Susceptibility of various parental lines of commercial white leghorn layers to infection with a naturally occurring recombinant avian leukosis virus containing subgroup B envelope and subgroup J long terminal repeat

Chickens from seven different parental lines of commercial White Leghorn layer flocks from three independent breeders were inoculated with a naturally occurring avian leukosis virus (ALV) containing an ALV-B envelope and an ALV-J long terminal repeat (LTR) termed ALV-B/J. Additional groups of chickens from the same seven parental lines were inoculated with ALV-B. Chickens were tested for ALV viremia and antibody at 0, 4, 8, 16, and 32 wk postinfection. Chickens from all parental lines studied were susceptible to infection with ALV-B with 40%-100% of inoculated chickens positive for ALV at hatch following embryo infection. Similarly, infection of egg layer flocks with the ALV-B/J recombinant virus at 8 days of embryonation induced tolerance to ALV with 86%-100% of the chickens viremic, 40%-75% of the chickens shedding virus, and only 2/125 (2%) of the chickens producing serum-neutralizing antibodies against homologous ALV-B/J recombinant virus at 32 wk postinfection. In contrast, when infected with the ALV-B/J recombinant virus at hatch, 33%-82% of the chickens were viremic, 28%-47% shed virus, and 0%-56% produced serum-neutralizing antibodies against homologous ALV-B/J recombinant virus at 32 wk postinfection. Infection with the ALV-B/J recombinant virus at embryonation and at hatch induced predominately lymphoid leukosis (LL), along with other common ALV neoplasms, including erythroblastosis, osteopetrosis, nephroblastomas, and rhabdosarcomas. No incidence of myeloid leukosis (ML) was observed in any of the commercial White Leghorn egg layer flocks infected with ALV-B/J in the present study. Data suggest that the parental line of commercial layers may influence development of ALV-B/J-induced viremia and antibody, but not tumor type. Differences in type of tumors noted in the present study and those noted in the field case where the ALV-B/J was first isolated may be attributed to differences in the genetics of the commercial layer flock in which ML was first diagnosed and the present commercial layer flocks tested in the present study.     

J亚群与E亚群禽白血病自然重组病毒的全基因组序列分析

为了解我国东北地区部分养鸡场禽白血病病毒(ALV)的基因组序列特征及其变异情况,本研究从具有典型血管瘤病变的禽白血病发病鸡中分离到一株J亚群ALV(ALV-J)命名为JL0901,并进行了全基因测序.将该序列与已发表的ALV-J毒株序列进行比较研究,结果表明JL0901基因组的gag和pol基因相对保守,而env基因和3'端非编码区(3'UTR)的变异较大.对JL0901的env基因核苷酸序列进一步分析发现,在其gp85基因和gp37基因交界位置发生J亚群和E亚群ALV重组现象.本研究证实国内鸡群中存在J亚群和其他亚群ALV的自然重组现象,并表明国内ALV已出现新的变异趋势.     

Isolation and some characteristics of a subgroup J-like avian leukosis virus associated with myeloid leukosis in meat-type chickens in the United States.

Several subgroup J-like avian leukosis viruses (ALV-Js) were isolated from broiler breeder (BB) and commercial broiler flocks experiencing myeloid leukosis (ML) at 4 wk of age or older. In all cases, diagnosis of ML was based on the presence of typical gross and microscopic lesions in affected tissues. The isolates were classified as ALV-J by 1) their ability to propagate in chicken embryo fibroblasts (CEF) that are resistant to avian leukosis virus (ALV) subgroups A and E (C/AE) and 2) positive reaction in a polymerase chain reaction with primers specific for ALV-J. The prototype strain of these isolates, an isolate termed ADOL-Hc1, was obtained from an adult BB flock that had a history of ML. The ADOL-Hc1 was isolated and propagated on C/AE CEF and was distinct antigenically from ALV of subgroups A, B, C, D, and E, as determined by virus neutralization tests. Antibody to ADOL-Hc1 neutralized strain HPRS-103, the prototype of ALV-J isolated from meat-type chickens in the United Kingdom, but antibody to HPRS-103 did not neutralize strain ADOL-Hc1. On the basis of both viremia and antibody, prevalence of ALV-J infection in affected flocks was as high as 87%. Viremia in day-old chicks of three different hatches from a BB flock naturally infected with ALV-J varied from 4% to 25%; in two of the three hatches, 100% of chicks that tested negative for virus at hatch had evidence of viremia by 8 wk of age. The data document the isolation of ALV-J from meat-type chickens experiencing ML as young as 4 wk of age. The data also suggest that strain ADOL-Hc1 is antigenically related, but not identical, to strain HPRS-103 and that contact transmission of ALV-J is efficient and can lead to tolerant infection.     

