Identification of hog cholera viral isolates by use of monoclonal antibodies to pestiviruses

A collection of 90 field isolates of hog cholera virus (HCV) was used to test the specificity of four hybridoma cell lines secreting monoclonal antibodies against pestiviruses. Reaction of virus isolates and monoclonal antibodies was controlled by an indirect immunofluorescence assay (IFA). Two monoclonal antibodies which had been generated against HC virus strain "Alfort 187" were reactive only with HCV field isolates and an HCV reference strain but not with bovine viral diarrhoea virus (BVDV) reference strains. Two other monoclonal antibodies (generated against BVDV, strain NADL) reacted only with BVDV reference strains but not with HCV field isolates, although with 3 of these strains focal reactions involving only a few cells were detected. The ability to discriminate between both viruses is a diagnostic need which may be fulfilled by these monoclonal antibodies.

Characterization of epitopes on a variant surface glycoprotein from Trypanosoma congolense by six monoclonal antibodies

Monoclonal antibodies were isolated from mice immunized with variant surface glycoprotein of Trypanosoma congolense. Five out of the six monoclonals were able to detect epitopes at the cell surface in an indirect immunofluorescence analysis. One antibody did not react. Using protein-A-containing bacterial adsorbent all monoclonal antibodies precipitate glycosylated as well as non-glycosylated variant surface glycoprotein. Carbohydrate chains therefore do not appear to be part of the immunodeterminant structure recognized by the various monoclonal antibodies. Interaction of the monoclonal antibodies with protein fragments obtained by partial proteolysis with V8 protease from Staphylococcus aureus or papain allows the classification of the antibodies into three groups with different epitope specificity.

Monoclonal antibodies and characterization of epitopes of smooth Brucella lipopolysaccharides

Four mouse monoclonal antibodies generated against Brucella melitensis 16M, and three generated against B. suis 1330 were analysed. An ELISA (enzyme-linked-immunosorbent assay) with whole cells as antigens was used to determine cross-reactivities with other Gram-negative bacteria. Two antibodies showed cross-reactivity with smooth Brucella strains only. Five antibodies also reacted with Yersinia enterocolitica O:9, but not with other bacteria. Two of these antibodies had significantly higher titres with A greater than M serotype Brucella strains, indicating that these epitopes are related to the antigenic A complex. The antigenic determinants recognized by the monoclonal antibodies showed varying degrees of susceptibility towards oxidation. They were shown by immunoblotting to be located on the polysaccharide moiety of the O-side chain.

Preliminary serological characterization of bovine viral diarrhoea virus strains using monoclonal antibodies

Five monoclonal antibodies against the bovine viral diarrhoea (BVD) viral strain NADL were isolated and characterized by an indirect immunofluorescence assay. Extensive cross-reactions were detected when the antibodies were tested with 12 heterologous BVD and four hog cholera (HC) viral strains. One antibody reacted with all strains tested. Two antibodies were specific for cytopathogenic BVD viruses, but failed to react with HC virus. The other antibodies reacted to varying degrees with BVD and HC viral strains.

Inhibition of DNA binding of purified p55v-myc in vitro by antibodies against bacterially expressed myc protein and a synthetic peptide

To identify viral myc proteins, we have prepared myc-specific antibodies: (i) against a synthetic peptide corresponding to the nine carboxy-terminal amino acids of the viral myc (C9); (ii) against a bacterially expressed viral myc protein obtained by inserting the SalI-BamHI fragment of the viral MC29 DNA clone in the expression vector pPLc24. Both antisera recognize a protein of 55 000 mol. wt., p55v-myc, in MH2- and OK10-transformed fibroblasts. The protein is located in the nucleus, as shown by indirect immunofluorescence and cell fractionation. Antibodies against the C9 peptide were used to purify the p55v-myc by immunoaffinity column purification (3000-fold) from OK10- and MH2-transformed fibroblasts. p55v-myc binds to double-stranded DNA in vitro as does p110gag-myc. DNA binding in vitro is inhibited by the immunoglobulin fraction of antibodies against the bacterially expressed myc protein. Furthermore, a synthetic peptide consisting of 16 amino acids (C16) was used to isolate specific immunoglobulins which also inhibit DNA binding in vitro. OK10 codes, in addition to p55v-myc, for a p200gag-pol-myc polyprotein. The majority of this protein is located in the cytoplasm (79%). The purified protein binds to single-stranded RNA in vitro, unlike other gag-myc or myc proteins.

