The intranuclear location of simian virus 40 polypeptides VP2 and VP3 depends on a specific amino acid sequence

Identification of two functional nuclear localization signals in the capsid protein of duck circovirus

The capsid protein (CP) of duck circovirus (DuCV) is the major immunogenic protein and has a high proportion of arginine residues concentrated at the N terminus of the protein, which inhibits efficient mRNA translation in prokaryotic expression systems. In this study, we investigated the subcellular distribution of DuCV CP expressed via recombinant baculoviruses in Sf9 cells and the DNA binding activities of the truncated recombinant DuCV CPs. The results showed that two independent bipartite nuclear localization signals (NLSs) situated at N-terminal 1-17 and 18-36 amino acid residue of the CP. Moreover, two expression level regulatory signals (ELRSs) and two DNA binding signals (DBSs) were also mapped to the N terminus of the protein and overlapped with the two NLSs. The ability of CP to bind DNA, coupled with the karyophilic nature of this protein, strongly suggests that it may be responsible for nuclear targeting of the viral genome.

Characterization of the cassava geminivirus transcription activation protein putative nuclear localization signal

The geminivirus transcription activation protein (TrAP) localizes to the nucleus and contains a putative nuclear localization signal (NLS) ((28)PRRRR(32)) on the N-terminus. The role of individual residues of this putative NLS on nuclear localization and symptom induction was investigated using TrAP of East African cassava mosaic Cameroon virus (EACMCV). Subcellular localization was conducted using the green fluorescent protein (GFP). Results showed that the proline residue at position 28 (Pro-28) is essential for nuclear localization whereas individually, none of the four contiguous arginines is necessary for nuclear targeting. The role of each of the five NLS amino acid residues on TrAP-mediated disease phenotype and gene silencing suppression was investigated by expressing these mutants in Nicotiana benthamiana from the PVX vector and under the control of the Cauliflower mosaic virus 35S promoter. Results showed that all five residues of the NLS play a role on disease phenotype production in N. benthamiana plants. Furthermore, each of the NLS residues appeared to be required for suppression of VIGS but appeared not to be required for the ability of TrAP to transactivate transcription and interact with adenosine kinase (ADK).

Immunity and autoimmunity induced by polyomaviruses: clinical, experimental and theoretical aspects

In this chapter, polyomaviruses will be presented in an immunological context. Principal observations will be discussed to elucidate humoral and cellular immune responses to different species of the polyomaviruses and to individual viral structural and regulatory proteins. The role of immune responses towards the viruses or their proteins in context of protection against polyomavirus induced tumors will be described. One central aspect of this presentation is the ability of polyomaviruses, and particularly large T-antigen, to terminate immunological tolerance to nucleosomes, DNA and histones. Thus, in the present chapter we will focus on clinical, experimental and theoretical aspects of the immunity to polyomaviruses.

The VP2/VP3 Minor Capsid Protein of Simian Virus 40 Promotes the in Vitro Assembly of the Major Capsid Protein VP1 into Particles

The SV40 capsid is composed primarily of 72 pentamers of the VP1 major capsid protein. Although the capsid also contains the minor capsid protein VP2 and its amino-terminally truncated form VP3, their roles in capsid assembly remain unknown. An in vitro assembly system was used to investigate the role of VP2 in the assembly of recombinant VP1 pentamers. Under physiological salt and pH conditions, VP1 alone remained dissociated, and at pH 5.0, it assembled into tubular structures. A stoichiometric amount of VP2 allowed the assembly of VP1 pentamers into spherical particles in a pH range of 7.0 to 4.0. Electron microscopy observation, sucrose gradient sedimentation analysis, and antibody accessibility tests showed that VP2 is incorporated into VP1 particles. The functional domains of VP2 important for VP1 binding and for enhancing VP1 assembly were further explored with a series of VP2 deletion mutants. VP3 also enhanced VP1 assembly, and a region common to VP2 and VP3 (amino acids 119-272) was required to promote VP1 pentamer assembly. These results are relevant for controlling recombinant capsid formation in vitro, which is potentially useful for the in vitro development of SV40 virus vectors.

Nucleolar localization of cirhin, the protein mutated in North American Indian childhood cirrhosis

Cirhin (NP_116219), the product of the CIRH1A gene is mutated in North American Indian childhood cirrhosis (NAIC/CIRH1A, OMIM 604901), a severe autosomal recessive intrahepatic cholestasis. It is a 686-amino-acid WD40-repeat containing protein of unknown function that is predicted to contain multiple targeting signals, including an N-terminal mitochondrial targeting signal, a C-terminal monopartite nuclear localization signal (NLS) and a bipartite nuclear localization signal (BNLS). We performed the direct determination of subcellular localization of cirhin as a crucial first step in unraveling its biological function. Using EGFP and His-tagged cirhin fusion proteins expressed in HeLa and HepG2, cells we show that cirhin is a nucleolar protein and that the R565W mutation, for which all NAIC patients are homozygous, has no effect on subcellular localization. Cirhin has an active C-terminal monopartite nuclear localization signal (NLS) and a unique nucleolar localization signal (NrLS) between residues 315 and 432. The nucleolus is not known to be important specifically for intrahepatic cholestasis. These observations provide a new dimension in the study of hereditary cholestasis.

Identification of a nucleocapsid protein (VP35) gene of shrimp white spot syndrome virus and characterization of the motif important for targeting VP35 to the nuclei of transfected insect cells

To identify the protein encoded by a 687-bp open reading frame (ORF) of a salI genomic DNA fragment of shrimp white spot syndrome virus (WSSV), we expressed the ORF in a baculovirus/insect cell expression system. The apparent molecular mass of the recombinant protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was 35 kDa in insect cells. Antibody raised against bacterially synthesized protein of the ORF identified a nucleocapsid protein (VP35) in the extracts of both the purified WSSV virions and the nucleocapsids which comigrated with the 35-kDa baculovirus-expressed recombinant protein on SDS-PAGE. We also show by transient expression in insect cells (Sf9) that VP35 targets the nucleus. Two potential nuclear localization signals (NLSs) were characterized, but only one of them was important for targeting VP35 to the nuclei of transfected insect cells. Replacement of a cluster of four positively charged residues ((24)KRKR(27)) at the N terminus of the protein with AAAA resulted in mutant proteins that were distributed only in the cytoplasm, thus confirming that this sequence is a critical part of the functionally active NLS of VP35.

