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.

Male-mediated venereal transmission of endogenous avian leukosis virus

Congenital transmission of avian leukosis viruses (ALV) occurs readily through the egg, but transmission of ALV through male seminal fluid is considered to be nonexistent or rare. Progeny from mating endogenous late-feathering (LF), K/k+ males carrying an endogenous virus gene (ev21) with virgin early-feathering (EF) k+/w females were examined for the presence of infectious endogenous virus EV21 using an enzyme-labeled immunoassay for viral capsid antigen p27. All 177 LF chicks expressed EV21, p27, and 171 of 175 EF chicks did not express p27. Blood from the four p27-positive EF chicks revealed only infectious Subgroup E ALV as determined by subgroup-specific virus assays. Southern blot DNA hybridizations, however, ruled out germline integration of EV21 among the four infected EF progeny. Virus EV21 was not shed in albumens of the dams. Moreover, antibodies against ALV Subgroups A and E were not detected in dams 17 wk after the first insemination. Chicks infected with EV21 were found only in the first two of six hatches. Data suggested direct infection of the embryos from viremic semen rather than congenital infection through infected hens. Direct male transmission of EV21 to progeny may be the basis for persistence of refractory lines noted in some ALV eradication programs. Based on the absence of recombinants among 352 progeny, ev21 and K appear to be less than .3 cM apart.

In vitro translation of fractionated virus-specific RNA isolated from plasma of chicken infected by avian myeloblastosis virus. Unprocessed and processed myeloblastosis-associated virus env-polypeptide precursors

The 60 S viral RNA complex isolated from leukaemic plasma of chicken infected by avian myeloblastosis virus (AMV) was denatured, the poly(A)-RNA selected and centrifuged in a linear sucrose density gradient. RNA from each fraction was translated in vitro and the products were analyzed by slab polyacrylamide gel electrophoresis (PAGE). Unprocessed primary translation product (p64env) of MAV env gene from 21 S RNA fraction was immunoprecipitated by anti-gp85 serum. If, however, this RNA was translated in the presence of dog pancreas microsomal membranes (DPM), the processed 92 K MAV glycoprotein precursor (p92env) was immunoprecipitated by anti-gp85 serum. This precursor, unlike p64env was resistant to exogenous protease.

Occurrence of alternatively spliced leader-delta onc-poly(A) transcripts in chicken neuroretina cells infected with Rous-associated virus type 1: implication in transduction of the c-mil/c-raf and c-Rmil/B-raf oncogenes

We previously reported that serial passaging of Rous-associated virus type 1 in nondividing chicken embryo neuroretina cells leads to reproducible generation of acutely mitogenic retroviruses that transduced the catalytic domain of c-mil/c-raf or c-Rmil/B-raf. On the basis of structural analysis of several retroviruses, we proposed that the early step of oncogene transduction is the constitution of alternatively spliced leader-delta onc-poly(A) transcripts. Here, we show that neuroretina cells do synthesize hybrid leader-delta mil and leader-delta Rmil RNAs and that these RNAs exhibit mitogenic properties and serve as templates for the generation of transducing retorviruses.

Avian myeloblastosis virus core-bound 7 S DNA, highly bent minute structures with sequence-directed curvature

Structural properties and length distribution profile of 7 S avian myeloblastosis virus (AMV) DNA were studied by means of electron microscopy using two different techniques. This DNA represents mostly double strands, the single strands being in minority. We have shown directly that this DNA forms a bent structure typical of the majority of molecules. These bends are sensitive to the distamycin treatment which stretches most of the bent molecules. Some amount (up to 30%) of circular DNA molecules was detected also in DNA preparations, the nature and the size of which are reminiscent of electron microscopic data on microbubbles of replicating DNA. No specific AMV DNA structural features were found using osmium-tetroxide treatment. The basic size of AMV DNA was estimated to be approximately 150 bp, but its multimers were also detected. Their presence and significance is discussed.

Patterns of integration and expression of retroviral, non-replicative vectors in avian embryos: embryo developmental stage and virus subgroup envelope modulate tissue-tropism

We previously demonstrated that Avian Leukemia Viruses (ALV) carrying the v-myc gene specifically induce two types of tumors, cardiomyocytic tumors when the virus is injected before embryonic day 3 (E3), skin tumors when the virus is injected at E3 or E5. Aiming to elucidate the mechanisms which determine this time-dependent change in target, we infected chick and quail embryos at E3 and E5 with replication-deficient, lacZ gene-carrying, ALV-based viruses produced by a packaging cell line. Three constructs driven by 3 different Long Terminal Repeats (LTRs) were tested and yielded similar results. When the constructs were inoculated at E3 and the lacZ gene product revealed 5 days later, around 70% of the embryos carried lacZ+ clones in the heart, around 50% had positive clones in the skin anywhere on the body, while a few embryos displayed clones in internal organs (liver, stomach, lungs). Immunocytological identification of the heart cell type(s) expressing the virus revealed that the only cells infected were cardiomyocytes. When the constructs were inoculated at E5, no lacZ+ clones appeared in the heart but all were located in the cephalic skin. In order to examine the relationship between viral integration and expression, DNA of different organs or tissues from lacZ stained embryos was analyzed by PCR. A tight correlation between integration and expression in the heart and in the skin was revealed in most cases. In contrast, a significant PCR signal was often detected in the liver or the stomach despite weak or absent expression as revealed by lacZ+ clones. We then investigated the influence of envelope glycoprotein subgroups on the tropism of these constructs. The lacZ vector driven by RAV-2 LTRs was packaged as subgroups A, B or E viral particles. The A subgroup, used in the part of the study described above, infects both chick and quail while the B and E subgroups are specific for chick or quail respectively. These B and E subgroups induced lacZ+ clones in the heart (after E3 injection) while no clones or only a few were detected in the skin either after E3 or E5 injection. The following conclusions can be drawn: 1) cardiomyocytes are at E3 the major target for integration and expression of ALV-derived viruses in vivo; 2) targets change rapidly with embryonic age; and 3) tissue-specific infections depend on the envelope subgroup, thus presumably on the presence of the cognate receptor.(ABSTRACT TRUNCATED AT 400 WORDS)

