Hemadsorption and hemadsorption inhibition tests for rubella virus

Summary A hemadsorption (HAd) reaction was demonstrated in rubella-infected cell cultures using erythrocytes of 1-day-old chickens, adult chickens, pigeons, geese, sheep or bovines. HAd occurred at 4°C, room temperature or 37°C, and at a pH of 6.2 or 7.4. BHK-21 cells were the most satisfactory for demonstrating HAd; the reaction could be demonstrated only in heavily-infected cultures of other cell types. Infected BHK-21 cell cultures generally had to attain infectivity titers of 10^–3.5 to 10^–4.0 InD₅₀ per 0.1 ml in order for HAd to be demonstrable. The HAd reaction could be used to detect unneutralized virus in neutralizing antibody assays, and the inhibition of HAd in infected cell cultures was a very sensitive method for assay of rubella antibodies. A procedure was developed for identification of rubella virus isolates by HAd inhibition.The work on which this report is based was supported by Grant AI-01475 from the National Institute of Allergy and Infectious Diseases, National Institutes of Health, United States Public Health Service, Department of Health, Education, and Welfare.     

Modification of vaccinia virus penetration proteins analyzed by monoclonal antibodies

Modifications induced in structural vaccinia virus proteins that elicit the high infectious state by virus activating treatments involving trypsin and phosphatidylserine were analyzed using antivaccinia monoclonal antibodies (MABs). MABs reactive against each of the five outer layer proteins (VP54K, 34K, 32K, 29K, and 17K-25K) neutralized infectivity. VP54K possesses at least two neutralizing epitopes. Treatment with trypsin or with isolated plasma membrane cleaved VP54K into TVP41K carrying epitope A and removed a fragment containing epitope B from the virus. MABs against either of the epitopes could neutralize the virus. The exposure of epitope A concomitantly activated virus infectivity, and it was an essential step of penetration. MABs against VP17K-25K reacted more efficiently with trypsin-treated virus than with untreated virus, but the size of VP17K-25K was not affected by trypsin; this finding indicated that trypsin treatment rendered the VP17K-25K epitopes more accessible to antibody and hence to neutralization. MABs against VP32K and VP29K neutralized infectivity to the same extent irrespective of the state of activation. Virus treated with phosphatidylserine (PS) was neutralized more efficiently by MAB against VP34K than untreated virus, but the amount of antibody that reacted with the virus was the same before and after treatment with PS. Phosphatidylserine did not modify epitope structure itself, but it activated the function of VP34K. It was concluded that blocking of the functions attributed to any of the five proteins resulted in neutralization of virus infectivity, and treatment with trypsin and phosphatidylserine activates infectivity of vaccinia virus by modifying three of them (VP54K, VP34K, VP17K-25K) with characteristic behavior for each protein.     

Nucleotide sequence of the vaccinia virus hemagglutinin gene

Vaccinia virus hemagglutinin (HA) is expressed at late time of infection cycle, and it is nonessential for virus growth. Location of the HA structural gene was determined by hybrid-arrested and hybrid-selected translation methods at the right terminus of the HindIII A fragment. The position of the HA gene was confirmed by the production of the complete HA protein in the cells transfected with the plasmid containing that region. Examination of this nucleotide sequence revealed the positions of cleavage sites for a number of restriction endonucleases. The deduced amino acid sequence revealed that the HA protein is a member of typical surface membrane glycoproteins. Comparison of the nucleotide sequence upstream of the HA coding region with corresponding region of other late genes suggested the existence of the consensus decanucleotides TTCATTTa/tGT between 34 to 18 bp upstream to the initiation codon followed by a cluster of A or T, a unique feature of the late genes of vaccinia virus. These results in conjunction with the ease of isolating HA- mutants provide a basis for a new site suitable for inserting foreign genes.     

