–Barr virus nuclear protein

Phosphorylation on protein kinase C sites inhibits nuclear import of lamin B2. J Cell Biol 120, 1293–1304.

3C modulates transcription through interaction with the sequencespecific DNA-binding protein Jk. J Virol 69, 3108–3116.

Huber, J., Xiao, Y., Reid, J., Briggs, C., Jans, P. & Jans, D. (1996).

Sambrook, J. & Russell, D. W. (2001). Molecular Cloning, 3rd edn.

Regulation of protein transport to the nucleus. Todays Life Sci 1, 30–38.

Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.

Kieff, E. (1996). Epstein–Barr virus and its replication. In Fields

Virology, 3rd edn, pp. 2343–2396. Edited by B. N. Fields, D. M. Knipe & P. M. Howley. Philadelphia: Lippincott–Raven.

Sample, J. & Kieff, E. (1990). Transcription of the Epstein–Barr virus genome during latency in growth-transformed lymphocytes. J Virol 64, 1667–1674.

Kienzle, N., Young, D., Silins, S. L. & Sculley, T. B. (1996). Induction

Sample, J., Hummel, M., Braun, D., Birkenbach, M. & Kieff, E. (1986). Nucleotide sequences of mRNAs encoding Epstein–Barr

of pleckstrin by the Epstein–Barr virus nuclear antigen 3 family. Virology 224, 167–174.

virus nuclear proteins. A probable transcriptional initiation site. Proc Natl Acad Sci U S A 83, 5096–5100.

Knauf, J. A., Pendergrass, S. H., Marrone, B. L., Strniste, G. F., MacInnes, M. A. & Park, M. S. (1996). Multiple nuclear localization

Sample, J., Kieff, E. F. & Kieff, E. D. (1994). Epstein–Barr virus types

signals in XPG nuclease. Mutat Res 363, 67–75.

1 and 2 have nearly identical LMP-1 transforming genes. J Gen Virol 75, 2741–2746.

Krauer, K. G., Belzer, D. K., Liaskou, D., Buck, M., Cross, S., Honjo, T. & Sculley, T. (1998). Regulation of interleukin-1beta

Sculley, T. B., Apolloni, A., Stumm, R., Moss, D. J., MuellerLantczh, N., Misko, I. S. & Cooper, D. A. (1989). Expression of

transcription by Epstein–Barr virus involves a number of latent proteins via their interaction with RBP. Virology 252, 418–430.

Epstein–Barr virus nuclear antigens 3, 4 and 6 are altered in cell lines containing B-type virus. Virology 171, 401–408.

Le Roux, A., Berebbi, M., Moukaddem, M., Perricaudet, M. & Joab, I. (1993). Identification of a short amino acid sequence essential for

Shaulsky, G., Goldfinger, N., Ben-Ze’ev, A. & Rotter, V. (1990).

http://vir.sgmjournals.org

Nuclear accumulation of p53 protein is mediated by several nuclear 171

K. Krauer and others localization signals and plays a role in tumorigenesis. Mol Cell Biol 10, 6565–6577. Subramanian, C. & Robertson, E. S. (2002). The metastatic

suppressor Nm23-H1 interacts with EBNA3C at sequences located between the glutamine- and proline-rich domains and can cooperate in activation of transcription. J Virol 76, 8702–8709. Subramanian, C., Cotter, M. A. & Robertson, E. S. (2001).

Epstein–Barr virus nuclear protein EBNA-3C interacts with the human metastatic suppressor Nm23-H1: a molecular link to cancer metastasis. Nat Med 7, 350–355.

172

Sudbeck, P. & Scherer, G. (1997). Two independent nuclear localization signals are present in the DNA-binding high-mobility group domains of SRY and SOX9. J Biol Chem 272, 27848–27852. Wen, S. T., Jackson, P. K. & Van Etten, R. A. (1996). The cytostatic

function of c-Abl is controlled by multiple nuclear localization signals and requires the p53 and Rb tumor suppressor gene products. EMBO J 15, 1583–1595. Young, D. B., Krauer, K. G., Kienzle, N. & Sculley, T. B. (1997).

Both A and B type Epstein–Barr nuclear antigen interact with RBP-2N. J Gen Virol 78, 1671–1674.

Journal of General Virology 85