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Journal of Virology, January 2003, p. 433-442, Vol. 77, No. 1
0022-538X/03/$08.00+0     DOI: 10.1128/JVI.77.1.433-442.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Regulation of Minute Virus of Mice NS1 Replicative Functions by Atypical PKC In Vivo

Program of Applied Tumor Virology, Abteilung F0100,¹ Institut National de la Santé et de la Recherche Médicale U375, Deutsches Krebsforschungszentrum, Heidelberg, Germany²

Received 19 June 2002/ Accepted 27 September 2002

	ABSTRACT

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Minute virus of mice NS1 protein is a multifunctional phosphoprotein endowed with a variety of enzymatic and regulatory activities necessary for progeny virus particle production. To regulate all of its different functions in the course of a viral infection, NS1 has been proposed to be modulated by posttranslational modifications, in particular, phosphorylation. Indeed, it was shown that the NS1 phosphorylation pattern is altered during the infectious cycle and that the biochemical profile of the protein is dependent on the phosphorylation state of the polypeptide. Moreover, in vitro approaches have identified members of the protein kinase C (PKC) family, in particular, atypical PKC, as regulators of viral DNA replication through the phosphorylation of NS1 residues T435 and S473, thereby activating the protein for DNA unwinding activities. In order to substantiate these findings in vivo, we produced NS1 in the presence of a dominant-negative PKC mutant and characterized the purified protein in vitro. The NS1 protein produced under these conditions was found to be only partially phosphorylated and as a consequence to be deficient for viral DNA replication. However, it could be rescued for this viral function by treatment with recombinant activated PKC. Our data clearly demonstrate that NS1 is a target for PKC phosphorylation in vivo and that this modification is essential for the helicase activity of the viral polypeptide. In addition, the phosphorylation of NS1 at residues T435 and S473 appeared to occur mainly in the nucleus, providing further evidence for the involvement of PKC which, unlike PKC, accumulates in the nuclear compartment of infected cells.

	INTRODUCTION

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Minute virus of mice (MVM), an autonomous parvovirus, is a small nonenveloped spherical particle containing single-stranded linear DNA. This 5.1-kb DNA encodes two structural and at least four nonstructural proteins, of which only NS1, the 83-kDa, mainly nuclear polypeptide, is essential for virus propagation in all cell types. This multifunctional protein is endowed with regulatory as well as enzymatic activities essential for various processes involved in progeny virus production. Besides regulating its own promoter, NS1 trans-activates the promoter for capsid protein production, initiates viral DNA amplification, and interferes with host cell physiology, thereby allowing efficient virus propagation to occur. The capacities of NS1 to modulate host cell transcription, translation, and posttranslational modifications and to interact physically with a variety of host proteins are thought to contribute to the overall cytostatic and cytotoxic effects imposed by the viral polypeptide on host cells (for a review, see reference 37).

In order to exert its various functions in a timely and coordinated manner, NS1 was proposed to be regulated by posttranslational modifications, in particular, phosphorylation. In fact, by monitoring NS1 phosphorylation through metabolic labeling, it was shown that the phosphopeptide pattern of the protein undergoes consecutive changes in the course of a viral infection (8). Furthermore, the biochemical functions of NS1 proved to be tightly dependent on the phosphorylation state of the polypeptide (27). These findings argue strongly for NS1 regulation by discrete phosphorylation and dephosphorylation events. By use of a kinase-free in vitro replication system, it was demonstrated that the initiation of viral DNA amplification indeed requires NS1 phosphorylation by members of the protein kinase C (PKC) family (29) and that distinct NS1 replicative functions are independently regulated by phosphorylation (7, 12, 26, 27, 29).

