Parvoviral DNA replication has many features in common with prokaryotic rolling circle replication (RCR), including the pivotal role of an initiator protein which introduces a site-specific, single strand nick into a duplex origin sequence. In this process, the protein becomes covalently attached to the new 5' end of the DNA, while making available a 3' hydroxyl to prime de novo synthesis. Sequence comparisons of prokaryotic RCR initiators has revealed a set of three common motifs, two of which, a putative metal coordination site and a downstream active-site tyrosine motif, could be tentatively identified in parvoviral replicator proteins. We have introduced mutations into the NS1 gene of the murine parvovirus minute virus of mice (MVM), in the putative metal coordination site at H129, and into the three candidate tyrosine motifs at Y188, Y197, and Y210. Histidine-tagged mutant proteins were expressed in HeLa cells from recombinant vaccinia virus vectors and partially purified. None of the mutant proteins were able to initiate replication of origin-containing plasmids in vitro, and each showed impaired site-specific binding to the viral origin, with Y188 and Y197 being most severely defective. If this deficiency was minimized using low salt conditions, however, Y188 and Y197 mutant proteins were able to nick and become covalently attached to origin DNA, whereas Y210 and H129 mutant proteins were not, suggesting that the latter residues are part of the catalytic site of the NS1 nickase. Transfer of [32P]phosphate from substrate DNA to NS1, followed by cyanogen bromide cleavage of the complex, gave the single, labeled peptide consistent with Y210 being the linking tyrosine.
Rodent parvoviruses (PV) are recognized for their intrinsic oncotropism and oncolytic activity, which contribute to their natural oncosuppressive effects. Although PV uptake occurs in most host cells, some of the subsequent steps leading to expression and amplification of the viral genome and production of progeny particles are upregulated in malignantly transformed cells. By usurping cellular processes such as DNA replication, DNA damage response, and gene expression, and/or by interfering with cellular signaling cascades involved in cytoskeleton dynamics, vesicular integrity, cell survival, and death, PVs can induce cytostasis and cytotoxicity. Although productive PV infections normally culminate in cytolysis, virus spread to neighboring cells and secondary rounds of infection, even abortive infection or the sole expression of the PV nonstructural protein NS1, is sufficient to cause significant tumor cell death, either directly or indirectly (through activation of host immune responses). This review highlights the molecular pathways involved in tumor cell targeting by PVs and in PV-induced cell death. It concludes with a discussion of the relevance of these pathways to the application of PVs in cancer therapy, linking basic knowledge of PV-host cell interactions to preclinical assessment of PV oncosuppression. Clin Cancer Res; 18(13); 3516-23. Ó2012 AACR.
A DNA fragment containing the minute virus of mice 3 replication origin was specifically coprecipitated in immune complexes containing the virally coded NS1, but not the NS2, polypeptide. Antibodies directed against the amino-or carboxy-terminal regions of NS1 precipitated the NS1-origin complexes, but antibodies directed against NS1 amino acids 284 to 459 blocked complex formation. Using affinity-purified histidine-tagged NS1 preparations, we have shown that the specific protein-DNA interaction is of moderate affinity, being stable in 0.1 M salt but rapidly lost at higher salt concentrations. In contrast, generalized (or nonspecific) DNA binding by NS1 could be demonstrated only in low salt. Addition of ATP or ␥S-ATP enhanced specific DNA binding by wild-type NS1 severalfold, but binding was lost under conditions which favored ATP hydrolysis. NS1 molecules with mutations in a critical lysine residue (amino acid 405) in the consensus ATP-binding site bound to the origin, but this binding could not be enhanced by ATP addition. DNase I protection assays carried out with wild-type NS1 in the presence of ␥S-ATP gave footprints which extended over 43 nucleotides on both DNA strands, from the middle of the origin bubble sequence to a position some 14 bp beyond the nick site. The DNA-binding site for NS1 was mapped to a 22-bp fragment from the middle of the 3 replication origin which contains the sequence ACCAACCA. This conforms to a reiterated motif (ACCA) 2-3 , which occurs, in more or less degenerate form, at many sites throughout the minute virus of mice genome (J. W. Bodner, Virus Genes 2:167-182, 1989). Insertion of a single copy of the sequence (ACCA) 3 was shown to be sufficient to confer NS1 binding on an otherwise unrecognized plasmid fragment. The functions of NS1 in the viral life cycle are reevaluated in the light of this result.