Analysis of capsid formation of human polyomavirus JC (Tokyo-1 strain) by a eukaryotic expression system: splicing of late RNAs, translation and nuclear transport of major capsid protein VP1, and capsid assembly

Human polyomavirus JC (JCV) can encode the three capsid proteins VP1, VP2, and VP3, downstream of the agnoprotein in the late region. JCV virions are identified in the nucleus of infected cells. In this study, we have elucidated unique features of JCV capsid formation by using a eukaryotic expression system. Structures of JCV polycistronic late RNAs (M1 to M4 and possibly M5 and M6) generated by alternative splicing were determined. VP1 would be synthesized from M2 RNA, and VP2 and VP3 would be synthesized from M1 RNA. The presence of the open reading frame of the agnoprotein or the leader sequence (nucleotides 275 to 409) can decrease the expression level of VP1. VP1 was efficiently transported to the nucleus in the presence of VP2 and VP3 but distributed both in the cytoplasm and in the nucleus in their absence. Mutation analysis indicated that inefficiency in nuclear transport of VP1 is due to the unique structure in the N-terminal sequence, KRKGERK. Within the nucleus, VP1 was localized discretely and identified as speckles in the presence of VP2 and VP3 but distributed diffusely in their absence. These results suggest that VP1 was efficiently transported to the nucleus and localized in the discrete subnuclear regions, possibly with VP2 and VP3. By electron microscopy, recombinant virus particles were identified in the nucleus, and their intranuclear distribution was consistent with distribution of speckles. This system provides a useful model with which to understand JCV capsid formation and the structures and functions of the JCV capsid proteins.

Avian polyomavirus major capsid protein VP1 interacts with the minor capsid proteins and is transported into the cell nucleus but does not assemble into capsid-like particles when expressed in the baculovirus system

The baculovirus system was used to construct and isolate AcMNPV-VP1, AcMNPV-VP2 and AcMNPV-VP3 recombinant viruses which express the respective avian polyomavirus (APV) structural proteins in Sf9 insect cells. These recombinant AcMNPVs containing APV structural protein genes were utilized to investigate protein-protein interactions between the structural proteins. Immunofluorescence studies utilizing Sf9 cells infected with the AcMNPV-VP1 revealed that the VP1 protein was expressed and localized in the cytoplasm and not transported into the nucleus. When the cells were co-infected with the VP1 and either VP2 or VP3 recombinant viruses, immunofluorescence of the VP1 protein was localized in the nucleus, indicating that the VP1 protein was transported to the nucleus by both the VP2 and VP3 minor proteins. This observation was suggestive of a protein-protein interaction between the expressed proteins. This protein-protein interaction was substantiated by laser scanning confocal microscopy of Sf9 cells that were co-infected with VP1, VP2 and VP3 recombinant viruses. However, the minor proteins could not be co-isolated with VP1 protein by immunoaffinity chromatography using a monoclonal anti-VP1 serum. In addition, capsid-like particles could not be purified either by CsC1 density gradient centrifugation or by immunoaffinity chromatography. VP1 capsomeres were isolated by immunoaffinity chromatography from Sf9 cells infected with AcMNPV-VP1, with or without the minor protein(s), and these capsomeres could assemble in vitro into capsid-like particles. Electron microscopic observation of thin-sectioned Sf9 cells, which were co-infected with VP1, VP2 and VP3 recombinant viruses, demonstrated capsomere-like structures in the nucleus, but capsid-like particles were not observed.

How do animal DNA viruses get to the nucleus?

Genome and pre-genome replication in all animal DNA viruses except poxviruses occurs in the cell nucleus (Table 1). In order to reproduce, an infecting virion enters the cell and traverses through the cytoplasm toward the nucleus. Using the cell's own nuclear import machinery, the viral genome then enters the nucleus through the nuclear pore complex. Targeting of the infecting virion or viral genome to the multiplication site is therefore an essential process in productive viral infection as well as in latent infection and transformation. Yet little is known about how infecting genomes of animal DNA viruses reach the nucleus in order to reproduce. Moreover, this nuclear locus for viral multiplication is remarkable in that the sizes and composition of the infectious particles vary enormously. In this article, we discuss virion structure, life cycle to reproduce infectious particles, viral protein's nuclear import signal, and viral genome nuclear targeting.

Nuclear targeting of the cauliflower mosaic virus coat protein

The entry of the viral genomic DNA of cauliflower mosaic virus into the nucleus is a critical step of viral infection. We have shown by transient expression in plant protoplasts that the viral coat protein (CP), which is processed from the product of open reading frame IV, contains an N-terminal nuclear localization signal (NLS). The NLS is exposed on the surface of the virion and is thus available for interaction with a putative NLS receptor. Phosphorylation of the matured CP did not influence the nuclear localization of the protein but improved protein stability. Mutation of the NLS completely abolished viral infectivity, thus indicating its importance in the virus life cycle. The NLS seems to be regulated by the N terminus of the precapsid, which inhibits its nuclear targeting. This regulation could be important in allowing virus assembly in the cytoplasm.

Two proline-rich nuclear localization signals in the amino- and carboxyl-terminal regions of the Borna disease virus phosphoprotein

Borna disease virus (BDV) uses a unique strategy of replication and transcription which takes place in the nucleus, unlike other known, nonsegmented, negative-stranded RNA viruses of animal origin. In this process, viral constituents necessary for replication must be transported to the nucleus from the cytoplasm. We report here the evidence that BDV P protein, which may play an important role in viral replication and transcription, is transported into the nucleus in the absence of other viral constituents. This transportation is accomplished by its own nuclear localization signals (NLSs), which are present in both N-terminal (29PRPRKIPR36) and C-terminal (181PPRIYPQLPSAPT193) regions of the protein. These two NLSs can function independently and both have several Pro residues as key amino acids.