Insertion and deletion mutants of vaccinia virus

Thirteen viable insertion mutants of vaccinia virus have been constructed. These mutants, containing coding sequences of the herpes simplex virus thymidine kinase (HSV-TK) gene, were generated by marker transfer via in vivo recombination. The mutants were identified using a replica filter plating technique by in situ hybridization using 32P-nick translated HSV-TK sequences and obtained as pure cultures by repeated plaque purification. Some of these insertion mutants were in turn used as substrates to generate viable deletion mutants of vaccinia virus in the presence of 5'-bromodeoxyuridine. An example of this approach resulting in a vaccinia virus deleted of approximately 1.5 kb of nonessential DNA is presented. Furthermore, the analysis of spontaneously occurring viable deletion mutants of vaccinia lacking approximately 21.4 kb of nonessential DNA is described.     

Isolation and characterization of attenuated mutants of vaccinia virus

Attenuated variants of vaccinia virus with two specific and stable genetic markers were obtained after long-term passage of persistently infected Friend erythroleukemia (FEL) cells. The genetic markers were an 8-MDa deletion on the left HindIII-C terminus of the viral genome and sequence alterations localized in the middle of the HindIII-A DNA fragment. This latter genetic marker led to small plaque size phenotype of these variants. The mode of replication of these variants in tissue culture cells and their virulence in mice were analyzed. In cultured cells, these variants have greatly reduced virus yields in cell lines of different origins. These variants penetrate into cells, synthesize early and late viral proteins, and replicate their DNA with about the same efficiency as wild-type virus. The defect of these variants appears at some step during virus maturation. When groups of BALB/c mice were inoculated intraperitoneally (ip) with these variants, 50% of the mice survived with greater than or equal to 1 X 10(9) plaque-forming units (PFU) as opposed to about 50% survival for mice inoculated with 1 X 10(6) PFU of wild-type virus. Mice inoculated with these variants were fully protected when challenged ip with lethal doses of wild-type virus. The reduced virulence of these variants correlated with the 8-MDa deletion; in addition, the plaque size phenotype marker contributes to a further decrease of the virulence of vaccinia virus. Due to their limited virus production and protective immune response, these variants may be potentially useful as vaccines.     

Isolation and preliminary characterization of temperature-sensitive mutants of vaccinia virus

Methods have been developed for rapid isolation and genetic analysis of vaccinia virus mutants. These methods include: (1) monitoring mutagenesis by measuring conversion of wild-type, phosphonoacetic acid-sensitive virus to phosphonoacetic acid-resistant virus, (2) screening for mutants by plaque enlargement, and (3) a qualitative spot test for complementation. Twenty-six temperature-sensitive mutants of vaccinia virus have been isolated. All have reversion indices of 10^?4 or less. One-step growth experiments have been done at 40° and 31° with all the mutants and in all cases the virus yield at 40° is less than 8% of the yield observed at 31°. Complementation analysis has been completed on all 26 mutants, showing that these mutants together comprise 16 complementation groups. Twenty-four of the mutants have been analyzed for their ability to synthesize viral DNA at the nonpermissive temperature. The results show that 3 of the 24 have a DNA-negative phenotype. These three mutants fall into two complementation groups. Twenty-four of the mutants have been analyzed for their ability to synthesize early and late viral proteins at the nonpermissive temperature. From this analysis, four phenotypes appear: (1) normal, (2) a phenotype associated with DNA-negative mutants characterized by prolonged synthesis of early proteins and the absence of late protein synthesis, (3) weak or slow late protein synthesis, (4) abortive late protein synthesis.     

Immunological and virological characterization of improved construction of recombinant vaccinia virus expressing rinderpest virus hemagglutinin

Summary We constructed a recombinant vaccinia virus (RVV) expressing rinderpest virus (RPV) hemagglutinin (H) by modifying the promoter region of the original RVV. The promotor region was modified at three points, i.e., an outframe ATG was eliminated, the sequence between the promoter and initiation codon was shortened and the base sequence just upstream of the initiation codon was changed. As compared with the original RVV, the modified RVV was found to produce a remarkably large amount of H protein in infected rabbit kidney cells cultured in vitro and to induce high titers of anti-RPV-H antibodies in rabbits. The median protective doses in rabbits of the modified and of the original RVVs were 10² pfu and 10^3.5 pfu, respectively, indicating that the modified RVV was at least 10-times more effective in protection than the original. The neurovirulence of the modified RVV and the parental LC16mO strain was roughly at the same level, and was much lower than that of WR strain. The modified RVV was as heat-stable as the original one. These results indicate that the modified RVV could be a candidate rinderpest vaccine for further examinations including cattle.     