Recovery of acutely transforming viruses from myeloid leukosis induced by the HPRS-103 strain of avian leukosis virus

Viruses rapidly able to transform cultured chicken bone marrow cells have been isolated from cases of myelocytic myeloid leukosis (MML) induced experimentally by the HPRS-103 strain of avian leukosis virus, and from field cases of MML. HPRS-103 virus itself did not acutely transform cultured bone-marrow cells. These findings suggest that during myeloid leukemogenesis by HPRS-103 virus, recombinant viruses are generated with transduced cellular oncogenes. The transformed cell appeared to be a macrophage precursor cell. Transformed cells in culture lost their proliferative capacity after a few weeks and then tended to resemble more differentiated macrophages. This change could be reversed temporarily by addition of a myelomonocytic growth factor, cMGF, to the culture medium. In oncogenicity tests, a selection of the virus strains induced MML, nephroblastomas, renal adenomas/adenocarcinomas, and other tumors in line 21 meat-type chickens but not in line 0 chickens. This difference may have been related to a propensity for the virus strains to induce persistent tolerant viremic infections in the line 21 chickens following infection at 1 day of age. The oncogenic pattern was not clearly related to the ability of the viruses to transform cultured bone-marrow cells. The generation of acutely transforming viruses during myeloid leukemogenesis may be relevant to the occurrence of MML in the field.

Tissue tropism of avian leukosis viruses: analyses for viral DNA and proteins

Analyses of six tissues from Rous-associated virus type 1-infected chickens have revealed a number of tissue-specific differences in virus synthesis and distribution. Chicks were infected at 1 day of age. Tissue (bursa, thymus, liver, kidney, muscle, and brain) were harvested 1 month later. Each of the tissues contained an average of 1.8 to 4 copies of viral DNA per cell. Most of this DNA was integrated. In brain, about one-third of the total viral DNA was in an unintegrated, linear form. Bursa, thymus, liver, and kidney expressed both Gag and Env proteins. In contrast, muscle expressed more Gag than Env, and brain expressed neither Gag nor Env. Tissues that were producing both Gag and Env contained higher levels of mature virus particles than tissues that were not producing both of these proteins.

Myeloid leukaemogenicity and transmission of the HPRS-103 strain of avian leukosis virus

The HPRS-103 strain of avian leukosis virus (ALV) was isolated recently from meat-type chickens and represents a new envelope subgroup. Its oncogenicity has been studied in three meat-type and five Leghorn strains of chickens. In the meat-type strains, the virus, following embryonal inoculation, induced an overall incidence of 27% myelocytic myeloid leukosis (myelocytomatosis) and 12% renal adenomas, with long median latent periods. Amongst the Leghorn lines, these tumors occurred with similar incidence in line 0, but with lower or zero incidences in the other lines. A variety of other tumours occurred with low incidence. Embryonal infection resulted in a permanently tolerant viraemic state with shedding of ALV group specific (gs)-antigen to egg albumen; contact infection resulted mainly in the development of non-shedder birds with serum virus-neutralising antibodies. Contact infection in a meat-type line was associated with the development of transient or permanent viraemia in some birds, and a low tumour incidence. A viraemic phase was not detected following contact infection in a Leghorn line and no tumours developed. The long latent period between embryo infection and tumour mortality, apparently differing from the consequences of infection with acutely transforming ALVs, and the inability of HPRS-103 ALV to transform cultured bone marrow cells, suggests that this virus may lack a viral oncogene and exert its oncogenic properties by some other mechanism such as promoter insertion activation of a cellular oncogene.

[The technology for isolating the avian myeloblastosis virus in high titers from leukosis-free chicks]

In order to enhance the outcome of high-quality reverse transcriptase enzyme, an efficient biotechnology was developed of accumulating and isolating the avian myeloblastosis virus (AMV) in high titres from blood plasma of leukosis-free chickens. When commercial chickens are infected in most sensitive one-day age, the virus titre does not exceed the value of 10(12) particles per 1 ml of plasma. We used 3-4-day old leukosis free chickens and achieved a stable average titre of the virus of 5.10(12) particles/ml due to adaptation of the virus to such chickens and their selection for a high sensitivity to AMV.