Interaction of polyomavirus internal protein VP2 with the major capsid protein VP1 and implications for participation of VP2 in viral entry

A complex of the polyomavirus internal protein VP2/VP3 with the pentameric major capsid protein VP1 has been prepared by co-expression in Escherichia coli. A C-terminal segment of VP2/VP3 is required for tight association, and a crystal structure of this segment, complexed with a VP1 pentamer, has been determined at 2.2 A resolution. The structure shows specific contacts between a single copy of the internal protein and a pentamer of VP1. These interactions were not detected in the previously described structure of the virion, but the location of VP2 in the recombinant complex is consistent with features in the virion electron-density map. The C-terminus of VP2/VP3 inserts in an unusual, hairpin-like manner into the axial cavity of the VP1 pentamer, where it is anchored strongly by hydrophobic interactions. The remainder of the internal protein appears to have significant flexibility. This structure restricts possible models for exposure of the internal proteins during viral entry.

Self-assembly and protein-protein interactions between the SV40 capsid proteins produced in insect cells

Soluble SV40 capsid proteins were obtained by expression of the three late genes, VP1, VP2, and VP3, in Sf9 cells using baculovirus expression vectors. Coproduction of the capsid proteins VP1, VP2, and VP3 was achieved by infecting Sf9 cells with the three recombinant baculovirus species at equal multiplicities. All three proteins were found to be localized in the nuclear fraction. Electron microscopy of nuclear extracts of the infected cells showed an abundance of SV40-like capsid structures and heterogeneous aggregates of variable size, mostly 20-45 nm. Under the same staining conditions wild-type SV40 virions are 45 nm. The capsid-like particles sedimented in glycerol gradients similarly to authentic wild-type SV40 virions. Pentamers of the major capsid protein VP1 were also seen. Protein analysis on sucrose gradients demonstrated that the capsid-like particles can be disrupted by treatment with the reducing agent dithiothreitol and the calcium chelator EGTA. The capsid-like particles were found to be significantly less stable than SV40 virions and were partially stabilized by calcium ions. Understanding the complex interactions between the capsid proteins is important for the development of an efficient in vitro packaging system for SV40 virions and pseudovirions.

Analysis of a nuclear localization signal of simian virus 40 major capsid protein Vp1

The nuclear localization signal of the major structural protein, Vp1, of simian virus 40 was further defined by mutagenesis. The targeting activity was examined in cells microinjected with SV-Vp1 variant viral DNAs bearing either an initiation codon mutation of the agnoprotein or mutations in the Vp1 coding sequence or microinjected with pSG5-Vp1 and pSG5-Vp1 mutant DNAs in which Vp1 or mutant Vp1 is expressed from simian virus 40 early promoter. The Vp1 nuclear localization signal functioned autonomously without agno-protein once the Vp1 protein was synthesized in the cytoplasm. The targeting activity was localized to the amino-terminal 19 residues. While replacement of cysteine 10 with glycine, alanine, or serine did not affect the activity, replacement of arginine 6 with glycine caused the cytoplasmic phenotype. When multiple mutations were introduced among residue 5, 6, 7, 16, 17, or 19, the targeting activity was found to reside in two clusters of basic residues, a cluster of lysine 5, arginine 6, and lysine 7 and a cluster of lysine 16, lysine 17, and lysine 19. The clusters are independently important for nuclear localization activity.

Association with capsid proteins promotes nuclear targeting of simian virus 40 DNA

All animal DNA viruses except pox virus utilize the cell nucleus as the site for virus reproduction. Yet, a critical viral infection process, nuclear targeting of the viral genome, is poorly understood. The role of capsid proteins in nuclear targeting of simian virus 40 (SV40) DNA, which is assessed by the nuclear accumulation of large tumor (T) antigen, the initial sign of the infectious process, was tested by two independent approaches: antibody interception experiments and reconstitution experiments. When antibody against viral capsid protein Vp1 or Vp3 was introduced into the cytoplasm, the nuclear accumulation of T antigen was not observed in cells either infected or cytoplasmically injected with virion. Nuclearly introduced anti-Vp3 IgG also showed the inhibitory effect. In the reconstitution experiments, SV40 DNA was allowed to interact with protein components of the virus, either empty particles or histones, and the resulting complexes were tested for the capability of protein components to target the DNA to the nucleus from cytoplasm as effectively as the targeting of DNA in the mature virion. In cells injected with empty particle-DNA, but not in minichromosome-injected cells, T antigen was observed as effectively as in SV40-injected cells. These results demonstrate that SV40 capsid proteins can facilitate transport of SV40 DNA into the nucleus and indicate that Vp3, one of the capsid proteins, accompanies SV40 DNA as it enters the nucleus during virus infection.

Electroporation-mediated delivery of nucleolar targeting sequences from Semliki Forest virus nucleocapsid protein

Electroporation was used as a powerful and simple method to probe to the intracellular distribution and trafficking of signal sequences. By coupling synthetic peptides to carrier reporter groups, specific amino acid sequences responsible for nucleolar targeting of Semliki Forest virus (SFV) Core (C) protein were found out. In the N-terminal part of the C protein the sequences 66KPKKKKTTKPKPKTQPKK83 and 92KKKDKQADKKKKP105 are able to situate BSA or KLH as reporter proteins in the nucleolus, suggesting that SFV C protein contains at least two independent nucleolar targeting sequences.

Functional complementation of nuclear targeting-defective mutants of simian virus 40 structural proteins

Structural proteins of simian virus 40 (SV40), Vp2 and Vp3 (Vp2/3) and Vp1, carry individual nuclear targeting signals, Vp3(198-206) (Vp2(316-324) and Vp1(1-8), respectively, which are encoded in different reading frames of an overlapping region of the genome. How signals coordinate nuclear targeting during virion morphogenesis was examined by using SV40 variants in which there is only one structural gene for Vp1 or Vp2/3, nuclear targeting-defective mutants thereof, Vp2/3(202T) and Vp1 delta N5, or nonoverlapping SV40 variants in which the genes for Vp1 and Vp2/3 are separated, and mutant derivatives of the gene carrying either one or both mutations. Nuclear targeting was assessed immunocytochemically following nuclear microinjection of the variant DNAs. When Vp2/3 and Vp1 mutants with defects in the nuclear targeting signals were expressed individually, the mutant proteins localized mostly to the cytoplasm. However, when mutant Vp2/3(202T) was coexpressed in the same cell along with wild-type Vp1, the mutant protein was effectively targeted to the nucleus. Likewise, the Vp1 delta N5 mutant protein was transported into the nucleus when wild-type Vp2/3 was expressed in the same cells. These results suggest that while Vp1 and Vp2/3 have independent nuclear targeting signals, additional signals, such as those defining protein-protein interactions, play a concerted role in nuclear localization along with the nuclear targeting signals of the individual proteins.

