The Unique Envelope Gene of the Subgroup J Avian Leukosis Virus Derives from ev/J Proviruses, a Novel Family of Avian Endogenous Viruses

A new subgroup of avian leukosis virus (ALV), designated subgroup J, was identified recently. Viruses of this subgroup do not cross-interfere with viruses of the avian A, B, C, D, and E subgroups, are not neutralized by antisera raised against the other virus subgroups, and have a broader host range than the A to E subgroups. Sequence comparisons reveal that while the subgroup J envelope gene includes some regions that are related to those found in env genes of the A to E subgroups, the majority of the subgroup J gene is composed of sequences either that are more similar to those of a member (E51) of the ancient endogenous avian virus (EAV) family of proviruses or that appear unique to subgroup J viruses. These data led to the suggestion that the ALV-J env gene might have arisen by multiple recombination events between one or more endogenous and exogenous viruses. We initiated studies to investigate the origin of the subgroup J envelope gene and in particular to determine the identity of endogenous sequences that may have contributed to its generation. Here we report the identification of a novel family of avian endogenous viruses that include env coding sequences that are over 95% identical to both the gp85 and gp37 coding regions of subgroup J viruses. We call these viruses the ev/J family. We also report the isolation of ev/J-encoded cDNAs, indicating that at least some members of this family are expressed. These data support the hypothesis that the subgroup J envelope gene was acquired by recombination with expressed endogenous sequences and are consistent with acquisition of this gene by only one recombination event.     

A 19-Nucleotide Insertion in the Leader Sequence of Avian Leukosis Virus Subgroup J Contributes to Its Replication in Vitro but Is Not Related to Its Pathogenicity in Vivo

Subgroup J avian leukosis virus (ALV-J) was first isolated from meat-type chickens that had developed myeloid leukosis and since 2008, ALV-J infections in chickens have become widespread in China. A comparison of the sequence of ALV-J epidemic isolates with HPRS-103, the ALV-J prototype virus, revealed several distinct features, one of which is a 19-nucleotide (nt) insertion in the leader sequence. To determine the role of the 19-nt insertion in ALV-J pathogenicity, a pair of viruses were constructed and rescued. The first virus was an ALV-J Chinese isolate (designated rSD1009) containing the 19-nt insertion in its leader sequence. The second virus was a clone, in which the leader sequence had a deleted 19-nt sequence (designated rSD1009△19). Compared with rSD1009△19, rSD1009 displayed a moderate growth advantage in vitro. However, no differences were demonstrated in either viral replication or oncogenicity between the two rescued viruses in chickens. These results indicated that the 19-nt insertion contributed to ALV-J replication in vitro but was not related to its pathogenicity in vivo.     

The follicle promotes the evolution of variants of avian leukosis virus subgroup J in vertical transmission

Avian leukosis virus (ALV) is one of the main causative agent of tumor development, which brings enormous economic losses to the poultry industry worldwide. ALV can be transmitted horizontally and vertically, and the latter often give rise to more adverse pathogenicity. However, the propagation and evolution of ALV underlying vertical transmission remain not-well understood. Herein, an animal model for the evolution of variants of ALV subgroup J (ALV-J) in the vertical transmission was built and different organs from infected hens and plasma from their ALV-positive progenies were collected, and then three segments in the hypervariable regions of ALV (gp85-A, gp85-B, LTR-C) were amplified and sequenced using conventional Sanger sequencing and MiSeq high-throughput sequencing, respectively. The results showed that the genomic diversity of ALV-J occurred in different organs from ALV-J infected hen, and that the dominant variants in different organs of parental hens, especially in follicle, changed significantly compared with original inoculum strain. Notably, the dominant variants in progenies exhibited higher homologies with variants in parental hens’ follicle (88.9%–98.9%) than other organs (85.6%–91.1%), and most consistent mutations in the variants were observed between the progenies and parental hen’s follicle. Furthermore, HyPhy analysis indicated that the global selection pressure value (ω) in the follicle is significantly higher than those in other organs. In summary, an animal model for vertical transmission was built and our findings revealed the evolution of variants of ALV in the process of vertical transmission, moreover, the variants were most likely to be taken to the next generation via follicle, which may be related to the higher selection pressure follicle underwent.     