Development and characterization of monoclonal antibodies to subgroup A avian leukosis virus

Avian leukosis virus subgroup A (ALV‐A) is a retrovirus which infects egg‐type chickens and is the main pathogen of lymphoid leukosis (LL) and myeloid leukosis (ML). In order to greatly enhance the diagnosis and treatment of clinical avian leukemia, two monoclonal antibodies (MAbs) to ALV‐A were developed by fusion between SP2/0 and spleen cells from mice immunized with expressed ALV‐A env‐gp85 protein. Using immunofluorescence assay (IFA), two MAbs reacted with ALV‐A, but not with subgroups B and J of ALV. Western blot tests showed that molecular weight of ALV‐A envelope glycoprotein recognized by MAbs was about 53 kD. Isotyping test revealed that two MAbs (A5C1 and A4C8) were IgG1 isotypes. These MAbs can be used for diagnosis and epidemiology of ALV‐A.     

Development and characterization of monoclonal antibodies to subgroup J avian leukosis virus.

In an attempt to develop a specific diagnostic test for avian leukosis virus (ALV) subgroup J (ALV-J) strain Hc1, four monoclonal antibodies (MAbs), JE9, G2, 145, and J47, were generated that are specific for ALV-J envelope glycoprotein, gp85. Polymerase chain reaction (PCR) was used to amplify genomic pro-viral DNA of Avian Disease and Oncology Laboratory (ADOL)-Hc1 and ADOL-4817 envelope genes. Both open reading frames encoding glycoproteins gp85 and gp37 were cloned into baculoviruses. Abundant expression of gp85 and gp37 was detected in the recombinant viruses with specific antibody to Hc1 strain of the ALV-J. The expressed proteins were used for immunization of mice to produce hybridoma cell lines secreting MAbs specific to ALV-J envelope protein. A panel of MAbs was generated by fusing NS1 myeloma cells and spleen cells from mice immunized with the recombinant baculoviruses. With the use of an immunofluorescence assay, three MAbs (JE9, G2, 145) reacted with ALV-J but not with subgroups A, B, C, D, or E of ALV. MAb J47 reacted with all exogenous subgroups of ALV including A, B, C, D, and J but not with endogenous subgroup E viruses. Western blot analysis was performed with all four MAbs against recombinant baculovirus and Hc1-infected chicken embryo fibroblast (CEF) lysates. A major band with a molecular weight about 90 kD corresponding to the size of ALV-J envelope was consistently obtained. With these MAbs, we detected the Hc1 antigen in CEFs infected with several ALV-J viruses isolated in the United States and also in tissue sections from chickens infected with Hc1 strain of ALV-J. These MAbs will be useful reagents for the diagnosis of ALV-J infection because they recognize a common antigenic epitope in six isolates tested thus far.     