Cooperation of structural proteins during late events in the life cycle of polyomavirus

The polyomavirus minor late capsid antigen, VP2, is myristylated on its N-terminal glycine, this modification being required for efficient infection of mouse cells. To study further the functions of this antigen, as well as those of the other minor late antigen, VP3, recombinant baculoviruses carrying genes for VP1, VP2, and VP3 have been constructed and the corresponding proteins have been synthesized in insect cells. A monoclonal antibody recognizing VP1, alpha-PyVP1-A, and two monoclonal antibodies against the common region of VP2 and VP3, alpha-PyVP2/3-A and alpha-PyVP2/3-B, have been generated. Reactions of antibodies with antigens were characterized by indirect immunofluorescence, immunoprecipitation, and immunoblot analysis. Immunofluorescent staining of mouse cells infected with polyomavirus showed all antigens to be localized in nuclei. When the late polyomavirus proteins were expressed separately in insect cells, however, only VP1 was efficiently transported into the nucleus; VP2 was localized discretely around the outside of the nucleus, and VP3 exhibited a diffused staining pattern in the cytoplasm. Coexpression of VP2, or VP3, with VP1 restored nuclear localization. Immunoprecipitation of infected mouse cells with either anti-VP1 or anti-VP2/3 antibodies precipitated complexes containing all three species, consistent with the notion that VP1 is necessary for efficient transport of VP2 and VP3 into the nucleus. Purified empty capsid-like particles, formed in nuclei of insect cells coinfected with all three baculoviruses, contained VP2 and VP3 proteins in amounts comparable to those found in empty capsids purified from mouse cells infected with wild-type polyomavirus. Two-dimensional gel analysis of VP1 species revealed that coexpression with VP2 affects posttranslational modification of VP1.

Identification of a nuclear localization sequence in the polyomavirus capsid protein VP2

A nuclear localization signal (NLS) has been identified in the C-terminal (Glu307-Glu-Asp-Gly-Pro-Gln-Lys-Lys-Lys-Arg-Arg-Leu318) amino acid sequence of the polyomavirus minor capsid protein VP2. The importance of this amino acid sequence for nuclear transport of newly synthesized VP2 was demonstrated by a genetic "subtractive" study using the constructs pSG5VP2 (expressing full-length VP2) and pSG5 delta 3VP2 (expressing truncated VP2, lacking amino acids Glu307-Leu318). These constructs were transfected into COS-7 cells, and the intracellular localization of the VP2 protein was determined by indirect immunofluorescence. These studies revealed that the full-length VP2 was localized in the nucleus, while the truncated VP2 protein was localized in the cytoplasm and not transported to the nucleus. A biochemical "additive" approach was also used to determine whether this sequence could target nonnuclear proteins to the nucleus. A synthetic peptide identical to VP2 amino acids Glu307-Leu318 was cross-linked to the nonnuclear proteins bovine serum albumin (BSA) or immunoglobulin G (IgG). The conjugates were then labeled with fluorescein isothiocyanate and microinjected into the cytoplasm of NIH 3T6 cells. Both conjugates localized in the nucleus of the microinjected cells, whereas unconjugated BSA and IgG remained in the cytoplasm. Taken together, these genetic subtractive and biochemical additive approaches have identified the C-terminal sequence of polyoma-virus VP2 (containing amino acids Glu307-Leu318) as the NLS of this protein.

Assembly of viruslike particles by recombinant structural proteins of adeno-associated virus type 2 in insect cells

The three capsid proteins VP1, VP2, and VP3 of the adeno-associated virus type 2 (AAV-2) are encoded by overlapping sequences of the same open reading frame. Separate expression of these proteins by recombinant baculoviruses in insect cells was achieved by mutation of the internal translation initiation codons. Coexpression of VP1 and VP2, VP2 and VP3, and all three capsid proteins and the expression of VP2 alone in Sf9 cells resulted in the production of viruslike particles resembling empty capsids generated during infection of HeLa cells with AAV-2 and adenovirus. These results suggest a requirement for VP2 in the formation of empty capsids. Individual expression of the AAV capsid proteins in HeLa cells showed that VP1 and VP2 accumulate in the cell nucleus and VP3 is distributed between nucleus and cytoplasm. Coexpression of VP3 with the other structural proteins also led to nuclear localization of VP3, indicating that the formation of a complex with VP1 or VP2 is required for accumulation of VP3 in the nucleus.

Recognition of SV40-VP2 in the infected cell by antipeptide antibodies

Antipeptide antibodies were elicited against two synthetic peptides corresponding to amino acids 47-55 and 98-103 of the structural protein VP 2 of SV 40. The induced antibodies proved to be VP 2-specific in an immunoblot. In immunofluorescence these antibodies showed a discrete nuclear and perinuclear staining pattern. In immune electron microscopy studies the induced antibodies did not bind to major virions suggesting that VP 2 is not present at the surface of SV 40 particles.