The transforming protein of the MC29-related virus CMII is a nuclear DNA-binding protein whereas MH2 codes for a cytoplasmic RNA-DNA binding polyprotein

The acute avian leukemia viruses MH2 and CMII belong to the group of avian myelocytomatosis viruses, the prototype virus of which is MC29. This group of viruses is characterized by myc-specific oncogenes which are presumably expressed as gag-myc polyproteins. These polyproteins are synthesized in non-producer cells transformed by MH2 and CMII and have mol. wts. of 100 000 (p100) and 90 000 (p90), respectively. Monoclonal antibodies against the N terminus of gag, p19, were used to localize the protein in MH2- and CMII-transformed non-producer fibroblasts. Immunofluorescence and cell fractionation indicated that greater than 90% of p100 from MH2 was located in the cytoplasm, whereas greater than 70% of p90 from CMII resided in the nucleus. Isolation of p100 and p90 by immunoaffinity chromatography resulted in an approximately 2000-fold purification of the two polyproteins. Both of them, as well as p110 of MC29, bound to double-stranded DNA of chick fibroblasts in vitro. However, only the MH2-specific polyprotein p100 bound to RNA in vitro. Such a binding was not observed for p90 or p110, or for the purified gag precursor Pr76. Another polyprotein, gag-erbA, from avian erythroblastosis virus, which is also located in the cytoplasm, did not bind to RNA. Our results indicate that the CMII-specific polyprotein p90 behaved indistinguishably from the p110 of MC29. However, the MH2-specific polyprotein p100 exhibited unique and novel properties which were distinct from a gag-myc-type protein.

Decreased DNA-binding ability of purified transformation-specific proteins from deletion mutants of the acute avian leukemia virus MC29

Avian myelocytomatosis virus MC29 is a highly oncogenic replication-defective retrovirus that predominantly affects hematopoietic cells and causes acute leukemia in vivo and that transforms hematopoietic cells as well as fibroblasts in vitro. The transformation-specific sequence, v-myc, is expressed as part of a fusion protein that contains the viral structural protein p19. By use of monoclonal antibodies against p19 we showed that the v-myc-encoded protein is located in the nucleus of MC29-transformed fibroblasts and that after purification over an immunoaffinity column the protein binds to double-stranded DNA. In this report we describe the analysis of the v-myc gene product from MC29-transformed bone marrow cells. The immunoaffinity column-purified protein from these cells also bound to DNA and was indistinguishable from the purified protein from MC29-transformed fibroblasts. In addition, the v-myc gene products from fibroblasts transformed by three nonconditional mutants of MC29--which transform hematopoietic cells with a markedly decreased efficiency in vivo and in vitro but still transform fibroblasts in vitro, expressing deleted v-myc proteins--were analyzed. In contrast to the wild-type protein, the purified mutant proteins had decreased DNA-binding abilities. Furthermore, a preferential binding of the wild-type protein to poly(dG) . poly(dC) duplexes was observed. Such a specificity was lost with a mutant protein. These results provide evidence that the interaction of the v-myc protein with DNA may be directly involved in transformation of the hematopoietic target cells. Further, the transformation-specific fusion proteins purified from cells transformed by avian erythroblastosis virus, which belongs to a different class of acute leukemia viruses, and by Fujinami sarcoma virus were found not to be DNA-binding proteins, suggesting the existence of different transformation mechanisms.

DNA-mediated gene transfer in Friend leukemia cells by cotransfection of simian virus 40 DNA with herpes simplex virus thymidine kinase DNA

Thymidine kinase-negative Friend leukemia cells were cotransfected with simian virus 40 (SV40) DNA and thymidine kinase gene DNA of herpes simplex virus type 1. The transfected thymidine kinase-positive cells were selected in HAT medium, and SV40 T-antigen expression was observed over many months in cells cultured under selective conditions, and after adaptation to normal growth medium under nonselective conditions. It was shown by Southern blot hybridization that SV40 DNA was integrated in multiple copies in the chromosomal DNA of several clones. All SV40 DNA-containing Friend leukemia cell clones analyzed were able to undergo induced erythroid differentiation. Induced cultures still expressed SV40 T-antigen to the same extent that untreated control cultures did.

