Studies of the "chain reversal regions" of the avian sarcoma/leukosis virus (ASLV) and ebolavirus fusion proteins: analogous residues are important, and a His residue unique to EnvA affects the pH dependence of ASLV entry.

Most class I fusion proteins exist as trimers of dimers composed of a receptor binding and a fusion subunit. In their postfusion forms, the three fusion subunits form trimers of hairpins consisting of a central coiled coil (formed by the N-terminal helices), an intervening sequence, and a region containing the C helix (and flanking strands) that runs antiparallel to and packs in the grooves of the N-terminal coiled coil. For filoviruses and most retroviruses, the intervening sequence includes a "chain reversal region" consisting of a short stretch of hydrophobic residues, a Gly-Gly pair, a CX(6)CC motif, and a bulky hydrophobic residue. Maerz and coworkers (A. L. Maerz, R. J. Center, B. E. Kemp, B. Kobe, and P. Poumbourios, J. Virol. 74:6614-6621, 2000) proposed a model for this region of human T-cell leukemia virus type 1 (HTLV-1) Env in which expulsion of the final bulky hydrophobic residue is important for early conformational changes and specific residues in the chain reversal region are important for forming the final, stable trimer of hairpins. Here, we used mutagenesis and pseudovirus entry assays to test this model for the avian retrovirus avian sarcoma/leukosis virus (ASLV) and the filovirus ebolavirus Zaire. Our results are generally consistent with the model proposed for HTLV-1 Env. In addition, we show with ASLV EnvA that the bulky hydrophobic residue following the CX(6)CC motif is required for the step of prehairpin target membrane insertion, whereas other residues are required for the foldback step of fusion. We further found that a His residue that is unique to the chain reversal region of ASLV EnvA controls the pH at which ASLV entry occurs.

A single-amino-acid substitution in the TvbS1 receptor results in decreased susceptibility to infection by avian sarcoma and leukosis virus subgroups B and D and resistance to infection by subgroup E in vitro and in vivo.

The avian sarcoma and leukosis virus (ASLV) family of retroviruses contains five highly related envelope subgroups (A to E) thought to have evolved from a common viral ancestor in the chicken population. Three genetic loci in chickens determine the susceptibility or resistance of cells to infection by the subgroup A to E ASLVs. Some inbred lines of chickens display phenotypes that are somewhere in between either efficiently susceptible or resistant to infection by specific subgroups of ASLV. The tvb gene encodes the receptor for subgroups B, D, and E ASLVs. The wild-type Tvb(S1) receptor confers susceptibility to subgroups B, D, and E ASLVs. In this study, the genetic defect that accounts for the altered susceptibility of an inbred chicken line, line M, to infection by ASLV(B), ASLV(D), and ASLV(E) was identified. The tvb gene in line M, tvb(r2), encodes a mutant Tvb(S1) receptor protein with a substitution of a serine for a cysteine at position 125 (C125S). Here, we show that the C125S substitution in Tvb(S1) significantly reduces the susceptibility of line M cells to infection by ASLV(B) and ASLV(D) and virtually eliminates susceptibility to ASLV(E) infection both in cultured cells and in the incidence and growth of avian sarcoma virus-induced sarcomas in chickens. The C125S substitution significantly reduces the binding affinity of the Tvb(S1) receptor for the subgroup B, D, and E ASLV envelope glycoproteins. These are the first results that demonstrate a possible role of the cysteine-rich domain 3 in the function of the Tvb receptors.

Evolution of broad host range in retroviruses leads to cell death mediated by highly cytopathic variants.

