Interaction between chicken anaemia virus and live Newcastle disease vaccine.

Three groups of 150 SPF chickens were spray-vaccinated with live Newcastle disease La Sota-type vaccine (clone 30) at one day of age, and another three groups were NDV spray-vaccinated at 10 days of age. In each of the two series of NDV-vaccinated groups, one group also received at day-old 10(5) TCID50 of chicken anaemia virus (CAV) also and another group 10(5) TCID50 of CAV plus a low dose of virulent Marek's disease virus (MDV). After one week, chickens of the groups which had been NDV-vaccinated and CAV-infected at day-old, with or without MDV, showed severe respiratory distress, conjunctivitis, drooping wings and ruffled feathers. After two weeks, wet and inflamed eyes were observed. After three weeks the respiratory problems were overcome, but the entire group showed retarded growth as compared with the group which had received NDV vaccine only. The 'respiratory sounds' were milder in the chickens NDV-vaccinated at 10 days of age, about 10% of the chickens showing retarded growth. Mortality in CAV-infected chickens which had received NDV vaccine at day-old was above 30% at 4 weeks of age, and between 15 and 20% when NDV had been administered at the age of 10 days, and was 5% in the two NDC vaccine control groups. Decreased haematocrit levels were measured in all four CAV-infected groups at 14 days of age. In serum samples collected for 6 weeks at weekly intervals from chickens of the six groups, no differences were observed between HI antibody titres against NDV virus. Thus, dual infection with CAV and live NDV vaccine did not impair the humoral immune response against attenuated Newcastle disease vaccine.

Chicken anaemia virus influences the pathogenesis of Marek's disease in experimental infections, depending on the dose of Marek's disease virus.

Eight groups of 1-day-old chickens were inoculated with 0, 250, 5000, or 100,000 white blood cells of chickens infected with Marek's disease virus strain K (MDV-WBC). Four of these groups were additionally infected with 10(5) TCID50 chicken anaemia virus (CAV). At day 14 after inoculation, chickens infected with CAV had reduced haematocrit levels, reduced body weights, and depletion of the thymic cortex and bone marrow. Semi-quantitative immunohistochemical examination of nerves and visceral organs was performed at day 28 by immunoperoxidase staining in which a monoclonal antibody specific for leucocytes was used. CAV significantly enhanced the number of lymphoproliferative lesions induced by 5000 MDV-WBC. In contrast, CAV significantly reduced the number of lymphoproliferative lesions induced by 100,000 MDV-WBC. Comparable results were found at day 61 after macroscopic examination of nerves and visceral organs. These findings show that the pathogenesis of MD in experimental infections appears to be enhanced or inhibited by CAV, depending on the dose of MDV.

Inactivation of chicken anaemia virus in chickens by heating and fermentation.

The transmission of pathogenic microorganisms such as viruses by the use of animal products in animal feed constitutes a potential risk to the health of livestock. To reduce the risk, it is necessary to understand the survival of viruses during the processing of animal products to feed-stuffs. Since chicken anaemia virus (CAV) is very resistant to inactivation, we used it as a model for the inactivation of pathogenic viruses during treatment of animal products. It is concluded that fermentation of CAV viraemic tissue did not affect the inactivation of CAV, however, heating at a core temperature of 95 degrees C for 30 min or 100 degrees C for 10 min is sufficient to inactivate CAV. Compared with the conditions for inactivation reported in the literature for other pathogenic viruses, our treatment is more stringent. CAV viraemic chickens are thus suitable as a model to test the heat inactivation of pathogenic viruses.

[Classical fowl plague and milder influenza infections in birds and mammals]. / Klassieke vogelpest en mildere influenza-infecties bij vogels en zoogdieren.

Wild waterfowl are currently considered the largest reservoir of the various haemagglutinin (H) and neuraminidase (N) subtypes of influenza virus. Until now thirteen different H-types and nine different N-types have been detected in these populations. In the first instance, virus transmission from fowl to other animal species and to man is not causing disease problems. However, small changes at the molecular level of a given HN-subtype recently caused a dramatic increase in virulence for chickens. Genes fragments coding for haemagglutinin or neuraminidase can be exchanged between viruses which propagate in the same individual. This phenomenon-'genetic reassortment'-is of major epidemiological significance when it occurs in pigs. New influenza epidemics in the human population consistently originate in areas where waterfowl, pigs and human beings live close together. At the moment, the virological and serological diagnosis of influenza A infections is based ELISAs for antigen and antibody detection. Both ELISAs employ a monoclonal antibody directed against a conserved antigenic determinant of the influenza A nucleoprotein. The use of these tests can simplify the diagnosis of and screening for influenza A infections, particularly in those species which harbour several H- and N-subtypes.