Rescue of host-dependent conditional lethal mutants of vaccinia and rabbitpox viruses by Yaba virus

Summary Host-dependent conditional lethal mutants of vaccinia and rabbitpox viruses were rescued in nonpermissive host cells by Yaba virus, a poxvirus serologically distant from the rescued viruses.With 1 Figure     

麻疹病毒血凝素和融合蛋白基因的克隆与表达及其重组蛋白的免疫学评价

采用逆转录－多聚酶链反应（ＲＴ－ＰＣＲ）的方法从麻疹病毒Ｅｄｍｏｎｓｔｏｎ株基因组中扩增出血凝素Ｈ基因和融合蛋白Ｆ基因，并利用转移质粒将这两个基因分别重组到杆状病毒多角体蛋白启动子（ＰＨ）控制之下，获得重组病毒ｖＢＭＶＨ和ｖＢＭＶＦ。重组杆状病毒感染Ｓｆ９昆虫细胞，表达的重组蛋白分别具有血凝、血溶活性。红细胞吸附抑制试验、免疫印迹、酶联免疫试验结果显示重组蛋白在生物学、生化学特性与天然蛋白类似，并能被天然麻疹免疫血清（人、鼠、兔）所识别。动物实验表明，重组蛋白具有诱生中和抗体的能力。重组血凝素免疫血清还具有血凝抑制抗体活性。这些结果说明杆状病毒－昆虫细胞体系表达的麻疹病毒血凝素和融合蛋白具有较好的生物学活性及免疫原性和抗原性。     

Host-range restriction of vaccinia virus E3L-specific deletion mutants

The vaccinia virus (VV) E3L gene product functions as a dsRNA binding protein that is involved in conferring an interferon-resistant phenotype upon the virus. Studies with a vaccinia virus (VV) E3L^- deletion mutant (vP1080) have also demonstrated that the E3L gene product is critical for productive replication on certain cell substrates. While E3L was found to be nonessential for replication in chick embryo fibroblasts (CEFs), virus specifically deleted of E3L was found to be replication deficient in Vero, HeLa, and murine L929 cells. Further, the temporal block in replication appears to differ in these cell systems, as evidenced by the observed timing of protein synthesis inhibition. In Vero cells infected with the VV E3L^- mutant, there was no detectable protein synthesis after 2 hr post-infection, whereas in L929 cells normal protein patterns were observed even at late times post-infection. Expression of a heterologous dsRNA binding protein, the reovirus 3 protein, by the E3L^- mutant virus restored near wild-type growth characteristics, suggesting the critical nature for regulating dsRNA levels in VV-infected cells.     

Epitope mapping by deletion mutants and chimeras of two vesicular stomatitis virus glycoprotein genes expressed by a vaccinia virus vector

Deletion mutants and chimeras of the glycoprotein (G) genes of vesicular stomatitis virus serotypes Indiana (VSV-Ind) and New Jersey (VSV-NJ) were cloned in plasmids and vaccinia virus vectors under control of the bacteriophage T7 polymerase promoter for expression in CV-1 cells co-infected with a T7 polymerase-expressing vaccinia virus recombinant. Truncated and chimeric G proteins expressed by these vectors were tested for their capacity to react with VSV-Ind and VSV-NJ epitope-specific monoclonal antibodies (MAbs) by Western blot analysis for those antigenic determinants not affected by disulfide-bond reducing conditions or by immuno dotblot analysis for those that are. These experiments allowed us to create putative epitope maps for glycoproteins of both serotypes based on binding affinity and cross-reactivity of VSV-Ind and VSV-NJ MAbs for truncated or chimeric G proteins of known amino acid sequences. Seven of the 9 VSV-NJ G epitopes, including all 4 epitopes involved in virus neutralization by MAbs, mapped to the center (amino acid sequence 193-289) of the 517 amino acid VSV-NJ G protein. Four of the 11 VSV-Ind G epitopes, including 2 neutralizable epitopes, mapped to the cysteine-rich amino-terminal domain (amino acid sequence 80-183) of the 511 amino acid VSV-Ind G protein; the remaining 7 VSV-Ind G epitopes, including 2 involved in virus neutralization, were clustered in the cysteine-poor carboxy-terminal domain (amino acid sequence 286-428). In site-specific mutants of the VSV-Ind G gene defective in one or both glycosylation sites, only the amino-terminal epitopes of the VSV-Ind G protein were affected by deletion of the carbohydrate chain at residue 179; deletion of the carbohydrate chain at residue 336 did not alter reactivity of the G protein with any of the relevant monoclonal antibodies. These results are discussed in relation to earlier attempts to map the antigenic determinants of VSV-NJ and VSV-Ind G proteins by proteolysis of the G protein and by sequencing the G genes of mutant viruses selected for their resistance to neutralization by epitope-specific monoclonal antibodies.     

