A survey of tick-borne pathogens in dogs and their ticks in the Pantanal biome, Brazil.

Tick and blood samples collected from domestic dogs in the Brazilian Pantanal were tested by molecular methods for the presence of tick-borne protozoa and bacteria. Among 320 sampled dogs, 3.13% were infected by Babesia vogeli (Piroplasmida: Babesiidae), 8.75% by Hepatozoon canis (Eucoccidiorida: Hepatozoidae), 7.19% by Anaplasma platys (Rickettsiales: Anaplasmataceae), and 0.94% by an unclassified Anaplasma sp. In three tick species collected from dogs, the following tick-borne agents were detected: (a) B. vogeli, An. platys and Ehrlichia canis (Rickettsiales: Anaplasmataceae), infecting Rhipicephalus sanguineus sensu lato (Ixodida: Ixodidae) ticks; (b) H. canis, an unclassified Anaplasma sp. and Rickettsia amblyommii (Rickettsiales: Rickettsiaceae), infecting Amblyomma cajennense sensu lato (Ixodida: Ixodidae) ticks, and (c) Rickettsia sp. strain Atlantic rainforest, an emerging human pathogen, infecting Amblyomma ovale ticks. Molecular analysis, based on a mitochondrial gene, revealed that the Am. cajennense s.l. ticks of the present study corresponded to Amblyomma sculptum, a member of the Am. cajennense species complex, and that Rh. sanguineus s.l. belonged to the tropical lineage. Whereas dogs are exposed to a number of tick-borne bacterial and protozoan agents in the Pantanal biome, humans are potentially exposed to infection by spotted fever group rickettsiae (e.g. R. amblyommii and Rickettsia sp. strain Atlantic rainforest) because both Am. sculptum and Am. ovale are among the most important human-biting ticks in Brazil.

Susceptibility of adult chickens, with and without prior vaccination, to challenge with Marek's disease virus.

Marek's disease (MD) outbreaks can occur in previously healthy adult layer or breeder flocks. However, it is not clear whether such outbreaks are caused by recent challenge with highly virulent (vv and vv+) strains of MD virus (MDV; i. e., new infection hypothesis) or by exacerbation of an earlier MDV infection (i. e., old infection hypothesis). To discriminate between these hypotheses, adult White Leghorn chickens of laboratory strains or commercial crosses with or without prior vaccination or MDV exposure were challenged at 18-102 wk of age with highly virulent MDVs, and lesion responses were measured. Horizontal transmission was studied in one trial. Challenge of adult chickens, which were free from prior MDV vaccination or exposure, with highly virulent MDV strains induced transient paralysis or tumors in 60%-100% of 29 groups (mean = 91%), and horizontal spread of virus was detected. The magnitude of the response was similar to that induced by challenge at 3 wk of age. In contrast, comparable challenge of adult chickens, which had been vaccinated or exposed to MDV early in life, induced transient paralysis or tumors in 0%-6% of 12 groups (mean = 0. 5%), although some birds showed limited virologic evidence of infection and transmission of the virus to contacts. The MD responses were influenced by the virulence of the challenge virus strain, and to a lesser extent by virus dose and route of exposure. Strong inflammatory lesions were induced in the brain and nerves of adult specific pathogen-free (SPF) chickens at 9-15 days after infection. The low susceptibility of previously vaccinated and exposed groups to challenge at > or =18 wk of age suggests that late outbreaks of MD in commercial flocks are not likely a result of recent challenge alone and that additional factors could be involved.

Properties of a chicken lymphoblastoid cell line from Marek's disease tumor.

