Construction and characterization of novel fowlpox virus shuttle vectors.

Viral vectors are important vehicles in vaccine research. Avipoxviruses including fowlpox virus (FPV) play major roles in viral vaccine vector development for the prevention and therapy of human and other veterinary diseases due to their immunomodulatory effects and safety profile. Recently, we analyzed the genomic and proteomic backgrounds of the Chinese FPV282E4 strain. Based on analysis of the whole genome of FPV282E4, the FPV150 and FPV193 loci were chosen as insertion sites for foreign genes, and two shuttle vectors with a triple-gene expression cassette were designed and constructed. Homologous recombination between the FPV virus genome and sequences within the shuttle plasmids in infected cells was confirmed. The recombinants were obtained through several rounds of plaque purification using enhanced green fluorescent protein as a reporter and evaluated for the correct expression of foreign genes in vitro using RT-PCR, real-time PCR and Western blotting. Morphogenesis and growth kinetics were assayed via transmission electron microscopy and viral titering, respectively. Results showed that recombinant viruses were generated and correctly expressed foreign genes in CEF, BHK-21 and 293T cells. At least three different exogenous genes could be expressed simultaneously and stably over multiple passages. Additionally, the FPV150 mutation, FPV193 deletion and insertion of foreign genes did not affect the morphogenesis, replication and proliferation of recombinant viruses in cells. Our study contributes to the improvement of FPV vectors for multivalent vaccines.

Construction and characterisation of a recombinant fowlpox virus that expresses the human papilloma virus L1 protein.

BACKGROUND: Human papilloma virus (HPV)-16 is the most prevalent high-risk mucosal genotype. Virus-like-particle (VLP)-based immunogens developed recently have proven to be successful as prophylactic HPV vaccines, but are still too expensive for developing countries. Although vaccinia viruses expressing the HPV-16 L1 protein (HPV-L1) have been studied, fowlpox-based recombinants represent efficient and safer vectors for immunocompromised hosts due to their ability to elicit a complete immune response and their natural host-range restriction to avian species. METHODS: A new fowlpox virus recombinant encoding HPV-L1 (FPL1) was engineered and evaluated for the correct expression of HPV-L1 in vitro, using RT-PCR, immunoprecipitation, Western blotting, electron microscopy, immunofluorescence, and real-time PCR assays. RESULTS: The FPL1 recombinant correctly expresses HPV-L1 in mammalian cells, which are non-permissive for the replication of this vector. CONCLUSION: This FPL1 recombinant represents an appropriate immunogen for expression of HPV-L1 in human cells. The final aim is to develop a safe, immunogenic, and less expensive prophylactic vaccine against HPV.

Canarypox and fowlpox viruses as recombinant vaccine vectors: a biological and immunological comparison.

Canarypox and fowlpox viruses represent alternative vaccine vectors due to their natural host-range restriction to avian species. Although they cannot replicate in mammals, they correctly express transgenes in human cells and elicit a complete immune response in vaccinated subjects. Several studies have evaluated their genomic differences and protective efficacy in preclinical trials, but detailed information is not available for their transgene expression, cytokine modulation and abortive replication in mammals. This study demonstrates that the heterologous HIV gag/pol and env genes are more efficiently expressed by fowlpox in non-immune and immune cells. The production of retrovirus-like particles, the longer transgene expression, and a balanced cytokine induction may confer to fowlpox-based recombinants the ability to elicit a better immune response.

Canarypox and fowlpox viruses as recombinant vaccine vectors: an ultrastructural comparative analysis.

Due to their natural host-range restriction to avian species, canarypox virus (CP) and fowlpox virus (FP) represent efficient and safe vaccine vectors, as they correctly express transgenes in human cells, elicit complete immune responses, and show protective efficacy in preclinical animal models. At present, no information is available on the differences in the abortive replication of these two avipox viruses in mammalian cells. In the present study, the replicative cycles of CP and FP, wild-type and recombinants, are compared in permissive and non-permissive cells, using transmission electron microscopy. We demonstrate that in non-permissive cells, the replicative cycle is more advanced in FP than in CP, that human cells, whether immune or not, are less permissive to avipox replication than monkey cells, and that the presence of virus-like particles only occurs after FP infection. Overall, these data suggest that the use of FP recombinants is more appropriate than the use of CP for eliciting an immune response.

Squamous cell carcinoma with presence of poxvirus-like inclusions in the foot of a pink-backed pelican (Pelecanus rufescens).

