ABSTRACT
Avian leukosis virus subgroup J (ALV-J) is an avian retrovirus that can induce myelocytomas. A high-frequency mutation in gene envelope endows ALV-J with the potential for cross-species transmission. We wished to ascertain if the ALV-J can spread across species under selection pressure in susceptible and resistant hosts. First, we inoculated (in turn) two susceptible host birds (specific pathogen-free (SPF) chickens and turkeys). Then, we inoculated three resistant hosts (pheasants, quails and ducks) to detect the viral shedding, pathologic changes, and genetic evolution of different isolates. We found that pheasants and quails were infected under the selective pressure that accumulates stepwise in different hosts, and that ducks were not infected. Infection rates for SPF chickens and turkeys were 100% (16/16), whereas those for pheasants and quails were 37.5% (6/16) and 11.1% (3/27). Infected hosts showed immune tolerance, and inflammation and tissue damage could be seen in the liver, spleen, kidneys and cardiovascular system. Non-synonymous mutation and synonymous ratio (NS/S) analyses revealed the NS/S in hypervariable region (hr) 2 of pheasants and quails was 2.5. That finding suggested that mutation of isolates in pheasants and quails was induced by selective pressure from the resistant host, and that the hr2 region is a critical domain in cross-species transmission of ALV-J. Sequencing showed that ALV-J isolates from turkeys, pheasants and quails had moved away from the original virus, and were closer to the ALV-J prototype strain HPRS-103. However, the HPRS-103 strain cannot infect pheasants and quails, so further studies are needed.
Subject(s)
Animals , Amino Acid Sequence , Avian Leukosis , Virology , Avian Leukosis Virus , Classification , Genetics , Physiology , Chickens , Ducks , Virology , Galliformes , Virology , Host Specificity , Molecular Sequence Data , Poultry Diseases , Virology , Quail , Virology , Sequence Alignment , Turkeys , Virology , Viral Envelope Proteins , Chemistry , Genetics , MetabolismABSTRACT
The genomic diversity of Avian leukosis virus subgroup J (ALV-J) was investigated in an experimentally infected chicken. ALV-J variants in tissues from four different organs of the same bird were re-isolated in DF-1 cells, and their gp85 gene was amplified and cloned. Ten clones from each organ were sequenced and compared with the original inoculum strain, NX0101. The minimum homology of each organ ranged from 96.7 to 97.6%, and the lowest homology between organs was only 94.9%, which was much lower than the 99.1% homology of inoculum NX0101, indicating high diversity of ALV-J, even within the same bird. The gp85 mutations from the left kidney, which contained tumors, and the right kidney, which was tumor-free, had higher non-synonymous to synonymous mutation ratios than those in the tumor-bearing liver and lungs. Additionally, the mutational sites of gp85 gene in the kidney were similar, and they differed from those in the liver and lung, implying that organ- or tissue-specific selective pressure had a greater influence on the evolution of ALV-J diversity. These results suggest that more ALV-J clones from different organs and tissues should be sequenced and compared to better understand viral evolution and molecular epidemiology in the field.
Subject(s)
Animals , Avian Leukosis Virus , Avian Leukosis , Birds , Chickens , Clone Cells , Kidney , Liver , Lung , Molecular Epidemiology , Silent MutationABSTRACT
Abstract:Subgroup J avian leukosis virus (ALV-J) infect cells by binding to the chNHE1 receptor protein of the host and causes tumors. The tumor incidence of the ALV-J-infected chickens was observed by histo pathology, and virus was isolated on DF-1 cell line. The ALV-J load and mRNA of chNHElreceptor protein were detected by real time PCR. The relationship between ALV-J load, chNHE1 receptor expression levels and tumor spectrum was analyzed. The results showed that the tumors induced by ALV-J in laying hens and local lines of chicken were different. No significant relationship was observed between ALV-J load and tumor spectrum. ALV-J load was positively correlated with mRNA expression of chNHE1. The mRNA expression of chNHE1 increased when the tumors occurred. Our results suggest the chNHE1 protein is not only the receptor of ALV-J infected host but also play an important role in the process of tumor development. This study provides a scientific basis for further studying of oncogenic mechanism of ALV-J.
