VSV Pseudotype Particles with the Coat of Avian Myeloblastosis Virus

PSEUDOTYPES of vesicular stomatitis virus (VSV) with the coat of avian myeloblastosis (AMV) or murine leukaemia viruses—VSV(AMV) and VSV(MLV)—can be produced by growing VSV in chick cells preinfected with AMV or in mouse cells preinfected with MLV¹. The VSV particles carrying their own neutralization antigen and double-neutralizable particles may be inactivated with antiserum against VSV. The surviving pseudotypes possess neutralization, host-range and interference specificities corresponding to the tumour virus donating their coat. It has also been shown that a conditional lethal mutant of VSV in which a structural protein is affected is complemented under restrictive conditions with AMV. This mutant, ts-45, when complemented with AMV again predominantly produces the pseudotype VSV(AMV).     

Cell surface labelling of mononuclear cells with antisera associated to turnip yellow mosaic virus or alphalpha mosaic virus particles. A freeze-etch study

Synopsis Turnip yellow mosaic virus (TYMV) and alphalpha mosaic virus (AMV) were used as immuno-electron microscopical markers to detect cell surface receptors on mononuclear cells in freeze-etch replicas. TYMV particles were conjugated with vacuum-distilled glutaraldehyde to rabbit IgG anti-mouse immunoglobulins (TYMV-RAMIg conjugate) or to rabbit IgG anti-mouse antigen (TYMV-RAMTh conjugate). B-lymphocytes incubated with TYMV-RAMIg conjugate showed either randomly distributed particles or patches of virus particles on the etched surface of the cell membrane. Mouse thymocytes incubated with TYMV-RAMTh conjugate, however, showed only a random distribution of the virus particles. Human mononuclear cells incubated with rabbit IgG anti-AMV and AMV for the demonstration of the receptors for the Fc fragment of IgG showed the oblong shape of the AMV particles on the etched cell membrane. Fc receptors were either randomly distributed or aggregrated into patches. It is concluded that both types of virus particles are useful markers for the demonstration of membrane receptors in freeze-etch replicas of labelled cells.     

Incorporation of Precursors into Ribonucleic Acid, Protein, Glycoprotein, and Lipoprotein of Avian Myeloblastosis Virions

Freshly explanted leukemic myeloblasts produce avian myeloblastosis virus (AMV) at a constant rate without any obvious cytopathic effect; therefore, subviral components are continually synthesized at a steady rate. The incorporation of various radioactive precursors into virions was monitored by determination of radioactivity in purified virus after density equilibrium sedimentation in preformed sucrose gradients. The kinetics of incorporation of (3)H-uridine have shown that there is an average time interval of 3 to 4 hr (half-life) between the time viral ribo-nucleic acid (RNA) is synthesized and the time it is released as a mature virus particle; this represents the average time interval spent by AMV-RNA in an intracellular pool. Studies with (14)C-phenylalanine have revealed that some protein synthesis takes place at or near the cell surface immediately prior to maturation and release of virus. (14)C-glucosamine also appears to be incorporated into the outer viral envelope shortly before maturation. On the other hand, there is an average lag of about 16 to 20 hr before (14)C-ethanolamine incorporated into intracellular lipoprotein appears in free virions; this probably reflects the kinetics of replacement of cellular surface membrane. Actinomycin D inhibits AMV-RNA within 30 min but permits the maturation of AMV to continue for at least 2 hr. AMV released in the presence of actinomycin D contains AMV-RNA synthesized before the addition of the drug.     

Characterization of the hematopoietic target cells of AEV, MC29 and AMV avian leukemia viruses

The hematopoietic target cells of the three prototype strains of replication defective avian leukemia viruses (DLVs) were studied, using a newly developed, quantitative in vitro transformation assay. Our results show that the target cells of avian erythroblastosis virus (AEV) belong to the erythroid lineage while those of myelocytomatosis virus 29 (MC29) and avian myeloblastosis virus (AMV) belong to the myeloid lineage. As judged from suicide experiments using BUdR incorporation and irradiation with visible light, a higher proportion of AEV- and AMV-target cells are in cycle than MC29-target cells. Using differentiation specific antisera directed against cell surface antigens, we could demonstrate that the target cells of AEV express erythroblast-specific antigen(s) and less intensively erythrocyte-specific antigen(s), while those of MC29 and AMV express myeloblast-specific antigen(s). In addition, MC29-target cells express macrophage-specific antigen(s). None of the AEV-target cells are adherent or phagocytic, while a small proportion of the AMV-target cells are adherent and about half of the MC29-target cells are both adherent and phagocytic. Our results support the concept that DLVs specifically transform certain types of committed erythroid and myeloid progenitor cells. The target cells of AEV and AMV appear to resemble the respective transformed cells in their state of differentiation, whereas those of MC29 appear to be more immature than the corresponding transformed cells.     

