Chicken hepatomegaly and splenomegaly associated with novel subgroup J avian leukosis virus infection.

BACKGROUND: Subgroup J avian leukosis virus (ALV-J) is an oncovirus which can induce multiple types of tumors in chicken. In this report, we found novel ALV-J infection is closely associated with serious hepatomegaly and splenomegaly in chicken. CASE PRESENTATION: The layer chickens from six flocks in Jiangsu province, China, showed serious hemoperitoneum, hepatomegaly and splenomegaly. Histopathological results indicated focal lymphocytic infiltration, cell edema and congestion in the liver, atrophy and depletion of lymphocyte in the spleen. Tumor cells were not detected in all the organs. avian hepatitis E virus (aHEV), which is thought to be the cause of a very similar disease, big liver and spleen disease (BLS), was not detected. Other viruses causing tumors or liver damage including Marek's disease virus (MDV), reticuloendotheliosis virus (REV), fowl adenovirus (FAdV) and chicken infectious anemia virus (CIAV) were also proved negative by either PCR or RT-PCR. However, we did detect ALV-J in those chickens using PCR. Only novel ALV-J strains were efficiently isolated from these chicken livers. CONCLUSIONS: This is the first report that chicken hepatomegaly and splenomegaly disease was closely associated with novel ALV-J, highlighting the importance of ALV-J eradication program in China.

Pathologic Characterization of Coinfection with Histomonas meleagridis, Marek's Disease Virus, and Subtype J Avian Leukosis Virus in Chickens.

Histomonas meleagridis is a trichomonad protozoan parasite that can cause an important poultry disease known as histomoniasis; Marek's disease virus (MDV) and subtype J avian leukosis virus (ALV-J) usually cause avian oncogenic diseases. Although these diseases have been reported in a single pathogen infection, information about their coinfection is scarce. This study reports a naturally occurring case of coinfection with H. meleagridis, MDV, and ALV-J in a local chicken flock at the age of 150 days. Necropsy revealed necrosis and swelling in the liver and spleen. Histologic analysis showed large areas of mild to severe necrosis of hepatocytes, with numerous intralesional trophozoites of H. meleagridis by H&E and periodic acid-Schiff staining; H&E staining showed pleomorphic and neoplastic lymphoid tumor cells in the liver and myeloid cells with eosinophilic cytoplasmic granules in the spleen. Coexpression of MDV and ALV-J antigens was detected in the liver by fluorescence multiplex immunohistochemistry staining. The 18S rRNA gene of H. meleagridis, meq gene of MDV, and gp85 gene of ALV-J were identified in mixed liver and spleen tissues by PCR and sequencing, respectively.

Reporte de caso­Caracterización patológica de la coinfección con Histomonas meleagridis, el virus de la enfermedad de Marek y el virus de la leucosis aviar subtipo J en pollos Histomonas meleagridis es un parásito protozoario tricomonial que puede causar una enfermedad avícola importante conocida como histomoniasis; El virus de la enfermedad de Marek (MDV) y el virus de la leucosis aviar subtipo J (ALV-J) suelen causar enfermedades oncogénicas aviares. Aunque estas enfermedades se han reportado como infecciones patógenas separadas, la información sobre coinfección es escasa. Este estudio reporta un caso natural de coinfección con H. meleagridis, el virus de la enfermedad de Marek y el virus de la leucosis aviar subtipo J en una parvada de pollos local a la edad de 150 días. La necropsia reveló necrosis e inflamación del hígado y el bazo. El análisis histológico mostró grandes áreas de necrosis de hepatocitos de leve a severa, con numerosos trofozoítos intralesionales de H. meleagridis por tinción de hematoxilina y eosina y por tinción de ácido periódico-Schiff. La tinción de hematoxilina y eosina mostró células linfoides neoplásicas y pleomórficas en el hígado y en el bazo presencia de células mieloides con gránulos citoplásmicos eosinofílicos. La coexpresión de antígenos del virus de Marek y de la leucosis aviar subtipo J se detectó en el hígado mediante tinción inmunohistoquímica de fluorescencia múltiple. El gene de ARNr 18S de H. meleagridis, el gene meq del virus de Marek y el gene gp85 del virus de la leucosis aviar subtipo J se identificaron en tejidos mixtos de hígado y bazo mediante PCR y secuenciación, respectivamente.