Transcription of the chicken anemia virus (CAV) genome and synthesis of its 52-kDa protein.

This paper describes the expression of the chicken anemia virus (CAV) genome, a recently characterized single-stranded circular-DNA virus of a new type [Noteborn et al., J. Virol. 65 (1991) 3131-3139]. The major transcript from the CAV genome is an unspliced mRNA of about 2100 nucleotides (nt). Its transcription start point and poly(A)-addition site are located at nt 354 and 2317 of the CAV sequence, respectively. In vitro translation experiments provide evidence that the major CAV open reading frame encodes a 52-kDa protein by using the fifth AUG as a start codon of the unspliced CAV mRNA.

Detection of chicken anaemia virus by DNA hybridization and polymerase chain reaction.

A clone containing the complete genome of chicken anaemia virus (CAV) was used in hybridizations with DNA from various field isolates of CAV. CAV DNA from all field isolates was detected in a polymerase chain reaction with oligonucleotides derived from the sequence of the cloned CAV DNA as primers. By way of Southern blot analysis with (32)P-labelled DNA probes derived from cloned CAV DNA, all field isolates were shown to contain DNA molecules of about 2.3 kb, i.e. the size of cloned CAV DNA. In a dot-blot assay it was demonstrated that non-radioactively-labelled cloned CAV DNA hybridized specifically to DNA from field isolates. The cloned CAV DNA is highly similar to the DNA of field isolates, as borne out by restriction-enzyme mapping. We conclude that our cloned CAV genome is representative for CAV in the field. The described PCR and hybridization techniques, may, therefore, be used for research and diagnosis of CAV infections.

Interference of maternal antibodies with the immune response of foals after vaccination against equine influenza.

The purpose of the study was twofold. First, using two groups of 22 foals each, we investigated the extent to which maternal antibodies interfere with the humoral response against equine influenza. The foals were born to mares that had been vaccinated twice yearly against influenza since 1982. Foals of group I were vaccinated three times at early ages (12, 16, and 32 weeks of age), and foals of group II were likewise vaccinated but a later ages (24, 28, and 44 weeks of age). After the first and second vaccinations, neither group showed an increase in antibodies that inhibit haemagglutination. Group II foals, however, had a significantly stronger antibody response against nucleoprotein after the second vaccination than the foals of group I. After the third vaccination, group II foals had a significantly stronger and longer lasting antibody response against haemagglutinin than the foals of group I. However, the antibody response to nucleoprotein was comparable in both groups. Second, the foals of group II were studied to determine the persistence of maternal antibodies directed against a common nucleoprotein and the haemagglutinin of two strains of equine influenza A virus. Biological half-lives of 39, 32, and 33 days were calculated for maternal antibodies directed against haemagglutinin of strains H7N7 Prague and H3N8 Miami, and against the nucleoprotein respectively. Maternal antibody titres at the time of vaccination were closely related to the degree of interference with the immune response. Because even small amounts of maternal antibodies interfered with the efficacy of vaccination, we conclude that foals born to mares vaccinated more than once yearly against influenza virus should not be vaccinated before 24 weeks of age.

Detection of proviral DNA and viral RNA in various tissues early after avian leukosis virus infection.

Using molecular biological techniques, a study was made of the tissue tropism of avian leukosis virus (ALV) early after infection. Two strains of chickens, one with and the other without endogenous viral genes, were infected with ALV of subgroup A immediately after hatching; specimens of nine tissues and blood samples were analyzed at various times thereafter. A polymerase chain reaction (PCR), specific to ALV subgroup A, was used to detect proviral DNA and viral RNA. In situ hybridization was used to confirm the presence of proviral DNA in tissue samples and to calibrate the PCR. The pattern of detection of proviral DNA and of ALV-RNA in the various tissues was similar for both chicken strains. At 2 weeks of age, ALV-RNA was demonstrated in all tissues tested: bursa of Fabricius, thymus, bone marrow, proventriculus, liver, spleen, kidney, muscle, gonads, and blood samples, and at 4 weeks of age all tissues contained proviral DNA. No tropism for a specific tissue was observed early after an ALV infection.

Susceptibility of thymocytes for infection by chicken anemia virus is related to pre- and posthatching development.