Unlike double-stranded DNA viruses, such as simian virus 40, parvoviruses use a rolling-circle mode of DNA replication (RCR) similar to that described for bacteriophages and single-stranded plasmids. Thus, replication intermediates are produced by unidirectional strand displacement synthesis starting from single-strand nicks produced by parvovirus initiator protein NS1, which becomes covalently attached to the 5' end of the nicked strand. The free 3'-hydroxyl produced by this cleavage reaction then serves as a primer for DNA polymerase activity (for details, see references 5 and 10). Initiation and consecutive DNA amplification can be studied in vitro by using plasmids containing the minimal (left-end) origins of replication in the presence of cellular extracts, deoxynucleoside triphosphates (dNTPs), and purified NS1 (9). Recently, it was found that this in vitro replication reaction could be reconstituted by using recombinant polypeptides of NS1, polymerase , PCNA, RF-C, RPA, and nicking accessory protein PIF (5). In order to obtain a kinase-free in vitro replication system, we replaced the polymerase fraction with T4 bacteriophage DNA polymerase and used a subcellular fraction consecutively purified on phosphocellulose and threonine affinity columns to supply PIF, PCNA, and RPA. This modified in vitro system allowed us to study the regulation of NS1 replicative functions through phosphorylation (29) and, as a consequence, to show that recombinant PKC and an additional phorbol ester-stimulated component are sufficient to render dephosphorylated NS1 active for RCR (12).

Biochemical analyses of NS1 and site-directed mutants of NS1 have been performed to investigate the mechanisms of replication initiation at the protein level. NS1 is endowed with multiple enzymatic activities, such as ATP binding and hydrolysis (17), oligomerization (32), site-specific interaction with the origin (11, 21), site- and strand-specific endonuclease activity (6, 28), and helicase function (17, 26, 28), all of which proved to be essential for parvovirus DNA replication (26, 28). These developments allowed us to characterize the phosphorylation-dependent regulation of NS1 replicative functions on the biochemical level. Two NS1 target sites for atypical PKC or PKC phosphorylation, mapping at residues T435 and S473, were found to be essential for MVM DNA replication (7, 12). Phosphorylation of these residues appears to control two specific NS1-dependent events: (i) initiation of viral DNA replication through origin unwinding prior to nicking and trans-esterification (26) and (ii) viral DNA amplification through a processive helicase function in front of the replication fork (12, 26), ensuring polymerase -driven strand displacement synthesis.

All investigations performed so far regarding the involvement of PKCs in the regulation of MVM DNA replication have been based on either in vitro phosphorylation or the use of NS1 mutants to target PKC phosphorylation sites. The present investigation was performed to elucidate the role of PKC phosphorylation of NS1 under in vivo conditions and to analyze its impact on NS1 replicative functions. To obtain NS1 deprived of atypical PKC phosphorylation, we expressed the protein in mouse A9 cells in the presence of a dominant-negative PKC mutant. This strategy resulted in a partially phosphorylated NS1 protein which specifically lacked atypical PKC-induced modifications and which could be further purified and analyzed for its activities in vitro. In addition, we compared the pattern of phosphorylation of a purely cytoplasmic NS1 variant with that of the mainly nuclear wild-type protein, in relation to the subcellular distributions of atypical PKCs in mock- and MVM-infected A9 fibroblasts. The data presented here show that NS1 is a target for atypical PKC in vivo and that the resulting modifications control the replicative functions of NS1 at the level of its helicase activity. PKC phosphorylation of NS1 takes place predominantly in the nuclear compartment, in keeping with the accumulation of this kinase in the nucleus of the host cell. However, a significant fraction of PKC is still present in the cytoplasm, suggesting that additional factors mediate the compartmentalization of NS1 phosphorylation and activation.