Subject(s)
Animals , Avian Leukosis , Genetics , Metabolism , Virology , Avian Leukosis Virus , Genetics , Physiology , Chickens , Genetics , Metabolism , Poultry Diseases , Genetics , Metabolism , Virology , Receptors, Virus , Genetics , Metabolism , Sodium-Hydrogen Exchangers , Genetics , Metabolism , Viral LoadABSTRACT
To study the correlation between ELISA and IFA tests in detection of ALV-A/B antibody in chicken sera, ELSA S/P values and IFA titers for different serum samples were measured and statistically analyzed. The results indicated that there was a strong positive correlation between ELISA S/P values and IFA titers (r = 0.97435, P < 0.001). Because the positive correlation between ELISA and IFA was so strong and antibody positive rates were identical in two tests, it suggested that IFA could be used as a alternative method to replace ELISA kit when only limited numbers of samples to be tested to reduce the cost and increase the sensitivity.
Subject(s)
Animals , Antibodies, Viral , Blood , Allergy and Immunology , Avian Leukosis , Diagnosis , Allergy and Immunology , Virology , Avian Leukosis Virus , Classification , Allergy and Immunology , Cell Line , Chickens , Enzyme-Linked Immunosorbent Assay , Methods , Fluorescent Antibody Technique, Indirect , Methods , Poultry Diseases , Diagnosis , Allergy and Immunology , Virology , Species SpecificityABSTRACT
In order to clarify Avian leukosis virus (ALV) characteristics from Chinese native chicken breeds, three ALV JS11C1, JS11C2 and JS11C3 were isolated from Chinese native breed "luhua" by inoculation of DF1 cell culture and detection of p27 antigen. Using PCR amplification of env gene, the amplified gp85 genes were analyzed and compared to all six chicken ALV subgroups reported. The gp85 genes of these three viruses were 1 005bp in length and encoded 335 amino acids, and the gp37 genes were 609bp and encoded 203 amino acids. The homology of gp85 among these three isolated strains was 91.9%-97.0%. Comparing to 18 stains of subgroup A, B, C, D, E published in GenBank, the homology was only in the range of 77.7%-84.6%, significantly lower than the gp85 homology observed within the common chicken subgroups A (88.2%-98.5%), B (91.6%-98.8%), and E (97.9%-99.4%). The gp85 homology compared with subgroup J was only 34.2%-36.5%. These results suggested that three isolated strains from Chinese native breed "luhua" belong to a new subgroup different from all six known subgroups from Chickens, and thus designated as subgroup K.
Subject(s)
Animals , Avian Leukosis , Virology , Avian Leukosis Virus , Classification , Genetics , Metabolism , Breeding , Chickens , Genetics , Virology , Molecular Sequence Data , Phylogeny , Poultry Diseases , Virology , Viral Envelope Proteins , Genetics , MetabolismABSTRACT
The transmembrane protein (TM) encoded by gp37 gene plays a critical role when virus fusion with cell membrane occurs. Several highly conserved regions in TM are important targets for antivirus studies. Studies on structure and function of TM will provide basic information for anti-retrovirus, especially for avian leukosis virus. In the study, gp37 gene was amplified by PCR from the Chinese strain ALV-J-WS0701. The gp37 gene was cloned into pMD18-T vector, and was sequenced. Then, pFast-BacHTb-gp37 vector was constructed and expressed by baculovirus expression vector system. The expression product of gp37 gene was analyzed by indirect immunofluorescence assay and Western blot. The results showed that positive green fluorescence was present in sf9 cells infected with recombinant virus and a protein band with a molecular weight of 21kD was present in Western blot. It is concluded that gp37 gene was expressed in sf9 cells infected with recombinant virus successfully.