Amphiphilic properties of the avian myeloblastosis virus major glycoprotein, gp 80

The major glycoprotein (gp 80) from avian myeloblastosis virus (AMV) displays significant lipophilic properties, as shown by its strong interactions with acetylated uncharged decylamino agarose in hydrophobic chromatography. In effect, release from binding was achieved only by the added presence of a polarity reducing agent (ethylene glycol) and the strong anionic detergent sodium dodecyl sulfate. The hydrophobic behavior of the glycoprotein, coupled to the high content of hydrophilic carbohydrates, indicates its amphiphilic character. Confirmation of the amphiphilic nature of the AMV gp 80 was obtained by charge shift electrophoresis and crossed hydrophobic interaction immunoelectrophoresis. In both instances, the electrophoretic behavior of the glycoprotein was dependent on the presence of detergents. The AMV gp 80 displays the properties of integral membrane proteins.     

Serological Analysis of the Deoxyribonucleic Acid Polymerase of Avian Oncornaviruses II. Comparison of Avian Deoxyribonucleic Acid Polymerases

Monospecific antiserum prepared against the isolated deoxyribonucleic acid (DNA) polymerase of avian myeloblastosis virus (AMV) neutralized the endogenous ribonucleic acid-instructed DNA polymerase activity of detergent-disrupted virus. The viral polymerase was serologically unrelated to the seven major structural polypeptides of AMV. Furthermore, the viral enzyme was distinguished from normal cellular DNA polymerases by serological criteria; thus, antiserum against the viral enzyme neutralized its homologous antigen but not normal cellular DNA polymerases. Neutralization by antibody of viral DNA polymerase activity was observed with all avian leukemia-sarcoma viruses tested, irrespective of viral antigenic subtype. The DNA polymerase activity of avian reticuloendotheliosis virus, and of a variety of mammalian oncornaviruses, was not neutralized by antisera against the AMV polymerase. Immunological analysis of the RSValpha(O) mutant, which is deficient in DNA polymerase activity, shows this mutant to lack demonstrable polymerase antigen. Viral polymerase was identified by immunofluorescence as a cytoplasmic constituent in virus-producing chicken cells; polymerase antigen was not detected in uninfected (gs(-)) chicken cells.     

Flow cytometric analysis of tobacco and cowpea protoplasts infected in vivo and in vitro with alfalfa mosaic virus

Immunofluorescence flow cytometry was used to study the distribution of viral antigen in protoplast populations. Protoplasts were isolated from healthy and alfalfa mosaic virus (AMV) infected tobacco leaves (designated in vivo infected). Furthermore isolated tobacco and cowpea protoplasts were infected in vitro with AMV. The FITC-conjugated antibodies could penetrate formaldehyde fixed protoplasts. The flow cytometric measurements were rapid and reproducible. Comparable immunofluorescence patterns were found for all infected samples (per sample 10⁴ protoplasts were measured). Infectious virus could only be detected in in vivo infected tobacco protoplasts and in in vitro infected cowpea protoplasts.     

Surface antigens of Proteus mirabilis revealed by electroblotting from sodium dodecyl sulphate-polyacrylamide gels

Western Blotting of whole cell preparations of three strains of Proteus mirabilis after separation by electrophoresis on SDS-polyacrylamide gels revealed a complex pattern of antigens. Similar antigen profiles were obtained with isolated outer membranes indicating that the majority of cell surface antigens are located in the outer membrane. Major outer membrane proteins were strongly antigenic and cross-reactive. The highly immunogenic flagella were detected in whole cell preparations and visible in isolated outer membranes. Whereas the protein and flagellar antigens were cross-reactive, lipopolysaccharide (LPS) could only be detected as immunoreactive material using homologous antisera for each strain. The LPS appeared as two broad bands (high and low Mr, respectively) in immunoblots of whole cells, isolated outer membranes and purified LPS. However, isolated LPS could be resolved into multiple sharp bands when 4 M urea was included in the gel system. These discrete bands are assumed to represent differing O antigen chain lengths of the LPS as reported for other Gram-negative organisms.     