	MATERIALS AND METHODS

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Viruses and cells. Recombinant vaccinia viruses were generated in CV-1 cells, propagated in monolayer cultures of BSC-40 or HeLa cells, and purified over a sucrose cushion as previously described (25, 28). If no suitable antibodies were available for the detection of a recombinant protein (e.g., vDN), recombinant vaccinia viruses harboring the appropriate gene were identified by PCR with a rightward primer located within the encephalomyocarditis virus leader sequence (5'-GATGCCCAGAAGGTACCCCATTG-3') and a leftward primer specific for the coding sequence of the appropriate gene. Vaccinia virus vTF7-3 has been described elsewhere (15). The production of wild-type and mutant His₆-tagged NS1 as well as PKC has been reported elsewhere (7, 12, 28). Wild-type MVM was propagated in A9 cells. A9 and BSC-40 cells were grown as monolayer cultures in Dulbecco's modified Eagle's medium containing 10% fetal calf serum. HeLa-S3 cells were grown in suspension in Joklik's medium containing 10% fetal calf serum in Spinner bottles.

NS1and PKC mutants. (i) NS1 variants. The nucleotide binding site mutant K405R (25), the cytoplasmic deletion mutant dl158 (24), and the phosphorylation site mutants T435A and S473A (7, 12, 26) have been described and characterized elsewhere.

(ii) PKC dominant-negative mutant. The PKC-DN clone, encoding the regulatory domain of PKC (amino acids 27 to 236), was generated from the corresponding wild-type cDNA clone (12) by PCR with the primer pair 5'-ATACCATGGTAACACACTTTGAGCCTT-3' and 5'-ATGCTCGAGCGACGCTTTACCACTCTCC-3' and subcloned into pCR2.1 (Invitrogen, Groningen, The Netherlands) prior to transfer into pTMHis1.

Expression vectors and substrate plasmids. Plasmids pTM-1 (20) and pTHis-1 (27), used to generate recombinant vaccinia viruses, have been described elsewhere. Plasmids containing the active and inactive left-end origins of MVM DNA replication (pL1-2TC and pL1-2GAA, respectively) have been described by Cotmore and Tattersall (9).

Production and purification of recombinant proteins. PKC and NS1 polypeptides were produced from recombinant vaccinia viruses in suspension cultures of HeLa-S3 cells (27) by using vTF7-3 and the appropriate recombinant vaccinia virus containing the NS1 or the PKC gene under the control of the T7 promoter at 15 PFU/cell each. When needed, vaccinia virus expressing PKC-DN (or either of the control proteins NS2 and PKC) at 15 PFU/cell was added to achieve a dominant-negative effect directed against endogenous PKC. Infected cultures were harvested 18 h postinfection, whole (PKC) or nuclear (NS1) extracts were prepared, and His-tagged recombinant proteins were purified by using Ni²⁺-NTA-agarose (Qiagen) columns (28). Protein preparations were analyzed by discontinuous sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and Coomassie blue staining and tested for distinct biochemical properties.

NS1 metabolic labeling, purification, and phosphopeptide analyses. Metabolic labeling of NS1 and tryptic phosphopeptide analyses were performed essentially as previously described (27). A9 cell cultures (10⁷ cells) were infected with recombinant vaccinia viruses (15 PFU/cell each) and incubated for 3 h before the labeling medium (complete medium lacking phosphate and complemented with 10^-10 Ci of [³²P]orthophosphate [ICN]/cell) was added. After 4 h, the labeled cells were harvested directly in 1 ml of radioimmunoprecipitation assay buffer (20 mM Tris-HCl [pH 7.4], 150 mM NaCl, 1 mM EDTA, 0.1% SDS, 1% sodium deoxycholate, 1% Triton X-100) containing protease and phosphatase inhibitors. NS1 immunoprecipitation was carried out with 10 µl of anti-NS_N antiserum (27) for 2 h at room temperature. Immune complexes were precipitated with protein A-Sepharose, washed with radioimmunoprecipitation assay buffer, and further purified by SDS-10% PAGE. ³²P-labeled proteins were revealed by autoradiography after blotting on polyvinylidene fluoride membranes, and the band corresponding to NS1 was excised. Digestion of membrane-bound NS1 was performed with 50 U of trypsin for 18 h at 37°C. Tryptic peptides contained in the supernatant were recovered by lyophilization and analyzed on thin-layer cellulose plates in two dimensions, first by electrophoresis with pH 1.9 buffer and then by chromatography with phosphochromatography buffer.