To investigate the age-dependent mechanism of susceptibility for chicken anemia virus (CAV) infection, we inoculated embryos and chickens of ages between day 9 of embryonic development and day 28 after hatching with CAV. Chicken embryos inoculated at days 9 and 11 of development showed no CAV-infected cells in the thymus, nor in other lymphoid organs. Many CAV-infected cells were detected in the thymic cortex of all chicken embryos inoculated at days 13 and 16 of development and of all chickens inoculated 1, 3, and 7 days after hatching. All embryos and chickens that contained CAV-infected cells in the thymus also contained CAV-infected cells in the bone marrow, but not in the bursa of Fabricius or the spleen. In chickens inoculated at days 14 and 21, only few CAV-infected cells were detected in the thymus, whereas these cells were not detected in thymi of 28-day-old inoculated chickens. Depletion of the thymic cortex was only detected in chickens inoculated from day 16 of embryonic development till day 21 after hatching. Only hematocrit values of the chickens inoculated 1 and 3 days after hatching were below normal. The rationale for the simultaneous susceptibility of cells of the T-cell lineage and cells of the erythrocyte lineage is discussed. As far as the thymus is concerned, the absence of clinical and microscopical signs of CAV infection in older chickens and the inability of CAV to infect embryos at days 9 and 11 of embryonic development may be caused by a lack of susceptible thymocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of cloned chicken anemia virus DNA that contains all elements for the infectious replication cycle.

Circular double-stranded replication intermediates were identified in low-molecular-weight DNA of cells of the avian leukemia virus-induced lymphoblastoid cell line 1104-X-5 infected with chicken anemia virus (CAV). To characterize the genome of CAV, we cloned linearized CAV DNA into the vector pIC20H. Transfection of the circularized cloned insert into chicken cell lines caused a cytopathogenic effect, which was arrested when a chicken serum with neutralizing antibodies directed against CAV was added. Chickens inoculated at 1 day of age with CAV collected from cell lines transfected with cloned CAV DNA developed clinical signs of CAV. The 2,319-bp cloned CAV DNA contained all the genetic information needed for the complete replication cycle of CAV. The CAV DNA sequence has three partially overlapping major reading frames coding for putative peptides of 51.6, 24.0, and 13.6 kDa. The CAV genome probably contains only one promoter region and only one poly(A) addition signal. Southern blot analysis using oligomers derived from the CAV DNA sequence showed that infected cells contained double- and single-stranded CAV DNAs, whereas purified virus contained only the minus strand. It is the first time that the genome of one of the three known single-stranded circular DNA viruses has been completely analyzed.

Expression of avian leukaemia virus env-gp85 in Spodoptera frugiperda cells by use of a baculovirus expression vector.

We studied the genetic expression of gp85 of avian leukaemia virus (ALV) subgroup A in a baculovirus/insect cell system. 5'terminal sequences of the gag gene were added to precede the ALV gp85 sequence and a stop codon was introduced at the boundary of gp85 and gp37. The resulting construct was then cloned into the baculovirus transfer vector pAcYM1, which contains the polyhedrin promoter of Autographa californica nuclear polyhedrosis virus (AcNPV). Cells of the insect Spodoptera frugiperda (Sf9) were cotransfected with the resulting recombinant transfer vector pAc85 and infectious AcNPV/E2 DNA. After cotransfection, recombinant baculovirus that lacked the polyhedrin gene and expressed gp85 was selected from the supernatant and used to infect Sf9 cells. The expression of the gp85 gene peaked 3 days after infection, but expression products were not released into the culture medium even though the signal peptide had been cleaved. Owing to incomplete N-glycosylation in the insect cells the largest gp85 product had an Mr of only 65,000. In immunofluorescence tests and immunoblots the recombinant gp85 products reacted with polyclonal and monoclonal antibodies directed against ALV gp85 of subgroup A. Chickens inoculated with crude lysates of Sf9 cells infected with gp85-expressing recombinant baculovirus developed antibodies directed against ALV gp85. These antibodies were not capable of neutralizing ALV.

[Transgenic chickens]. / Transgene kippen.

