Stability of vaccinia virus DNA during persistent infections: accumulation of left-end deletions and of tandem repeats at both ends of the viral genome and prevention by interferon

Novel insights on the progression of intermediate viral forms in the morphogenesis of vaccinia virus

Morphogenesis of vaccinia virus (VACV) is a complex structural process in which the capture of all cytoplasmic stages is difficult due to the rapid transition between the different viral forms. Taking advantage of two VACV mutants (M65 and M101) with defined genetic alterations, we described by transmission electron microscopy (TEM) of ultrathin sections novel potential transition viral forms (Ts) with reorganization of the immature virus (IV) membrane and construction of the internal core, and illustrated the envelopment steps from the mature virus (MV) to the wrapped virus (WV) stages. Our observations allowed us to propose a sequence of structural events for VACV assembly that provides key clues about VACV morphogenesis.

Molecular characterization of Jurkat cells persistently infected with vaccinia virus mutant vp811

Previous reports from this laboratory demonstrated that persistent infections could be established in Jurkat cells with wild-type vaccinia virus (Jvac). The infected cells elicit increased expression of IL-2, IL-2Ralpha and IL-6 but not of IL-1beta nor of interferon-gamma. The persistently infected cells are also capable to transactivate the LTR gene of HIV-1 virus (HIV-1LTR). In addition, NFkappabeta and NFAT are found activated in Jvac. To find out whether the gene(s) responsible for establishment, maintenance and molecular characteristics of persistently infected cells are located in the terminal ends of the molecule, Jurkat cells were infected with a deletion mutant Vp811 that lacks 32.7 and 14.9 kb at the left and right terminal, respectively. The results indicate that the deletion mutant is capable of establishing persistent infections. The persistently infected cells show a similar pattern of expression to that observed in Jvac cells. It is concluded that the viral gene(s) involved in persistence and molecular cellular changes is (are) present in the mutant.

Poxvirus infection and apoptosis

The following excellent reviews have been published on poxviruses and apoptosis during the last few years: P.C. Turner and R.W. Moyer, Semin. Virology, 8: 453-469, 1998; J.L. Shisler and B. Moss, Semin. Immunol., 13: 67-72, 2001; and H. Everett and G. McFadden, Curr. Opin. Microbiol., 5: 395-402, 2002. These articles dealt with the viral products and the mechanisms by which they interfere with apoptosis. In this review, we summarize new and old information and also introduce a new approach to explore interactions between the host cell and the replicating virus.

Vaccinia virus envelope D8L protein binds to cell surface chondroitin sulfate and mediates the adsorption of intracellular mature virions to cells

We previously showed that an envelope A27L protein of intracellular mature virions (IMV) of vaccinia virus binds to cell surface heparan sulfate during virus infection. In the present study we identified another viral envelope protein, D8L, that binds to chondroitin sulfate on cells. Soluble D8L protein interferes with the adsorption of wild-type vaccinia virions to cells, indicating a role in virus entry. To explore the interaction of cell surface glycosaminoglycans and vaccinia virus, we generated mutant viruses from a control virus, WR32-7/Ind14K (A27L(+) D8L(+)) to be defective in expression of either the A27L or the D8L gene (A27L(+) D8L(-) or A27L(-) D8L(+)) or both (A27L(-) D8L(-)). The A27L(+) D8L(+) and A27L(-) D8L(+) mutants grew well in BSC40 cells, consistent with previous observations. However, the IMV titers of A27L(+) D8L(-) and A27L(-) D8L(-) viruses in BSC40 cells were reduced, reaching only 10% of the level for the control virus. The data suggested an important role for D8L protein in WR32-7/Ind14K virus growth in cell cultures. A27L protein, on the other hand, could not complement the functions of D8L protein. The low titers of the A27L(+) D8L(-) and A27L(-) D8L(-) mutant viruses were not due to defects in the morphogenesis of IMV, and the mutant virions demonstrated a brick shape similar to that of the control virions. Furthermore, the infectivities of the A27L(+) D8L(-) and A27L(-) D8L(-) mutant virions were 6 to 10% of that of the A27L(+) D8L(+) control virus. Virion binding assays revealed that A27L(+) D8L(-) and A27L(-) D8L(-) mutant virions bound less well to BSC40 cells, indicating that binding of viral D8L protein to cell surface chondroitin sulfate could be important for vaccinia virus entry.