The use of additive and subtractive approaches to examine the nuclear localization sequence of the polyomavirus major capsid protein VP1

A nuclear localization signal (NLS) has been identified in the N-terminal (Ala1-Pro-Lys-Arg-Lys-Ser-Gly-Val-Ser-Lys-Cys11) amino acid sequence of the polyomavirus major capsid protein VP1. The importance of this amino acid sequence for nuclear transport of VP1 protein was demonstrated by a genetic "subtractive" study using the constructs pSG5VP1 (full-length VP1) and pSG5 delta 5'VP1 (truncated VP1, lacking amino acids Ala1-Cys11). These constructs were used to transfect COS-7 cells, and expression and intracellular localization of the VP1 protein was visualized by indirect immunofluorescence. These studies revealed that the full-length VP1 was expressed and localized in the nucleus, while the truncated VP1 protein was localized in the cytoplasm and not transported to the nucleus. These findings were substantiated by an "additive" approach using FITC-labeled conjugates of synthetic peptides homologous to the NLS of VP1 cross-linked to bovine serum albumin or immunoglobulin G. Both conjugates localized in the nucleus after microinjection into the cytoplasm of 3T6 cells. The importance of individual amino acids found in the basic sequence (Lys3-Arg-Lys5) of the NLS was also investigated. This was accomplished by synthesizing three additional peptides in which lysine-3 was substituted with threonine, arginine-4 was substituted with threonine, or lysine-5 was substituted with threonine. It was found that lysine-3 was crucial for nuclear transport, since substitution of this amino acid with threonine prevented nuclear localization of the microinjected, FITC-labeled conjugate.

Characterization of a nuclear localization sequence in the polyomavirus capsid protein VP1

Expression of VP1-beta-galactosidase fusion proteins in the yeast Saccharomyces cerevisiae was used to identify a domain of the polyomavirus VP1 capsid protein which targets this protein to the nucleus. Fusion of the first 17 amino acids of VP1 to beta-galactosidase was sufficient for nuclear localization, whereas fusion of the first 12 amino acids gave a "mixed" cytoplasmic-nuclear phenotype. Mutation of a putative targeting sequence MAPKR(5)K from R to S changed the localization of a 21 amino acid fusion protein from the nucleus to cytoplasm. These results define a nuclear location signal in the amino terminus of polyomavirus VP1 and separate this function from the high-affinity DNA binding function previously defined for this region.

Nuclear localization of budgerigar fledgling disease virus capsid protein VP2 is conferred by residues 308-317

The capsid protein VP2 of budgerigar fledgling disease virus (BFDV) contains two sequences (residues 309-315 and 334-340) which are homologous to the prototypic nuclear localization sequence (NLS) of the simian virus 40 T-antigen. Using recombinant potential NLS-beta-galactosidase fusion proteins we identified amino acid residues 308-317 (VPKRKRKLPT) to be the NLS of BFDV capsid proteins VP2 and VP3. Microfluorometry studies show that the BFDV-VP2 signal is considerably more efficient in nuclear transport kinetics, than the NLS of SV40-VP2, corresponding to amino acid residues 317-326 (PNKKKRKLSR).

Occurrence of beta-turn potentials around nuclear and nucleolar localization sequences

The biological significance of turn structures is now of great topical interest. By using the protein conformational prediction method of Chou and Fasman, the present work predicts that 17 nuclear localization signals and a nucleolar localization signal reported so far contain turn potentials. Two nuclear localization signals, human lamin A and c-myc protein (peptide M1), however, cannot be predicted as containing beta-turns by the prediction method. To date, no physical characterization of any nuclear or nucleolar location signal by X-ray crystallography and nuclear magnetic resonance spectroscopy has been performed. Employing conformation prediction methods, therefore, would be useful for elucidating structural features of nuclear and nucleolar location signals.

Production of hepatitis B virus nucleocapsidlike core particles in Xenopus oocytes: assembly occurs mainly in the cytoplasm and does not require the nucleus

The location of hepatitis B virus (HBV) nucleocapsid (core particle) assembly in infected cells remains controversial. Some lines of evidence implicate the nucleus; others favor the cytoplasm. Via injection of a synthetic mRNA encoding the HBV nucleocapsid protein (p21.5), we have expressed both unassembled p21.5 and nucleocapsidlike core particles in Xenopus oocytes. Subcellular fractionation reveals that approximately 91% of the unassembled p21.5 and 95% of the core particles are cytoplasmic, with only 9 and 5%, respectively, in the nucleus. We present evidence showing that unassembled p21.5 equilibrates between nucleus and cytoplasm by passive diffusion and that intact core particles do not enter the nucleus. To examine the role of the nucleus in core particle formation, we expressed p21.5 in surgically anucleate oocytes. We show that anucleate oocytes support efficient core particle formation, indicating that (i) the nucleus is not essential for assembly and (ii) the cytoplasm can assemble most core particles found in oocytes. On the basis of our data, we propose that in oocytes, most core particle assembly (up to 95%) occurs in the cytoplasm, but that at least approximately 5% of the cellular core particles are assembled in the nucleus and remain there. We discuss the implications of these findings for the formation of replication-competent core particles in infected cells.

Identification and functional analysis of the nuclear localization signals of ribosomal protein L25 from Saccharomyces cerevisiae

The regions of the large subunit ribosomal protein L25 from Saccharomyces cerevisiae responsible for nuclear localization of the protein were identified by constructing fusion genes encoding various segments of L25 linked to the amino terminus of beta-galactosidase. Indirect immunofluorescence of yeast cells expressing the fusions demonstrated that amino acid residues 1 to 17 as well as 18 to 41 of L25 promote import of the reporter protein into the nucleus. Both nuclear localization signal (NLS) sequences appear to consist of two distinct functional parts: one showed relatively weak nuclear targeting activity, whereas the other considerably enhances this activity but does not promote nuclear import by itself. Microinjection of in vitro prepared intact and N-terminally truncated L25 into Xenopus laevis oocytes demonstrated that the region containing the two NLS sequences is indeed required for efficient nuclear localization of the ribosomal protein. This conclusion was confirmed by complementation experiments using a yeast strain that conditionally expresses wild-type L25. The latter experiments also indicated that amino acid residues 1 to 41 of L25 are required for full functional activity of yeast 60 S ribosomal subunits. Yeast cells expressing forms of L25 that lack this region are viable, but show impaired growth and a highly abnormal cell morphology.