Subcellular localization of PKCs. For determination of the subcellular localization of endogenous PKC isoforms, A9 cells were grown on "spot slides." Infections with MVM (30 PFU/cell) were performed for various periods of time. Cells were then fixed with paraformaldehyde, immunostained with various PKC-specific antibodies, and stained with either fluorescein isothiocyanate-, Cy2-, Texas red-, or Cy3-conjugated secondary immunoglobulin G (IgG) antibodies directed against the respective immunoglobulins (see legends to figures). Analyses were performed by standard immunofluorescence microscopy and by laser scanning confocal microscopy (Leica TCS SP laser fitted to a Leica IMRBE microscope).

Helicase assays. Helicase assays were carried out as described previously (28). M13-VAR was used as a substrate and was prepared by annealing the M13rev primer (Amersham) to M13 single-stranded DNA followed by extension for 5 min at room temperature in the presence of T7 polymerase and dNTPs, including [-³²P]dATP. ³²P-labeled fragments of various lengths were obtained by the addition of ddGTP and further incubation for 20 min. Purified NS1 was incubated with 20 ng of substrate for 40 min in the presence of 2 mM ATP. The reactions were stopped by the addition of SDS and EDTA, and the products were analyzed by 7% nondenaturing PAGE in the presence of 0.1% SDS.

Replication assays. Replication assays were carried out as described previously (29) in the presence of subcellular fraction P1-Thr, 3 U of T4 DNA polymerase, and approximately 200 ng of His-tagged vaccinia virus-produced NS1 (as determined by Coomassie blue staining after SDS-PAGE). P1-Thr consists of the flowthrough fraction of 293 cell extracts purified on phosphocellulose columns and relieved of endogenous serine-threonine kinases by L-Thr affinity chromatography. This fraction contains the replication factors RPA, PCNA, and PIF. The assays were carried out with a 20-µl total volume containing 20 mM HEPES-KOH (pH 7.5), 5 mM MgCl₂, 5 mM KCl, 1 mM dithiothreitol, 0.05 mM each dNTP, 2 mM ATP, 40 mM creatine phosphate, 1 µg of phosphocreatine kinase, 10 µCi of [-³²P]dATP (3,000 mCi/mmol), and 20 ng of the appropriate DNA template (pL1-2TC or pL1-2GAA) (12). After incubation at 37°C for 2 h, the reaction was stopped by the addition of 60 µl of 20 mM Tris (pH 7.5)-10 mM EDTA-0.2% SDS and incubation at 70°C for at least 30 min. The reaction products were analyzed by agarose gel electrophoresis after immunoprecipitation with anti-NS_N antiserum and digestion with HindIII.

	RESULTS

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NS1 phosphorylation and regulation by PKC in vivo. MVM NS1 is a multifunctional phosphoprotein that is thought to be primed for its various tasks by differential phosphorylation events in a timely coordinated manner exerted by distinct cellular protein kinases (8). In fact, a variety of in vitro analyses have shown that PKCs (29), particularly PKC (12, 26), are able to activate NS1 for its replicative functions, regulating the DNA unwinding activity of the viral product by phosphorylation at residues T435 and S473. However, the relevance of this kinase for NS1 regulation under in vivo conditions has remained elusive.

To rule out the possible involvement of alternative, as-yet-undefinded cellular protein kinases with the same substrate specificity as atypical PKC in NS1 phosphorylation in vivo, we designed a specific knockout strategy for living cells based on the genuine regulatory properties of PKCs. Atypical PKCs in the inactive state are thought to be in a closed conformation, in which the substrate binding site is blocked due to its interaction with the N-terminally located pseudosubstrate region. Upon interaction with acidic lipids, such as phosphatidylserine (PS), or the appropriate membranes in the cellular environment, a conformational switch disconnects the pseudosubstrate region from the catalytic center of the enzyme, thereby allowing binding and phosphorylation of the substrate to occur (22). In order to specifically inactivate endogenous PKC, we decided to supply the regulatory domain containing the pseudosubstrate region in excess to block the catalytic site of the enzyme. This complex of PKC with the artificially produced peptide, mimicking a closed conformation, is unable to respond to stimulation with the cofactor PS. The PKC regulatory region should thus behave in a dominant-negative manner, hence, its designation here as PKC-DN.