Use of protein A to improve sensitisation of latex particles with antibodies to plant viruses

Protein A-coated latex (PAL) was compared with uncoated latex (L) for sensitisation with antibodies to five plant viruses: apple mosaic virus (ApMV), arabis mosaic virus (AMV), plum pox virus (PPV), potato virus Y ordinary strain (PVY°) and prunus necrotic ringspot virus (NRS V). A range of globulin concentrations was used with each antiserum and detection end points determined in serial dilutions of infective sap. When sensitised with antibodies to ApMV, PAL detected ApMV readily, whereas L did not. When sensitized with antibodies to PVY° and AMV, PAL gave higher detection end points than L. However, PAL gave little increase in sensitivity with the antisera to PPV and NRSV. Non-specific aggregation of latex, which sometimes occurred in very dilute sap with PAL, could be dispersed by adding 0.02% Tween-20 to the extraction buffer. Globulins of PVY° and AMV could be used at higher dilutions with PAL than with L, giving a saving in antiserum. Both types of latex sensitised with PVY° antibody globulins readily detected the tobacco veinal necrosis and C strains of this virus.     

Transformation of Brown Leghorn chicken embryo fibroblasts by avian myeloblastosis virus proviral DNA.

Brown Leghorn chicken embryo fibroblasts were transfected with a mixture of avian myeloblastosis virus (AMV) and myeloblastosis-associated virus type 1 (MAV1) proviral DNA purified from lambda-Charon 4A recombinant clones. A transformed cell line (T1AM) able to grow without anchorage in semisolid medium was obtained. The presence of both proviral AMV and MAV sequences was detected in T1AM DNA by hybridization with v-myb- and MAV1-specific probes. Altered AMV and MAV1 proviral genomes were found in T1AM genome. Characterization of the RNA species expressed in transformed cells showed that in addition to a 2.5-kilobase (kb) putative subgenomic v-myb-specific RNA, three other myb-containing RNAs (9.4, 8.4, and 7.0 kb) were present in T1AM cells. No AMV genomic RNA was detected. Also, a new 5.0-kb MAV1-specific RNA species was expressed in transformed cells in addition to MAV1 genomic RNA species (7.8 kb). No infectious AMV virions are released by T1AM cells. Chicken embryo fibroblasts infected by T1AM-released virions contained and expressed all MAV1 sequences detected in T1AM transformed cells but did not express any transformation parameter. These results indicated that the presence of AMV proviral sequences in T1AM cells is responsible for their transformed phenotype.     

Expression of oncornavirus antigens in peripheral leucocytes of patients with chronic myeloid leukaemia.

Peripheral leucocytes from 16 patients with chronic myeloid leukaemia (CML) were examined for the presence of oncornavirus p30 antigens by indirect cytoplasmic immunofluorescence. The leucocytes of 12 patients who could be kept in balance by chemotherapy proved to be negative or contained the p30 antigen of mammalian endogenous oncornaviruses as the only viral antigen. In the leucocytes of four patients being in blastoid crisis, an antigen related to the p30 antigen of mammalian leukaemia-sarcoma viruses was detected. In five of six patients decrease in sensitivity to chemotherapy, or blastoid crisis, was preceded by expression of leukaemia-sarcoma virus p30 antigen(s). Leucocytes from 15 CML patients kept in balance by chemotherapy and those from seven being in blastoid crisis, were examined by indirect membrane immunofluorescence for the presence of antigen(s) related to the gp70 antigen of the simian and murine leukaemia-sarcoma virus. All tests proved to be negative.     

Human cytomegalovirus-induced immediate early antigens: analysis in sodium dodecyl sulfate-polyacrylamide gel electrophoresis after immunoprecipitation.

Immediate early antigen (IEA) induced in human lung fibroblasts by human cytomegalovirus was characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis after immunoprecipitation with IEA-positive human sera. Two polypeptides of 76,000 daltons (76K) and 82K were detectable within 90 min after infection. Polypeptides of similar molecular weight were also found in immunoprecipitates of human cytomegalovirus-infected cells nonpermissive for virus replication. IEA is located within the nucleus, although some of the 76K material appears to be located on the outer nuclear membrane. Raising salt concentrations in the extraction buffer increased antigen extraction. The contribution of these IEA polypeptides to IEA nuclear fluorescent staining is discussed.     