Properties of a chicken lymphoblastoid cell line (MSB-1) from a Marek's disease tumor were studied. The cell line grew well at 41 degrees C in medium RPMI-1640 supplemented with 10% bovine fetal serum and had a doubling time of 8-12 hours. Cells grown in stationary suspension culture did not attach to the vessel and had the morphology of typical lymphoblasts. At 37 degrees C, the cell line grew initially but ceased to divide after several subcultures. In the subcultures maintained for 48-72 hours, 1-2% of the cells produced Marek's disease virus (MDV)-specific intracellular and mambrane antigens and contained herpesvirus particles when examined by the electron microscope. Cocultivation of these cells with duck or chicken embryo fibroblast cultures resulted in transfer of infection and production of microplaques typical of MDV. Peripheral nerve lesions and lymphoid tumors characteristic of Marek's disease were caused by inoculation of susceptible chicks with MSB-1 cells or duck cells infected with strain BC-1 of MDV recovered from the MSB-1 cell line. No specific tumors were produced at the site of inoculation, and infection was readily transmitted to cagemates. Tumors were also produced in the skeletal muscles and seemed to be largely virus induced. MSB-1 cell line was free of C-type virus particles.

Development of cell-mediated immunity to Marek's disease tumor cells in chickens inoculated with Marek's disease vaccines.

Chickens inoculated with herpesvirus of turkeys or with apathogenic or attenuated vaccine strains of Marek's disease virus (MDV) developed a T-cell-mediated immune response to Marek's disease (MD) tumor cells. This immune response was detected in a 4-hour 51Cr-release assay in which effector cells obtained from spleens of vaccinated chickens were reacted with 51Cr-labeled target cells of an MD lymphoblastoid cell line (MSB-1). The cytotoxic effector cells generated by the vaccine viruses had characteristics similar to those noted previously for anti-MSB-1 effector cells generated by MDV. The immune response was specific to MSB-1 cells, because another target cell line (TLT) antigenically unrelated to MSB-1 cells was not lysed by the effector cells nor did the unrelated target cells inhibit the cytotoxicity of effector cells against MSB-1 target in a cold-target inhibition assay. Because MSB-1 cells contain MD tumor-associated surface antigen, we postulated that the immune response detected in the vaccinated chickens may be directed against this antigen and that the antitumor antigen immunity may play a role in the mechanism of vaccine protection against lymphoma development by pathogenic MDV.

Reduced incidence of Marek's disease gross lymphomas in T-cell-depleted chickens.

Chickens of line 7, highly susceptible to Marek's disease (MD), were depleted of T-cells by neonatal thymectomy, total-body gamma-irradiation, and multiple injections with antithymocyte serum. In two replicate experiments, significantly fewer gross lymphomas were present in T-cell-depleted chickens than in intact or in T-cell-depleted, reconstituted hatchmates; these findings provided evidence that T-cells may be the principal target for MD virus (MDV) transformation, T-cell depletion was not complete, and the presence of microscopic lesions in T-cell-depleted chickens was attributed to residual T-cells. Ten lymphomas from intact chickens and 2 lymphomas from a T-cell-depleted chicken were examined for cellular composition. All lymphomas consisted predominantly of T-cells. The results of this and other published studies indicated that T-cells may have a dual role in MD; They may serve as a target for lymphoma formation by MDV and also may participate in immune surveillance against the disease in resistant chickens.

Lymphoid neoplasms in chicken flocks free of infection with exogenous avian tumor viruses.

More than 4,500 breeding female chickens of nine inbred lines maintained under specific-pathogen-free conditions to approximately 500 days of age were studied. Routine monitoring and special assays indicated that they were free of infection by exogenous viruses of the leukosis-sarcoma and the reticuloendotheliosis groups. Some birds were maintained free of Marek's disease (MD) virus infection in plastic isolators, and others were maintained in conventional chicken houses and vaccinated with the herpesvirus of turkeys to prevent the lesions of MD. Ten birds bearing lymphoid tumors were observed in two sublines of one line of chickens known to produce embryos that spontaneously produce Rous-associated virus, type 0 (RAV-O), an endogenous virus of the chicken. Four tumors were found in chickens of one subline maintained free of MD virus infection in isolators. These tumors did not involve the bursa and had some histologic features different from those typical of lymphoid leukosis. Six tumors were found in chickens of the other subline that were vaccinated to prevent MD; these tumors involved the bursa and were typical of lymphoid leukosis but not MD. These results suggest that two types of tumors may have been observed. The fact that DNA extracted from both types of tumors did not contain exogenous lymphoid leukosis virus sequences confirms the virologic evidence that exogenous viruses were not involved. The fact that endogenous viral sequences were not increased in copy number suggests that the endogenous virus RAV-O did not directly induce the tumors. Two birds with tumors not involving the bursa were found alive, and transplantable lymphoid tumors were developed. These tumors were of T-cell origin rather than of bursa cell origin as would be expected of lymphoid leukosis. These are the first reported lymphoid tumors that have been observed in the absence of known exogenous tumor virus infection in chickens. Our evidence suggests that the endogenous virus RAV-O did not play a primary role in the induction of these tumors.