Stimulation of lymphokines in Jurkat cells persistently infected with vaccinia virus

The response of the human CD4+ T-cell line Jurkat to infection with vaccinia virus was investigated. Virus titers peaked approximately 3 to 4 days after infection, while cell growth paralleled that of uninfected cells, indicating that growth rates were not appreciably affected by viral infection. Results from plaque assays and fluorescence-activated cell sorter (FACS) analyses of virus antigens demonstrated that a persistent infection in which the percentage of infected cells and the virus titers fluctuated from passage to passage was established. Further characterization of the persistent infection revealed that the virus influences cellular functions. Induction of interleukin-2 (IL-2) and IL-2 receptor alpha (IL-2R alpha) in Jvac cells was shown by enzyme-linked immunosorbent assay and FACS analysis, respectively. Hybridization of cellular RNA with cloned probes confirmed the increased IL-2 expression and demonstrated that Jvac cells also expressed more IL-6 but not gamma interferon (IFN-gamma) or IL-1 beta. Dual-antibody staining and FACS analysis for vaccinia virus antigens and IL-2R alpha indicated that IL-2R alpha expression was restricted to the infected cells. Jvac cells were also resistant to superinfection, an additional proof that persistent infection elicited phenotypic changes in the cell population.

Isolation and characterization of mutants of vaccinia virus with a modified 94-kDa inclusion protein

We have characterized one of the most highly expressed genes of vaccinia virus, WR strain, in the wild type and in several spontaneous mutants isolated from persistently infected cells. This gene encodes the 94-kDa inclusion protein, which is the vaccinia virus counterpart of the 160-kDa A-type inclusion (ATI) protein of cowpox virus. The homology index between both genes is greater than 95%. A deletion of two consecutive adenylate residues is responsible for a frameshift mutation and premature translational termination in the vaccinia virus gene. In addition, several point mutations and small deletions occur in the 94K gene. The deduced protein contains 725 amino acids, and 4 of the 10 repeated motifs present in the carboxyl terminus of the cowpox virus 160-kDa protein are conserved. In several mutants independently isolated from untreated and interferon-treated persistently infected cells, the gene encodes a 40-kDa protein. In mutant 87-4, this truncated protein is due to the insertion of a cytidilate residue that produces a frameshift mutation and premature translational termination. The deduced protein contains 366 amino acids and has lost all the repetitions. Transcriptional analysis has shown that the steady-state levels of mRNAs in cells infected with the mutants or wild-type vaccinia virus are similar. However, the accumulation of this protein in cells infected with the mutants is reduced indicating some instability. In addition the mutated protein is not recognized by polyclonal antisera. Existence of tandemly repeated sequences at the carboxyl terminus of this family of inclusion proteins correlates with their antigenicity. These results indicate a high degree of mutability of the ATI gene and products, which apparently has no consequence on replication in vitro, but could have relevance to control of the infection by immune responses in animal hosts.

Stability of molluscum contagiosum virus DNA among 184 patient isolates: evidence for variability of sequences in the terminal inverted repeats

The stability of the Molluscum contagiosum virus Type 1 genome (188 kbp) was studied in 184 DNA isolates from 131 patients. Variability of up to 1.5 kbp at both ends of the genome symmetrically was observed using restriction analysis of the DNA isolates and by Southern Blot experiments using cloned and labeled HindIII terminal DNA fragments of MCV-1 prototype DNA. The variable sequences were mainly confined to the terminal fragments and parts of the MCV-1 terminal repeats. Labeled probes did not detect terminal sequences of MCV Type 2 under the applied stringency. A less marked instability of the central MCV-1 BamHI DNA fragment F was observed within the genome coordinates 0.431 to 0.454 mu. Reiteration of tandem repeats similar to those described for vaccinia virus might explain the variability of the terminal sequences and might be involved in viral replication.

Vaccinia virus induces cell fusion at acid pH and this activity is mediated by the N-terminus of the 14-kDa virus envelope protein

The mechanism by which the large-size poxviruses enter animal cells is not known. In this investigation we show that acid pH treatment of wild-type vaccinia virus-infected cells triggers strong fusion of cells in culture, with an optimum at pH 4.8. We have identified the virus-induced fusion protein as a 14-kDa envelope protein, based on the ability of a 14-kDa specific monoclonal antibody (mAbC3) to block vaccinia virus-induced fusion-from-within and fusion-from-without. We provide genetic evidence for a role of the 14-kDa protein in cell fusion, since insertion of the 14-kDa encoding gene into the genome of nonfusogenic mutant viruses generates heterozygous viruses that now acquire acid pH-dependent fusion activity. DNA sequence analyses of the 14-kDa encoding gene of the mutant viruses, 65-16 and 101-14, reveal N-terminal deletions of 46 and 10 amino acids, respectively. These deletions remove a small hydrophobic region at the N-terminus of the 14-kDa protein and prevent fusion. Our findings demonstrate that vaccinia virus can induce strong fusion of cells in culture at acid pH implying some entry of the virus by endocytosis, that the 14-kDa virus envelope protein is the fusogenic protein, and that the N-terminal proximal region is involved in fusion.