蛋鸡J亚群禽白血病病毒SD1009分离株的分离鉴定及全基因组序列分析

为分析我国J亚群禽白血病病毒(ALV-J)蛋鸡分离株的进化关系,本研究将山东省某鸡场采集的蛋鸡病料样品接种DF-1细胞系,利用ELISA群特异性抗原检测以及亚群特异性间接免疫荧光方法,分离鉴定得到一株ALV-J,命名为SD1009,并对其进行全基因组测序,将该序列与其他ALV-J代表性病毒株序列进行比较。结果表明:SD1009分离株的gag和pol基因相对保守,与各参考病毒株的同源性为95%～99%,env基因的同源性为91%～95%;在其5'UTR中出现了连续19 bp的插入突变,与TW-3577、SDAU09C3、JS09GY6、JS09GY3蛋鸡分离株的5'UTR基本一致,提示19 bp的插入现象可能是近年来蛋鸡ALV-J的进化趋势;此外,其3'UTR的rTM和DR区出现部分缺失现象,该缺失部分也可能与ALV-J进化相关。     

Immunohistochemical localization of avian leukosis virus subgroup J in tissues from naturally infected chickens.

The tissue tropism of avian leukosis virus (ALV) subgroup J (ALV-J) was investigated in congenitally infected broiler chickens by an immunohistochemistry technique detecting gp85 viral glycoprotein. All organs examined contained detectable antigen. The most intense staining was in the adrenal gland, heart, kidney, and proventriculus. Intense staining for viral antigen in the heart may explain the ability of ALVs to cause cardiomyopathy. Although recent investigations failed to demonstrate specific viral staining in bone marrow from infected chickens, we were able to show moderate staining in myelocytic precursor cells in bone marrow. This finding agrees with previous work showing cell cultures of bone marrow are susceptible to ALV-J infection and the tendency of subgroup J to predominantly induce myeloid rather than lymphoid neoplasms.     

Myotropic avian leukosis virus subgroup J infection in a chicken

The study describes a highly productive myotropic avian leukosis virus infection (ALV) in a 3-month-old female chicken. At necropsy, ascites, hepatic fibrosis and cardiomegaly were seen. Histologically, the most striking lesion was the presence of cytoplasmic basophilic inclusions in myocardial fibers. Immunostaining for ALV group specific antigen p27 revealed a diffuse presence of virus antigen in cardiac myofibers, in smooth muscle fibers of most of the organs, and in rare, pancreatic and ovarian theca cells. Ultrastructurally, myocardial inclusions consisted of clusters of 50-60 nm round particles with interspersed ribosome-like granules. Numerous C-type particles were found in intercellular spaces of ALV p27 positive tissues. PCR analyses revealed the presence of both ALV-E and ALV-J related sequences. In chicken genome, ALV-E is usually present as endogenous provirus therefore, the pathological findings observed in this case are considered to be related with the ALV-J infection. The results of this report further confirm that ALV-J may be responsible for highly productive myotropic infections.     

Heterophil function and resistance to staphylococcal challenge in broiler chickens naturally infected with avian leukosis virus subgroup J

Avian leukosis virus subgroup J has a high tropism for myeloid lineage cells and frequently induces neoplastic transformation of myelocytes. The impact of congenital avian leukosis virus subgroup J infection on the function of circulating heterophils and susceptibility to staphylococcal infection was investigated. Six-week-old broiler chickens negative for exogenous avian leukosis viruses or congenitally infected with avian leukosis virus subgroup J were inoculated intravenously with 10(6) colony-forming units of Staphylococcus aureus, and pre- and postinoculation heterophil function was assessed. All chickens developed a leukocytosis with heterophilia after inoculation, but total leukocyte and heterophil counts were significantly higher in leukosis-negative chickens than in virus-infected chickens. Tenosynovitis was more severe in leukosis-negative chickens, and 2/10 (20%) of the virus-infected chickens had no histologic evidence of tenosynovitis. Osteomyelitis in the tibiotarsus or tarsometatarsus developed in 5/10 (50%) of the chickens in each group. S. aureus was recovered from the hock joint of 6/10 (60%) of the chickens in each group. Heterophils from all chickens exhibited similar phagocytic ability pre- and postinoculation. Heterophils from virus-infected chickens exhibited less bactericidal ability preinoculation than did heterophils from leukosis-negative chickens. However, postinoculation bactericidal ability was similar in both groups. Avian leukosis virus subgroup J provirus was present in heterophils isolated from congenitally infected chickens. Heterophils isolated from broiler chickens congenitally infected with avian leukosis virus subgroup J exhibit no significant functional deficits, and infected and uninfected chickens exhibit similar susceptibility to staphylococcal infection.     