Squamous cell carcinoma (SCC) or avian keratoacanthoma is a neoplastic skin lesion of unknown aetiology that has been well described in birds. Some studies have reported that poxviruses may contribute to the onset of SCC. Here we describe a case of SCC on the underside of a pelican's foot. Histologically, the tumour consisted of irregular cords of pleomorphic epithelial cells that invaded the adjacent tissues. Additionally, keratinized epithelial cells and moderate numbers of keratin pearls were observed. Intracytoplasmic inclusions, a characteristic of this virus, were observed in some of these cells, and viral particles were characterized by electron microscopy. Although the aetiology of the carcinoma in this case may have been secondary to chronic focal trauma, the possibility of a latent or chronic form of fowlpox should be considered in the pathogenesis of the lesion.

Morphogenesis of fowlpox virus in a baby hamster kidney cell line.

Fowlpox virus (FWPV) recombinant vaccines are presently being tested as an antihuman immunodeficiency virus vaccine for humans. However, biosafety, as well as the morphogenesis of FWPV in mammalian cells, are not well understood. Currently, electron microscopy is the method of choice for analyzing virus morphogenesis in cell lines. In this study, four different electron microscopic techniques were used to study FWPV morphogenesis in the Syrian baby hamster kidney (BHK-21) cell line: direct negative stain electron microscopy, ultrathin section transmission electron microscopy, cryoimmunoelectron microscopy, and scanning electron microscopy. The study showed matured viruses, as well as other stages of fowlpox virus maturation, in BHK-21 cells that led to productive virus multiplication. A number of virus-containing vesicles and plasma membrane-associated mature viruses at an early stage in the budding process were observed. In addition, intracellular mature virus was observed in layers of the trans-Golgi network, a characteristic of intracellular mature virus wrapping that results in the formation of intracellular enveloped virus. The size and morphology of FWPV observed in this study are comparable with previously published data. This study presents the first morphological evidence for the release of FWPV by budding in BHK-21 cells.

Morphogenesis and release of fowlpox virus.

Release of fowlpox virus (FWPV) as extracellular enveloped virus (EEV) appears to proceed both by the budding of intracellular mature virus (IMV) through the plasma membrane and by the fusion of intracellular enveloped virus (IEV) with the plasma membrane. Based on the frequency of budding events compared to wrapping events observed by electron microscopy, FWPV FP9 strain seems to exit chick embryo fibroblast cells predominantly by budding. In contrast to vaccinia virus (VV), the production of FWPV extracellular virus particles is not affected by N(1)-isonicotinoyl-N(2)-3-methyl-4-chlorobenzoylhydrazine (IMCBH). Comparison of the sequence of the VV F13L gene product with its FWPV orthologue showed a mutation, in the fowlpox protein, at the residue involved in IMCBH resistance in a mutant VV. Glucosamine, monensin or brefeldin A did not have any specific effect on FWPV extracellular virus production. Cytochalasin D, which inhibits the formation of actin filaments, reduces the production of extracellular virus particles by inhibiting the release of cell-associated enveloped virus (CEV) particles from the plasma membrane. Involvement of actin filaments in this mechanism is further supported by the co-localization of actin with viral particles close to the plasma membrane in the absence of cytochalasin D. Actin is also co-localized with virus factories.

Fowlpox virus host range restriction: gene expression, DNA replication, and morphogenesis in nonpermissive mammalian cells.

Fowlpox virus (FPV), type species of the Avipoxvirus genus, causes a slow-spreading pox disease of chickens. Following infection of mammalian cells there is no evidence of productive replication of FPV although cytopathic effects are induced and FPV recombinants have been shown to express foreign genes from vaccinia virus early/late promoters. Here we report results of a study to investigate the expression of FPV genes, the replication of FPV genomic DNA, and any ultrastructural changes in mammalian cells infected by wild-type virus, undertaken as a first step in elucidating the nature of the block (or blocks) to productive replication of FPV in mammalian cells. Early and late gene expression as well as genomic DNA replication was observed in fibroblast-like cell lines of monkey and human origin. Furthermore, viral morphogenesis was observed in monkey cells, with the production mainly of immature particles though smaller numbers of apparently mature virus particles were observed.

Isolation of poxvirus from debilitating cutaneous lesions on four immature grackles (Quiscalus sp.).

Poxvirus was isolated from nodules on four immature grackles (Quiscalus sp.) collected in two residential areas of Victoria, Texas. All of the birds were emaciated and had nodules on the eyelids, bill, legs, toes, and areas of the skin on the wings, neck, and ventral abdomen. These pox nodules were extensive and probably interfered with both sight and flight. The preliminary diagnosis was confirmed by virus isolation, histopathology, and electron microscopy. Poxvirus was isolated on the chorioallantoic membrane of embryonated hen's eggs and in Muscovy duck embryo fibroblast cell culture. Phaenicia calliphoridae (blowfly) larvae were found in one of the pox nodules, raising the possibility of mechanical transmission of the virus by contaminated adult blowflies.