The ability of many retroviruses to cause disease can be correlated to their cytopathic effect (CPE) in tissue culture characterized by an acute period of cell death and viral DNA accumulation. Here, we show that mutants of a subgroup B avian retrovirus (Alpharetrovirus) cause a very dramatic CPE in certain susceptible avian cells that is coincident with elevated levels of apoptosis, as measured by nuclear morphology, and persistent viral DNA accumulation. These mutants also have a broadly extended host range that includes rodent, cat, dog, monkey, and human cells (31). Previously, we have shown that the mutants exhibit diminished resistance to superinfection. The results presented here have important implications for the process of evolution of retroviruses to use distinct cellular receptors.

Integration targeting by avian sarcoma-leukosis virus and human immunodeficiency virus in the chicken genome.

We have analyzed the placement of sites of integration of avian sarcoma-leukosis virus (ASLV) and human immunodeficiency virus (HIV) DNA in the draft chicken genome sequence, with the goals of assessing species-specific effects on integration and allowing comparison to the distribution of chicken endogenous retroviruses (ERVs). We infected chicken embryo fibroblasts (CEF) with ASLV or HIV and sequenced 863 junctions between host and viral DNA. The relationship with cellular gene activity was analyzed by transcriptional profiling of uninfected or ASLV-infected CEF cells. ASLV weakly favored integration in active transcription units (TUs), and HIV strongly favored active TUs, trends seen previously for integration in human cells. The ERVs, in contrast, accumulated mostly outside TUs, including ERVs related to ASLV. The minority of ERVs present within TUs were mainly in the antisense orientation; consequently, the viral splicing and polyadenylation signals would not disrupt cellular mRNA synthesis. In contrast, de novo ASLV integration sites within TUs showed no orientation bias. Comparing the distribution of de novo ASLV integration sites to ERVs indicated that purifying selection against gene disruption, and not initial integration targeting, probably determined the ERV distribution. Further analysis indicated that ERVs in humans, mice, and rats showed similar distributions, suggesting purifying selection dictated their distributions as well.

An epizootic of subcutaneous tumors associated with subgroup A avian leukosis/sarcoma virus in young layer chickens.

An outbreak of subcutaneous tumors in young layer chickens in a flock in Japan was investigated. Tumors appeared as extensive swelling or bulbous protrusions of the integument and were observed in the head or wing of chickens approximately 9 wk old, with a prevalence of 0.4% (157 of 42,000) in the affected flock. Histologically, two types of tumor were observed: myxoma containing abundant hyaluronic acid and neurofibroma with hyperplasia of the Herbst corpuscles. Ultrastructurally, type C retroviruses, such as viral particles, were found in the tumors. The tumors were specifically stained by immunohistochemistry using monoclonal antibodies against the subgroup A avian leukosis/sarcoma virus (ALSV) and yielded a positive reaction to primers specific for subgroup A ALSV by reverse transcriptase-polymerase chain reaction assay. The virus was isolated from the tumors. Seventeen of 20 clinically normal chickens in the affected flock showed antibodies against ALSV. These results suggest that subcutaneous tumors are associated with subgroup A ALSV infection.

Selective repression of myoD transcription by v-Myc prevents terminal differentiation of quail embryo myoblasts transformed by the MC29 strain of avian myelocytomatosis virus.

We have investigated the mechanism by which expression of the v-myc oncogene interferes with the competence of primary quail myoblasts to undergo terminal differentiation. Previous studies have established that quail myoblasts transformed by myc oncogenes are severely impaired in the accumulation of mRNAs encoding the myogenic transcription factors Myf-5, MyoD and Myogenin. However, the mechanism responsible for such a repression remains largely unknown. Here we present evidence that v-Myc selectively interferes with quail myoD expression at the transcriptional level. Cis-regulatory elements involved in the auto-activation of qmyoD are specifically targeted in this unique example of transrepression by v-Myc, without the apparent participation of Myc-specific E-boxes or InR sequences. Transiently expressed v-Myc efficiently interfered with MyoD-dependent transactivation of the qmyoD regulatory elements, while the myogenin promoter was unaffected. Finally, we show that forced expression of MyoD in v-myc-transformed quail myoblasts restored myogenin expression and promoted extensive terminal differentiation. These data suggest that transcriptional repression of qmyoD is a major and rate-limiting step in the molecular pathway by which v-Myc severely inhibits terminal differentiation in myogenic cells.