Molecular characterization of three recombinant isolates of avian leukosis virus obtained from contaminated Marek's disease vaccines

Three natural recombinant avian leukosis viruses (ALV; PDRC-1039, PDRC-3246, and PDRC-3249) expressing a subgroup A gp85 envelope protein and containing long terminal repeats (LTR) of endogenous ALV-E viruses were isolated from contaminated commercial Marek's disease vaccines, cloned, and completely sequenced. Their full genomes were analyzed and compared with representative strains of ALV. The proviral DNA of all three isolates displayed 99.3% identity to each other, suggesting a possible common ancestor, even though the contaminating viruses were obtained from three separate vaccine serials produced by two different vaccine manufacturing companies. The contaminating viruses have a genetic organization typical of replication-competent alpharetroviruses. The proviral genomes of PDRC-1039 and PDRC-3246 are 7497 bp long, and the PDRC-3249 is three base pairs shorter because of a deletion of a threonine residue within the gp85 coding region. The LTR, gag, pol, and the transmembrane (TM) region (gp37) of the env gene of all three viruses displayed high identity to endogenous counterpart sequences (>98%). Only the surface (SU) region (gp85) of the env gene displayed high identity with exogenous ALV-A (98.7%). Locus-specific polymerase chain reaction (PCR) analysis for ALV endogenous sequences (ev loci) in the chicken embryo fibroblasts used to produce the original vaccine vials identified the presence of ev-1, ev-2, ev-3, ev-4, and ev-6 in all three vaccines. Homologous recombination most likely took place to involve the SU region of the env gene because the recombinant viruses only differ in this particular region from the consensus ALV-E. These results suggest that the contaminating ALV isolates probably emerged by recombination of ALV-A with endogenous virus sequences before vaccine preparation.     

Isolation and characterization of emerging subgroup J avian leukosis virus associated with hemangioma in egg-type chickens

Subgroup J avian leukosis virus (ALV-J), first isolated in 1989, predominantly causes myeloid leukosis (ML) in meat-type or egg-type chicken. Since 2006, the clinical cases of hemangioma rather than ML in commercial layer flocks associated with ALV-J have been reported, but it was still not clear whether the novel oncogenic ALV-J had emerged. We characterized SCAU-HN06 isolate of ALV-J from hemangioma in commercial Roman layers through animal experiment and full-length proviral genome sequence analysis. The SPF white leghorn egg-type chickens infected with SCAU-HN06 in ovo at day 11 of incubation showed an overall incidence of 56% hemangioma and 8% renal tumor throughout the 22-week trial, the mortality rate was 16%. Most genes of SCAU-HN06 isolate showed high nucleotide sequence identity to JS09GY6 which was isolated from Hy-Line Variety Brown layers suffering hemangioma. The 19-bp insertion in leader sequence and one key deletion in E element were the common features of SCAU-HN06 and JS09GY6. SCAU-HN06 and those ALV-Js associated with hemangioma, possibly recombinants of ALV-J and other avian retrovirus, may share the same ancestor.     

Immune response of chickens inoculated with a recombinant avian leukosis virus

Specific-pathogen-free embryos (18-day incubation) and hatched chicks were inoculated with a recombinant avian leukosis virus (ALV) produced by recombinant DNA techniques. Enzyme-linked immunosorbent assays were used to measure the production of viral-protein-specific antibody and the viral protein, p27, in the serum at 2, 5, 8, 14, and 20 weeks of age. Of the inoculated chickens surviving to 20 weeks, 64% produced viral-protein-specific antibodies and 42% transiently produced the viral protein, p27. Chickens inoculated as embryos did not differ significantly from those inoculated at hatch with respect to antibody and viral protein production. Antibody production peaked at 5 weeks postinoculation and declined over the remaining 15 weeks of the study. No evidence of chronic tolerant infection or mortality due to neoplastic disease was found.     

Localization of avian leukosis virus subgroup J in naturally infected chickens by RNA in situ hybridization.