Nucleotide sequence and genome organization of the murine polyomavirus, Kilham strain

The polyomavirus Kilham strain (KV) represents a second murine member of the polyomavirus family. However, in contrast to other polyomaviruses, KV exhibits a stringent host and cell specificity. To determine the relationship of these viruses, the complete DNA sequence of KV consisting of 4754 bp was determined. The predicted organization of K virus was found to be comparable to that of other members of the polyomavirus family with two strands coding in an opposite direction of an intergenic region harboring putative control elements for gene expression. These include consensus elements for the origin of DNA replication as well as predicted promoter protein binding domains. Inferred signal sequences for 3' and 5' end formation of mRNAs and splice/branch site consensus sequences resemble those found among the SV40 group of viruses. From the organization of the genome two nonstructural proteins, large T and small t antigen, are predicted, both of which share the same amino-terminal sequence. Three putative capsid proteins VP1, VP2, and VP3 are encoded by alternative open reading frames. The nucleotide sequence in the proposed origin of DNA replication and the inferred amino acid sequence of the viral proteins suggest an evolutionary relationship placing KV between the murine PyV and the SV40 group of viruses. In the region bearing putative transcriptional control elements less nucleotide similarity to that of other polyomaviruses is found and this may reflect the unique host and cell specificity of KV.

Simian virus 40 Vp2/3 small structural proteins harbor their own nuclear transport signal

We have used a microinjection approach to identify a domain of the simian virus 40 (SV40) structural proteins Vp2 and Vp3(Vp2/3) responsible for their nuclear transport. By using both synthetic peptides, containing small regions of Vp2/3 conjugated to bovine serum albumin (BSA), and beta-galactosidase-Vp3 fusion proteins, we have narrowed this nuclear transport signal (NTS) to 9 amino acids (198 to 206 of Vp3 or 316 to 324 of Vp2), Gly-Pro-Asn-Lys-Lys-Lys-Arg-Lys-Leu. The porter proteins carrying the NTS or mutant NTS were microinjected into the cytoplasm of TC7 cells and their subcellular localization following the subsequent incubation period was determined immunologically using anti-BSA IgG or anti-beta-galactosidase. The 9-residue NTS peptide localized BSA into the nucleus of injected cells, changing lysine-202 to threonine or valine abolished this accumulation while changing arginine-204 to lysine did not grossly affect transport. A peptide containing the carboxyl-terminal 13 residues of Vp3 failed to localize BSA to the nucleus. Several single or double point mutations at Vp3 residues 202 and 204 have been introduced by site-directed mutagenesis. Vp3 residues 194-234, containing either a wild-type or mutated sequence at 202 and/or 204, were expressed in Escherichia coli as Vp3-beta-galactosidase fusion proteins. Addition of the carboxyl-terminal 40 residues, but not an internal 150 residues, to otherwise cytoplasmic beta-galactosidase promoted entry of the fusion protein into the nucleus. Changing lysine-202 into threonine, valine, or methionine abolished this nuclear accumulation as did changing arginine-204 into lysine. A double mutant at both positions was also blocked. We have also observed that the lectin wheat germ agglutinin inhibits the nuclear accumulation of BSA carrying the Vp2/3 NTS while the lectin concanavalin A had no effect. These data indicate that even small nuclear proteins can contain NTS's which most likely utilize a mechanism for nuclear import similar to that described for other larger proteins.

Two independent signals, a nuclear localization signal and a Vp1-interactive signal, reside within the carboxy-35 amino acids of SV40 Vp3

The carboxy-terminal 35 amino acids (numbering 199 to 234) of SV40 Vp3 are essential for the nuclear localization of the protein as well as for its interactions with Vp1. Here, we describe studies directed at the further mapping of these two functions. Deletion and site-directed mutants of Vp3 were created within both a eukaryotic transfection and an SP6 transcription vector which encode Vp3. The subcellular localization of mutant Vp3's was assayed by immunofluorescence microscopy following DNA transfections, and the Vp1-interactive determinant of Vp3 was mapped by a recently described eukaryotic in vitro translation/interaction system. We show that a plasmid-encoded wild-type Vp3, whose overlapping Vp1 coding segment has been removed by mutagenesis, continues to localize to the nucleus in the absence of any SV40 Vp1. Thus, Vp3 is capable of nuclear localization on its own. Modification of Lys-202 of Vp3 into Thr is sufficient to destroy the wild-type nuclear localization of the protein, but has no effect on its interactions with Vp1. Furthermore, deletion of the terminal 13 amino acids, 222 to 234, of Vp3 does not affect its wild-type nuclear localization, but is sufficient to destroy its interactions with Vp1. Thus, the Vp3 amino acids 199-221--specifically Lys-202--are important for its nuclear localization, while the Vp3 amino acids 222-234 play a role in its interactions with Vp1. Thus, the two functions, a Vp3 nuclear localization signal and a Vp1-interactive determinant, are spatially and functionally separable within the last 35 residues of Vp3 and are, hence, independent.

Function of two discrete regions is required for nuclear localization of polymerase basic protein 1 of A/WSN/33 influenza virus (H1 N1)

Polymerase basic protein 1 (PB1) of influenza virus (A/WSN/33), when expressed from cloned cDNA in the absence of other viral proteins, accumulates in the nucleus. We have examined the location and nature of the nuclear localization signal of PB1 by using deletion mutants and chimeric constructions with chicken muscle pyruvate kinase, a cytoplasmic protein. Our studies showed some novel features of the nuclear localization signal of PB1. The signal was present internally within residues 180 to 252 of PB1. Moreover, unlike most nuclear localization signals, it was not a single stretch of contiguous amino acids. Instead, it possessed two discontinuous regions separated by an intervening sequence which could be deleted without affecting its nuclear localization property. On the other hand, deletion of either of the two signal regions rendered the protein cytoplasmic, indicating that the function of both regions is required for nuclear localization and that one region alone is not sufficient. Both of these signal regions contained short stretches of basic residues. Possible ways by which this novel bipartite signal can function in nuclear localization are discussed.