Minute virus of mice NS1, an 83-kDa mainly nuclear phosphoprotein, is the only viral nonstructural protein required in all cell types and it is involved in multiple processes necessary for virus propagation. The diversity of functions assigned to NS1, together with the variation of its complex phosphorylation pattern during infection, suggested that the various activities of NS1 could be regulated by distinct phosphorylation events. So far, it has been demonstrated that NS1 replicative functions, in particular, DNA-unwinding activities, are regulated by protein kinase C (PKC), as exemplified by the modulation of NS1 helicase activity by PKClambda phosphorylation. In order to determine further impact of phosphorylation on NS1 functions, including the induction of cytopathic effects, a mutational approach was pursued in order to produce NS1 variants harboring amino acid substitutions at candidate PKC target residues. Besides the determination of two additional in vivo phosphorylation sites in NS1, this mutagenesis allowed the segregation of distinct NS1 functions from one another, generating NS1 variants with a distinct activity profile. Thus, we obtained NS1 mutants that were fully proficient for trans activation of the viral P38 promoter, while being impaired in their replicative functions. Moreover, the alterations of specific PKC phosphorylation sites gave rise to NS1 polypeptides that exerted reduced cytotoxicity, leading to sustained gene expression, while keeping functions necessary for progeny virus production, i.e., viral DNA replication and activation of the capsid gene promoter. These data suggested that in the course of a viral infection, NS1 may undergo a shift from productive to cytotoxic functions as a result of a phosphorylation-dependent regulation.
Integrin α5β1 and p53 convergent pathways in the control of anti-apoptotic proteins PEA-15 and survivin in high-grade glioma
Integrin α5β1 expression is correlated with a worse prognosis in high-grade glioma. We previously unraveled a negative crosstalk between integrin α5β1 and p53 pathway, which was proposed to be part of the resistance of glioblastoma to chemotherapies. The restoration of p53 tumor-suppressor function is under intensive investigations for cancer therapy. However, p53-dependent apoptosis is not always achieved by p53-reactivating compounds such as Nutlin-3a, although full transcriptional activity of p53 could be obtained. Here we investigated whether integrin α5β1 functional inhibition or repression could sensitize glioma cells to Nutlin-3a-induced p53-dependent apoptosis. We discovered that α5β1 integrin-specific blocking antibodies or small RGD-like antagonists in association with Nutlin-3a triggered a caspase (Casp) 8/Casp 3-dependent strong apoptosis in glioma cells expressing a functional p53. We deciphered the molecular mechanisms involved and we showed the crucial role of two anti-apoptotic proteins, phosphoprotein enriched in astrocytes 15 (PEA-15) and survivin in glioma cell apoptotic outcome. PEA-15 is under α5β1 integrin/AKT (protein kinase B) control and survivin is a p53-repressed target. Moreover, interconnections between integrin and p53 pathways were revealed. Indeed PEA-15 repression by specific small-interfering RNA (siRNA)-activated p53 pathway to repress survivin and conversely survivin repression by specific siRNA decreased α5β1 integrin expression. This pro-apoptotic loop could be generalized to several glioma cell lines, whatever their p53 status, inasmuch PEA-15 and survivin protein levels were decreased. Our findings identify a novel mechanism whereby inhibition of α5β1 integrin and activation of p53 modulates two anti-apoptotic proteins crucially involved in the apoptotic answer of glioma cells. Importantly, our results suggest that high-grade glioma expressing high level of α5β1 integrin may benefit from associated therapies including integrin antagonists and repressors of survivin expression.