Avian leukosis virus subgroup J infection influences the gut microbiota composition in Huiyang bearded chickens

Avian leukosis virus (ALV) poses a major threat to poultry. The chicken gut microbiota plays critical roles in host performance, health and immunity. However, the effect of viral infection on the microbiota of Chinese local chickens is not well understood. In this study, we performed high-throughput 16S rRNA gene sequencing and evaluated the gut microbiota profiles using faeces from ALV subgroup J (ALV-J)-infected and healthy Huiyang bearded chickens (Chinese local chickens). At the phylum level, ALV-J infection mainly increased the abundance of Bacteroidetes and Proteobacteria and decreased that of Firmicutes. An analysis at the order, family and genus levels showed that the abundance of Lactobacillales, Lactobacillaceae and Lactobacillus was the highest in normal chicken faeces, accounting for 89·07%, 86·47% and 86·46%, respectively, of phylotypes. Moreover, samples from ALV-J-infected chickens were enriched with Bacteroidales, Clostridiales, Bacteroidaceae, Ruminococcaceae, Lachnospiraceae and Bacteroides. Our findings highlight that ALV-J infection alters the gut microbiota and disrupts the host–microbial homeostasis in chickens, which may be involved in the pathogenesis of ALV-J infection.     

禽白血病病毒J亚群env基因的克隆和序列分析

应用多聚酶链反应（PCR）的方法扩增出ADOL-4817毒株的囊膜蛋白env基因,并克隆进大肠杆菌。经核酸序列分析证明,env基因的大小为1746 bp,其中gp85和gp37由1554 bp组成,可翻译成517个氨基酸,分子量为57.7 D。根据糖基化位点N-X-S/T的特点,发现ADOL-4817的env蛋白有15个潜在的糖基化位点。同源性分析证明,ADOL-4817的env基因与其它ALV-J的env基因序列同源性为88.8%～92.4%,而与外源性ALVs的相应序列的同源性仅为40.5%～51.4%,然而,与内源性的EAV-HP毒株的类env基因的同源性高达91.2%;另外,ADOL-4817毒株的gp37在C末端多了13个氨基酸。这些结果提示,ALV-J的env基因存在广泛的变异性,env基因可能来源于内源性和外源性ALVs的重组。     

Detection and Molecular Characterization of J Subgroup Avian Leukosis Virus in Wild Ducks in China

To assess the status of avian leukosis virus subgroup J (ALV-J) in wild ducks in China, we examined samples from 528 wild ducks, representing 17 species, which were collected in China over the past 3 years. Virus isolation and PCR showed that 7 ALV-J strains were isolated from wild ducks. The env genes and the 3′UTRs from these isolates were cloned and sequenced. The env genes of all 7 wild duck isolates were significantly different from those in the prototype strain HPRS-103, American strains, broiler ALV-J isolates and Chinese local chicken isolates, but showed close homology with those found in some layer chicken ALV-J isolates and belonged to the same group. The 3′UTRs of 7 ALV-J wild ducks isolates showed close homology with the prototype strain HPRS-103 and no obvious deletion was found in the 3′UTR except for a 1 bp deletion in the E element that introduced a binding site for c-Ets-1. Our study demonstrated the presence of ALV-J in wild ducks and investigated the molecular characterization of ALV-J in wild ducks isolates.     

Genetic Structure and Molecular Variability of Cucumber mosaic virus Isolates in the United States

Cucumber mosaic virus (CMV) has a worldwide distribution and the widest host range of any known plant virus. From 2000 to 2012, epidemics of CMV severely affected the production of snap bean (Phaseulos vulgaris L.) in the Midwest and Northeastern United States. Virus diversity leading to emergence of new strains is often considered a significant factor in virus epidemics. In addition to epidemics, new disease phenotypes arising from genetic exchanges or mutation can compromise effectiveness of plant disease management strategies. Here, we captured a snapshot of genetic variation of 32 CMV isolates collected from different regions of the U.S including new field as well as historic isolates. Nucleotide diversity (π) was low for U.S. CMV isolates. Sequence and phylogenetic analyses revealed that CMV subgroup I is predominant in the US and further showed that the CMV population is a mixture of subgroups IA and IB. Furthermore, phylogenetic analysis suggests likely reassortment between subgroups IA and IB within five CMV isolates. Based on phylogenetic and computational analysis, recombination between subgroups I and II as well as IA and IB in RNA 3 was detected. This is the first report of recombination between CMV subgroups I and II. Neutrality tests illustrated that negative selection was the major force operating upon the CMV genome, although some positively selected sites were detected for all encoded proteins. Together, these data suggest that different regions of the CMV genome are under different evolutionary constraints. These results also delineate composition of the CMV population in the US, and further suggest that recombination and reassortment among strain subgroups does occur but at a low frequency, and point towards CMV genomic regions that differ in types of selection pressure.     