Activation of the c-myb locus is insufficient for the rapid induction of disseminated avian B-cell lymphoma

We have previously reported that infection of 9- to 13-day-old chicken embryos with RAV-1 results in rapid development of a novel B-cell lymphoma in which proviral insertion has activated expression of the c-myb gene (E. Pizer and E. H. Humphries, J. Virol. 63:1630-1640, 1989). The biological properties of these B-cell lymphomas are distinct from those associated with the B-cell lymphomas that develop following avian leukosis virus proviral insertion within the c-myc locus. In an extension of this study, more than 200 chickens, infected as 10- to 11-day-old embryos, were examined for development of lymphomas that possess disrupted c-myb loci. Fourteen percent developed disseminated B-cell lymphoma. In the majority of these tumors, the RAV-1 provirus had inserted between the first and second exons that code for p75c-myb. However, insertions between the second and third exons and between the third and fourth exons were also detected. In situ analysis of myb protein expression in tumor tissue revealed morphological features suggesting that the tumor originates in the bursa. Within the bursa, the lymphoma appeared to spread from follicle to follicle without compromising the structural integrity of the organ. Tumor masses in liver demonstrated heterogeneous levels of myb protein suggestive of biologically distinct subpopulations. In contrast to the morbidity data, immunohistological analysis of bursae from 4- to 6-week-old chickens at risk of developing lymphomas bearing altered c-myb loci revealed lesions expressing elevated levels of myb in 16 of 19 birds. The activated myb lymphoma displayed very poor capacity to proliferate outside its original host. Only 1 of 33 in vivo transfers of tumor to recipient hosts established a transplantable tumor. None of the primary tumor tissue nor the transplantable tumor exhibited the capacity for in vitro proliferation. Similar experimental manipulation has yielded in vitro lines established from avian B-cell lymphomas expressing elevated levels of c-myc or v-rel. The dependence on embryonic infection for development of activated-myb lymphoma suggests a requirement for a specific target cell in which c-myb is activated by proviral insertion. It is likely, moreover, that continued tumor development requires elevated expression of myb proteins within a specific cell population in a restricted stage of differentiation.

Fusion of the nuclear oncoproteins v-Myb and v-Ets is required for the leukemogenicity of E26 virus

The highly leukemogenic avian retrovirus E26 expresses the two transcriptional activator-type oncogenes v-myb and v-ets as a nuclear fusion protein. Previous studies have shown that both oncogenes cooperate in the transformation of erythroid cells in vitro and that the phenotypes of transformed cells differ, depending on whether the oncogenes are coexpressed as separate proteins or as a fusion protein. Here we show that virus constructs encoding either v-Myb or v-Ets as their only oncoprotein are nonleukemogenic and that constructs coexpressing nonfused v-Myb and v-Ets proteins appear to be weakly leukemogenic. Surprisingly, leukemic animals injected with the latter contain highly leukemogenic variant viruses that exhibit internal deletions in their genome, resulting in the synthesis of novel Myb-Ets fusion proteins. These results show that v-Myb and v-Ets must be fused to cause leukemia and establish a new mechanism of oncogene activation and cooperation.

Interactions between endogenous virus loci ev6 and ev21. 2. Congenital transmission of EV21 viral product to female progency from slow-feathering dams

The influence of the endogenous virus ev6 on congenital transmission of EV21, the infectious viral product encoded by locus ev21, and the immune response to exogenous avian leukosis virus (ALV) infection was studied in rapid-feathering (RF) female progeny from four classes of slow-feathering (SF) (ev21+ and RF (ev21-) dams with and without ev6. Apart from transmitting infectious EV21 and ev6 to progency, dam ev genotype did not influence the immune response or shedding of RPL-40. The endogenous virus envelope glycoprotein encoded by ev6, however, completely restricted shedding and congenital transmission of infectious endogenous virus EV21, from SF dams. After 19 wk of exposure to ALV strain RPL-40 infected cage mates, only 11% of the congenitally infected female progeny mounted neutralizing antibodies against RPL-40, whereas 73% of their noncongenitally infected sisters seroconverted. More ev6+ female progeny, however, were shedders of RPL-40 and developed tumors than ev6- sisters. Among progeny from the four classes of dams, EV21 congenitally infected hens had the highest incidence (31%) of RPL-40-induced tumors.

In ovo infection with the avian retrovirus RAV-1 leads to persistent infection of the central nervous system

The ability of an avian retrovirus to cause central nervous system (CNS) disease was investigated in chickens infected in ovo with Rous associated virus-1. Viral envelope and core proteins and mature virions were found throughout CNS parenchyma, with the highest amounts localized in the granular layer of the cerebellum, in blood vessel endothelium, and the choroid plexus. This distribution was established by the time of hatching and persisted throughout the 14 weeks of observation. The highest levels of integrated proviral DNA and viral mRNA, were present in the cerebellum, consistent with the distribution of viral antigens. Mononuclear cell infiltrates were evident throughout the CNS, consistent with an inflammatory process. However, demyelination or vacuolar changes, as observed in other retroviral-induced CNS diseases, were not detected. Clinical symptoms of progressive neurologic dysfunction, i.e., weakness or paralysis of the hindlimbs, imbalance, and ataxia, were present in 7 of 38 infected chickens before termination of the experiment at 14 weeks posthatch. Viral antigens or lymphocyte infiltration were not detected in peripheral nerves. These findings suggest that the avian system may provide a valuable model to analyze the mechanisms governing retroviral induced CNS disease.

FH3, a v-myc avian retrovirus with limited transforming ability

We have isolated a new acute avian transforming virus which contains the oncogene myc. This virus, designated FH3, was isolated after injection of a 10-day-old chick embryo with avian leukosis virus. While FH3 shares many properties with other v-myc-containing avian retroviruses, it also has several unique properties. The primary target for transformation in vitro is chicken macrophages; infection of chicken fibroblasts does not lead to complete morphological transformation. FH3 also exhibits a limited host range, in that Japanese quail macrophages and fibroblasts are infected but are not completely transformed. FH3 induces in vivo a limited tumor type if injected into 10-day-old chick embryos; only a cranial myelocytoma, which does not appear to be metastatic, can be detected. The v-myc gene of FH3 is expressed predominantly as a P145 Gag-Myc protein which is encoded by a ca. 8-kilobase genomic RNA. This FH3-encoded polyprotein is localized in the nucleus of all infected cells, whether or not they are transformed.