During a productive infection, the prototype strain of the parvovirus minute virus of mice (MVMp) induces dramatic morphological alterations in permissive A9 fibroblasts, culminating in cell lysis at the end of infection. These cytopathic effects (CPE) result from rearrangements and destruction of the cytoskeletal microand intermediate filaments, while other structures such as the nuclear lamina and particularly the microtubule network remain protected throughout the infection (J. P. F. Nüesch et al., Virology 331:159-174, 2005). In order to unravel the mechanism(s) by which parvoviruses trigger CPE, we searched for NS1 interaction partners by differential affinity chromatography, using distinct NS1 mutants debilitated specifically for this function. Thereby, we isolated an NS1 partner polypeptide, whose interaction with NS1 correlated with the competence of the viral product for CPE induction, and further identified it by tandem mass spectrometry and Western blotting analyses to consist of the catalytic subunit of casein kinase II, CKII␣. This interaction of NS1 with CKII␣ suggested interference by the viral protein with intracellular signaling. Using permanent cell lines expressing dominant-negative CKII␣ mutants, we were able to show that this kinase activity was indeed specifically involved in parvoviral CPE and progeny particle release. Furthermore, the NS1/CKII␣ complex proved to be able to specifically phosphorylate viral capsids, indicating a mediator function of NS1 for CKII activity and specificity, at least in vitro. Altogether our data suggest that parvovirus-induced CPE is mediated by NS1 interference with intracellular CKII signaling.The autonomous parvovirus minute virus of mice (MVMp) consists of a small icosahedral nonenveloped particle with a single-stranded 5.1-kb linear DNA as a genome. This DNA codes for two structural (VP) proteins and at least four nonstructural (NS) proteins. Among the nonstructural regulatory proteins, only the large 83-kDa polypeptide NS1 is essential for productive infection of all cells, while the three 24-kDa NS2 polypeptides are dispensable in some permissive cell lines. A productive infection of mouse A9 fibroblasts with MVMp culminates in cell lysis and progeny virus release (for a review, see reference 8). The NS1 protein was found to be endowed with cytotoxic function(s) and to be sufficient to alter the morphology of the host cells (6) and eventually cause their death (3). Interestingly, this activity was potentiated as a result of transformation of the target cell with oncogenes (24). The mechanisms of NS1-induced cytotoxicity and the processes of cell lysis and release of infectious progeny particles, however, are poorly understood.MVMp infection of A9 cells leads to characteristic alterations of the host cell morphology, which may facilitate virus replication and the eventual release of progeny particles. Early during infection, subnuclear structures termed APAR bodies are formed, which serve as replication centers for viral DNA amplification (2, 11). At lat...
Late in infection, parvovirus minute virus of mice (MVMp) induces the lysis of mouse A9 fibroblasts. This effect depends on the large nonstructural phosphoprotein NS1, which plays in addition a major role in viral DNA replication and progeny particle production. Since the NS1 C-terminal region is subjected to late phosphorylation events and protein kinase C (PKC) family members regulate NS1 replicative activities, the present study was conducted to determine the impact of PKCs on NS1 cytotoxic functions. To this end, we performed site-directed mutagenesis, substituting alanine residues for two consensus PKC-phosphorylation sites located within the NS1 C-terminal region, T585 and S588. Although these substitutions had no detectable effect on virus multiplication in a single-round infection, the NS1-585A mutant virus was significantly less toxic to A9 cells than wild-type MVMp, whereas the NS1-588A mutant virus was endowed with a higher killing potential. These alterations correlated with specific changes in the late phosphorylation pattern of the mutant NS1 proteins compared to the wild-type polypeptide. Since the mutations introduced in this region of the viral genome also made changes in the minor nonstructural protein NS2, a contribution of this polypeptide to the above-mentioned phenotypes of mutant viruses cannot be excluded at present. However, the involvement of NS1 in these phenotypes was directly supported by the respective reduced and enhanced capacity of NS1-585A and NS1-588A recombinant proteins for inducing morphological alterations and cell detachment in transfected A9 cultures. Altogether, these data suggest that late-occurring phosphorylation of NS1 specifically regulates the cytotoxic functions of the viral product and that residues T585 and S588 contribute to this control in an antagonistic way.The autonomous parvovirus minute virus of mice (MVMp) is a small icosahedral particle with a linear single-stranded DNA (ssDNA) of 5.1 kb as a genome. MVMp replication depends on host cell factors specifically present in S phase, resulting in a restriction of its propagation in proliferating tissues. This feature is likely to contribute to the oncotropism displayed by this virus, although additional factors appear to be required (51). The viral DNA comprises two overlapping transcription units. The right-hand unit encodes two capsid proteins, VP1 and VP2, which are expressed under the control of the P38 promoter, while the left-hand unit, driven by the P4 promoter, produces the two nonstructural proteins NS1 and NS2. The large nonstructural protein NS1 is endowed with multiple functions necessary for progeny virus production, while the small nonstructural proteins NS2, expressed in three distinct isoforms according to their unique C termini, are dispensable for MVMp propagation in nonmurine cell types (15,35).The functions and regulation of the NS1 protein have been investigated in great detail. This protein combines multiple enzymatic and nonenzymatic functions, such as ATP binding and hydrolysis (6, 56)...
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