The novel subgroup J of avian leukosis virus (ALV-J) has emerged as a significant cause of myeloid neoplasia and weight suppression in broiler chickens. We investigated viral tropism using RNA in situ hybridization (ISH) in naturally infected chickens. Formalin-fixed tissues were collected from 12-day-old embryos (seven infected, two control) and from 0-week-old (four infected, one control), 3-week-old (five infected, one control), 6-week-old (five infected, one control), and 9-week-old (10 infected, two control) chickens naturally infected with ALV-J in ovo. A 636-base antisense riboprobe complementary to the 3' and 5' ends of the pol and env viral genes, respectively, was constructed. Strong positive staining was present in cardiac myocytes, Purkinje fibers, vascular and pulmonary smooth muscle, renal glomeruli, distal tubules, and pituitary glands. Light staining was present in gastrointestinal smooth muscle, thyroid and adrenal glands, and follicular medullae in the cloacal bursa. Staining was not present in any hematopoietic precursors. Tissues from newly hatched chicks exhibited the strongest and most consistent staining, whereas staining in embryos was minimal. RNA ISH confirmed the presence of ALV-J-specific nucleic acid within cytoplasmic inclusions in cardiac myocytes, Purkinje fibers, pituitary glands, and renal glomeruli. Viral tropism for cardiac myocytes and Purkinje fibers may relate pathogenetically to the cardiomyopathy and congestive heart failure described in index chicken flocks infected with ALV-J. Viral tropism for endocrine organs may relate pathogenetically to the weight suppression associated with infection.     

LTR对J亚群禽白血病病毒感染的影响

为探讨LTR基因在骨髓瘤病变型J亚群禽白血病病毒(ALV-J) NX0101致病中的作用,利用反向遗传将血管瘤病变型ALV-J HN06株中两端LTR元件替换至NX0101株的相应位置,拯救出重组病毒NX-HNLTR株.人工接种7日龄SPF雏鸡,分别检测NX0101株和NX-HNLTR株对鸡体的影响.感染鸡生长都较慢.感染NX0101株的鸡,胸腺指数和腔上囊指数明显比对照组低,脾脏指数与对照组相比波动较大,骨髓和脾脏在攻毒后3周可检测到病毒整合到基因组中,胸腺和腔上囊在攻毒后6周才检测到.感染NX-HNLTR株的鸡脾脏指数明显比对照组低,攻毒后2周可检测到病毒整合到脾脏基因组中,骨髓和胸腺分别在攻毒后3周和6周检测到.结果提示,LTR对NX0101株感染鸡的免疫器官有一定的影响.     

K亚群禽白血病病毒分离株全基因组测序及序列分析

K亚群禽白血病病毒(ALV-K)是近年来从地方品种鸡分离鉴定的新亚群ALV。本试验在对江苏某原种鸡场保存的琅琊鸡开展禽白血病净化过程中,分离并鉴定1株ALV-K,命名为JS13LY19。为探明其基因组来源及特征,对JS13LY19分离株前病毒DNA进行了分段克隆和测序,获得全长基因组序列,并与各亚群ALV参考株进行比对分析。结果显示,JS13LY19分离株符合复制完整型C型反转录病毒特征,缺乏肿瘤基因。其gp85基因相较于其他亚群ALV,与ALV-K参考株遗传进化关系最为接近,与ALV-K原型株JS11C1一致性最高(99.2%);而gag、pol、gp37、LTR、UTR及JS13LY19与内源性ALV显示出更高的一致性(92.0%～99.4%);其LTR U3区比大部分外源性ALV LTR少了1个CAAT enhancer盒、PRE盒、CArG盒及Y盒。JS13LY19分离株极有可能是JS11C1与内源性ALV重组产生,且具有内源性ALV LTR及U3区转录调控元件的部分缺失,可能使JS13LY19转录能力下降而致病性降低。     