Helical disposition of proteins and lipopolysaccharide in the outer membrane of Escherichia coli

In bacteria, several physiological processes once thought to be the products of uniformly dispersed reactions are now known to be highly asymmetric, with some exhibiting interesting geometric localizations. In particular, the cell envelope of Escherichia coli displays a form of subcellular differentiation in which peptidoglycan and outer membrane proteins at the cell poles remain stable for generations while material in the lateral walls is diluted by growth and turnover. To determine if material in the side walls was organized in any way, we labeled outer membrane proteins with succinimidyl ester-linked fluorescent dyes and then grew the stained cells in the absence of dye. Labeled proteins were not evenly dispersed in the envelope but instead appeared as helical ribbons that wrapped around the outside of the cell. By staining the O8 surface antigen of E. coli 2443 with a fluorescent derivative of concanavalin A, we observed a similar helical organization for the lipopolysaccharide (LPS) component of the outer membrane. Fluorescence recovery after photobleaching indicated that some of the outer membrane proteins remained freely diffusible in the side walls and could also diffuse into polar domains. On the other hand, the LPS O antigen was virtually immobile. Thus, the outer membrane of E. coli has a defined in vivo organization in which a subfraction of proteins and LPS are embedded in stable domains at the poles and along one or more helical ribbons that span the length of this gram-negative rod.     

Persistence of genomes of both herpesvirus of turkeys and Marek's disease virus in a chicken T-lymphoblastoid cell line

A cell line tentatively designated as MDCC-BO1(T), was established from spleen cells of an apparently healthy chicken inoculated with herpesvirus of turkey (HVT). BO1(T) cells were T lymphoblastoid cells and the more than 95% of them had Marek's disease (MD) tumor-associated surface antigen (MATSA). However, no viral internal antigens or membrane antigens could be demonstrated in them by immunofluorescence tests using chicken anti-HVT and -MD virus (MDV) sera. The virus could be rescued from BO1(T) cells by co-cultivation with chick embryo fibroblasts (CEF). The DNA of the rescued virus was characterized as HVT DNA by its sedimentation profile in a neutral glycerol gradient and its endonuclease Hind III cleavage-pattern. Ultrastructural studies on CEF infected with the rescued virus revealed the presence of HVT-like virions. However, DNA-DNA reassociation kinetics showed that the BO1(T) cells contained a few copies of NVT and also MDV genomes.     

Quantitative Determination and Location of Newly Synthesized Virus-Specific Ribonucleic Acid in Chicken Cells Infected with Rous Sarcoma Virus

A sensitive and quantitative nucleic acid hybridization assay for the detection of radioactively labeled avian tumor virus-specific RNA in infected chicken cells has been developed. In our experiments we made use of the fact that DNA synthesized by virions of avian myeloblastosis virus in the presence of actinomycin D (AMV DNA) is complementary to at least 35% of the sequences of 70S RNA from the Schmidt-Ruppin strain (SRV) of Rous sarcoma virus. Annealing of radioactive RNA (either SRV RNA or RNA extensively purified from SRV-infected chicken cells) with AMV DNA followed by ribonuclease digestion and Sephadex chromatography yielded products which were characterized as avian tumor virus-specific RNA-DNA hybrids by hybridization competition with unlabeled 70S AMV RNA, equilibrium density-gradient centrifugation in Cs(2)SO(4) gradients, and by analysis of their ribonucleotide composition. The amount of viral RNA synthesized during pulse labeling with (3)H-uridine could be quantitated by the addition of an internal standard consisting of (32)P-labeled SRV RNA prior to purification and hybridization. This quantitative assay was used to determine that, in SRV-infected chicken cells labeled for increasing lengths of time with (3)H-uridine, labeled viral RNA appeared first in a nuclear fraction, then in a cytoplasmic fraction, and still later in mature virions. This observation is consistent with the hypothesis that RNA tumor virus RNA is synthesized in the nucleus of infected cells.     

Incidence and Control of Necrotic Leaf Mosaic Caused by Arabis Mosaic Virus in Lilium tigrinum splendens in the Netherlands

Necrotic mosaic on leaves and ring spots on bulb scales of Lilium tigrinum splendens, can be caused by arabis mosaic virus (AMV). Primarily infected bulbs can show spongy roots and large necrotic areas on creamy coloured bulb scales. Consecutive series of plants replanted for monthly periods in infested soil were mostly infected by AMV at a high rate (70%) throughout the year. Very low or undetectable numbers of Xiphinema diversicandatum, nematodes in soil dilution experiments infected lilies very efficiently (50–70 %). In general, soil disinfestation with dichloropropene, dazomet, methylbromide, and other disinfectants were variably fairly effective, particularly when yellow crocus among which couch was abundant, was previously grown for two years. The influx of AMV infected material into the soil was assumed to increase the number of AMV-carrying nematodes, and may be one cause of the failure of soil disinfestation. A survey of AMV infested soil in lily-growing regions in The Netherlands indicated its occurrence in a few fields only. Complex control measures applicable under growers' conditions, in addition to the variably effective soil disinfestation, are indicated.