Function of two discrete regions is required for nuclear localization of polymerase basic protein 1 of A/WSN/33 influenza virus (H1 N1)

Polymerase basic protein 1 (PB1) of influenza virus (A/WSN/33), when expressed from cloned cDNA in the absence of other viral proteins, accumulates in the nucleus. We have examined the location and nature of the nuclear localization signal of PB1 by using deletion mutants and chimeric constructions with chicken muscle pyruvate kinase, a cytoplasmic protein. Our studies showed some novel features of the nuclear localization signal of PB1. The signal was present internally within residues 180 to 252 of PB1. Moreover, unlike most nuclear localization signals, it was not a single stretch of contiguous amino acids. Instead, it possessed two discontinuous regions separated by an intervening sequence which could be deleted without affecting its nuclear localization property. On the other hand, deletion of either of the two signal regions rendered the protein cytoplasmic, indicating that the function of both regions is required for nuclear localization and that one region alone is not sufficient. Both of these signal regions contained short stretches of basic residues. Possible ways by which this novel bipartite signal can function in nuclear localization are discussed.

The 15 amino acid residues preceding the amino terminus of the envelope protein in the yellow fever virus polyprotein precursor act as a signal peptide

The 15 amino acids which precede the sequence of the envelope (E) protein in the yellow fever virus (YFV) polyprotein precursor have been proposed to function as a signal peptide for the E protein (P. Desprès A. Cahour, C. Wychowski, M. Girard and M. Bouloy; Ann. Inst. Pasteur/Virol., 139, 59-67, 1988). To confirm this hypothesis, recombinant SV40 genomes were constructed in which the sequence of the E protein, or that of the poliovirus VP0 capsid polypeptide were placed immediately downstream of and in frame with the sequence of the putative signal peptide, under the control of the late SV40 promoter. The E protein expressed by the hybrid virus SV-E was recognized by two neutralizing monoclonal antibodies directed against the YFV envelope protein. In this construct, the E protein was deleted of its C-terminal transmembrane zone. Therefore, as expected, the protein appeared to be efficiently transported along the exocytic pathway and excreted into the cell culture medium. In addition, when the putative signal peptide was fused in frame with poliovirus polypeptide VP0, the expressed chimeric polypeptide was targeted to the endoplasmic reticulum where it underwent glycosylation.

Synthesis, posttranslational modifications, and nuclear transport of polyomavirus major capsid protein VP1

Polyomavirus major capsid protein VP1 synthesis was studied in infected primary baby mouse kidney cells. A standard curve of VP1 protein was used to quantitate VP1 in the cytoplasm and nucleus of infected cells during the time course of infection. Polyomavirus VP1 continued to be accumulated in the cytoplasm of the cells until 27 h postinfection, at which time the synthesis of VP1 leveled off. VP1 continued to accumulate in the nucleus of the infected cells throughout the course of infection. The presence of the six isospecies, A to F, of polyomavirus VP1 was also studied to determine the relative quantity of each species during the time course of infection. All six species were found in the cytoplasm and nucleus of infected cells at various times postinfection. However, the relative quantity of each species was different at early as compared with later times of infection. In addition, phosphorylated VP1 was found in isolated polyribosomes of infected cells, suggesting that phosphorylation of VP1 is a cotranslational modification. Examination of the effect of macromolecular synthesis on the transport of VP1 into the nucleus of infected baby mouse kidney cells as well as the rate of its nuclear accumulation during and after protein synthesis inhibition revealed that the continual transport and accumulation of VP1 in the nucleus required protein synthesis.

Cell-dependent efficiency of reiterated nuclear signals in a mutant simian virus 40 oncoprotein targeted to the nucleus

We investigated the requisites for, and functional consequences of, the relocation to the nucleus of a transforming nonkaryophilic mutant of the simian virus 40 large T antigen (a natural deletion mutant lacking an internal large-T-antigen domain that includes the signal for nuclear transport). Synthetic oligonucleotides were used to obtain gene variants with one or more copies of the signal-specifying sequence inserted near the gene 3' end, in a region dispensable for the main large-T-antigen functions. The analysis of stable transfectant populations showed that mouse NIH 3T3 cells, rat embryo fibroblasts, and simian CS cells (a subclone of CV1 cells) differed considerably in their ability to localize some variant molecules into the nucleus. CS cells were always the most efficient, and NIH 3T3 cells were the least efficient. The nuclear localization improved either with reiteration of the signal or with a left-flank modification of the signal amino acid context. Three signals appeared to be necessary and sufficient, even in NIH 3T3 cells, to obtain a nuclear accumulation comparable to that of wild-type simian virus 40 large T antigen; other signal-cell combinations caused a large variability in subcellular localization among cells of the same population, as if the nuclear uptake of some molecules depended on individual cell states. The effect of the modified location on the competence of the protein to alter cell growth was examined by comparing the activity of variants containing either the normal signal or a signal with a mutation (corresponding to large-T-antigen amino acid 128) that prevented nuclear transport. It was found that the nuclear variant was slightly more active than the cytoplasmic variants in rat embryo fibroblasts and NIH 3T3 cells and was notably less active in CS cells.

Nucleotide sequence of the human polyomavirus AS virus, an antigenic variant of BK virus

The complete DNA sequence of the human polyomavirus AS virus (ASV) is presented. Although ASV can be differentiated antigenically from the other human polyomaviruses (BK and JC viruses), it shares 94.9% homology at the nucleotide level with the Dunlop strain of BK virus. Differences found in ASV relative to BK virus include the absence of tandem repeats in its regulatory region, the deletion of 32 nucleotides in the late mRNA leader region (altering the initiation codon for the agnoprotein), the presence of a cluster of base pair substitutions within the coding region of the major capsid protein, VP1, and the absence of 4 amino acids in the carboxy-terminal region of the early protein, T antigen. The 43 nucleotides deleted in the Dunlop strain of BK virus relative to the Gardner prototype strain of BK virus are present in ASV. Possible reasons for the distinct antigenicity of the ASV capsid, given the high degree of nucleotide homology with BK virus, are discussed. To reflect the high degree of sequence homology between ASV and BK virus, we suggest ASV be renamed BKV(AS).