实时荧光定量RT-PCR检测禽白血病病毒J亚群

将禽白血病病毒J亚群(ALV-J)NX0101毒株接种1日龄和7日龄SPF雏鸡并设阴性对照组,采用实时荧光定量RT-PCR方法,定期检测病毒在体内的复制情况。根据GenBank发表的ALV-Jenv基因保守序列(AY897227)设计1对特异性引物扩增目的基因;根据鸡的3-磷酸甘油醛脱氢酶(GAPDH)基因序列(K01458),在保守区内设计1对引物扩增内参照基因,分别克隆入质粒作为标准品制作标准曲线,采用SYBR GreenⅠ染料建立荧光定量PCR法,并对方法的特异性、敏感性和重复性进行评价。结果显示,标准曲线的Ct值与标准品浓度的对数值之间存在线性关系;最低每个反应可检测到60个拷贝的病毒数,比常规PCR灵敏度高1 000倍。检测结果分别采用绝对定量法和相对定量法进行分析,都达到了良好的效果。通过对病毒含量变化的检测发现,在雏鸡4周龄时,2个接毒组ALV-J病毒突然呈对数式增长。据此分析ALV-J病毒在体内经过3~4周潜伏后,突然呈暴发式增长,这种情况可能和临床表现的免疫抑制直接相关。结果表明,本试验建立了一种特异性强、敏感性高、可定量分析ALV-J病毒增殖的方法,为进一步相关研究奠定了基础。     

Cardiomyopathy in broiler chickens congenitally infected with avian leukosis virus subgroup J

Dilated cardiomyopathy and ascites in broiler chickens are frequently associated with rapid growth and pulmonary hypertension, but can be associated with some avian leukosis virus (ALV) infections. The novel subgroup J of ALV has a high cardiac tropism, but dilated cardiomyopathy has not been reported previously. We report a dilated cardiomyopathy incidence of 11.1% in broiler chickens congenitally infected with ALV subgroup J (ALV-J). Gross lesions included severe body weight suppression, cardiomegaly with biventricular dilation, right ventricular hypertrophy, visceral congestion, and ascites. Cardiac myocytes and Purkinje fibers contained 2- to 10-microm intracytoplasmic magenta inclusions that contained ALV-J-specific nucleic acid. Ultrastructurally, inclusions contained ribosomes and immature virions and were associated with myofibril disruption and disarray. Peracute centrilobular hepatic necrosis was present in most cases. ALV-J-associated cardiomyopathy may involve a direct viral effect on cardiac myocytes and Purkinje fibers.     

Detection and localization of naturally transmitted avian leukosis subgroup J virus in egg-type chickens by in situ PCR hybridization

Avian leukosis virus (ALV) subgroup J (ALV-J) is an exogenous ALV and causes myeloid leukosis in meat-type chickens. We have previously reported the isolation and identification of ALV-J in commercial layer flocks from 12 farms in northern China. In this report, we further characterized this virus by in situ polymerase chain reaction (PCR) hybridization in various affected organs of chickens from six of the 12 farms. A routine method for hybridization of nucleic acid uses radioactive probe, such as a P32-labelled probe. We found that the non-radioactive digoxigenin (DIG) probe is sensitive enough to detect the nucleic acid of virus in chicken tissues. We used a pair of published primers (H5/H7) specific to the gp85 envelope gene and 3' region of pol gene of prototype ALV-J strain HPRS-103. The total RNA extracted from tumour, bone marrow, oviduct, liver and spleen of the diseased chickens from six commercial flocks, and cDNA was successfully amplified. Using the primers and cDNA, we obtained an ALV-J-specific cDNA probe of 545 bp in length by PCR. In situ PCR with H5/H7 primers was carried out in the paraffin sections from tissues of the diseased chickens, followed by in situ hybridization using the DIG-labelled cDNA probe. Positive hybridization signals were detected in the cytoplasm of paraffin sections of tumours and other organ tissues. The intensity of the signals was documented using an image analysis system measuring integral optical density (IOD). The IOD values for tissue sections treated by in situ PCR hybridization are significantly higher than that by in situ hybridization alone (P < 0.01). These data taken together suggest that in situ PCR hybridization is a more sensitive technique for detection of ALV-J in tissue sections.