Characteristics of JMV Marek's disease tumor: a nonproductively infected transplantable cell lacking in rescuable Virus.

Cells of the JMV Marek's disease (MD) tumor, originally produced by rapid serial passage of MD lymphoma cells in chickens, were characterized to determine whether they were of host or donor origin and to ascertain certain virus-host cell interrelationships. Differences noted in blood group B surface alloantigens between tumor cells and host lymphocytes indicated a probable nonhost origin (i.e., transplantability) of the tumor. JMV spleen tumors contained predominantly large lymphoblasts bearing MD tumor-associated surface antigen. DNA from JMV tumor cell suspensions hybridized significantly with MD virus cRNA, which indicated that JMV cells contained at least a portion of the MD virus genome. No MD virus was rescued from JMV tumors by techniques suitable for rescue of virus from MD lymphomas. The JMV tumor cells were also devoid of MD virus-specific antigens. These properties differed markedly from those of MD lymphoma cells and make the JMV tumor cell a unique, potentially valuable, tool for further study of oncogenic herpesvirus infection and tumor immunity in the chicken.

A phosphonoacetate-resistant mutant of herpesvirus of turkeys.

A phosphonoacetate (PA)-resistant mutant of the herpesvirus of turkeys (HVT) was isolated and characterized. The mutant of HVT resistant to PA (HVTpa) replicated in duck embryo fibroblast (DEF) culture in media containing 300 microgram PA/ml, whereas the replication of the wild type of HVT (HVTwt) was completely inhibited in DEF culture in media containing 100 microgram PA/ml. The HVTpa was distinct from the HVTwt in plaque morphology, but was indistinguishable antigenically and showed in vitro temperature sensitivity at 41 degrees C (3741 degrees C efficiency of replication was about 5). It replicated poorly in chickens and failed to provide complete protection against challenge with Marek's disease virus (MDV). The HVTpa-induced DNA polymerase had an apparent inhibition constant for PA, an apparent inhibition constant for pyrophosphate, and an apparent Michaells constant for dCTP about 10, 2, and 2.5 times, respectively, greater than the constants for the HVTwt-induced enzyme and was also more thermolabile.

Oncogenesis by Marek's disease herpesvirus in chickens lacking expression of endogenous (gs, chick helper factor, Rous-associated virus-O) and exogenous avian RNA tumor viruses.

Chickens free of exogenous avian leukosis virus (ALV) infection, replicating endogenous ALV (Rous-associated virus-O), gs antigen, and chick helper factor were fully susceptible to induction of Marek's disease (MD) by ALV-free MD viruses. Dual infection with Rous-associated virus-2 and MD virus did not significantly alter the character of the MD lesions. Thus exogenous ALV infection was not requisite for MD virus-induced oncogenesis. Although participation of endogenous RNA tumor virus genes in MD lesion induction could not be excluded, expression of such genes in MD tumors as gs antigen was not established.

Low oncogenic potential of avian endogenous RNA tumor virus infection or expression.