Transgenic mice are produced by retroviral insertion, micro-injection in the early embryo, and recently by transfection of embryonic stem cells. Transgenic chickens were only made by retroviral vectors based on avian leukemia virus (ALV) and reticuloendotheliosis (REV) genomes. A replication-defective retroviral vector is preferentially used because these do not induce infectious virus. Since chickens are lacking endogenous REV sequences, a replication defective REV vector is most useful for practical application. Transgenic disease resistance is most likely obtained by blocking of viral receptors. By this approach recently transgenics with resistance against ALV infection were made at the Regional Poultry Disease Laboratory in East Lansing. Inhibition of virus replication by antisense DNA, which is complementary to viral mRNA, is promising for the future. Considerable research efforts still have to be made, however. Production of biomedical proteins will most likely be the first practical use of transgenic chickens. For the time being, vaccines will be used for the control of infectious diseases. The current live-virus vaccines will be replaced by inactivated (sub-unit) vaccines and thereafter by recombinant DNA vaccines based on viral vectors.

Construction of a bovine-murine heteromyeloma cell line; production of bovine monoclonal antibodies against rotavirus and pregnant mare serum gonadotrophin.

Bovine-murine heteromyeloma cell lines were prepared by fusing lymphoid cells from a bovine leukemia virus (BLV)-infected cow with mouse myeloma cells. Selection of hybrid cell colonies was based on the ratio of bovine and murine chromosomes, the presence of cell-surface immunoglobulins and growth characteristics. First-generation fusion partners were compared for fusion efficiency and the number of antigen-specific antibody-producing clones generated. Hybrid cell colonies that initially secreted antibodies were selected from first-generation heteromyelomas to function as second-generation fusion partners. Although fusion efficiencies for both generations did not differ, the second-generation heteromyelomas yielded a higher number of specific antibody-producing clones. Fusion of hteromyelomas with either lymph node cells or splenocytes indicated that fusion with lymph node cells results in a higher number of specific antibody-producing clones, whereas fusion efficiency was found to be higher with splenocytes. The optimal time intervals between the final booster injection and fusion were found to be 4 days for splenocytes and 7 days for lymph node cells. Finally, the characterization of bovine monoclonal antibodies against bovine rotavirus and pregnant mare serum gonadotrophin and their neutralizing capacities in vitro are described.

An ELISA for detection of antibodies against influenza A nucleoprotein in humans and various animal species.

A double antibody sandwich blocking ELISA, using a monoclonal antibody (MAb) against influenza A nucleoprotein (NP) was developed to detect antibodies against influenza. Collections of serum samples were obtained from human and various animal species. All influenza A subtypes induced antibodies against hemagglutinins and NP. A close correlation between titers of the hemagglutination inhibition (HI) test and the NP-ELISA was seen. Antibodies against influenza NP were demonstrated in serum samples from humans, ferrets, swine, horses, chickens, ducks, guinea pigs, mice, and seals. The serum samples were collected at intervals during prospective epidemiological studies, from experimental and natural infections, and vaccination studies. The decline of maternal antibodies was studied in swine and horses. The NP-ELISA enables rapid serological diagnosis and is suited for influenza A antibody screening, especially in species which harbor several influenza subtypes. The HI and neuraminidase inhibition tests, however, must still be used for subtyping.

In situ detection by monoclonal antibody D-35.1 of cells infected with Marek's disease virus that interact with splenic ellipsoid-associated reticulum cells.

Immuno- and enzyme-histochemical staining procedures were used to investigate in vivo the interaction of Marek's disease virus (MDV) with splenic non-lymphoid cells. The newly developed monoclonal antibody D-35.1, which recognizes all three MDV serotypes, was used to study the localization of MDV at various times after intramuscular inoculation of 1-day-old chicks with MDV strain K. The D-35.1-positive cells were detected in the bursa of Fabricius, spleen, thymus, proventriculus, and cecal tonsils, and the number of chickens showing the cells increased between days 4 and 10. From day 21, the skin of the chickens contained D-35.1-positive feather follicles. The D-35.1 monoclonal antibody did not stain any cells in peripheral blood, nerves, kidney, and gonads at any time. In addition, D-35.1-positive cells were not detected in lymphoproliferative lesions in visceral organs and peripheral nerves. Double staining procedures on serial sections using monoclonal antibody CVI-ChNL-68.2, specific for splenic ellipsoid-associated reticulum cells, revealed that the majority of D-35.1-positive cells were situated in the peri-capillary sheath of reticulum cells at day 10. The sheath of cells detected by monoclonal antibody CVI-ChNL-68.2 was disrupted, and they were clustered around D-35.1-positive cells. These results support the hypothesis that ellipsoid-associated reticulum cells are involved in the early pathogenesis of Marek's disease.

Use of milk samples and monoclonal antibodies directed against BLV-p24 to identify cattle infected with bovine leukemia virus (BLV).