Pathogenic effect of osteopetrosis virus strain MAV-2(0) on guinea fowl pancreas

Osteopetrosis virus strain MAV-2(0) in guinea fowl pancreas induces early unspecific changes in separate acini and the development of neoplasia among apparently unaffected acinar tissue. The tumors were classified as serous and mucinous adenomas and adenocarcinomas, as well as poorly differentiated carcinomas. Foci of phenotypically altered acinar cells were observed in single experimental birds.

Determination of avian leucosis virus in chicken pancreas

30 one-day-old chickens of the commercial HX-SL hybrid from the incubator house at Premyslovice were infected with tissue culture supernatant of clone LSCC-H32. This tissue culture produced the virus of avian lymphoid leucosis of subgroups A and B. After killing at the age of 21-37 weeks, samples of chick pancreas were examined histopathologically and by electron microscopy. Serological examination of serum and feather pulp for presence of avian sarcoma-leucosis gs antigen was simultaneously performed, using the ELISA test. In the pancreas of the experimental chickens both complete and incomplete viral particles of avian leucosis were found. Most frequently, they were localised in the electron-dense secretions of the lumen of pancreatic acini at apical plasma membranes of acinar cells but also in zymogenic granules and in intercellular spaces. The significance of these findings to possible horizontal transmission is discussed.

Long terminal repeat (LTR) sequences, env, and a region near the 5' LTR influence the pathogenic potential of recombinants between Rous-associated virus types 0 and 1

A series of recombinants between Rous-associated virus type 0 (RAV-0), RAV-1, and a replication-competent avian leukosis virus vector (RCAN) have been tested for disease potential in day-old inoculated K28 chicks. RAV-0 is a benign virus, whereas RAV-1 and RCAN induce lymphoma and a low incidence of a variety of other neoplasms. The results of the oncogenicity tests indicate that (i) the long terminal repeat regions of RAV-1 and RCAN play a major role in disease potential, (ii) subgroup A envelope glycoproteins are associated with a two- to fourfold higher incidence of lymphoma than subgroup E glycoproteins, and (iii) certain combinations of 5' viral and env sequences cause osteopetrosis in a highly context-dependent manner. Long terminal repeat and env sequences appeared to influence lymphomogenic potential by determining the extent of bursal infection within the first 2 to 3 weeks of life. This would suggest that bursal but not postbursal stem cells are targets for avian leukosis virus-induced lymphomogenesis. The induction of neutralizing antibody had no obvious influence on the incidence of lymphoma.

Importance of the medullary macrophage in the replication of lymphoid leukosis virus in the bursa of Fabricius of chickens

Electron microscopy and immunocytochemistry were used to study the development of lymphoid leukosis virus infection in the bursa of Fabricius of experimentally infected chicken embryos and chickens. In embryos infected at 7 days of incubation and killed 10 days later, virus particles and group-specific viral antigen were confined mainly to the connective tissue of the lamina propria of the bursal mucosal folds; a few developing follicles had discrete virions and group-specific antigen between cells. In chickens infected at 1 day of age, infection (as determined by use of electron microscopy and immunocytochemistry) was maximal in 1- to 4-month-old birds, and the greatest concentration of virus and group-specific viral antigen was in the medulla of the follicles. Although lymphoid leukosis virus was released from lymphocytes, epithelial cells, and macrophages, virus replication in the medullary macrophages was more active than that in the other cells. Normal medullary macrophages had cell membrane vesicles (50 to 80 nm in diameter) that covered part of all of the cell membrane surface. In infected chickens, virus particles frequently developed within these vesicles. Comparable vesicles were not found on cortical macrophages. Results of the present study indicated that the medullary macrophage was the principal host cell for replication of lymphoid leukosis virus in the bursa of Fabricius of the chicken.

Genetic determinants of neoplastic diseases induced by a subgroup F avian leukosis virus

Two subgroup F avian leukosis viruses, ring-necked pheasant virus (RPV) and RAV-61, were previously shown to induce a high incidence of a fatal proliferative disorder in the lungs of infected chickens. These lung lesions, termed angiosarcomas, appear rapidly (4 to 5 weeks after infection), show no evidence of proto-oncogene activation by proviral integration, and are not induced by avian leukosis viruses belonging to other subgroups. To identify the viral sequences responsible for induction of these tumors, we constructed recombinant viruses by exchanging genomic segments of molecularly cloned RPV with those of a subgroup A leukosis virus, UR2AV. The ability to induce rapid lung tumors segregated only with the env sequences of RPV; the long terminal repeat of RPV was not required. However, recombinants carrying both env and long terminal repeat sequences of RPV induced lung tumors with a shorter latency. In several cases, recombinant viruses exhibited pathogenic properties differing from those of either parental virus. Recombinants carrying the gag-pol region of RPV and the env gene of UR2AV induced a high incidence of a muscle lesion termed infiltrative intramuscular fibromatosis. One recombinant, EU-8, which carries the gag-pol and LTR sequences of RPV, and the env gene of UR2AV, induced lymphoid leukosis after an unusually short latent period. The median time of death from lymphoid leukosis was 6 to 7 weeks after infection with EU-8 compared with approximately 5 months for UR2AV.