Detection of fowlpox virus DNA by in situ hybridization using a biotinylated probe.

In situ hybridization was applied to detect fowlpox virus (FPV) DNA in formalin-fixed paraffin-embedded sections of the skin from infected chickens by using a biotinylated probe and a streptavidin-alkalinephosphatase conjugate. The immunohistochemical examination was applied to compare the distribution of the FPV DNA to that of related antigenic protein in serial sections. In the infected epithelial cells, FPV DNA was detected in cytoplasmic inclusion bodies and in the rest of cytoplasm. Likewise, immunohistochemical examination revealed the virus antigen in cytoplasm. Ultrastructurally, virions were observed in the cytoplasmic inclusion bodies, and immature virus particles were in the rest of the cytoplasm. The study proved restricted distribution of FPV DNA in the cytoplasm.

Morphogenesis of canary poxvirus and its entrance into inclusion bodies.

A virus isolated from a natural outbreak of canarypox was replicated on the chorioallantoic membranes of chicken embryos, and its ultrastructure and development were observed. Electron microscopy of thin sections of pocks produced on the chorioallantoic membranes revealed a variety of developmental forms which appear similar to those demonstrated in studies of vaccinia, ie, viroplasm or viral factories; immature, undifferentiated virions partially enclosed by membranes; completely enclosed nondifferentiated spherical or oval virions; immature virions with discrete nucleoids; and the more compact brick-shaped mature virions. Two types of A-type inclusions were noted: those with virions around the periphery, and those filled with virus particles. The appearance of mature viruses within the inclusion bodies and different stages of viruses outside the inclusion indicate that in a course of development, maturing poxvirus may enter the inclusion bodies as they acquire surface tubules on their envelopes. Mature virions also were seen budding out of the cell membrane, apparently enveloped in a portion of the membrane. Studies showing the entrance of poxvirus into inclusion bodies have not been reported. In this report, electron micrographs are shown of viruses entering inclusion bodies.

Isolation of surface tubules of fowlpox virus.

Surface tubules of fowlpox virus were isolated using chemical and physical methods. Suspensions of lipid cytoplasmic inclusion bodies were obtained by treating infected chorioallantoic membranes with 1% trypsin. Inclusions were treated with ultrasonic sound, detergents, and enzymes and were examined by electron microscopy. Although lipase treatment altered the morphology of lipid inclusions, no viral surface tubules were recovered. Treatment with the detergent Nonidet-P40 followed by 2-mercaptoethanol disrupted virions without allowing surface tubules to be recovered. Disruption of lipid inclusions by ultrasonic sound or manual grinding of chorioallantoic membranes produced free virions but only small numbers of tubules. These results indicate that surface tubules can be recovered, but that the lipid nature of cytoplasmic inclusions interferes with procedures commonly used in tubule purification.

Avian pox infection in a Canada goose (Branta canadensis).

Lesions suggestive of Avian Pox were found on a debilitated Canada goose (Branta canadensis). These were demonstrated histologically to be characteristic poxvirus lesions and poxvirus particles were seen using electron microscopy. The virus was successfully transmitted to domestic geese but not to leghorn chickens or to domestic ducks.

Avian pox virus. An ultrastructural study on a cherrug falcon. Brief report.

The ultrastructure and maturation of avian pox particles is described in the rare case of a naturally infected hawk (Falco cherrug). As in other cells infected by fowlpox virus two types of inclusion bodies are encountered in the cytoplasm: firstly assemblies of fluffy filamentous material apparently giving rise to immature virions. They are thought to present virus factories (inclusion body B). Secondly mature virus particles budded into extensive groupings (Bollinger bodies, inclusion body A) which display a fine structure identical to other strains of fowlpox virus.

Poxvirus infection in a spectacled Amazon parrot (Amazona albifrons).

Avian pox was determined to be the cause of death of a spectacled Amazon parrot (Amazona albifrons). Intracytoplasmic inclusion bodies were visualized by light microscopy in esophageal and bronchial epithelial lesions. Electron microscopy revealed pox-virus virions in the inclusions.

Rapid diagnosis of some avian virus diseases.

Direct electron microscopy was used to identify virions of infectious laryngotracheitis in lysed tracheal cells and of fowlpox in scabs and exudates from natural cases. Rapid identification of avian adenovirus and infectious laryngotracheitis by gel diffusion was possible using antigens prepared by simple distilled-water lysis of infected cell cultures. Precipitin lines were often visible within 5 hours.