To produce the PKC-DN mutant, the cDNA fragment coding for the regulatory domain of this kinase was expressed by means of recombinant vaccinia viruses in mammalian cells. It should be noted that although PKC and PKC pseudosubstrate sites are identical, it is likely that differences within the sequences surrounding the regulatory domain, particularly around the zinc finger region, are sufficient to discriminate between the two atypical PKCs in vivo. Thus, the greater part of the PKC regulatory domain, corresponding to amino acids 27 to 236, was cloned into pTM-1, and recombinant vaccinia viruses expressing this PKC variant under the control of the bacteriophage T7 promoter and an encephalomyocarditis virus leader sequence were generated. For comparison, the NS1 protein was also coexpressed with wild-type PKC or the parvovirus NS2 protein in order to rule out side effects due to randomly expressed polypeptides.

To investigate the involvement of PKC in NS1 phosphorylation in vivo, NS1 was expressed either alone or in the presence of PKC-DN or wild-type PKC, metabolically ³²P labeled, and processed for tryptic phosphopeptide analyses. As shown in Fig. 1B versus Fig. 1A and C, the coexpression of PKC-DN correlated with the suppression of a major spot in the NS1 phosphopeptide map, while allowing the other phosphorylation events to occur. Since this spot was previously obtained upon in vitro phosphorylation of NS1 by recombinant PKC and was assigned to NS1 peptides harboring the phosphorylation sites T435 and S473 (7, 12), we were able to demonstrate that these two regulatory sites in NS1 are indeed targeted by PKC in vivo. Interestingly, an additional NS1 phosphopeptide became apparent upon inhibition of PKC (Fig. 1B), illustrating the interconnection of different phosphorylation pathways. It should also be noted that no increase in NS1 phosphorylation was observed upon overexpression of recombinant wild-type PKC (Fig. 1C), indicating that the amount of endogenous PKC present in the cells was not limiting for NS1 phosphorylation.

View larger version (53K): [in this window] [in a new window]   FIG. 1. In vivo phosphorylation of NS1 in the presence and absence of active PKC. Wild-type NS1 was expressed either alone (A) or in the presence of PKC-DN (B) or recombinant PKC (C) by infecting A9 cells with recombinant vaccinia viruses. After metabolic 32P labeling, NS1 was purified by immunoprecipitation and SDS-PAGE. Phosphorylation of the individual NS1 polypeptides was determined by tryptic phosphopeptide analyses with two-dimensional thin layer electrophoresis and chromatography and was revealed by autoradiography. Arrows indicate spots which showed a reduced intensity after the coexpression of NS1 with PKC-DN, while the asterisk indicates a phosphopeptide which was induced under these conditions.

View larger version (86K): [in this window] [in a new window]   FIG. 2. The helicase activity of NS1 depends on its phosphorylation by PKC. The unwinding activity of purified NS1 polypeptides was determined in standard helicase assays in the presence of 2 mM ATP by using M13-VAR as a substrate. The reaction products were analyzed by 7% PAGE in the presence of 0.1% SDS. Lanes: 1 and 2, native and heat-denatured input substrates, respectively; 3, NS1 mutant K405M (nucleotide binding site mutant), serving as a negative control; 4, wild-type fully phosphorylated NS1; 5 and 6, wild-type NS1 dephosphorylated by treatment with alkaline phosphatase; 7, PKC alone; 8, NS1 mutant S473A; 9, NS1 mutant T435A; 10, NS1 produced in the presence of NS2; 11, NS1 produced in the presence of recombinant PKC; 12 and 13, NS1 produced in the presence of PKC-DN. Reactivation reactions shown in lanes 6 to 9 and 13 were performed in the presence of activated recombinant PKC.