Subject(s)
Animals , Avian Leukosis , Virology , Avian Leukosis Virus , Classification , Genetics , Cell Line , Chickens , Cloning, Molecular , Gene Expression , Spodoptera , Viral Envelope Proteins , Genetics , MetabolismABSTRACT
The subgroup J of ALV [ALV-J] has emerged as an important pathogen of meat-type chickens since 1989. This virus is responsible for economic losses due to both mortality and depressed performance in chickens. So, the objective of this study is the detection of ALV-J in the albumen of commercial and native fowl eggs using RT-PCR. Three hundred and seventy egg albumens were randomly selected from different farms of Fars province, Iran. These eggs were obtained from the flocks of two research centers on native fowl production [70 eggs], a broiler grandparent farm [60 eggs], three broiler breeder farms [180 eggs], and a commercial layer flock [60 eggs]. RT-PCR was undertaken on isolated RNA from egg samples using a pair of ALV-J specific primers H5/H7 that produced a 545 basepair fragment. RT-PCR analyses detected ALV-J in 15 of 180 [8.33%] samples from three broiler breeders farms, 17 of 70 [24.28%] samples from flocks of two research centers of native fowls production, and none of the samples of commercial layer and broiler grandparent farms. Direct sequencing using primers specific for subgroup ALV-J verified the viral subgroup in the RT-PCR amplification products. This is the first report of the ALV-J in egg albumen in Iran which indicates the necessity to apply eradication programs for ALV-J in the poultry industry and native fowls in Iran
Subject(s)
Animals , Avian Leukosis Virus/genetics , Eggs/virology , Albumins/analysis , Reverse Transcriptase Polymerase Chain Reaction/veterinary , Molecular Sequence Data , Phylogeny , PoultryABSTRACT
An adult female budgerigar [Melopsittacus undulates] presented with abdominal enlargement. The condition of the bird deteriorated after needle aspiration for cytological examination. The budgerigar was euthanatized and a complete necropsy was performed. Microscopic sections were prepared and stained with hematoxylin and eosin, Gram staining, periodic acid-Schiff [PAS] and acid-fast staining. Escherichia coll was isolated in pure culture. Necropsy revealed the presence of granulomatous lesions of varying sizes at different locations and hepatomegaly, oviduct impaction and oophoritis. Histopathologically, typical granuloma with a central area of coagulation necrosis and bacterial colonies surrounded by lymphocytes, macrophages and multinucleated giant cells were found. These granulomas were present in the liver, oviduct and intestinal tract. A sheet of neoplastic cells and disruption of the normal hepatic architecture was seen. The diagnosis was lymphoid leucosis and coligranuloma
Subject(s)
Animals , Female , Avian Leukosis Virus , Avian Leukosis , Salpingitis , OophoritisABSTRACT
The aggressive and invasive nature of brain tumors has hampered progress in the design and implementation of efficacious therapies. The recent success of targeted therapies in other tumor types makes this an attractive area for research yet complicating matters is the ability of brain tumors to circumvent the targeted pathways to develop drug resistance. Effective therapies will likely need to target more than one signaling pathway or target multiple nodes within a given pathway. Key to identifying these targets is the elucidation of the driver and passenger molecules within these pathways. Animal models provide a useful tool with many advantages in the study of these pathways. These models provide a means to dissect the critical components of tumorigenesis, as well as serve as agents for preclinical testing. This review focuses on the use of the RCAS/tv-a mouse model of brain tumors and describes their unique ability to provide insight into the role of oncogene cooperation in tumor development and progression.
Subject(s)
Animals , Humans , Mice , Avian Leukosis Virus , Genetics , Avian Proteins , Genetics , Brain Neoplasms , Genetics , Pathology , Disease Models, Animal , Disease Progression , Drug Evaluation, Preclinical , Methods , Genetic Vectors , Glioma , Genetics , Pathology , Mice, Transgenic , Oncogenes , Genetics , Receptors, Virus , GeneticsABSTRACT
The increasing incidence and mortality associated with advanced stages of melanoma are cause for concern. Few treatment options are available for advanced melanoma and the 5-year survival rate is less than 15%. Targeted therapies may revolutionize melanoma treatment by providing less toxic and more effective strategies. However, maximizing effectiveness requires further understanding of the molecular alterations that drive tumor formation, progression, and maintenance, as well as elucidating the mechanisms of resistance. Several different genetic alterations identified in human melanoma have been recapitulated in mice. This review outlines recent progress made in the development of mouse models of melanoma and summarizes what these findings reveal about the human disease. We begin with a discussion of traditional models and conclude with the recently developed RCAS/TVA somatic cell gene delivery mouse model of melanoma.
Subject(s)
Animals , Humans , Mice , 9,10-Dimethyl-1,2-benzanthracene , Avian Leukosis Virus , Genetics , Avian Proteins , Genetics , Metabolism , Cell Line, Tumor , Disease Models, Animal , Gene Transfer Techniques , Genetic Vectors , Genetics , Melanocytes , Metabolism , Melanoma , Genetics , Pathology , Melanoma, Experimental , Genetics , Mice, Transgenic , Neoplasm Transplantation , Receptors, Virus , Genetics , Metabolism , Skin Neoplasms , Genetics , Pathology , Tetradecanoylphorbol Acetate , TransgenesABSTRACT
Mouse models of cancer enable researchers to learn about tumor biology in complicated and dynamic physiological systems. Since the development of gene targeting in mice, cancer biologists have been among the most frequent users of transgenic mouse models, which have dramatically increased knowledge about how cancers form and grow. The Chinese Journal of Cancer will publish a series of papers reporting the use of mouse models in studying genetic events in cancer cases. This editorial is an overview of the development and applications of mouse models of cancer and directs the reader to upcoming papers describing the use of these models to be published in coming issues, beginning with three articles in the current issue.