Replacement of primary chicken embryonic fibroblasts (CEF) by the DF-1 cell line for detection of avian leucosis viruses.

International regulations prescribe that the absence of avian leucosis viruses (ALV) in avian live virus vaccines has to be demonstrated. Primary chicken embryo fibroblasts (CEF) from special SPF chicken lines are normally used for detection of ALV. The suitability of the DF-1 cell line for ALV-detection, as alternative for primary CEF, was studied in three types of experiments: (1) in titration experiments without cell passage, (2) in experiments with passages in cell cultures according to European Pharmacopoeia requirements, and (3) in experiments with commercial live avian vaccines that had been spiked with known amounts of ALV. In all tests the sensitivity of ALV-A and ALV-J detections on DF-1 cells was at least as high as on primary CEF. The sensitivity of ALV-B detection was always superior when DF-1 cells were used. ALV were detected earlier in all comparative tests when DF-1 cells were used. ALV-A, ALV-B and ALV-J all induced CPE on DF-1 cells, whereas no clear CPE was seen on CEF-cells. For reasons of sensitivity, standardisation as well as reduction of animal use, the data support the use of DF-1 cells to monitor absence of ALV in vaccine virus seed lots or finished products.     

A 205-Nucleotide Deletion in the 3′ Untranslated Region of Avian Leukosis Virus Subgroup J,Currently Emergent in China,Contributes to Its Pathogenicity

In the past 5 years, an atypical clinical outbreak of avian leukosis virus subgroup J (ALV-J), which contains a unique 205-nucleotide deletion in its 3′ untranslated region (3′UTR), has become epidemic in chickens in China. To determine the role of the 205-nucleotide deletion in the pathogenicity of ALV-J, a pair of viruses were constructed and rescued. The first virus was an ALV-J Chinese isolate (designated HLJ09SH01) containing the 205-nucleotide deletion in its 3′UTR. The second virus was a chimeric clone in which the 3′UTR contains a 205-nucleotide sequence corresponding to a region of the ALV-J prototype virus. The replication and pathogenicity of the rescued viruses (rHLJ09SH01 and rHLJ09SH01A205) were investigated. Compared to rHLJ09SH01A205, rHLJ09SH01 showed a moderate growth advantage in vitro and in vivo, in addition to exhibiting a higher oncogenicity rate and lethality rate in layers and broilers. Increased vascular endothelial growth factor A (VEGF-A) and vascular endothelial growth receptor subtype 2 (VEGFR-2) expression was induced by rHLJ09SH01 more so than by rHLJ09SH01A205 during early embryonic vascular development, but this increased expression disappeared when the expression levels were normalized to the viral levels. This finding suggests that the expression of VEGF-A and VEGFR-2 is associated with viral replication and may also represent a novel molecular mechanism underlying the oncogenic potential of ALV-J. Overall, our findings not only indicate that the unique 205-nucleotide deletion in the ALV-J genome occurred naturally in China and contributes to increased pathogenicity but also point to the possible mechanism of ALV-J-induced oncogenicity.     

Acutely transforming avian leukosis virus subgroup J strain 966: defective genome encodes a 72-kilodalton Gag-Myc fusion protein

Avian leukosis virus subgroup J (ALV-J), the most recent member of the avian retroviruses, is predominantly associated with myeloid leukosis in meat-type chickens. We have previously demonstrated that the acutely transforming virus strain 966, isolated from an ALV-J-induced tumor, transformed peripheral blood monocyte and bone marrow cells in vitro and induced rapid-onset tumors, suggesting transduction of oncogenes (L. N. Payne, A. M. Gillespie, and K. Howes, Avian Dis. 37:438-450, 1993). In order to understand the molecular basis for the rapid transformation and tumor induction, we have determined the complete genomic structure of the provirus of the 966 strain. The sequence of the 966 provirus clone revealed that its genome is closely related to that of HPRS-103 but is defective, with the entire pol and parts of the gag and env genes replaced by a 1,491-bp sequence representing exons 2 and 3 of the c-myc gene. LSTC-IAH30, a stable cell line derived from turkey monocyte cultures transformed by the 966 strain of ALV-J, expressed a 72-kDa Gag-Myc fusion protein. The identification of the myc gene in 966 virus as well as in several other ALV-J-induced tumors suggested that the induction of myeloid tumors by this new subgroup of ALV occurs through mechanisms involving the activation of the c-myc oncogene.     