Nuclear transport of adenovirus DNA polymerase is facilitated by interaction with preterminal protein

The mRNAs for the 80 kd adenovirus preterminal protein (pTP) and the 140 kd DNA polymerase (AdPol) contain several exons spliced to the main open reading frames (m-ORFs) located in the early transcription unit E2B. These proteins were transiently expressed in monkey kidney cells (CV1) utilizing the first ATG (pTP1 and AdPol1) or the ATG of a linker inserted at the beginning of the m-ORFs (pTP2 and AdPol2). Only pTP2 and AdPol2 were functionally active in an in vitro replication initiation assay. Both pTP1 and pTP2 were transported to the nucleus. The sequence RLPV(R)6VP, which is present in both pTPs, is identified as their nuclear localization signal. In contrast, AdPol1 was cytoplasmically localized, whereas AdPol2 was distributed in both compartments, suggesting that the nuclear localization signal for AdPol is within the first 139 amino acids. Interestingly, when AdPol1 and pTP1 or AdPol2 and pTP2 were coexpressed in the transfected cells, the nuclear distribution of AdPol1 or AdPol2 was significantly increased. We demonstrate that the nuclear transport of AdPol is facilitated, irrespective of the presence of its nuclear localization signal, by interaction with pTP.

Cell-dependent efficiency of reiterated nuclear signals in a mutant simian virus 40 oncoprotein targeted to the nucleus

We investigated the requisites for, and functional consequences of, the relocation to the nucleus of a transforming nonkaryophilic mutant of the simian virus 40 large T antigen (a natural deletion mutant lacking an internal large-T-antigen domain that includes the signal for nuclear transport). Synthetic oligonucleotides were used to obtain gene variants with one or more copies of the signal-specifying sequence inserted near the gene 3' end, in a region dispensable for the main large-T-antigen functions. The analysis of stable transfectant populations showed that mouse NIH 3T3 cells, rat embryo fibroblasts, and simian CS cells (a subclone of CV1 cells) differed considerably in their ability to localize some variant molecules into the nucleus. CS cells were always the most efficient, and NIH 3T3 cells were the least efficient. The nuclear localization improved either with reiteration of the signal or with a left-flank modification of the signal amino acid context. Three signals appeared to be necessary and sufficient, even in NIH 3T3 cells, to obtain a nuclear accumulation comparable to that of wild-type simian virus 40 large T antigen; other signal-cell combinations caused a large variability in subcellular localization among cells of the same population, as if the nuclear uptake of some molecules depended on individual cell states. The effect of the modified location on the competence of the protein to alter cell growth was examined by comparing the activity of variants containing either the normal signal or a signal with a mutation (corresponding to large-T-antigen amino acid 128) that prevented nuclear transport. It was found that the nuclear variant was slightly more active than the cytoplasmic variants in rat embryo fibroblasts and NIH 3T3 cells and was notably less active in CS cells.

In vitro assay for protein-protein interaction: carboxyl-terminal 40 residues of simian virus 40 structural protein VP3 contain a determinant for interaction with VP1

Intermolecular interactions between polypeptide chains play essential roles in the functioning of proteins. We describe here an in vitro assay system for identifying and characterizing such interactions. Such interactions are difficult to study in vivo. We have translated synthetic, nonmethyl-capped RNAs in a cell-free protein-synthesizing system. The translation products were allowed to interact posttranslationally to form protein-protein complexes. The chemical nature of the protein interaction(s) was determined by coimmunoprecipitation of associating proteins, sedimentation through sucrose gradients, followed by NaDodSO4/polyacrylamide gel electrophoresis or by nonreducing NaDodSO4/polyacrylamide gel electrophoresis. The system has been utilized to show the self-assembly of monomeric VP1, the major structural protein of simian virus 40, into disulfide-linked pentamers and to show the noncovalent interaction of another structural protein, VP3, with VP1 at low monomer concentrations. Additionally, we show that the carboxyl-terminal 40 amino acids of VP3 are essential and sufficient for its interaction with VP1 in vitro. The in vitro assay system described here provides a method for identifying the domains involved in, and the molecular nature of, protein-protein interactions, which play an important role in such biological phenomena as replication, transcription, translation, transport, ligand binding, and assembly.

Two nuclear location signals in the influenza virus NS1 nonstructural protein

The NS1 protein of influenza A virus has been shown to enter and accumulate in the nuclei of virus-infected cells independently of any other influenza viral protein. Therefore, the NS1 protein contains within its polypeptide sequence the information that codes for its nuclear localization. To define the nuclear signal of the NS1 protein, a series of recombinant simian virus 40 vectors that express deletion mutants or fusion proteins was constructed. Analysis of the proteins expressed resulted in identification of two regions of the NS1 protein which affect its cellular location. Nuclear localization signal 1 (NLS1) contains the stretch of basic amino acids Asp-Arg-Leu-Arg-Arg (codons 34 to 38). This sequence is conserved in all NS1 proteins of influenza A viruses, as well as in that of influenza B viruses. NLS2 is defined within the region between amino acids 203 and 237. This domain is present in the NS1 proteins of most influenza A virus strains. NLS1 and NLS2 contain basic amino acids and are similar to previously defined nuclear signal sequences of other proteins.

Expression of the yellow fever virus envelope protein using hybrid SV40/yellow fever viruses

The cDNA coding for the yellow fever virus (YFV) envelope protein (E) was inserted into an SV40 vector under the control of the late promoter in place of the VP1 gene. The recombinant virus expressed a 52-Kd polypeptide which was detected by immunoprecipitation with a monoclonal antibody raised against the E protein. Surprisingly, this protein was visualized in the nucleus of the infected cells. The possible presence of a sequence involved in nuclear migration of the E protein and naturally ignored during virus infection is discussed. The sequence coding for the mature E protein is directly preceded in the YFV genome by a sequence of 45 nucleotides coding for a 15-amino-acid long hydrophobic oligopeptide. The sequence of this oligopeptide was inserted into the SV40 recombinant virus between the ATG codon and the first codon for the E protein. The E protein expressed by this new SV40 recombinant virus was found to be localized in the cytoplasm of the infected cells in association with intracellular membranes. These results strongly suggest that the 15-amino-acid long hydrophobic region naturally plays a role as a signal peptide for the E protein.