Endogenous Avian Leukosis Virus in Combination with Serotype 2 Marek's Disease Virus Significantly Boosted the Incidence of Lymphoid Leukosis-Like Bursal Lymphomas in Susceptible Chickens.

In 2010, sporadic cases of avian leukosis virus (ALV)-like bursal lymphoma, also known as spontaneous lymphoid leukosis (LL)-like tumors, were identified in two commercial broiler breeder flocks in the absence of exogenous ALV infection. Two individual ALV subgroup E (ALV-E) field strains, designated AF227 and AF229, were isolated from two different breeder farms. The role of these ALV-E field isolates in development of and the potential joint impact in conjunction with a Marek's disease virus (MDV) vaccine (SB-1) were further characterized in chickens of an experimental line and commercial broiler breeders. The experimental line 0.TVB*S1, commonly known as the rapid feathering-susceptible (RFS) line, of chickens lacks all endogenous ALV and is fully susceptible to all subgroups of ALV, including ALV-E. Spontaneous LL-like tumors occurred following infection with AF227, AF229, and a reference ALV-E strain, RAV60, in RFS chickens. Vaccination with serotype 2 MDV, SB-1, in addition to AF227 or AF229 inoculation, significantly enhanced the spontaneous LL-like tumor incidence in the RFS chickens. The spontaneous LL-like tumor incidence jumped from 14% by AF227 alone to 42 to 43% by AF227 in combination with SB-1 in the RFS chickens under controlled conditions. RNA-sequencing analysis of the LL-like lymphomas and nonmalignant bursa tissues of the RFS line of birds identified hundreds of differentially expressed genes that are reportedly involved in key biological processes and pathways, including signaling and signal transduction pathways. The data from this study suggested that both ALV-E and MDV-2 play an important role in enhancement of the spontaneous LL-like tumors in susceptible chickens. The underlying mechanism may be complex and involved in many chicken genes and pathways, including signal transduction pathways and immune system processes, in addition to reported viral genes.IMPORTANCE Lymphoid leukosis (LL)-like lymphoma is a low-incidence yet costly and poorly understood disease of domestic chickens. The observed unique characteristics of LL-like lymphomas are that the incidence of the disease is chicken line dependent; pathologically, it appeared to mimic avian leukosis but is free of exogenous ALV infection; inoculation of the nonpathogenic ALV-E or MDV-2 (SB-1) boosts the incidence of the disease; and inoculation of both the nonpathogenic ALV-E and SB-1 escalates it to much higher levels. This study was designed to test the impact of two new ALV-E isolates, recently derived from commercial broiler breeder flocks, in combination with the nonpathogenic SB-1 on LL-like lymphoma incidences in both an experimental egg layer line of chickens and a commercial broiler breeder line of chickens under a controlled condition. Data from this study provided an additional piece of experimental evidence on the potency of nonpathogenic ALV-E, MDV-2, and ALV-E plus MDV-2 in boosting the incidence of LL-like lymphomas in susceptible chickens. This study also generated the first piece of genomic evidence that suggests host transcriptomic variation plays an important role in modulating LL-like lymphoma formation.

Circular RNA Vav3 sponges gga-miR-375 to promote epithelial-mesenchymal transition.

Circular RNAs (circRNAs) are evolutionarily conserved and widely present, but their functions remain largely unknown. Recent development has highlighted the importance of circRNAs as the sponge of microRNA (miRNA) in cancer. We previously reported that gga-miR-375 was downregulated in the liver tumors of chickens infected with avian leukosis virus subgroup J (ALV-J) by microRNA microarray assay. It can be reasonably assumed in accordance with previous studies that the gga-miR-375 may be related to circRNAs. However, the question as to which circRNA acts as the sponge for gga-miR-375 remains to be answered. In this study, circRNA sequencing results revealed that a circRNA Vav3 termed circ-Vav3 was upregulated in the liver tumors of chickens infected with ALV-J. In addition, RNA immunoprecipitation (RIP), biotinylated RNA pull-down and RNA-fluorescence in situ hybridization (RNA-FISH) experiments were conducted to confirm that circ-Vav3 serves as the sponge of gga-miR-375. Furthermore, we confirmed through dual luciferase reporter assay that YAP1 is the target gene of gga-miR-375. The effect of the sponge function of circ-Vav3 on its downstream genes has been further verified by our conclusion that the sponge function of circ-Vav3 can abrogate gga-miR-375 target gene YAP1 and increase the expression level of YAP1. We further confirmed that the circ-Vav3/gga-miR-375/YAP1 axis induces epithelial-mesenchymal transition (EMT) through influencing EMT markers to promote tumorigenesis. Finally, clinical ALV-J-induced tumor livers were collected to detect core gene expression levels to provide a proof to the concluded tumorigenic mechanism. Together, our results suggest that circ-Vav3/gga-miR-375/YAP1 axis is another regulator of tumorigenesis.