Complementation analysis of the dales collection of vaccinia virus temperature-sensitive mutants

A collection of randomly generated temperature-sensitive (ts) vaccinia virus (strain IHD-W) mutants were reported by S. Dales et al., (1978, Virology, 84, 403-428) in 1978 and characterized by electron microscopy. We have performed further genetic analysis on the Dales collection of mutants to make the mutants more useful to the scientific community. We obtained the entire Dales collection, 97 mutants, from the American Type Culture Center (ATCC). All 97 mutants were grown and reassessed for temperature sensitivity. Of these, 16 mutants were either very leaky or showed unacceptably high reversion indices even after plaque purification and therefore were not used for further analysis. The remaining 81 ts mutants were used to perform a complete complementation analysis with each other and the existing Condit collection of ts vaccinia virus (strain WR) mutants. Twenty-two of these 81 Dales mutants were dropped during complementation analysis due to erratic or weak behavior in the complementation test. Of the 59 mutants that were fit for further investigation, 30 fall into 13 of Condit's existing complementation groups, 5 comprise 3 previously identified complementation groups independent of the Condit collection, and 24 comprise 18 new complementation groups. The 59 mutants which were successfully characterized by complementation will be accessioned by and made available to the scientific community through the ATCC.     

Protective immunity provided by HLA-A2 epitopes for fusion and hemagglutinin proteins of measles virus

Natural infection and vaccination with a live-attenuated measles virus (MV) induce CD8(+) T-cell-mediated immune responses that may play a central role in controlling MV infection. In this study, we show that newly identified human HLA-A2 epitopes from MV hemagglutinin (H) and fusion (F) proteins induced protective immunity in HLA-A2 transgenic mice challenged with recombinant vaccinia viruses expressing F or H protein. HLA-A2 epitopes were predicted and synthesized. Five and four peptides from H and F, respectively, bound to HLA-A2 molecules in a T2-binding assay, and four from H and two from F could induce peptide-specific CD8+ T cell responses in HLA-A2 transgenic mice. Further experiments proved that three peptides from H (H9-567, H10-250, and H10-516) and one from F protein (F9-57) were endogenously processed and presented on HLA-A2 molecules. All peptides tested in this study are common to 5 different strains of MV including Edmonston. In both A2K(b) and HHD-2 mice, the identified peptide epitopes induced protective immunity against recombinant vaccinia viruses expressing H or F. Because F and H proteins induce neutralizing antibodies, they are major components of new vaccine strategies, and therefore data from this study will contribute to the development of new vaccines against MV infection.     

Presence of hemagglutinin in the vaccinia virion

Summary Purified vaccinia virus freed from demonstrable hemagglutinating activity was inactivated and, subsequently, disintegrated by treatment with pepsin. The preparations obtained were examined in the electron microscope and tested for hemagglutinating and precipitating activity as well as for their immunogenicity. The release of hemagglutinating activity from the virions was dependent upon the concentration of pepsin used. Precipitinogens and antigen capable of inducing complement fixing antibodies in rabbits were released by low concentrations of pepsin. Formation of neutralizing and especially hemagglutination inhibiting antibodies was induced by preparations obtained by treatment with higher concentrations of pepsin. Immunization with one mg, but not with 0.1 mg, of inactivated but undigested virions resulted in formation of hemagglutination inhibiting antibodies. The site of a hemagglutinin component in the vaccinia virion is discussed.