Subject(s)
Animals , Humans , Mice , Avian Leukosis Virus , Genetics , Avian Proteins , Genetics , Metabolism , Disease Models, Animal , Gene Targeting , Mice, Transgenic , Neoplasm Metastasis , Neoplasms, Experimental , Genetics , Metabolism , RNA Interference , Receptors, Virus , Genetics , MetabolismABSTRACT
During July to November in 2007, several outbreaks of Hemangiomas in Hy-line Brown laying hens were observed in China. The virus that infected these flocks was identified in cultured DF-1 cells by PCR and indirect fluorescent assay (IFA) with ALV-J specific monoclonal antibody JE-9. The gp85 gene of one strain named WS0705 of ALV-J was cloned and expressed. Phylogenetic analysis showed that gp85 amino sequences of WS0705 strain had the highest homology with that of the prototype HPRS-103. The gp85 gene from a constructed plasmid pMD18-T-WS0705gp85 was cloned into baculovirus transfer vector. rBac-WS0705gp85 was obtained by the Bac-to-Bac baculovirus expression system. The rBac-WS0705gp85 protein was analyzed by indirect immunofluor escence assay and Western blot. The results showed that positive green fluorescent was present in Sf9 cells infected with the recombinant virus and a 35 kD band was present in western blot. It is concluded that WS0705 gp85 gene was expressed in Sf9 cells infected with the recombinant virus and the SU protein of WS0705 can bind specifically to JE9 MAb of ALV-J. The expressed protein can be used to detect hemangiomas induced by ALV-J.
Subject(s)
Animals , Amino Acid Sequence , Avian Leukosis Virus , Classification , Genetics , Blotting, Western , Cell Line , Cloning, Molecular , Electrophoresis, Polyacrylamide Gel , Gene Expression , Hemangioma , Virology , Phylogeny , Polymerase Chain Reaction , Sequence Alignment , Viral Envelope Proteins , Chemistry , Genetics , MetabolismABSTRACT
The critical time of avian leukosis virus subgroup J (ALV-J)-mediated immunosuppression was determined by body weight, relative immune organ weight, histopathology, and presence of group specific antigen and antibodies in specific pathogen-free (SPF) chickens. CD4+ and CD8+ cell activity in the spleen, total and differential leukocyte counts in blood, and viral RNA levels in spleen were measured. Significant growth suppression was observed in the two ALV-J-infected groups. A strong immune response by infected groups was present in spleen at 2-weeks-of-age, but after 4-weeks-of-age, the response decreased quickly. The thymus and bursa showed persistent immunosuppression until 4-weeks-of-age. Proliferation of fibroblasts and dendritic cells were observed in immune organs at 4- and 5-weeks-of-age. However, the granulocyte cell number was markedly lower in the infected groups than in the control group. In group 1 (day 1 infection) CD4+ cells increased during the second week but significantly decreased during the fourth week, while group 2 (day 7 infection) showed the opposite effect. Viral RNA increased significantly by the fourth week. These data identify 3~4 weeks post-infection as the key time at which the ALV-J virus exerts its immunosuppressive effects on the host.
Subject(s)
Animals , Antibodies, Viral/blood , CD4 Antigens/blood , CD8 Antigens/blood , Avian Leukosis/immunology , Avian Leukosis Virus/classification , Body Weight , Chickens , China , Enzyme-Linked Immunosorbent Assay/veterinary , Immune Tolerance , Leukocyte Count/veterinary , Poultry Diseases/immunology , RNA, Viral/genetics , Real-Time Polymerase Chain Reaction/veterinary , Reverse Transcriptase Polymerase Chain Reaction/veterinary , Specific Pathogen-Free Organisms , Spleen/immunologyABSTRACT
To study the correlation between 50% tissue-culture infective dose (TCID50) value and p27 antigen S/P value of Avian leukosis virus subgroup J and discuss their significance, chicken embryo fibroblast (CEF) cells were inoculated with Avian leukosis virus subgroup J strain NX0101 and samples were tested continuously for ten days after changing maintenance media. The correlation between TCID50 and p27 antigen S/P value of ten days were then analysized. Simultaneously, DF-1 cells were inoculated with NX0101 and passaged to 20 generations. Samples taken from 1st generation, 5th generation, 10th generation, 15th generation and 20th generation were tested for the TCID50 titer and the p27 antigen S/P value separately. A significant Pearson correlation was found between them in CEF cells (r = 0.85277; P < 0.0001) and in DF-1 cells (r = 0.93000; P = 0.0220). This study provided an important parameter for predicting TCID50 by detecting the p27 antigen S/P value.