禽白血病病毒J亚群env基因的克隆和序列分析

应用多聚酶链反应（PCR）的方法增出ADOL－4817毒株的囊膜蛋白env基因,并克隆进大肠杆菌。经核酸序列分析证明,env基因的大小为1746bp,其中gp85和gp37mh 1554bp组成,可翻译成517个氨基酸,分子量为57.7kD。根据糖基化位点N－X－S／T的特点,发现ADOL－4817的env蛋白有15个潜在的糖基化位点。同源性分析证明,ADOL－4817的env基因与其它ALV－J的env基因序列同源性为88.8％－92.4%,而与外源性ALVs的相应序列的同源性仅为40.5％－51.4％,然而,与内源性的EAV－HP毒株的类env基因的同源性高达91.2％;另外,ADOL－4817毒株的gp37d C末端多了13个氨基酸,这些结果提示,ALV－J的env基因存在广泛的变异性,env基因可能来源于内源性和外源性ALVs的重组。     

Identification of Cyst Nematodes of Agronomic and Regulatory Concern with PCR-RFLP of ITS1

The first internally transcribed spacer region (ITS1) from cyst nematode species (Heteroderidae) was compared by nucleotide sequencing and PCR-RFLP. European, Asian, and North American isolates of five heterodefid species were examined to assess intraspecific variation. PCR-RFLP patterns of amplified ITS1 DNA from pea cyst nematode, Heterodera goettingiana, from Northern Ireland were identical with patterns from Washington State. Sequencing demonstrated that ITS1 heterogeneity existed within individuals and between isolates, but did not result in different restriction patterns. Three Indian and two U.S. isolates of the corn cyst nematode, Heterodera zeae, were compared. Sequencing detected variation among ITS1 clones from the same individual, between individuals, and between isolates. PCR-RFLP detected several restriction site differences between Indian and U.S. isolates. The basis for the restriction site differences between isolates from India and the U.S. appeared to be the result of additional, variant ITS1 regions amplified from the U.S. isolates, which were not found in the three India isolates. PCR-RFLP from individuals of the U.S. isolates created a composite pattern derived from several ITS1 types. A second primer set was specifically designed to permit discrimination between soybean (H. glycines) and sugar beet (H. schachtii) cyst nematodes. Fok I digestion of amplified product from soybean cyst nematode isolates displayed a uniform pattern, readily discernible from the pattern of sugar beet and clover cyst nematode (H. trifolii).     

致蛋鸡血管瘤J亚群禽白血病病毒cDNA全序列分析

【目的】了解近年来我国商品蛋鸡群中以血管瘤为主要表型的J亚群禽白血病病毒(Avian Leukosis Virus subgroup J,ALV-J)的分子生物学特性,为控制ALV-J在鸡群中流行提供基础资料。【方法】采用PCR扩增和序列分析技术,对分离自血管瘤或者血管瘤与髓样细胞瘤(Myeloid Leukosis,ML)并存的3株蛋鸡ALV-J毒株前病毒DNA的全序列及3株商品蛋鸡血管瘤型分离毒和1株商品蛋鸡ML型分离毒的致瘤关键性序列进行研究。【结果】来自血管瘤或者血管瘤与ML并存的商品蛋鸡分离毒株与来自肉鸡分离毒株的全序列差异明显,在遗传进化树上分属两个大的分支;研究发现商品蛋鸡血管瘤及ML混合病例分离毒JS09GY3与JS09GY6株的引物结合位点(Primer Binding Site,PBS)-Leader中出现极为罕见的连续19bp的插入突变,其与劳斯相关病毒1(Rous Associated Virustype1,RAV-1)、劳斯相关病毒2(Rous Associated Virustype2,RAV-2)及劳斯肉瘤病毒施密特-鲁宾二氏[Rous sarcoma virus(strain Schmidt-RuppinB),RSV-SRB]毒株序列相同;通过对U3区调控元件的分析,发现血管瘤商品蛋鸡病例分离毒NHH与JS09GY5的U3区各发生1处连续序列缺失,出现了极为独特的c-Est-1、TCF11及C/EBP结合位点,这些调控元件可能与病毒的致肿瘤特性相关;所测的5株血管瘤商品蛋鸡分离毒均保留完整E元件,而所有肉鸡分离毒的E元件均发生了几乎相同的大部分序列缺失;首次发现血管瘤商品蛋鸡分离毒JS09GY3的E元件中有11bp的连续插入序列。【结论】商品蛋鸡血管瘤型ALV-J与肉鸡分离毒在全序列上差异明显,U3、DR1和E元件等区域有一部分特殊的突变与毒株的宿主类型和肿瘤表型有一定关系,其功能尚需进一步研究。而血管瘤型、髓细胞瘤型ALV-J可能是ALV-J与其它反转录病毒的重组毒。     