Of chickens either spontaneously producing or exogenously infected in ovo with Rous-associated virus, type O (RAV-O), an endogenous virus of the chicken, only 1 died with lymphoid leukosis (LL), the most common neoplasm associated with the leukosis-sarcoma virus group. Because the chickens were not kept in strict isolation, it could not be assumed that the one LL was induced by RAV-O. In contrast, RAV-1-infected chickens from the same lines had a high incidence of LL and other neoplasms. Over 800 chickens of several inbred lines were maintained in plastic isolators free of exogenous avian leukosis-sarcoma virus infection for from 500 to nearly 1,000 days of age. No LL was observed, even though some lines are known to produce RAV-O spontaneously or to express inherited gs antigen. Three neoplasms of unknown etiology were observed, but none generally associated with leukosis virus infection. We concluded that avian endogenous virus expression had little, if any, oncogenic potential, and that exogenous avian leukosis viruses were responsible for most naturally occurring neoplasms.

Natural mechanisms of controlling lymphotropic herpesvirus infection (Marek's disease) in the chicken.

Four categories of natural resistance phenomena against Mareks disease in chickens, i.e., maternal antibody, age resistance, genetic resistance, and natural immunization, are described. In nature, these forms of resistance probably act in concert through comlex interrelationships. The mechanisms are not well understood but include humoral immunity (maternal antibody), cell-mediated immunity, and possibly other mechanisms. The possible role of newly discovered tumor-specific antigens in cell-mediated immunity against Marek's disease lymphomas is discussed.

The effect of B-cell immunosuppression on age-related resistance of chickens to Marek's disease.

Chickens were bursectomized by cyclophosphamide treatment at hatching. At 8 or 9 weeks of age, bursectomized and unbursectomized hatchmates, free from prior infection, were challenged with pathogenic Marek's disease virus. Oncogenicity of the virus inoculum was confirmed by inoculating 1-day-old susceptible chickens. At the time of virus challenge, blood cells from the cyclophosphamide-treated chickens were able to mount a vigorous graft-versus-host reaction in allogeneic embryos. This ability indicated that the thymus function was intact. There were no significant differences in Marek's disease response of bursectomized and unbursectomized chickens, in spite of a severe defect in the bursa-dependent functions in the bursectomized chickens. Some bursa-deficient chickens had non-proliferating, presumably regressing lesions in peripheral nerves. Because these lesions lacked plasma cells, it was concluded that the plasma cell may not play a functional role in recovery from Marek's disease.

Retrovirus insertion into herpesviruses.

Recent studies have indicated that retroviruses can integrate into and mutate the genomes of herpesviruses during co-infection. This interaction has the potential to change the host range and pathogenicity of both viruses and result in novel infectious agents and diseases. This phenomenon also allows genetic material to be exchanged between these viruses and their hosts.

Genetic mapping of quantitative trait loci affecting susceptibility to Marek's disease virus induced tumors in F2 intercross chickens.

Marek's disease (MD) is a lymphoproliferative disease caused by the MD virus (MDV), which costs the poultry industry nearly $1 billion annually. To identify quantitative trait loci (QTL) affecting MD susceptibility, the inbred lines 6(3) (MD resistant) and 7(2) (MD susceptible) were mated to create more than 300 F2 chickens. The F2 chickens were challenged with MDV JM strain, moderately virulent) at 1 wk of age and assessed for MD susceptibility. The QTL analysis was divided into three stages. In stage 1, 65 DNA markers selected from the chicken genetic maps were typed on the 40 most MD-susceptible and the 40 most MD-resistant F2 chickens, and 21 markers residing near suggestive QTL were revealed by analysis of variance (ANOVA). In stage 2, the suggestive markers plus available flanking markers were typed on 272 F2 chickens, and three suggestive QTL were identified by ANOVA. In stage 3, using the interval mapping program Map Manager and permutation tests, two significant and two suggestive MD QTL were identified on four chromosomal subregions. Three to five loci collected explained between 11 and 23% of the phenotypic MD variation, or 32-68% of the genetic variance. This study constitutes the first report in the domestic chicken on the mapping of non-major histocompatibility complex QTL affecting MD susceptibility.