Targeting retroviral vector infection to cells that express heregulin receptors using a TVA-heregulin bridge protein.

Previously we have shown that it is possible to target retroviral vectors to cells using avian sarcoma and leukosis virus (ASLV) receptor-ligand and receptor-single-chain antibody bridge proteins (now designated as GATEs for guided adaptors for targeted entry). In this report we were interested in determining whether this approach can be used to deliver retroviral vectors specifically to cells that express heregulin receptors. Heregulin receptors are attractive targets for retroviral vector-based gene delivery protocols since they are often overexpressed on the surfaces of cancer cells. To explore this possibility, the TVA-herbeta1 protein was generated, consisting of the extracellular domain of the TVA receptor for ASLV-A fused to the EGF-like region of heregulin beta1. TVA-herbeta1 bound specifically to cells that express heregulin receptors, rendering them susceptible to efficient and specific infection by subgroup A ASLV vectors. In addition, these activities of TVA-herbeta1 were abrogated specifically in the presence of another bridge protein that contained the same ligand domain. These data confirm that the GATE protein TVA-herbeta1 mediates targeted retroviral infection via cell surface heregulin receptors.

Role of calcium in protein folding and function of Tva, the receptor of subgroup A avian sarcoma and leukosis virus.

Tva is the cellular receptor for subgroup A avian sarcoma and leukosis virus (ASLV-A). The viral receptor function of Tva is determined by a 40-residue cysteine-rich motif called the LDL-A module. In this study, we expressed and purified the wild-type (wt) Tva LDL-A module as well as several mutants and examined their in vitro folding properties. We found that, as for other LDL-A modules, correct folding and structure of the Tva LDL-A module is Ca2+ dependent. When calcium was present during in vitro protein folding, the wt module was eluted as a single peak by reverse-phase high-pressure liquid chromatography. Furthermore, two-dimensional nuclear magnetic resonance (NMR) spectroscopy gave well-dispersed spectra in the presence of calcium. In contrast, the same protein folded in vitro in the absence of calcium was eluted as multiple broad peaks and gave a poorly dispersed NMR spectrum in the presence of calcium. The calcium affinity (Kd) of the Tva LDL-A module, determined by isothermal titration calorimetry, is approximately 40 microM. Characterization of several Tva mutants provided further evidence that calcium is important in protein folding and function of Tva. Mutations of the Ca2+-binding residues (D46A and E47A) completely abrogated the Ca2+-binding ability of Tva, and the proteins were not correctly folded. Interestingly, mutations of two non-calcium-binding residues (W48A and L34A) also exerted adverse effect on Ca2+-dependent folding, albeit to a much less extent. Our results provide new insights regarding the structure and function of Tva in ASLV-A entry.

Soluble receptor-induced retroviral infection of receptor-deficient cells.

Current models of retroviral entry hypothesize that interactions between the host cell receptor(s) and viral envelope protein induce structural changes in the envelope protein that convert it to an active conformation, allowing it to mediate fusion with the membrane. Recent evidence supporting this hypothesis is the demonstration that Tva, the receptor for subgroup A avian sarcoma and leukosis virus (ASLV-A), induces conformational changes in the viral envelope protein. These changes include conversion of the envelope protein to an active, membrane-binding state likely representing a fusogenic conformation. To determine whether binding of the soluble Tva (sTva) receptor was sufficient to activate fully the fusogenic potential of the ASLV-A envelope protein, we have evaluated the ability of ASLV-A to infect receptor-deficient cell lines in the presence of sTva. Soluble receptor efficiently mediated infection of cells devoid of endogenous Tva in a dose-dependent manner, and this infection was dependent absolutely on the addition of sTva. The infectivity of the virus was enhanced dramatically in the presence of the polycationic polymer Polybrene or when centrifugal forces were applied during inoculation, resulting in viral titers comparable to those achieved on cells expressing endogenous receptor. sTva functioned to mediate infection at low concentrations, approaching the estimated binding constant of the receptor and viral envelope protein. These results demonstrate that receptor binding can activate the ASLV-A envelope protein and convert it to a fusogenic conformation competent to mediate the fusion of the viral and cellular membranes.