Pleomorphic Malignant Mesothelioma in a Broiler Breeder Infected with Avian Leucosis Virus Subgroup J.

Avian leucosis virus (ALV) is an oncogenic retrovirus that induces tumours including lymphoid leucosis and myeloid leucosis. Pleomorphic malignant mesothelioma and myelocytoma, which were thought to be induced by ALV subgroup J (ALV-J) infection, were identified in a 432-day-old broiler breeder. The bird showed no clinical signs; however, at necropsy examination there were multiple nodules in the alimentary tract. Microscopical analysis showed that these consisted of pleomorphic cells and myelocyte-like cells. Immunohistochemistry revealed that the pleomorphic cells were atypical and expressed cytokeratin, vimentin, c-kit, calretinin and ALV. The myelocyte-like cells were also positive for ALV. Retroviral type C particles were observed by electron microscopy. ALV-E and ALV-J nucleotide sequences were detected in DNA extracted from formalin-fixed and paraffin wax-embedded small intestinal tissue. Based on these results, the tumours were diagnosed as pleomorphic malignant mesothelioma and myelocytoma and were thought to have been induced by ALV-J infection. This is the first report of malignant mesothelioma associated with naturally acquired ALV-J infection.

Characterizing the histopathology of natural co-infection with Marek's disease virus and subgroup J avian leucosis virus in egg-laying hens.

Marek's disease virus (MDV) and avian leucosis virus (ALV) are known to cause tumours in egg-laying hens. Here, we investigated the aetiology of tumours in a flock of egg-laying hens vaccinated against MDV. We carried out gross pathology and histopathological examinations of the diseased tissues, identified virus antigen and sequenced viral oncogenes to elucidate the cause of death in 21-22-week-old hens. At necropsy, diseased hens had distinctly swollen livers, spleens, and proventriculus, and white tumour nodules in the liver. The spleen and liver had been infiltrated by lymphoid tumour cells, while the proventriculus had been infiltrated by both lymphoid tumour cells and myeloblastic cells. Subtype J ALV (ALV-J) and MDV were widely distributed in the proventricular gland cells, and the lymphoid tumour cells in the liver and the spleen. In addition, positive ALV-J signals were also observed in parts of the reticular cells in the spleen. MDV and ALV-J antigens were observed in the same foci of the proventricular gland cells; however, the two antigens were not observed in the same foci from the spleen and liver. The amino acid sequence of the AN-1 (the representative liver tumour tissue that was positive for both ALV-J and MDV) Meq protein was highly similar to the very virulent MDV QD2014 from China. Compared to the ALV-J HPRS-103 reference strain, 10 amino acids (224-CTTEWNYYAY-233) were deleted from the gp85 protein of AN-1. We concluded that concurrent infection with MDV and ALV-J contributed to the tumorigenicity observed in the flock.

Growth retardation induced by avian leukosis virus subgroup J associated with down-regulated Wnt/ß-catenin pathway.