Subject(s)
Animals , Chick Embryo , Avian Leukosis , Virology , Avian Leukosis Virus , Allergy and Immunology , Virulence , Fibroblasts , Virology , Proliferating Cell Nuclear Antigen , Allergy and Immunology , Viral Load , Allergy and ImmunologyABSTRACT
The purpose of this study was to compare the whole genome sequences and replication dynamics in cell cultures of two Avian leukosis viruses of subgroup B (ALV) isolates, SDAU09E3 and SDAU09C2. Comparison of the amino acid sequences indicated that the gp85 identity of these two subgroup B isolates was 95.4%, the identity with other three ALV-B reference strains was 91.0%-94.9%, and less than 87.9% with ALV subgroup A, C, D, E and J. Comparison of the nucleotide sequence of gag and pol genes indicated that homologies of gag gene and pol gene of these two ALV-B isolates with all compared reference strains of different subgroups were above 93%. Homologies of LTR sequence of these two ALV-B isolates with other exogenous ALVs subgroups A, B, C, D and J were 72.6%-88.3%, but only 51.5% when compared with endogenous ALV subgroup E. The identity of LTR between these two ALV-B strains was only 74.8%, which was far lower than the identity of other genes. The identity of U3 region of LTR between these two ALV-B isolates was only 68.8% and there were obvious differences in the number CAAT Boxes. Replication dynamics in DF-1 cell indicated that the value of TCID50 was similar between 2 isolates but the concentration of nucleocapsid protein p27 antigen of SDAU09E3 was significantly higher than SDAU09C2 in cell culture supernatant, which indicated there was no parallel relationship between p27 antigen concentration and infectious virus particles. Whether such difference was resulted from the diversity of U3 region of LTR, further studies with their recombinant infectious clones is necessary.
Subject(s)
Animals , Chick Embryo , Antibodies, Viral , Allergy and Immunology , Avian Leukosis Virus , Classification , Genetics , Physiology , Base Sequence , Cell Line , Cells, Cultured , Chickens , Genome, Viral , Genetics , Molecular Sequence Data , Phylogeny , Poultry Diseases , Virology , Sequence Alignment , Sequence Homology, Nucleic Acid , Viral Matrix Proteins , Genetics , Virus Replication , PhysiologyABSTRACT
By inoculation of blood samples in DF-1 (C/E) cell culture, an exogenous avian leukosis virus (ALV) strain SDAU09C2 was isolated from a breeder farm of Chinese native breed "Luhua" in Shandong province. Comparisons of the amino acid sequence of env gene gp85 from the isolate with those from other ALV reference strains of different subgroups indicated that SDAU09C2 had the highest gp85 identity to two reference strains of subgroup B of 92.5%. Its gp85 identity to other chicken ALV subgroups A, C, D, E was in the range of 73.2%-87.9%. The identity to subgroup J was only 30.3%-32.4%. This is the first report on isolation and identification of ALV-B and its gp85 from Chinese native breed chickens.
Subject(s)
Animals , Female , Amino Acid Sequence , Avian Leukosis , Virology , Avian Leukosis Virus , Chemistry , Classification , Genetics , Breeding , Chickens , Molecular Sequence Data , Phylogeny , Poultry Diseases , Virology , Viral Envelope Proteins , Chemistry , GeneticsABSTRACT
To characterize the long terminal repeat (LTR) of the ALV-J strain which can induce hemangioma, fragments of provirus LTR of the three different ALV-J strains SCAU-HN06, NX0101 and JS-nt were amplified with a pair of specific primers, then cloned and subjected to sequence analysis. In comparison with the prototype ALV-J strains HPRS-103 and ADOL-7501, the LTRs of domestic strains (SCAU-HN06, NX0101, JS-nt and SD07lk1) had an 88.0%-97.2% nucleotide sequence identity; the U5 and R regions in the LTR had a high nucleotide similarity, while the U3 region in the LTR showed significant variance. The LTR fragments from the different ALV-J strains were inserted into the upstream of bacterial CAT gene of the plasmid pCAT-Basic, respectively. The resultant recombinant plasmids were transfected into DF-1 cells. The transfected cells were harvested 48 h post-transfection, and cell lysates were prepared for CAT expression detection. The CAT assay was performed using CAT-ELISA. The results showed that the promoter activity of the LTRSCAU-HNO6 was a little higher than those of LTRJS-nt and LTRNX0101, but there was no significant difference in the promoter activity among the compared LTRs.