Basic fibroblast growth factor induces cell migration and proliferation after glia-specific gene transfer in mice.

Basic fibroblast growth factor (bFGF) is overexpressed in most high-grade human gliomas, implying that it is involved in the pathogenesis of these tumors. To assess the biological effect of inappropriate production of bFGF in normal astrocytes, we developed a system for glia-specific gene transfer in transgenic mice. A transgene encoding the receptor for subgroup A avian leukosis virus and controlled by the astrocyte-specific glial fibrillary acidic protein promoter permits efficient glia-specific transfer of genes carried by subgroup A avian leukosis virus vectors. With this system, we have demonstrated that bFGF induces proliferation and migration of glial cells in vivo, without the induction of tumors.

Avian erythroblastosis virus E26: only one (myb) of two cell-derived coding regions is necessary for oncogenicity.

The oncogene hypothesis postulates that mutated cellular genes, termed proto-onc genes, function as cancer genes because they are related to retroviral onc genes. However, in contrast to retroviral onc genes, mutated proto-onc genes from cancers are not sufficient for carcinogenesis. Therefore, it has been proposed that mutated proto-onc genes depend on other proto-onc genes for carcinogenesis. Since the oncogene of the avian leukemia virus E26 includes coding regions derived from two cellular proto-onc genes, proto-myb and proto-ets, this hybrid gene has been proposed to be a model for two-gene-carcinogenesis. Here we set out to test this proposal. For this purpose myb and ets deletion mutants of cloned E26 provirus were prepared, and the corresponding viruses, produced by transfected primary chicken embryo cells, were tested for leukemogenicity in newborn chickens. It was found that an ets deletion mutant was just as leukemogenic as the wild-type virus and that a myb deletion mutant lacked leukemogenicity completely. To eliminate the possibility that our E26 myb deletion mutant failed to be leukemogenic because it failed to replicate, the virus was titered by a quantitative polymerase chain reaction (PCR) method. By this method, E26 from the plasma of infected chickens was first allowed to reverse-transcribe viral RNA to cDNA in vitro, and then the cDNA concentration was determined from the lowest dilution that gave a positive signal after amplification of E26 cDNA by the PCR method. Virus titers of about 10(5) per ml were found for wild type and for myb and ets deletion mutants of E26. It is concluded that the ets region is not essential for carcinogenesis, and E26 derives transforming function from overexpression of its proto-myb coding region via the retroviral promoter. Thus, E26 is a single-hit carcinogen and, like all other oncogenic retroviruses, is not a model for two-gene-carcinogenesis. Viral ets probably reflects a genetic accident that transduced sequences of proto-ets together with proto-myb in generating E26.

Poultry oncogenic retroviruses and humans.

Viruses of the avian leukosis/sarcoma group (ALSV) and reticuloendotheliosis viruses (REV) are highly prevalent in chickens and turkeys and naturally cause tumors in them. Commercial chickens are positive for antibodies, and a proportion actually carry infectious virus. Virus may be present in chicken products and in eggs, thus human exposure is virtually universal. The viruses show little potential for producing infectious viral particles in mammalian cells; nevertheless, they have the capacity to infect and transform mammalian cells (including human cells) in vitro, and to induce tumors in a variety of mammals, including primates. Most, but not all, of the serological studies in humans have been negative. Given the known behavior of these viruses in mammals, this was not unexpected. Moreover, there were methodological problems with most of the studies. There is some epidemiological evidence associating putative poultry exposure with cancer in humans. However, this has not been rigorously investigated. This paper is a comprehensive review of the extent of the carcinogenic potential these viruses show for humans. It is concluded, virological evidence indicates, that these viruses could conceivably have a carcinogenic potential for humans, but if so, at a level much less than in chickens. Whether this is insignificant, or translates to a real risk, is not known at the moment. Therefore, there is a need for definitive studies to completely rule out this possibility.