Avian leukosis virus subgroup J (ALV-J), an oncogenic retrovirus, induces growth retardation and neoplasia in chickens, leading to enormous economic losses in poultry industry. Increasing evidences showed several signal pathways involved in ALV-J infection. However, what signaling pathway involved in growth retardation is largely unknown. To explore the possible signaling pathway, we tested the cell proliferation and associated miRNAs in ALV-J infected CEF cells by CCK-8 and Hiseq, respectively. The results showed that cell proliferation was significantly inhibited by ALV-J and three associated miRNAs were identified to target Wnt/ß-catenin pathway. To verify the Wnt/ß-catenin pathway involved in cell growth retardation, we analyzed the key molecules of Wnt pathway in ALV-J infected CEF cells. Our data demonstrated that protein expression of ß-catenin was decreased significantly post ALV-J infection compared with the normal (P < 0.05). The impact of this down-regulation caused low expression of known target genes (Axin2, CyclinD1, Tcf4 and Lef1). Further, to obtain in vivo evidence, we set up an ALV-J infection model. Post 7 weeks infection, ALV-J infected chickens showed significant growth retardation. Subsequent tests showed that the expression of ß-catenin, Tcf1, Tcf4, Lef1, Axin2 and CyclinD1 were down-regulated in muscles of growth retardation chickens. Taken together, all data demonstrated that chicken growth retardation caused by ALV-J associated with down-regulated Wnt/ß-catenin signaling pathway.

Mutations in and Expression of the Tumor Suppressor Gene p53 in Egg-Type Chickens Infected With Subgroup J Avian Leukosis Virus.

To investigate the molecular mechanisms of the oncogenic effects of avian leukosis virus subgroup J (ALV-J), we examined mutations in and the expression of p53 in the myelocytomas distributed in the liver, spleen, trachea, and bone marrow, as well as in fibrosarcomas in the abdominal cavity and hemangiomas in skin from chickens that were naturally or experimentally infected with ALV-J. Two types of mutations in the p53 gene were detected in myelocytomas of both the experimentally infected and the naturally infected chickens and included point mutations and deletions. Two of the point mutations have not been reported previously. Partial complementary DNA clones with a 122-bp deletion in the p53 gene ORF and a 15-bp deletion in the C-terminus were identified in the myelocytomas. In addition, moderate expression of the mutant p53 protein was detected in the myelocytomas that were distributed in the liver, trachea, spleen, and bone marrow. Mutant p53 protein was not detected in the subcutaneous hemangiomas or in the abdominal fibrosarcomas associated with natural and experimental ALV-J infection, respectively. These results identify mutations associated with abnormal expression of p53 in ALV-J-associated myelocytomas, suggesting a role in tumorigenesis.

Immunoregulatory effects of Taishan Pinus massoniana pollen polysaccharide on chicks co-infected with avian leukosis virus and Bordetella avium early in ovo.

In recent years, co-infection of chicken embryos with immunosuppressive viruses and bacteria occurs with an annually increasing frequency. Consequently, studies on new and safe immunoregulators, especially plant polysaccharides, have become a popular topic in the poultry industry. In the present study, we selected 300 specific pathogen free embryonated eggs, which were injected with subgroup B avian leukosis virus (ALV-B) and Bordetella avium (B. avium) to establish an artificial co-infection model. The chicks that hatched from these co-infected embryonated eggs were treated with Taishan Pinus massoniana pollen polysaccharide (TPPPS). Results indicated that relevant indices in the co-infection group were significantly lower than that in B. avium-only group. Furthermore, pathogenicity of B. avium was exacerbated, with the chicks exhibiting decreased body weights. The TPPPS groups exhibited gradual improvements in immune function and developmental status. Therefore, in terms of improving immunologic function and production performance, TPPPS could be used as immunoregulator for immune responses.

Cardiac pathology and molecular epidemiology by avian leukosis viruses in Japan.

Epidemiological studies suggest that retroviruses, including human immunodeficiency virus type 1, are associated with cardiomyopathy and myocarditis, but a causal relationship remains to be established. We encountered unusual cardiomyocyte hypertrophy and mitosis in Japanese native fowls infected with subgroup A of the avian leukosis viruses (ALVs-A), which belong to the genus Alpharetrovirus of the family Retroviridae and mainly induce lymphoid neoplasm in chickens. The affected hearts were evaluated by histopathology and immunohistochemistry, viral isolation, viral genome sequencing and experimental infection. There was non-suppurative myocarditis in eighteen fowls and seven of them had abnormal cardiomyocytes, which were distributed predominantly in the left ventricular wall and showed hypertrophic cytoplasm and atypical large nuclei. Nuclear chains and mitosis were frequently noted in these cardiomyocytes and immunohistochemistry for proliferating cell nuclear antigen supported the enhancement of mitotic activity. ALVs were isolated from all affected cases and phylogenic analysis of envSU genes showed that the isolates were mainly classified into two different clusters, suggesting viral genome diversity. In ovo experimental infection with two of the isolates was demonstrated to cause myocarditis and cardiomyocyte hypertrophy similar to those in the naturally occurring lesions and cardiac hamartoma (rhabdomyoma) in a shorter period of time (at 70 days of age) than expected. These results indicate that ALVs cause myocarditis as well as cardiomyocyte abnormality in chickens, implying a pathogenetic mechanism different from insertional mutagenesis and the existence of retrovirus-induced heart disorder.