Avian leukemias and lymphomas: interplay between retroviruses and herpesviruses.

Avian leukemias and lymphomas are caused primarily by retroviruses and herpesviruses. The protooncogenes activated by avian retroviral insertions in B & T-cell lymphomas will be summarized, with discussion on a new common insertion site, bravo, associated with RAV-O LTR insertion. Two novel interactions between avian retroviruses and Marek's disease herpesvirus (MDV) will be described: one involves direct interactions between putative viral oncoproteins and the other integrative recombination between these two viruses.

Powder pattern recoupling at 10 kHz spinning speed applied to cellulose.

Effective powder pattern recoupling by pi-pulses at spinning speeds up to 10kHz has been introduced. In a 2D experiment, the static chemical shift spectra of the indirect dimension were separated by the isotropic values of the direct dimension. Sufficient high spinning speeds ensured optimal exploitation of spectral intensities. This experiment was used to extract the 13C chemical shift tensor values of native Cellulose I and regenerated Cellulose II.

Reduction of horizontal transmission of avian leukosis virus subgroup J in broiler breeder chickens hatched and reared in small groups.

Transmission of avian leukosis virus, subgroup J (ALV-J), from donor chickens inoculated as embryos to simulate congenital infection to uninfected hatchmates was studied in two strains of commercial broiler breeder chickens. Chicks of two commercial lines free of ALV-J became infected when hatched (1/2 lots positive) or reared (8/8 lots positive) in direct physical contact with ALV-J-infected donors. Infection also occurred when chicks were exposed in the hatchery to ALV-J-infected donors by cloacal swab transfer (2/2 lots positive), needle transfer during subcutaneous inoculation (2/2 lots positive), or ingestion of infected meconium (2/2 lots positive). However, transmission was delayed or prevented by wire partitions in the hatcher and rearing of small groups in cubicles, and rarely (1/10 lots positive) resulted from short-term direct or indirect contact. In a simulated field test, a flock of 503 broiler breeder chickens with an initial embryo infection rate of 4.6% was hatched and reared as 48 small groups to 4 weeks of age. Groups were tested at hatch and at 3 weeks, and 14 infected groups were eliminated. This flock tested negative for ALV-J infection from 4 to 32 weeks and did not transmit infection to progeny or develop tumours. A control group of 377 chickens with a similar initial infection rate was hatched and reared as a single group. This control flock transmitted virus to 5.7% of its progeny and about 5% of the hens developed tumours. The small-group hatching and rearing practices employed in these studies allowed for the accurate identification and removal of groups containing chickens infected prior to hatching and prevented horizontal transmission of ALV-J between uninfected and infected groups for at least 4 weeks. More importantly, application of these procedures successfully eradicated ALV-J in a single generation under laboratory conditions. This suggests that similar procedures could be a valuable adjunct to virus eradication programmes in the field.

Characterization and experimental reproduction of peripheral neuropathy in White Leghorn chickens.

A clinical neurological syndrome termed peripheral neuropathy (PN) that resembles Marek's disease (MD) occurred at low frequency in a commercial layer strain for several years. Study of chickens from six field cases showed that the PN syndrome could be distinguished pathologically from MD on the basis of several factors, including onset as early as 6 weeks, presence of B-type but not A-type lesions in peripheral nerves, and absence of visceral lymphomas. Serotype 1 MD virus could not be isolated from blood from any chicken or demonstrated in tissues by histochemistry or polymerase chain reaction assays. Moreover, the syndrome was not prevented by MD vaccination, either in the field or in laboratory trials. PN was induced in 3 to 54%of commercial line chickens inoculated at 1 or 6 days of age with whole blood or buffy coat cells from clinically affected donor chickens. Sonicated cells also induced PN, but plasma was ineffective. Chickens did not develop PN if reared in isolators without cellular transfer or when vaccinated solely against MD. However, PN was observed in 9% of 57 B*2/*19 commercial chickens reared in isolators following vaccination against MD, infectious bursal disease, Newcastle disease and infectious bronchitis, suggesting that common vaccines may predispose chickens to PN. The data confirmed a strong influence of the major histocompatibility complex (B-complex) on both naturally occurring and experimentally induced PN with the B*19 haplotype conferring susceptibility compared with other alleles. It is postulated that PN may represent an autoimmune reaction to nerve tissue that may result from response to a combination of common vaccines. These studies confirmed that PN is distinct from MD, provided criteria for its differential diagnosis, identified strategies for its control, and established a model for its experimental induction.