Embryonic infection with the endogenous avian leukosis virus Rous-associated virus-0 alters responses to exogenous avian leukosis virus infection

We inoculated susceptible chicken embryos with the endogenous avian leukosis virus Rous-associated virus-0 (RAV-0) on day 6 of incubation. At 1 week after hatching, RAV-0-infected and control chickens were inoculated with either RAV-1 or RAV-2, exogenous viruses belonging to subgroups A and B, respectively. The chickens injected with RAV-0 as embryos remained viremic with exogenous virus longer and either failed to develop type-specific humoral immunity to exogenous virus or developed it later than the control chickens not inoculated with RAV-0. The RAV-0-injected chickens also developed neoplasms at a much higher frequency than did the control chickens. We suggest that the lower immune responses of the RAV-0-injected chickens were due to an immunological tolerance to envelope group-specific glycoproteins shared among endogenous and exogenous viruses.

Differential transcription from the long terminal repeats of integrated avian leukosis virus DNA

In avian leukosis virus-induced lymphoma and erythroblastosis, the expression of the proto-oncogenes c-myc and c-erbB is activated by downstream or readthrough transcripts initiated within integrated proviral DNA. To determine the relative abundance of viral RNAs extending into the downstream cellular sequences independently of the effects that may be exerted by specific sites of proviral integration, we examined the RNA of infected avian fibroblasts. Using a nuclease protection strategy to detect downstream, readthrough, and normal viral RNAs and to distinguish them from each other, we found that transcripts initiated within the 3' long terminal repeat, i.e., downstream transcripts, were undetectable in infected fibroblasts and could not have amounted to more than 1 to 2% of the total viral RNA. However, readthrough RNAs, which are transcripts initiated within the 5' long terminal repeat and extended beyond the viral polyadenylation site into the downstream cellular DNA, were present at relatively high levels, making up approximately 15% of the total viral RNA.

Differences in sequences encoding the carboxyl-terminal domain of the epidermal growth factor receptor correlate with differences in the disease potential of viral erbB genes

Eleven recently isolated erbB-transducing viruses as well as avian erythroblastosis virus (AEV)-R (ES4) and AEV-H have been characterized for the type of disease they cause, their ability to transform fibroblasts in culture, their ability to cause disease in pedigrees of chicken that differ in susceptibility to erbB-induced erythroblastosis, and the structure of their erbB genes. Differences in each of the biological parameters correlated with differences in erbB sequences encoding the C-terminal domain of the epidermal growth factor receptor (EGFR). Seven viruses were strain restricted in their ability to induce erythroblastosis and did not transform fibroblasts. These seven viruses contained v-erbB genes encoding the complete C terminus of the EGFR. AEV-R and AEV-H were not pedigree restricted in their ability to induce erythroblastosis and could transform fibroblasts. These viruses contain v-erbB genes that lack codons for the immediate C terminus of the EGFR. Three viruses caused angiosarcoma and one caused fibrosarcoma. The angiosarcoma and fibrosarcoma-inducing viruses were not strain restricted and did not cause erythroblastosis. The v-erbB genes of each of these viruses contained extensive internal deletions or 3' truncations in sequences encoding the C-terminal domain of the EGFR.

Susceptibility of avian B lymphocytes to retroviral infection parallels that of fibroblasts

The ability of conventional virus receptors to mediate infection and transformation of immature B cells by the avian leukosis virus (ALV) was analyzed in chimeric chickens whose bursa of Fabricius contained a mixture of B cells from subgroup A virus receptor-positive and -negative chickens. The data indicate that factors that determine resistance of fibroblasts to ALV infection also apply to bursal cells and that other receptors expressed by B cells, i.e., antigen or mitogen receptors, do not initiate infection or transformation, at least not independent of conventional virus receptors.

[A preparation of short DNA chains synthesized in vivo after introduction into DNA from live cells of trioxsalen crosslinks is not enriched by replication initiation regions]

The experiments undertaken in order to verify the trioxsalen-crosslinking method suggested by Russev and Vassilev for isolation of eukaryotic replication origins are described. It was found that the preparation of viral DNA isolated by the above mentioned method from CV-1 cells lytically infected with SV40 was not enriched in sequences including SV40 replication origin. The hybridization pattern of DNA preparation isolated by the trioxsalen-crosslinking procedure from chicken erythroblastosis cells with the cloned fragments of globin gene domain was found to be identical to those of the total DNA probe. The DNA fraction enriched in replication origins was isolated from the same cells with the aid of nascent DNA strand extrusion method by Zannis-Hadjopoulos et al. The hybridization pattern of this DNA fraction with the cloned fragments of chicken alpha-globin gene domain was different from those of total DNA. Taking together, the results of our experiments demonstrate that trioxsalen-crosslinking procedure does not lead to the isolation of replication origins from the objects studied in the present investigation.

Activation of c-erbB in avian leukosis virus-induced erythroblastosis leads to the expression of a truncated EGF receptor kinase

Chicken erythroblastosis caused by avian leukosis virus (ALV) is thought to be mediated by activation of the c-erbB/EGF receptor oncogene by a promoter-insertion mechanism. Here we study the proteins expressed by two ALV-induced leukemias and compare them with the avian EGF receptor and with the oncogene product of avian erythroblastosis virus (v-erbB) which was shown to be a truncated EGF receptor. It appears that the two leukemias express truncated EGF receptors of slightly different sizes with intrinsic tyrosine kinase activity. Hence, acute and chronic retroviruses utilize a common pathway for transformation. Moreover, the proteins expressed in the leukemias are similar to the avian EGF receptor with respect to their phosphopeptide maps, suggesting that they do not carry the C-terminal deletion characteristic of v-erbB.