Reproduction of hemangioma by infection with subgroup J avian leukosis virus: the vertical transmission is more hazardous than the horizontal way.

BACKGROUND: Clinical cases of hemangioma associated with subgroup J avian leukosis virus (ALV-J) have been reported in commercial chicken layer flocks since 2006. We attempted to reproduce hemangioma through experimental infection with ALV-J to evaluate viral pathogenicity in layer birds and their progenies. RESULTS: Body weight and indexes for immune organs of chickens infected with ALV-J strain SCDY1 were lower than those in controls. Proliferation of lymphocytes was observed in many tissues, and viral integration was detected in the genome of lymphocytes at 14 days post-infection, along with virus shedding. ALV-J was also efficiently transmitted from eggs to progenies. Embryo hatchability and progeny mortality were lower than those for controls. The efficiencies of virus shedding and virus integration in the lymphocytes of progenies were higher than those in parents. CONCLUSIONS: ALV-J is able to inhibit the growth of infected chickens, and causes damage to immune organs. Vertical transmission of ALV-J appears to be more deleterious than horizontal transmission.

Simultaneous endemic infections with subgroup J avian leukosis virus and reticuloendotheliosis virus in commercial and local breeds of chickens.

Epidemiological studies of subgroup J avian leukosis virus (ALV-J) and reticuloendotheliosis virus (REV) infections were conducted during 1999 to 2009 on 29 chicken flocks of various commercial and local breeds located in six provinces in China. Samples were typically from chickens with myelocytomas or proventricular lesions. ALV-J was isolated from 25 flocks including seven out of seven flocks containing "yellow chickens" or other local breeds and several flocks of layer chickens. REV was isolated from 19 flocks. Co-infection of ALV-J and REV was confirmed in 11/38 birds of 8/15 flocks with myelocytomatosis and in 11/24 birds of 3/5 flocks with proventricular lesions. Both ALV-J and REV were vertically transmitted in four breeder flocks of local chicken breeds. One experiment in specific pathogen free chickens indicated that co-infection at hatch strongly depressed antibody responses to ALV-J but not to REV. The results suggest that infections with both ALV-J and REV have become endemic in local breeds, including breeder flocks where both viruses appear to be perpetuated by vertical transmission. In addition, both viruses were present in at least some commercial broiler, layer and breeder flocks. Eradication programmes are needed but will be difficult, especially in local breeds. This unprecedented concurrence of simultaneous endemic infections with ALV-J and REV may have serious economic consequences and needs to be better understood.

In ovo infection with an avian leukosis virus causing fowl glioma: viral distribution and pathogenesis.

We have previously isolated an avian leukosis virus (ALV) from a chicken affected with so-called fowl glioma. A resistance-inducing factor test indicated that the isolate was classified into a subgroup A. The distribution and pathogenicity were investigated in C/O specific pathogen free chickens infected in ovo with this virus. Histologically, 11 of 12 (92%) infected birds had non-suppurative encephalitis and three birds (25%) showed the characteristic nodules of fowl glioma at 50 or 100 days of age. Non-suppurative myocarditis with matrix inclusions and atypical myocytes were also noted in nine (75%) of the birds and the ALV antigens were immunohistochemically detected in various general organs as well as the central nervous system and heart. The semi-quantitative determination of the proviral DNA and viral RNA supported the immunohistochemical results and indicated that the virus was likely to replicate especially in myocardial fibres. The isolated ALV failed to induce other neoplastic lesions in this line of chickens within the experimental period of 100 days, despite the broad tissue tropism throughout the body. These results confirmed that this virus was able to induce glioma in embryo-inoculated chickens.

Molecular indications for in vivo integration of the avian leukosis virus, subgroup J-long terminal repeat into the Marek's disease virus in experimentally dually-infected chickens.