View larger version (74K): [in this window] [in a new window]   FIG. 3. Reactivation of dephosphorylated NS1 in replication assays. NS1-dependent RCR of plasmids containing the left-end active (T) or inactive (G) origin was determined in a kinase-free in vitro system based on P1-Thr and T4 DNA polymerase (29). The reaction products were analyzed by 0.8% agarose gel electrophoresis after immunoprecipitation with anti-NSN antiserum, HindIII restriction digestion, and deproteination. The migration positions of the linearized plasmid (a), a replication intermediate produced by dephosphorylated NS1 (b), and higher-molecular-weight species that represent replication products with displaced single-stranded tails (c) are indicated on the right. Lanes: 1, mutant Y210F (linkage tyrosine mutant), serving as a negative control; 2 and 3, fully phosphorylated NS1; 4 to 7, NS1 produced in the presence of PKC-DN; 8 to 13, fully dephosphorylated NS1 (alkaline phosphatase treatment). Reactions in lanes 6, 7, 10, 12, and 13 were performed in the presence of activated recombinant PKC; reactions in lanes 11 to 13 were performed in the presence of activated subcellular fraction HA-2.

View larger version (32K): [in this window] [in a new window]   FIG. 4. Tryptic phosphopeptide analyses of wild-type NS1 and cytoplasmic NS1 variant dl158. (A) Schematic pattern. (B and C) Peptide analyses. Wild-type NS1 (B) and mutant dl158 (C) were expressed by means of recombinant vaccinia viruses in A9 cells, metabolically 32P labeled, and purified by immunoprecipitation and SDS-PAGE. Tryptic phosphopeptide maps were obtained by two-dimensional thin-layer electrophoresis and chromatography and were revealed by autoradiography. Arrows indicate a spot that was significantly reduced in intensity in the dl158 map and that was previously assigned to NS1 peptides harboring the phosphorylation sites T435 and S473 (7, 12), as indicated by filled dots in the schematic pattern.

To this end, A9 cells were grown on spot slides, infected or not infected with MVM for 24 h, and fixed with paraformaldehyde. Individual PKCs were then identified with isoform-specific antibodies. NS1 was detected by polyclonal antiserum NS1_C, raised against the C-terminal 16 amino acids of NS1 (24). The subcellular distributions of the PKCs and NS1 were then determined by using standard and confocal laser scanning microscopy. Figure 5 shows confocal images of representative cells (>80% of the cell population) obtained repeatedly after independent infections. PKC was found in both the cytoplasmic and the nuclear compartments of both mock- and MVM-infected cells. However, MVM-infected cells could be distinguished from controls by the nuclear localization of the PKC signal, which colocalized at least in part with the NS1 signal (Fig. 5, left column). Since no increase in the total protein content of PKC was observed upon MVM infection of A9 cells (8), this intensification of nuclear staining likely reflected the association of the kinase with membranes (or other nuclear structures) as a consequence of activation processes. Surprisingly, PKC did not appear to concentrate in distinct nuclear structures, such as the autonomous parvovirus-associated replication (APAR) bodies, which were recently shown to constitute parvovirus DNA replication centers (1). Therefore, the sites at which NS1 becomes phosphorylated and activated by atypical PKCs may be spatially dissociated from those at which NS1 initiates viral DNA replication, even though both events take place in the nuclear compartment.