Association of gag-myc proteins from avian myelocytomatosis virus wild-type and mutants with chromatin

The localization of the transformation-specific proteins was analyzed in quail embryo fibroblast cell lines transformed by wild-type avian myelocytomatosis virus MC29 and by three of its deletion mutants, Q10A , Q10C , and Q10H , with altered transforming capacities, and in a chicken fibroblast cell line transformed by the avian erythroblastosis virus (AEV). These viruses code for polyproteins consisting of part of the gag gene and of a transformation-specific region, myc for MC29 and erb A for AEV. Analysis by indirect immunofluorescence using monoclonal antibodies against p19, the N-terminal region of the polyprotein, showed that the gag-myc proteins in cells transformed by the wild-type MC29 as well as by the three deletion mutants are located in the nucleus. In contrast, cells transformed by AEV, which express the gag-erb A protein, give rise to cytoplasmic fluorescence. Fractionation of cells into nuclear and cytoplasmic fractions and analysis by immunoprecipitation and gel electrophoresis confirmed these results. About 60% of the gag-myc proteins of wild-type as well as of mutant origin were found in the nucleus, while 90% of the gag-erb A protein was present in the cytoplasm. Also, pulse-chase analysis indicated that the gag-myc protein rapidly accumulates in the nucleus in just 30 min. Further, it was shown that the wild-type and also mutant gag-myc proteins are associated with isolated chromatin. Association to chromatin was also observed for the gag-myc protein from MC29-transformed bone marrow cells, which are believed to be the target cells for MC29 virus in vivo.

Co-expression of mouse and rat haemoglobins in interspecific hybrids of mouse and at erythroleukemia cells

A modified technique for cell fusion with lysolecithin-lipid emulsions was used to generate hybrid erythroleukemia cell lines from Friend leukemia mouse cells (FLC) and chemically transformed rat erythroleukemia cells. Chromosome analysis of the hybrid cells showed the presence of both parental genomes even after long culture periods. The hybrids were still able to undergo erythroid differentiation after dimethylsulphoxide (DMSO) stimulation. Analysis of the globin chains from the DMSO-stimulated cells showed that both the rat and the mouse erythroid phenotypes were expressed. This demonstrates the compatibility of the regulatory genetic elements for the control of erythroid differentiation in cell hybrids of erythroleukemic populations from different species.

Biochemical characterization of transformation-specific proteins of acute avian leukemia and sarcoma viruses

The biological and biochemical properties of the transformation-specific proteins of three avian oncornaviruses with different oncogenic potentials were compared, namely the gag-myc protein of the avian myelocytomatosis virus MC29, the gag-erb A protein of the avian erythroblastosis virus AEV, and the gag-fps protein of Fujinami sarcoma virus FSV. These oncogenes were analyzed in transformed fibroblasts that expressed only the transforming proteins but showed no virus replication. Monoclonal antibodies against the viral structural protein p19, which is the N-terminus of the proteins, were used for indirect immunofluorescence, for immunoprecipitation of the proteins from subcellular fractions, and for immunoaffinity column chromatography. With this last method a 3000-fold purification of the proteins was obtained. By indirect immunofluorescence it was shown that the gag-myc protein was located in the nucleus, and bound to DNA after purification. The gag-erb A protein was not nuclear but probably located in the cytoplasm and did not bind to DNA after purification. Neither of the two proteins exhibited protein kinase activity. In contrast, the gag-fps protein did not bind to DNA but showed protein kinase activity after purification. It was not located in the nucleus either.

Isolation of monoclonal antibodies against avian oncornaviral protein p19

For the production of monoclonal antibodies against pp60src and the gag precursor protein Pr76gag, the spleens of mice bearing tumors that had been induced by avian sarcoma virus Schmidt-Ruppin D-transformed cells were used. One hybridoma culture produced antibodies that were directed against the p19 portion of the gag precursor. However, no antibodies directed against pp60src could be detected in any of the hybridoma supernatants. The anti-p19-producing hybridoma culture was cloned twice in soft agar, and a stable clone was used for the production of high-titer ascites fluid in mice. The monoclonal antibodies belonged to the immunoglobulin G subclass 2b. The antibodies precipitated Pr76gag and the processed virion-associated p19, as well as the 75,000-molecular-weight gag fusion protein from avian erythroblastosis virus-transformed bone marrow cells. Also, viral ribonucleoprotein complexes were specifically precipitable, indicating that they contain p19 molecules.

Inducibility of spleen focus-forming virus by BrdUrd is controlled by the differentiated state of the cell

All Friend cells--except thymidine kinase (ATP:thymidine 5'-phosphotransferase, EC 2.7.1.21)-deficient mutants--are highly inducible for the release of biologically active spleen focus-forming virus (SFFV) after exposure to BrdUrd. We studied SFFV production in somatic cell hybrids made between Friend leukemia cells (FLC) and cells expressing various differentiation programs. High inducibility of SFFV and release of constitutive Friend virus (FV) and SFFV are eliminated in all hybrids in which the potential for erythroid differentiation is suppressed. FV release and its induction by BrdUrd are unchanged in hybrids that maintain the expression of erythroid differentiation.