Marek's disease virus, a herpesvirus, and avian leukosis virus, subgroup J, a retrovirus, are oncogenic viruses of poultry. Both viruses may infect the same flock, the same bird and the same cell. In a double-infected cell, the retroviral DNA can integrate into the cellular or the Marek's disease virus (MDV) genome. The retroviral-long terminal repeat (LTR) integration into MDV was first described by Isfort et al., (Proc Natl Acad Sci 89, 991-995, 1992) following tissue culture co-infection. The recombinant virus isolated, RM1, had altered biological properties compared to the parental MDV (Witter R.L., Li D., Jones D., and Kung H.-J., Avian Dis 41, 407-421, 1997) . The issue of retroviral sequence integration into herpesviruses in vivo, in cases of double-virus infection is of wide significance in general virology and veterinary medicine; it also represents a special case of gene transposition. Using the avian system, we aimed to determine occurrence of such integrations in vivo. Chickens were experimentally co-infected with both avian leukosis virus (ALV) subgroup J and with MDV. To demonstrate the presence of the retroviral LTR in the MDV genome we applied the Hot Spot-combined PCR assay (Borenshtain R. and Davidson I., J Virol Meth 82, 119-127, 1999) that consisted of two consecutive steps of amplification. By that HS-cPCR assay, certain MDV genomic sites, defined as HS for integration were specifically amplified, the HS step, and then subjected to screening in an attempt to detect LTR inserts. The screening was achieved by amplification using heterologous primer sets, one for the MDV hot spot and the other for the retroviral LTR, the cPCR step. The products were Southern blotted and hybridized with MDV and ALV-LTR probes. Chimeric molecules were detected and evidenced by an intense signal in 3/10 chickens and weakly in other 3/10 birds. Detection was by LTR amplification, sequencing and multiple alignment to the ALV-J-LTR sequence. The present study indicated that chimeric molecules were produced in vivo.

In vivo events of retroviral long terminal repeat integration into Marek's disease virus in commercial poultry: detection of chimeric molecules as a marker.

The present study demonstrated, for the first time, that not only in vitro, but also in vivo, coinfections with Marek's disease virus (MDV) and each of the three avian retroviruses (reticuloendotheliosis virus [REV], avian lymphoid leukosis virus [ALV], and ALV-J) lead to retroviral long terminal repeat (LTR) integration into MDV. A total of 306 chicken and 59 turkey commercial flocks, submitted for differential avian oncogenic virus diagnosis, served to evaluate the flock mixed virus infection rate, the rate of birds with a multiple virus infection, and the issue of retroviral LTR integration into MDV in vivo. About a quarter of the tumor-bearing commercial flocks carried a mixed MDV and retrovirus infection. A total of 2926 DNA samples were analyzed, including 2428 chicken and 498 turkey DNA samples. Of these, 991 DNAs originated from flocks with a multiple virus infection. In 103 DNA preparations from that group (103/991, 10.4%), including 38 and 56 from chicken blood and tumor tissues, respectively, and nine samples from turkey blood, multiple virus sequences were detected by polymerase chain reaction (PCR). Fifty-six of the 103 samples were further analyzed by the previously developed hot spot-combined (HS-cPCR assay, of which 48% (27/56) contained chimeric MDV and retroviral LTR molecules. When extrapolated to the total samples derived from the flocks with multiple virus infection, that rate implies that about 5% of the DNA samples would carry MDV-retrovirus integration events. Several birds held a variety of chimeric molecules, indicating that several recombination events occurred simultaneously. The validation of the MDV and retroviral LTR chimeric constitution of these molecules was derived by the MDV and retroviral heterologous primers used for their creation by the HS-cPCR assay, Southern blotting and their detection by retroviral LTR probes, and LTR amplification from the gel-purified chimeric molecules. From several molecules, the LTR was sequenced, and a 161-bp retroviral LTR sequence was demonstrated. Our biochemical data imply that a recent integration occurred in the birds. The viability of recombinant viruses represented by the chimeric molecules will be further approached.

A low incidence of histiocytic sarcomatosis associated with infection of chickens with the HPRS-103 strain of subgroup J avian leukosis virus.