Subject(s)
Animals , Avian Leukosis Virus , Classification , Genetics , Base Sequence , Chickens , Molecular Sequence Data , Phylogeny , Promoter Regions, Genetic , Genetics , Sequence Homology, Nucleic AcidABSTRACT
Subgroup J Avian Leukosis Virus [ALV-J] was isolated in the late 1980s from meat-type chickens in the United Kingdom. ALV-J with exception of some acute variants, cause myeloid leukosis in meattype chickens with long incubation period. In this study while the status of Avian Leukosis Virus Subgroup J in six different strain of broiler grandparent flocks of Iran evaluated, the evaluation of different primers and some molecular methods also were done. For this reason, 100 blood samples, which had EDTA, 100 mixed of white blood cells and plasma and 100 feather pulps were collected from one farm of each broiler grandparent strain. PCR and nested PCR were methods that used for the study. In molecular study before the extraction of DNA from samples; In order to decrease the number of samples, 10 mixed of white blood cells and plasma, blood or feather pulp pooled. In molecular study with PCR all of samples were negative, but in nested PCR reaction, from six broiler strains, five strains infected to ALV-J. The results indicate that the most of broiler strains in Iran have been infected to ALVJ. The results also indicate that we can simply use pooled samples for the study of ALV-J in a flock by nested-PCR test
Subject(s)
Animals , Avian Leukosis Virus , Chickens , Polymerase Chain ReactionABSTRACT
Two strains of Avian leukosis virus subgroup B (ALV-B) were isolated for the first time in China Hy-line White on the cultured DF-1 cells which were inoculated tissue samples from by an ELISA assay, a histopathology examination and a PCR-based diagnosis. The results from the ELISA assay indicated that the positive rate of serum antibodies to ALV-B and ALV-J virus were 16.3% (15/92) and 13% (12/92), respectively. The histopathological examination indicated that two types of tumor cells existed at same focus in liver and spleen, which mainly were myelocytoma cells and lymphosarcoma cells. The PCR-based diagnosis were performed as follows: the cellular DNA was extracted from the inoculated DF-1 cells; the specific fragments of 1100 bp and 924 bp were obtained by a PCR system with the diagnostic primers of ALV-B and ALV-J; and the PCR results for ALV-A, MDV and REV were all negative. Then, the amplified fragments of the two ALV-B stains were partially sequenced and shown an identity of 92.8%,94.7% with the prototype strain of ALV-B (RSV Schmidt-ruppin B). The identities of two ALV-J strains with the prototype strain HPRS-103 at 96.9%, 91.5%; The identities of two ALV-J strains with the American prototype strain at 85.9%, 81.5%. Our study had shown that ALV-B was isolated for the first time from the ALV-J infected commercial layer flocks in China. It also indicated that the chance of genetic recombination among various subgroups of ALV was increased.
Subject(s)
Animals , Avian Leukosis , Pathology , Virology , Avian Leukosis Virus , Classification , Genetics , Cell Line , Chickens , China , Liver , Pathology , Virology , Molecular Sequence Data , Phylogeny , Poultry Diseases , Pathology , Virology , Spleen , Pathology , VirologyABSTRACT
Two Avian leukosis viruses of subgroup J (ALV-J) were isolated from layers by inoculating the sample into chicken embryo fibroblast (CEF) cells and by indirect fluorescent assay (IFA) with ALV-J specific monoclonal antibody JE-9. Sequence comparison indicated the gp85 identities were only in the ranges of 83.4%-87.3% compared with five international reference strains and 86.4%-89.6% compared with eight Chinese strains isolated from white meat-type chickens. The gp37 identities were in the range of 91.8-96.4% compared with the five international strains and 93.4-95.9% compared with the eight domestic strains. When compared with the above thirteen strains, two layers isolates were more close to the prototype HPRS-103 and had less deletion in 3'-Ter than those strains. All strains isolated from white meat-type chickens in China had a deletion in the "E" region of 3'-Ter except these two isolates, suggesting these two ALV-J isolates from layers have different evolution origins from other Chinese isolates from white meat-type chickens.