Leukemogenicity of avian oncovirus S13

Avian oncovirus S13 induces erythroblastic and granulocytic leukemias in line 6 and Spafas chickens. It also causes anemia, sarcomas, and endothelial proliferation. The leukemic cells contain the transformation-specific protein of S13, gp155.

An enzyme-linked immunosorbent assay for detection of antibodies to exogenous avian leukosis virus

A microplate enzyme-linked immunosorbent assay (ELISA) for detecting antibodies to avian leukosis virus (ALV) of subgroups A and B in infected chickens was developed with the use of Rous-associated virus (RAV)-1 (subgroup A) and RAV-2 (subgroup B) antigens purified by sucrose-gradient centrifugation. The antigen was used for ELISA after treatment with Triton X-100. In the ELISA, the subgroup viral antigen reacted strongly with homologous antiserum but also reacted with heterologous antiserum. Tests with serum absorbed with purified homologous and heterologous virus and tests for antigen-blocking by group-specific antibodies to ALV revealed that the reaction was caused mainly by subgroup-specific antibodies. The ELISA was 8 to 32 times more sensitive than the virus-neutralization (VN) test and detected antibodies to ALV earlier than the VN test in chickens infected experimentally with RAV-1 and RAV-2. In field application of the ELISA, 44.2% of 484 chicken sera were positive for RAV-1 and/or RAV-2 antigen, and 80.4% of flocks were positive. These findings indicate that ELISA is superior to the VN test in sensitivity, simplicity, rapidity, and applicability for large-scale field surveys for ALV infection.

Viral matrix inclusion bodies in myocardium of lymphoid leukosis virus-infected chickens

Chicken embryos and healthy adult chickens naturally infected with lymphoid leukosis virus were used to investigate viral inclusion bodies in myocardial cells by light and electron microscopies and by immunocytochemical technique. Intracytoplasmic viral matrix inclusion bodies frequently appeared in the myocardium of adult chickens, but not in that of embryos. In light microscopic preparations, inclusions were irregularly distributed, were basophilic, and contained ribonucleic acid. Ultrastructurally, inclusions in myocardial cells were in areas containing numerous interstitial C-type particles. Early inclusions were composed of clusters of ribosomes associated with sarcoplasmic tubules; spherical bodies developed among these ribosomes. Mature inclusions were composed of numerous spherical bodies (50 to 75 nm) with interspersed ribosomes and of ribosomes clustered at the periphery. Inclusions were not membrane-enclosed. Occasionally, spherical bodies were in paracrystalline arrays. Multiple budding occurred on cell membranes adjacent to matrix inclusions. The viral group-specific protein, p27, was demonstrated by the peroxidase-antiperoxidase method and by the protein A-gold method in the spherical bodies, in nucleoids of mature virus particles, and among ribosomes of inclusions. The results indicate that the matrix inclusions were the result of lymphoid leukosis virus infection and were the product of viral protein synthesis on ribosomes.

Variation in susceptibility to avian sarcoma viruses and expression of endogenous avian leukosis virus antigens in specific pathogen-free chicken lines

Five lines of chickens maintained as specific pathogen-free flocks in Australia were characterized in relation to endogenous antigens and endogenous avian leukosis virus expression. Embryos of line N were predominantly of C/E phenotype, uniformly positive for group-specific antigen and chick helper factor (gs+chf+) and 38% expressed endogenous virus at a very low titre. Embryos of line M4 were uniformly of C/ABE phenotype and were either gs+chf+ or gs-chf+. Line W19 embryos segregated for susceptibility to viruses of subgroup A, B and D and were either of C/E or C/ABE phenotype. The majority of W19 embryos were gs+chf+ with a small proportion being gs+chf-. Line I13 embryos were either of C/0 or C/ABE phenotype, uniformly gs-chf- and 44% of embryos expressed endogenous virus at a low titre. Line S segregated for susceptibility to subgroup E virus and embryos were either of C/E or C/0 phenotype, while the majority of embryos from line S were gs-chf- with some embryos being gs+chf+ or gs-chf+. The degree of interference of gs+chf+ and gs-chf+ phenotypes with subgroup E virus infection was identical with the interference patterns of classical gs+chf+ and gs-chf+ phenotypes. The resistance to infection with avian sarcoma viruses of subgroups E in lines N and M4, and to a degree in line W19, was highly associated with the presence of chf. Resistance to subgroup E virus was independent of chf in lines S and I13, probably being under the control of an independent locus. Cellular restriction of endogenous virus replication existed in all subgroup E virus-susceptible cells of line I13 in contrast to cells of line S which supported replication of endogenous virus. The phenotype of chicken cells for the expression of endogenous gs antigen and chf could accurately be predicted from the test performed on whole blood cells.

Mechanisms of oncogenesis by subgroup F avian leukosis viruses

Subgroup F avian leukosis viruses, such as RAV-61 and ring-necked pheasant virus, are recombinants between exogenous chicken retroviruses and endogenous pheasant viruses and contain new envelope (env) genes. Chickens infected as 10-day-old embryos with subgroup F viruses develop fibrosarcomas, nephroblastomas, osteopetrosis, B-cell lymphomas, and a high incidence of a proliferative disorder involving the lung. Fibrosarcomas, nephroblastomas, and lymphomas appear after long latent periods (3 to 12 months). They contain discrete virus-cell junction fragments and are therefore clonal outgrowths of a single infected cell. Two ring-necked pheasant virus-induced B-cell lymphomas and an adenocarcinoma of the abdomen contained proviruses integrated at the c-myc locus and elevated levels of myc mRNA. At least four of the fibrosarcomas appeared to contain proviruses integrated at a common site, suggesting that a specific cellular gene may be involved in these tumors. The host gene has not been identified, however; 16 different oncogene probes failed to hybridize to fibrosarcoma junction fragments. In contrast to these neoplasms, lung lesions appeared rapidly (4 to 5 weeks), showed no evidence of clonality, and lacked long terminal repeat-initiated transcripts other than viral 35S and 21S mRNA. We conclude, therefore, that subgroup F retroviruses induce the proliferative disorder of the lung by a different mechanism.