Ten cases of histiocytic proliferative lesions in meat-type chickens associated in low incidence with infection by subgroup J avian leukosis virus (ALV) are described. Six were field cases in adult chickens from naturally infected flocks and four were from younger birds from transmission experiments with HPRS-103 ALV or the related acutely transforming ALV strains 17 and 879. The lesions were observed mostly in the spleen and in some cases in other organs. Microscopically, the lesions were comprised mainly of pleomorphic histiocyte-like cells admixed with variable numbers of lymphoid cells. More detailed studies were carried out on two birds at 4 and 7 wk of age following infection with HPRS-103 at 1 day of age. These birds had multiple small nodular lesions in the spleen, liver, and kidney that appeared similar cytologically to the more extensive lesions in older birds. Monoclonal antibodies specific for various lymphoid and nonlymphoid accessory cells were used in immunohistochemical studies to identify a predominance of cells of monocyte/macrophage lineage, and CD4- and CD8-positive lymphocytes, in the splenic nodules. Ultrastructural studies also revealed a similar mixed population of cells. Expression of ALV group-specific antigen, and gag and ALV-J env RNA, was not a marked feature of the histiocytic lesions. The proliferative histiocytic lesion is designated a histiocytic sarcomatosis.

Analysis of the initiation period of spontaneous autoimmune thyroiditis (SAT) in obese strain (OS) of chickens.

The early, predictable, onset of spontaneous autoimmune thyroiditis (SAT) in Obese strain (OS) chickens provides a unique opportunity to analyse the mechanisms initiating autoimmunity which is virtually impossible to obtain in humans. In this study we focused on the respective roles of viruses and macrophages in the initiation of SAT. To analyse viruses, leukosis virus-free OS chickens were bred over three generations and reared under gnotobiotic conditions. By 2 weeks of age there were no differences in the levels of thyroid mononuclear cell infiltration between these and control animals. The role of mononuclear phagocytes in SAT was determined by their depletion via injecting newborn OS chicks with silica or carrageenan and dichloro-methylene diphosphonate encapsulated into liposomes. Although this treatment did not substantially change the amount of macrophages in primary lymphoid organs or blood, there was destruction of splenic architecture and, most importantly, mononuclear cell infiltration of the thyroids was significantly lower compared to controls. The role of activated macrophages in SAT is discussed.

Mucin histochemistry of virus-induced duodenal adenomas in guinea fowl.

The type of mucoproteins in virus-induced duodenal adenomas in guinea fowl were compared with those in the normal duodenal mucosa. The mucin-producing cells in the latter contained a mixture of acid and neutral mucins. Neutral and sulphomucins prevailed in the crypts and in the lower part of the villi, while the amount of the sialomucins increased progressively toward the tip of the villi. In the adenomas, goblet cells were more numerous and were unevenly distributed. In their mucin profile the deeply located tumor glandular structures resembled normal crypts and lower parts of the villi and superficial portions of the adenomas were similar to the upper part of the villi. Qualitative changes in the mucin secretion with deviation from the normal vertical distribution of mucin types were rarely observed. The histochemical study carried out supplemented the histological characterization of the virus-induced duodenal adenomas and contributed to the elucidation of some aspects of their histogenesis.

Chronic myocarditis and circulatory syndrome in a White Leghorn strain induced by an avian leukosis virus: light and electron microscopic study.

Specific-pathogen-free white leghorn chickens were inoculated at 1 day of age with avian leukosis virus (ALV, RAV-1). All chickens in Expt. 1, killed 33 or 64 days postinoculation, had focal chronic lymphocytic or lymphoplasmacytic myocarditis. Among those held beyond 33 days, eight of 22 developed lesions in the myocardium that resulted in a chronic circulatory syndrome (CCS) typical of right-sided heart failure. Chickens in Expt. 2 were held for 210 days, and 21% of 125 developed CCS. In Expt. 2, ALV particles were found by electron microscopy in myocardium of 100%, 72%, and 89% of inoculated chickens that developed CCS, lymphoid leukosis, or that had no gross lesions, respectively. These findings were in accord with the immunoperoxidase staining of tissue sections for group-specific antigen of ALV. In areas of extensive virus replication, there were often abnormal virus particles and also round bodies, which may have been remnants of host-cell membranes formed in the budding process. In contrast to findings in hearts, the spleens were usually negative for virus and viral antigen.