An indirect double-antibody sandwich (IDAS) enzyme-linked immunosorbent assay (ELISA) using milk samples was developed to identify cows infected with bovine leukemia virus (BLV). Two monoclonal antibodies (McAbs) were used. One, which was directed against BLV core protein p24, was used to coat ELISA plates; the other was used to prepare a horseradish peroxidase (HRP) conjugate directed against bovine immunoglobulin. The IDAS-ELISA detected antibodies directed against BLV-p24 in 97% of the milk samples collected from known seropositive cows identified by the agar gel precipitation test (AGTP). Even when milk samples were diluted 1:50, 93% of the seropositive cows were identified. Only 0.43% of the 4000 milk samples collected in The Netherlands reacted nonspecifically. Nonspecific binding disappeared, however, when these samples were diluted 50 times in BLV-negative milk. In a comparative evaluation of BLV test-kits in various European laboratories, our IDAS-ELISA using McAb directed against p24 was one of the most sensitive.

Postnatal development of mucosa-associated lymphoid tissues in chickens.

The postnatal development of chicken mucosa-associated lymphoid tissues of the eyes, lungs, and intestines were investigated with monoclonal antibodies specific for either all leucocytes, B lymphocytes, mononuclear phagocytes, IgM, IgG, or IgA. Attention has been paid to the relation of lymphoid infiltrates with their surrounding mucosae, the segregation into B-cell and T-cell areas, development of germinal centers, and secretory immunoglobulins. Abundant secretory IgM and IgA was detected in the epithelium of the Harderian glands in the orbits, even though they lacked large leucocyte infiltrates with germinal centers. Lymphoid tissues in the mucosae of lungs and intestines developed separate B-cell and T-cell areas. The proventriculus, Meckel's diverticulum, and Peyer's patches generally contained germinal centers from 12 weeks of age on. Because chickens as young as 2 weeks old had germinal centers in bronchus-associated lymphoid tissue and cecal tonsils, these areas were probably highly stimulated by antigens. Isotype-specific monoclonal antibodies were used to detect IgM-, IgG-, and IgA-bearing follicular cells in the same germinal center.

Distribution and function of non-lymphoid cells positive for monoclonal antibody CVI-ChNL-68.2 in healthy chickens and those infected with Marek's disease virus.

Immuno-enzyme histochemistry was used to study the staining pattern and tissue distribution of monoclonal antibody CVI-ChNL-68.2 that specifically reacts with a subset of non-lymphoid cells in healthy chickens and those infected with Marek's disease virus (MDV). Functional characteristics of CVI-ChNL-68.2-positive cells, e.g. antigen uptake, are determined. In the liver CVI-ChNL-68.2 recognizes reticulum cells, whereas in the bursa of Fabricius it detects single cells in the interfollicular connective tissue. In the spleen CVI-ChNL-68.2 reacts selectively with the reticulum cells of the ellipsoid. In some MDV-infected chickens the splenic reticulum cells show a different staining and distribution pattern. Furthermore, the proliferative lesions associated with Marek's disease contain many CVI-ChNL-68.2-positive cells. The possible role of CVI-ChNL-68.2-positive cells in disseminating Marek's disease virus is discussed.

Transient depletion of cortical thymocytes induced by chicken anaemia agent.

Chicken anaemia agent (CAA) causes severe anaemia, loss of body weight, and hypoplasia of thymus at day 14 after inoculation of one-day-old chickens. Several reports have described an enhancement of concurrent infections with f.e. Marek's disease virus, Infectious Bursal Disease virus, and Reovirus. Immunohistochemical methods were used to describe the immunopathological lesions of the thymus that probably form the basis of the immunodeficiency caused by CAA. Monoclonal antibodies and antisera against leucocytes, T lymphocytes, CD4, B lymphocytes, mononuclear phagocytes, MHC class II, and keratin were used. At day 14 after inoculation, the thymic cortex was completely depleted of thymocytes, whereas the medulla was not. T-cell areas in the spleen also lacked T lymphocytes. In contrast the cortex still contained stromal cells with MHC class II molecules and keratin. At day 21, the cortex had completely regenerated and all clinical signs of CAA infection had disappeared. Labelling experiments with BrdU in 4-week-old control chickens demonstrated that 25% of the divided cells was detected in the medulla and 75% in the cortex. The tissue tropism of CAA may, apart from the preference for rapidly dividing cells, be directed by specific cell determinants.