Differential attenuation of the induction by Marek's disease virus of transient paralysis and persistent neurological disease: a model for pathogenesis studies.

Since different biological characteristics of Marek's disease virus (MDV) are attenuated at different passage levels in cell culture, an analysis of attenuation times provides, in theory, a model for establishing the presence or absence of relationships between characteristics, thus providing a basis to link them to genetic changes in the causative virus. We have used this model to better understand the pathogenesis of the central nervous system infection as well as to evaluate the relationship of clinical neurological disease to various other parameters of MDV infection. Inoculation of 15 x7 crossbred chickens with strain 648A of very virulent plus MDV at different passage levels (between 10 and 100) showed that two neurological syndromes (transient paralysis (TP) and persistent neurological disease), were attenuated at different passage levels. While strain 648A lost the ability to induce TP between 30 and 40 passages in chicken embryo fibroblast cultures, an event closely related with all parameters of MDV infection involving viral replication (early cytolytic infection in lymphoid organs and viral replication in the feather follicle epithelium), the ability to induce persistent neurological disease was lost between 80 and 90 passages in chicken embryo fibroblasts, coincident with the loss of neoplastic lesions in peripheral nerves and other visceral organs. These data strongly suggest that transient paralysis and persistent neurological disease are unrelated and differently regulated. Moreover, comparison of brain changes induced by strain 648A at passage level 30 (TP) and at passage level 40 (no TP) also contributed to a better understanding of which brain alterations are associated with the onset of TP. The use of viruses at different passage levels with varying degrees of attenuation is presented as a useful tool for studying pathogenesis of MDV infection.

The immunodominant proteins of reticuloendotheliosis virus.

The antigenic profiles of three REV prototype strains, CSV, SNV and REV-T and eight Israeli isolates were analysed by SDS-PAGE and immunoblotting with convalescent chicken serum, three mAbs, 11A25, 11C237 and 11C100, a rabbit antiserum to REV-T whole virus (Cui et al., 1986) and a rabbit antiserum to REV-A p30 gag protein (Tsai et al., 1985). Under both reducing (+DTT) and non-reducing conditions of SDS-PAGE, a major immunodominant 75-100 kDa band was shared by all strains examined. In contrast to the chicken serum that recognized both continuous and discontinuous epitopes on the 75-100 kDa band of all the isolates, the mAbs and the two rabbit sera behaved otherwise. Only the DTT-resistant epitopes on the 75-100 kDa band of REV-T were recognized by the rabbit antisera and the mAb 11C237, and only the DTT-labile epitopes of REV-T 75-100 kDa antigen were detected by mAb 11C100. The two mAbs 11A25 and 11C237 detected discontinuous epitopes of all the strains except SNV, while the rabbit antisera recognized the discontinuous epitopes on the 75-100 kDa band of all the 11 strains. The rabbit antisera and mAb 11C237 detected additional lower molecular weight proteins and the mAb 11C237 also detected three proteins of high molecular weight under non-reducing conditions only. The p30 antiserum detected the low molecular weight proteins demonstrating their gag gene-encoded identity. From these results we conclude that the major immunogen of REV is the 75-100 kDa protein that contains both continuous and discontinuous epitopes. With this panel of antibodies the eight new isolates appeared to belong antigenically to REV subtype 3 (Chen et al., 1987).