A single point mutation of Ala-25 to Asp in the 14,000-Mr envelope protein of vaccinia virus induces a size change that leads to the small plaque size phenotype of the virus

The molecular defect responsible for a structural and functional abnormality of the 14,000-molecular-weight (14K) envelope protein of vaccinia virus has been identified. Through DNA sequence analysis of the entire 14K gene from wild-type vaccinia virus and three vaccinia virus mutants, a single base change of C to A was found that resulted in the substitution of Asp for Ala-25. This mutation is responsible for protein size abnormality, as documented by cell-free translation in a rabbit reticulocyte lysate of in vitro mRNA transcripts. In addition, through marker rescue experiments we show that this mutation is responsible for the small plaque size phenotype of vaccinia virus mutants. The structural consequence of the point mutation is a possible turn in an alpha-helix domain with destabilization of a hydrophobic interaction at the N terminus, resulting in monomers and trimers of vaccinia virus 14K protein with decreased electrophoretic mobilities. The functional consequence of the point mutation is a reduction in virulence of the virus.

Humoral immune response elicited by highly attenuated variants of vaccinia virus and by an attenuated recombinant expressing HIV-1 envelope protein

Attenuated variants of vaccinia virus have excellent potential for the construction of safe recombinant live vaccines. In this investigation, highly attenuated variants of vaccinia virus with several genetic markers and a variant recombinant were tested in Balb/c mice for their ability to induce humoral immune response. Mice primed with variants that had an 8-MDa deletion at the left end of the viral genome induced similar levels of circulating anti-vaccinia antibodies as the wild-type virus. However, mice primed with variants that had several genetic lesions (deletions and point mutations) induced lower levels of circulating anti-vaccinia antibodies. Mice primed and boosted with a recombinant variant with several genetic lesions, and containing the complete envelope gene of the human immunodeficiency virus (HIV) and the bacterial beta-galactosidase (beta-gal) gene, induced significant antibody response to gp 160 and beta-gal. The antibody response to gp 160 was markedly increased by successive inoculations with the recombinant variant. Our findings provide evidence that the extent of activation of the immune system by vaccinia variants can be modulated by the nature of the virus genetic lesion. In addition, when these variants are used as recombinant vaccines, it is possible to induce low levels of circulating anti-vaccinia antibodies after priming and yet achieve significant antibody response to virus-expressed foreign antigens, even after repeated boosters. Such variants could be useful in the design of live recombinant viruses as safe vaccines.

Characterization of vaccinia virus deletion mutants isolated from persistently infected Friend erythroleukemia cells

Persistent viral infections in vitro are useful to study the evolution of virus populations in the absence of immunological pressure. Several deletion mutants have been isolated in this laboratory from Friend erythroleukemia cells persistently infected with vaccinia virus strain IHD-W, designated SQAvac. Two of the mutants, which remain stable after serial passage in L cells, have been characterized. The deletion which range between 20 to 22 kb, has been localized at the left terminus comprising HindIII fragments C and N. In addition, HindIII B fragment lost the sequences that hybridize to pAG5, a plasmid containing the 3.5 kb terminal sequences and acquired different restriction sites. Phenotypic characterization of these mutants revealed that they were not replication defective since they grew in all cell lines tested and produced plaques of the same size as the wild-type. However, they were less effective in suppressing host protein synthesis. The LD50 for the mutants titered in NIH Swiss female mice was greater than 10(9) PFU as compared to 10(6) PFU for the wild-type, indicating reduced virulence in vivo. These mutants, which display different properties to previously described mutants with deletions at the left terminus, provide another valuable system to study the molecular basis of virulence of vaccinia.

Attenuated deletion mutants of vaccinia virus lacking the vaccinia growth factor are defective in replication in vivo

Understanding the molecular basis of virulence in poxvirus is of great importance for the development of recombinant vaccines using vaccinia virus as a vector. We have previously described mutants of vaccinia virus with deletions ranging from 20 to 21 kb at the left terminus and with attenuated phenotype. The virulence of these mutants was studied, using different routes of inoculation, for protection from wild-type challenge in mice and for replication in vivo. Regardless of the route of inoculation, the LD50 of the deletion mutants is at least 1000-fold higher than that of the wild-type. Results from protection experiments using viable and ultraviolet-inactivated viruses, and from determination of infectivity in different organs, indicated that the mutants were unable to replicate in vivo. Southern blot hybridization of viral DNA with pSC16, a plasmid containing the vaccinia growth factor (VGF) gene, revealed that in the IHD-W strain of vaccinia virus this gene is localized at the left terminus exclusively and that the mutants lack this gene. The results suggest that absence of the VGF gene is correlated with inability to replicate in vivo and decreased virulence.