View larger version (36K): [in this window] [in a new window]   FIG. 5. Subcellular localization of endogenous atypical PKC and PKC in mock- and MVM-infected A9 cells. A9 cells were grown on spot slides, infected or not infected with MVM (30 PFU/cell), and fixed 24 h postinfection with paraformaldehyde. PKC was detected by using an isoform-specific mouse monoclonal antibody (Becton Dickinson P22520) and revealed with Cy3-conjugated anti-mouse IgG. PKC was detected by using a specific goat polyclonal antiserum (Santa Cruz) and revealed with fluorescein isothiocyanate-conjugated anti-goat IgG. For double-immunofluorescence staining, NS1 was detected with rabbit antiserum NS1C (7). Subcellular localization of PKCs and NS1 was analyzed by using laser scanning confocal microscopy. (a and b) Uninfected A9 cells. (c to h) MVM-infected A9 cells. (a and c) Anti-PKC (red). (e) Anti-NS1 (green). (g) Merge. (b and d) Anti-PKC (green). (f) Anti-NS1 (red). (h) Merge. Bars, 10 µm.

It is worth mentioning that the subcellular distributions of PKC and PKC were also characterized after the expression of these isoforms by means of recombinant vaccinia viruses. These analyses confirmed both the specificity of the antibodies for the respective PKC isoforms and the genuine intracellular distributions of these kinases (data not shown). Together with the similarity of the intracellular NS1 phosphorylation patterns in recombinant vaccinia virus- and MVM-infected cells (8), these observations support the use of the vaccinia virus expression system to investigate the interplay between NS1 and atypical PKCs.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Previous in vitro studies showed that phosphorylation of MVM major nonstructural protein NS1 is involved in the modulation of its biochemical activities (27). In consequence, distinct phosphorylation events are essential to endow the viral protein with properties enabling it to achieve distinct functions required for progeny virus production (8, 12, 29). In particular, atypical PKC was found to control NS1 DNA unwinding functions, i.e., enzymatic activities involved in viral DNA replication at both the initial nicking reaction and the subsequent strand displacement synthesis (12, 26, 27, 29). Although supported by investigations with NS1 variants obtained by site-directed mutagenesis at consensus PKC phosphorylation sites (7, 12, 26), the relevance of PKC-driven NS1 phosphorylation and regulation for MVM DNA replication remained to be demonstrated under in vivo conditions. This question was addressed in this work by using a dominant-negative construct to generate partially dephosphorylated NS1 in vivo and subsequently analyzing the purified protein in vitro. The data presented provide direct evidence for NS1 phosphorylation by PKC under in vivo conditions and, moreover, the regulation of NS1-dependent viral DNA replication by modulation of its helicase activity through these modifications. In addition, our results exemplify the interconnection between the activation of PKCs and their compartmentalization inside host cells.

PKC was shown to play an important role in the organization of the cell. Recently, PKC and its homologue in Caenorhabitis elegans, PAR3, were identified as signaling components regulating the shape and polarity of epithelial and neuronal cells (13, 23, 30, 35); they are involved in the regulation of the disassembly of actin stress fibers in ras-transformed cells (36). Furthermore, PKC proved able to trigger signaling cascades involving its own PDK-1/PKC pathway (31) or the signaling cascade of MEK/ERK protein kinases (2, 34). Hence, the experimental modulation of PKC may have significant consequences for cell physiology and thereby additional indirect influences on progeny virus production. Therefore, we used a PKC knockout approach in which the lack of in vivo phosphorylation of NS1 was further analyzed for its effect on the biochemical activities of the viral polypeptide outside the cellular environment. The recombinant vaccinia virus expression system makes this strategy possible, since it allows NS1 to be produced in mammalian cells both in sufficient amounts and with a phosphorylation pattern highly similar to that of the genuine NS1 polypeptide produced by MVM in mouse cells (8, 28). Thus, NS1 produced in the presence of a dominant-negative mutant, PKC-DN, was found to be only partially phosphorylated and to lack helicase and replication activities, defects that could be restored by supplementation of the in vitro assay mixtures with activated PKC. These experiments clearly demonstrated the direct involvement of this atypical PKC isoform in the phosphorylation of NS1 and the regulation of its replicative functions. This complementation in vitro excludes possible indirect effects of the PKC knockout through alterations of host cell physiology.