Oncogenecity of an avian erythroblastosis virus in mutant strains of Japanese quails

The susceptibility of 12 mutant strains of Japanese quails to the R strain of avian erythroblastosis virus (AEV) was examined. Three strains, SBPP, PNN and CWE, showed high susceptibility and developed various types of tumors including erythroblastosis, hemangioma and myeloblastic leukemia. In relatively resistant WE strain, increased incidence and various types of tumors were observed by modification of host conditions. These results indicate pluripotential oncogenicity of AEV in quails as well as partial control of AEV-oncogenesis by genetical background of the host.

Differential response to avian leukosis virus infection exhibited by two chicken lines

Infection of susceptible chickens with avian leukosis virus (ALV) results in the development of bursal lymphomas. These neoplasms develop within the bursa of Fabricius following a latent period of several months. The response exhibited by two previously uncharacterized chicken lines to ALV infection has been examined. The two lines, Hyline SC and FP, responded differently to ALV infection. During a 24-week period following intravenous ALV infection, 27 of 50 SC chickens developed bursal lymphomas. No lymphomas developed in the 36 FP chickens tested. A majority of the SC chickens that developed lymphomas also exhibited widespread metastasis to the liver, spleen, and kidneys. Analysis of cellular DNA from the primary and metastatic tumors demonstrated the clonal nature of these neoplasms and revealed altered c-myc loci, as reported in other studies, suggesting the importance of this locus in the development of these tumors. Further characterization of the ALV infection of SC and FP chickens will provide an opportunity to analyze the mechanism of resistance and to contribute to the understanding of the tumorigenic process.

Distribution of lymphoid leukosis virus and p27 group-specific antigen in tissues from laying hens

In order to gain insight into transmission and pathogenesis of infection, specimens from laying hens that had been naturally exposed to lymphoid leukosis virus (LLV) were tested for group-specific antigen (gsa) of the virus by immunofluorescence (IF), complement fixation (CF), and the enzyme-linked immunosorbant assay (ELISA). Electron microscopic examinations determined the distribution of C-type virus particles in tissues, and the phenotypic-mixing test served as a biological assay for exogenous LLV. The IF gsa was found in all organs tested, and fluorescence was usually found where virus particles were concentrated. In the oviduct and intestine, IF gsa was frequently at the border of the lumina and in the connective tissue associated with basal membranes of glands. In skin, the antigen was detected in smooth muscle, in feather pulp, and in basal epidermal cells of developing feathers. Results of various tests on Ottawa strains of chickens were usually in agreement. For example, among hens that shed gsa into egg albumen, only the viremic hens were consistently positive for IF gsa in both spleens and oviducts. Geometric mean CF titers of antigen were respectively five- and 23-fold higher in spleens and oviducts from viremic hens than in those from nonviremic hens. These findings suggest that the gsa was associated with exogenous virus infection. In Cornell S strain hens that had not been exposed to LLV, gsa was detected in splenic tissue by CF and ELISA but not by the IF test. This gsa was presumed to be of endogenous origin.

The erbB gene of avian erythroblastosis virus is a member of the src gene family

The erbB gene of an avian erythroblastosis virus, AEV-H, was determined to be 1812 nucleotides long and was predicted to code for a protein of 67,638 daltons. Unexpectedly, a sequence of 285 amino acids in the middle of the protein showed a significant homology (38%) with the sequence in the carboxy terminus of p60src. The nucleotide sequence of a mutant of AEV-H, td-130, which induces sarcomas but not erythroblastosis in chicken, was also analyzed. A deletion of 169 nucleotides was identified in the 3' half of the erbB gene, indicating that the gene codes for a truncated protein with the predicted molecular weight of 46,667. These findings suggest that the homologous domain of erbB protein with its N-terminal portion is sufficient for the transformation of fibroblasts and that one-third of the carboxy-terminal domain has a key role for the transformation of erythroid cells.

Site-specific mutagenesis of avian erythroblastosis virus: erb-B is required for oncogenicity

Avian erythroblastosis virus (AEV) induces both erythroblastosis and fibrosarcomas in susceptible birds. Two domains within its replication-defective genome, erb-A and erb-B, have been implicated in AEV-mediated oncogenesis. An efficient transfection system for generating infectious, transforming virus from molecular clones of AEV and RAV-1 (helper virus) was combined with the techniques of site-specific mutagenesis to investigate the contribution of erb-B to the two forms of oncogenesis induced by AEV. Deletion and frameshift mutations were constructed in the erb-B locus of cloned AEV DNA in vitro. Infectious retroviruses harboring these mutations were recovered and their ability to transform fibroblasts in vitro or induce erythroleukemia in vivo was assessed. The presence of mutant viral genomes in chick embryo fibroblasts or erythroblasts of infected birds was confirmed by suitable biochemical analyses. Expression of viral genes in cells infected with AEV mutants was examined by immunoprecipitation with antisera to erb-A and erb-B proteins. It was found that the product of erb-B is necessary for transformation of fibroblasts and induction of erythroblastosis by AEV, although a small portion of this protein at the carboxy terminus is dispensable.