The mechanism of transduction of proto-oncogene c-src by avian retroviruses

Chicken c-src sequences have been transduced by avian leukosis viruses (ALV) and by partial src-deletion (td) mutants of Rous sarcoma virus in several independent events. Analyses of the recombination junctions in the genomes of src-containing viruses and the c-src DNA have shed light on the mechanism of transduction, which involves at least two steps of recombination. The initial recombination between a viral genome and the 5' region of c-src appears to occur at the DNA level. This step does not require extensive homology and can be mediated by stretches of sequences with only partial homology. The 5' recombination junction can also be formed by splicing between viral and c-src sequences. The second recombination is presumed to occur between the transducing ALV or td viral RNA and the viral-c-src hybrid RNA molecule generated from the initial recombination. This step involving recombination at the 3' ends of those molecules restores the 3' viral sequences essential for replication to the viral-c-src hybrid molecule. High frequency of c-src transduction by partial td mutants suggests that the second recombination is greatly enhanced when there is sequence homology between the transducing virus and the 3' region of c-src. Incorporation of the c-src sequences into an ALV genome results in greatly elevated expression of the gene. However, increased expression of c-src alone is insufficient to activate its transforming potential. Structural changes in c-src are necessary to convert it into a transforming gene. The changes can be as small as single nucleotide changes resulting in single amino aid substitutions at certain positions. Mutations can occur rapidly during viral replication after c-src is incorporated into the viral genome. Therefore, it is most likely that transduction of c-src by ALV is followed by subsequent mutation and selection for the sarcomagenic virus. In the case of transduction by td viruses that retain certain src sequences, joining of these sequences with the transduced c-src apparently is sufficient to activate its transforming potential.     

ALV-J GP37 Molecular Analysis Reveals Novel Virus-Adapted Sites and Three Tyrosine-Based Env Species

Compared to other avian leukosis viruses (ALV), ALV-J primarily induces myeloid leukemia and hemangioma and causes significant economic loss for the poultry industry. The ALV-J Env protein is hypothesized to be related to its unique pathogenesis. However, the molecular determinants of Env for ALV-J pathogenesis are unclear. In this study, we compared and analyzed GP37 of ALV-J Env and the EAV-HP sequence, which has high homology to that of ALV-J Env. Phylogenetic analysis revealed five groups of ALV-J GP37 and two novel ALV-J Envs with endemic GP85 and EAV-HP-like GP37. Furthermore, at least 15 virus-adapted mutations were detected in GP37 compared to the EAV-HP sequence. Further analysis demonstrated that three tyrosine-based motifs (YxxM, ITIM (immune tyrosine-based inhibitory motif) and ITAM-like (immune tyrosine-based active motif like)) associated with immune disease and oncogenesis were found in the cytoplasmic tail of GP37. Based on the potential function and distribution of these motifs in GP37, ALV-J Env was grouped into three species, inhibitory Env, bifunctional Env and active Env. Accordingly, 36.91%, 61.74% and 1.34% of ALV-J Env sequences from GenBank are classified as inhibitory, bifunctional and active Env, respectively. Additionally, the Env of the ALV-J prototype strain, HPRS-103, and 17 of 18 EAV-HP sequences belong to the inhibitory Env. And models for signal transduction of the three ALV-J Env species were predicted. Our findings and models provide novel insights for identifying the roles and molecular mechanism of ALV-J Env in the unique pathogenesis of ALV-J.     