In vitro reactivation of NS1 helicase activity can be achieved with either one of the atypical PKCs, PKC or PKC (12). Although the involvement of PKC in general cannot be ruled out, it is not supported by the differences shown for the kinases in our experiments. (i) The differences in the primary structure between the regulatory domains of PKC and PKC imply specific inhibition of PKC by our dominant-negative mutant. (ii) The intracellular distributions of the two kinases are different. Nuclear phosphorylation of regulatory sites T435 and S473 likely is targeted by nuclear PKC, while mainly cytoplasmic PKC is a very doubtful candidate for these phosphorylation events.

During the course of an MVM infection, viral protein NS1 not only drives viral DNA replication but also is directly responsible for cell disturbances that eventually lead to cell lysis and release of progeny particles (4). To ensure the optimal production of viruses, NS1 functions are thought to become temporally regulated so that cytotoxic activities are delayed and do not interfere with virus replication. This regulation could be achieved by time-dependent changes in the pattern of phosphorylation of the viral polypeptide (8). However, some NS1 modifications, such as PKC phosphorylation at residues T435 and S473, activate the capacity of NS1 for both replication (12, 26) and alterations of host cell morphology (7). Therefore, additional means to regulate NS1 activities besides phosphorylation may be necessary to dissociate these conflicting activities.

Sequential functioning of NS1 could also be achieved through spatial regulation based on compartmentalization of the viral product and/or its regulators within infected cells. This possibility is consistent with results of the present investigation showing that PKC phosphorylation at residues T435 and S473 occurs predominantly in the nucleus. This evidence suggests that newly synthesized NS1 polypeptides remain underphosphorylated until they migrate to the nucleus, in which they are further modified and activated for their replicative functions. Despite the finding that the same modifications endow NS1 with the ability to induce alterations of host cell morphology (7), this toxic activity becomes apparent only after NS1 has been exported from the nucleus to interact with the cytoskeleton. In keeping with this proposal, an NS1 mutant with a C-terminal deletion was almost fully sequestered in the nucleus, proved to be competent for replication (24), but had less cytotoxic activity than the wild-type (30% cytoplasmic) polypeptide (18). Although this scenario is only hypothetical at this time, it raises the intriguing possibility that NS1 priming for distinct functions is controlled, at least in part, at the level of nuclear-cytoplasmic transport. Again, as already well described for DNA replication activities, the functionally related simian virus 40 large T antigen provides an interesting precedence for this type of regulation (33). Moreover, recent findings concerning the regulatory properties of small parvovirus protein NS2 also support NS1 regulation by compartmentalization. NS2 was recently shown to directly interact with nuclear export factor CRM1 (3), which proved to be essential for the nuclear egress of newly assembled capsids (14, 19). By analogy, NS2 could also be involved in the regulation of the export of other cellular and viral constituents, such as NS1 polypeptides. However, whether the nuclear export of NS1 is further subject to regulation by posttranslational modifications remains to be shown.

	ACKNOWLEDGMENTS

 
We are indebted to Bernard Moss (NIH) for making the T7-driven vaccinia virus expression system available to us. We are most grateful to Peter Tattersall and Susan Cotmore for plasmid constructs and helpful discussions.

This work was supported by the Commission of the European Communities.

	FOOTNOTES

 
* Corresponding author. Mailing address: Program of Applied Tumor Virology, Abteilung F0100, and INSERM U375, Deutsches Krebsforschungszentrum, Im Neuenheimer Feld 242, D-69120 Heidelberg, Germany. Phone: (49) 6221 424969. Fax: (49) 6221 424962. E-mail: jpf.nuesch{at}dkfz-heidelberg.de.

This article is dedicated to Harald zur Hausen on the occasion of his retirement as head of the Deutsches Krebsforschungszentrum, with gratitude and appreciation for 20 years of leadership.

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Top Abstract Introduction Materials and Methods Results Discussion References

 

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