Site-specific mutagenesis of avian erythroblastosis virus: v-erb-A is not required for transformation of fibroblasts

Avian erythroblastosis virus (AEV) is an acutely transforming retrovirus whose putative oncogenes (v-erb-A and v-erb-B) encode the proteins P74gag-erb-A and P61-68erb-B. The existence of these two gene products has prompted the question of whether one or both proteins are required in the transformation of erythroblasts and fibroblasts by AEV. In the accompanying manuscript, we describe the use of site-specific mutagenesis to generate mutants of AEV unable to synthesize P61-68erb-B. Here we present our analysis of the oncogenic potential of an AEV mutant unable to synthesize P74gag-erb-A due to a large deletion encompassing both gag and v-erb-A sequences. The erb-A-mutant retrovirus propagated quite poorly on fibroblasts in culture; however, fibroblasts harboring the erb-A mutant genome were transformed in the absence of P74gag-erb-A expression. The mutant virus failed to induce erythroleukemias in chickens, but the validity of this finding is compromised by the poor replicative capacity of the mutant. The results presented in this and the preceding manuscript indicate that P61-68erb-B is both necessary and sufficient for neoplastic transformation of fibroblasts by AEV; by contrast, a role for p74gag-erb-A in leukemogenesis by AEV has not yet been rigorously excluded.

Rapid induction of osteopetrosis by subgroup E recombinant viruses

Avian osteopetrosis is a proliferative bone disorder initiated at high frequency by MAV-2(O), a subgroup B avian myeloblastosis-associated virus. To examine the role of the MAV-2(O) genome in osteopetrosis induction, a series of recombinant viruses between MAV-2(O) and RAV-O was constructed. Recombinant viruses were selected for rapid growth and subgroup E envelopes. The T1 oligonucleotide fingerprint patterns of viruses selected in this manner demonstrated that they were recombinants and were clonally pure because they had oligonucleotides from each parent, and each oligonucleotide was present in single molar yield. When injected into 10-day-old chicken embryos, approximately 50% of the recombinant viruses induced osteopetrosis within 3 weeks after hatch. Therefore, subgroup E envelope did not inhibit osteopetrosis induction. The osteopetrosis that was induced varied from slight to severe, but none of the recombinant viruses induced osteopetrosis as severe as the MAV-2(O) parent.

Newly generated avian erythroblastosis virus produces noninfectious particles lacking env-gene products

The H strain of avian erythroblastosis virus (AEV-H) was recently isolated from the liver emulsion of a chicken that suffered from erythroblastosis after being inoculated with subgroup A leukosis virus. AEV-H induced erythroblastosis or sarcoma when inoculated into chickens and transformed chick embryo fibroblasts (CEF) in vitro. Analysis of viral proteins synthesized in cells, which were named HNP, transformed by AEV-H but not producing transforming virus revealed tha the genome of AEV-H directed the synthesis of the gag gene products, Pr76gag and Pr180gag-pol, which was the precursor of active reverse transcriptase. Thus the HNP produced virions that were not infectious due to a defect of the env gene. Studies on the viral RNA showed that a 35 S RNA, estimated to be 8000 nucleotides long, was the genomic RNA of AEV-H and probably carried one transforming gene, which is most likely erbB gene. The gene organization of AEV-H was suggested to be 5'-gag-pol-onc-3'. These data imply that the single oncogene is responsible for both erythroblastosis and sarcoma.

A new avian erythroblastosis virus, AEV-H, carries erbB gene responsible for the induction of both erythroblastosis and sarcomas

The genome structure of a newly isolated avian erythroblastosis virus, AEV-H, was analyzed. Using DNA probes specific for the LTR sequence of SR-RSV-A, and for the erbA gene and the erbB gene of the ES4 strain of AEV, we have shown that the genome of AEV-H is 35S in size and carries the erbB gene but not the erbA gene. Comparison of the restriction sites of molecularly cloned AEV-H DNA with that of cloned DNA of the associated virus revealed that the env gene of the associated virus was replaced with the erbB gene to generate AEV-H. The genome structure of AEV-H is, therefore, determined to be 5'-gag-pol-erbB-3'. Moreover, we have isolated a mutant of AEV-H, td-130, that can induce sarcomas but not erythroblastosis in chickens. The restriction analysis of proviral DNA of the td-130 showed that it carries a deletion of about 150 to 200 nucleotides in the erbB gene. These data indicate that the erbB protein is responsible for both erythroblastosis and sarcomas.

Avian leukosis virus infection and congenital transmission in lines of chickens resisting selection for reduced shedding

Two lines (D and E) of three breeder lines of chickens that had resisted selection for reduced avian leukosis virus (ALV) congenital transmission on the breeder's premises did not resist the same selection procedures (tests for gs-antigen in albumen) under laboratory conditions. The incidence of ALV congenital transmission in the remaining third line (F) was spontaneously reduced from 13% to 0.9%. Environmental ALV exposure of uninfected chicks after hatching induced 7-10% of the progeny from lines E and F to become congenital transmitters but had negligible effects on line D. Neither errors in identifying dams nor horizontal transmission leading to congenital transmission were great enough to explain the lack of improvements in the three lines on the breeder's premises. Conditions of environmental exposure on the breeder's farm seem most likely to account for the resistance to reduced shedding. These findings suggest that the effectiveness of testing and selection procedures used to reduce ALV may be greatly influenced by the environment.