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)

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.

Cytocidal effect caused by the envelope glycoprotein of a newly isolated avian hemangioma-inducing retrovirus.

We isolated a field strain of avian hemangioma retrovirus (AHV) which induces a cytopathic effect (CPE) on cultured avian and mammalian cells shortly after infection. The kinetics of cell killing were dependent on the multiplicity of infection. The CPE on avian and mammalian cells was independent of virus replication, because UV-irradiated virus led to cell death as well. Biochemical and genetic experiments indicated that AHV env gene products were responsible for the CPE. Partially purified AHV envelope glycoproteins (gp85), but not those of the Rous sarcoma virus Prague C strain, induced a CPE. Rous-associated virus type 1, in which the env region was replaced by the AHV gp85 region, induced a CPE on avian and mammalian cultured cells. Therefore, we suggest that CPE is induced by AHV via interaction between viral gp85 and the cell membrane. This mode of CPE is unique among avian sarcoma-leukemia viruses.

Avian erythroblastosis virus transforms a novel mast cell-basophil precursor target in the Japanese quail.

Hematopoietic cells of the Japanese quail were transformed by avian erythroblastosis virus in vivo and in vitro. In both circumstances, the infected hematopoietic tissues exhibited a dual oncogenic response of erythroid and mast cell-basophil elements. The erythroid transformants escaped the avian erythroblastosis virus block in differentiation and progressed to hemoglobinization. Resulting basophilic cells were morphologically, biochemically, and ultrastructurally identical to mast cell-basophils observed in other species. None of the virally transformed cells actively produced reverse transcriptase activity. Nonproducer cell lines synthesized viral RNA and both v-erbA and v-erbB proteins. These results indicate that the Japanese quail has a viral target cell different from that of the chicken. The implications of a single bipotential transformation target yielding both erythroid and mast cell-basophil colonies is discussed.

[Retroviruses with 2 oncogenes]. / Retrowirusy majace dwa onkogeny.

Less than a decade ago, some acute transforming avian leukemia retroviruses that transduced not one but two distinct cellular genes that could cooperate in the viral-proned transformation processes was discovered. In this paper three examples of such retroviruses are presented. This are: avian erythroblastosis virus ES 4 (AEV-ES 4), avian erythroblastosis virus E 26 (AEV-E 26), avian Mill-Hill-2 myelocytomatosis virus (MH 2).

Retention or loss of v-mil sequences after propagation of MH2 virus in vivo or in vitro.

During propagation of the defective avian retrovirus MH2 in the presence of replication-competent helper virus, deletion of portions of the viral genome occurred frequently. After transformation of quail cells in vitro, v-mil sequences were lost, leading to populations of MH2 viruses which were highly deficient for mil gene expression but which could transform macrophage and fibroblast cells in vitro with high efficiency. In contrast, after induction of tumors in quail with mil-deficient MH2 viral stocks, a majority of the tumor DNAs contained mil+ proviruses, suggesting that there is selection for retention of the v-mil gene in vivo and that the mil protein may play a role in the oncogenicity of MH2 virus. We also isolated MH2-transformed cell lines which contained deleted proviruses arising from packaging and subsequent integration of the subgenomic v-myc-encoding mRNA. Some of these cell lines produced viruses which encoded abnormal v-myc proteins and had altered in vitro transforming properties. These altered phenotypes may be caused by mutations within the v-myc gene.

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.

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.