禽白血病A亚群病毒gp85的单因子血清制备及其特异性鉴定

【目的】为了研究出一种能够针对A亚群禽白血病的快速特异性诊断试剂。【方法】将A亚群禽白血病病毒(ALV-A)SDAU09E1株接种于DF1细胞上,以感染细胞DNA为模板,通过PCR方法扩增出1023bp的ALV-A-gp85基因。将其正确阅读框架插入表达载体PET-32a(+)中,实现在BL21(Rosetta)宿主菌中表达。将纯化的融合蛋白常规免疫小鼠,制备得抗血清。【结果】实验成功获得52.8kDa的重组融合蛋白,且具有良好的免疫原性。间接免疫荧光试验(IFA)表明该血清可与ALV-A和ALV-B反应,但不与ALV-J反应。【结论】该实验首次在国内外研制出能用于鉴别性检测经典的A/B亚群ALV的单因子血清,可与ALV-J特异性单抗互补作用于外源性ALV感染的鉴别性诊断。我国鸡群同时受经典的ALV-A/B和新出现的ALV-J困扰,鉴别诊断非常必要,研究这种试剂具有较高的实用价值。     

Expression of endogenous retrovirus ev/J <Emphasis Type="Italic">gp85</Emphasis> gene and analysis of its immunoreactivity in comparison with exogenous viral protein

The envelope gene gp85 of ev/J, a new family of endogenous avian retroviral sequences identified recently, has the most extensive nucleotide sequence identity ever described with ALV-J avian leukosis virus. This report described expression of ev/J envelope gene gp85 derived from commercial meat-type chicken using the Invitrogen Bac-to-Bac baculovirus expression system. The antigenicity and immunoreactivity of the recombinant endogenous gp85 gene product (SU) were analyzed by indirect immunofluorescence, Western blot, indirect and blocking Enzyme-Linked ImmunoSorbent Assay (ELISA) using JE9 monoclonal antibody (MAb) against the envelope protein of ALV-J (ADOL-4817), positive mouse antiserum against the ev/J gp85 SU and sera from chicken naturally infected with ALV-J. The results showed that the ev/J gp85 SU can bind specifically to JE9 MAb and antiserum from chicken naturally infected with ALV-J, and the binding reactivity between exogenous ALV-J gp85 SU and natural positive chicken serum against exogenous ALV-J can be blocked by positive mouse serum against the ev/J gp85 SU. It is concluded that recombinant endogenous gp85 gene product (SU) has close immunological relatedness to the envelope protein of exogenous ALV-J (ADOL-4817 and IMC₁₀₂₀₀ strain). Foundation items: Natural Science Foundation of China (30460098); China Postdoctoral Science Foundation funded project (2005038585).     

Segregation of EAV-HP Ancient Endogenous Retroviruses within the Chicken Population

Avian leukosis virus subgroup J (ALV-J), an exogenous avian retrovirus, is thought to have evolved by recombination with the highly identical env gene of the endogenous avian retrovirus EAV-HP. Embryonic expression of EAV-HP env has been suggested to be associated with the induction of immunological tolerance, a feature observed in a significant proportion of meat-type chickens infected with ALV-J. In support of this hypothesis, we demonstrate that EAV-HP loci, some of which could be associated with tolerance, are still segregating within the chicken population.     

Expression of Endogenous Retrovirus ev/J gp85 Gene and Analysis of Its Immunoreactivity in Comparison with Exogenous Viral Protein

The envelope gene gp85 of ev/J,a new family of endogenous avian retroviral sequences identified recently, has the most extensive nucleotide sequence identity ever described with ALV-J avian ieukosis virus. This report described expression of ev/J envelope gene gp85 derived from commercial meat-type chicken using the Invitrogen Bac-to-Bac baculovirus expression system. The antigenicity and immunoreactivity of the recombinant endogenous gp85 gene product (SU) were analyzed by indirect immunofluorescence, Western blot, indirect and blocking Enzyme-Linked ImmunoSorbent Assay (ELISA) using JE9 monoclonal antibody (MAb) against the envelope protein of ALV-J (ADOL-4817), positive mouse antiserum against the ev/J gp85 SU and sera from chicken naturally infected with ALV-J. The results showed that the ev/J gp85 SU can bind specifically to JE9 MAb and antiserum from chicken naturally infected with ALV-J, and the binding reactivity between exogenous ALV-J gp85 SU and natural positive chicken serum against exogenous ALV-J can be blocked by positive mouse serum against the ev/J gp85 SU. It is concluded that recombinant endogenous gp85 gene product (SU) has close immunological relatedness to the envelope protein of exogenous ALV-J (ADOL-4817 and IMC<,10200> strain).