Purification of foamy viral particles

Foamy viruses are non-pathogenic retroviruses and represent a tool for vector development. For gene therapy applications and for analyses of viral protein composition infectious particles need to be purified, which has been difficult for foamy viruses in the past. Here, we describe a novel, simple, and fast purification method for prototype foamy viruses with high purity using size exclusion and affinity chromatography. More than 99,9% of the contaminating proteins were removed. The purified viruses were used to determine the amount of the incorporated Pol protein relative to Gag. The determined Gag to Pol PR-RT ratio of 30:1 confirmed previous studies suggesting FV virions encapsidate fewer number of Pol molecules than orthoretroviruses.

In Vitro Evolution of Bovine Foamy Virus Variants with Enhanced Cell-Free Virus Titers and Transmission

Virus transmission is essential for spreading viral infections and is a highly coordinated process which occurs by cell-free transmission or cell-cell contact. The transmission of Bovine Foamy Virus (BFV) is highly cell-associated, with undetectable cell-free transmission. However, BFV particle budding can be induced by overexpression of wild-type (wt) BFV Gag and Env or artificial retargeting of Gag to the plasma membrane via myristoylation membrane targeting signals, closely resembling observations in other foamy viruses. Thus, the particle release machinery of wt BFV appears to be an excellent model system to study viral adaption to cell-free transmission by in vitro selection and evolution. Using selection for BFV variants with high cell-free infectivity in bovine and non-bovine cells, infectivity dramatically increased from almost no infectious units to about 105-106 FFU (fluorescent focus forming units)/mL in both cell types. Importantly, the selected BFV variants with high titer (HT) cell-free infectivity could still transmit via cell-cell contacts and were neutralized by serum from naturally infected cows. These selected HT-BFV variants will shed light into virus transmission and potential routes of intervention in the spread of viral infections. It will also allow the improvement or development of new promising approaches for antiretroviral therapies.

Risk assessment: a model for predicting cross-species transmission of simian foamy virus from macaques (M. fascicularis) to humans at a monkey temple in Bali, Indonesia

Contact between humans and nonhuman primates (NHPs) frequently occurs at monkey temples (religious sites that have become associated with free-ranging populations of NHPs) in Asia, creating the potential for NHP-human disease transmission. In March 2003 a multidisciplinary panel of experts participated in a workshop designed to model the risk of NHP-human pathogen transmission. The panel developed a risk assessment model to describe the likelihood of cross-species transmission of simian foamy virus (SFV) from temple macaques (Macaca fascicularis) to visitors at monkey temples. SFV is an enzootic simian retrovirus that has been shown to be transmitted from NHPs to humans. In operationalizing the model field data, laboratory data and expert opinions were used to estimate the likelihood of SFV transmission within this context. This model sets the stage for a discussion about modeling as a risk assessment tool and the kinds of data that are required to accurately predict transmission.

RNA and protein requirements for incorporation of the Pol protein into foamy virus particles

Foamy viruses (FVs) generate their Pol protein precursor molecule independently of the Gag protein from a spliced mRNA. This mode of expression raises the question of the mechanism of Pol protein incorporation into the viral particle (capsid). We previously showed that the packaging of (pre)genomic RNA is essential for Pol encapsidation (M. Heinkelein, C. Leurs, M. Rammling, K. Peters, H. Hanenberg, and A. Rethwilm, J. Virol. 76:10069-10073, 2002). Here, we demonstrate that distinct sequences in the RNA, which we termed Pol encapsidation sequences (PES), are required to incorporate Pol protein into the FV capsid. Two PES were found, which are contained in the previously identified cis-acting sequences necessary to transfer an FV vector. One PES is located in the U5 region of the 5' long terminal repeat and one at the 3' end of the pol gene region. Neither element has any significant effect on RNA packaging. However, deletion of either PES resulted in a significant reduction in Pol encapsidation. On the protein level, we show that only the Pol precursor, but not the individual reverse transcriptase (RT) and integrase (IN) subunits, is incorporated into FV particles. However, enzymatic activities of the protease (PR), RT, or IN are not required. Our results strengthen the view that in FVs, (pre)genomic RNA functions as a bridging molecule between Gag and Pol precursor proteins.

The replication strategy of foamy viruses

The replication strategy of foamy viruses diverges in many aspects from what is commonly accepted as the rules of retroviral replication. Although many questions on the details of the replication pathway are still unanswered, it appears that foamy viruses have adopted a strategy which functionally bridges the retroviral and the hepadnaviral replication pathways. A number of experimental findings in favour of the view that foamy viruses are reverse transcribing DNA viruses which integrate into the host cell genome are discussed.

Foamy virus vectors

Gene therapy is a promising novel treatment for a variety of human diseases. Successful application of gene therapy requires the availability of vehicles with the ability to efficiently deliver and express genes. Viral vectors are efficient means of transferring a gene of interest into target cells. Current available vehicles for gene transfer are either inefficient or potentially unsafe for human gene therapy applications. Foamy viruses offer a fresh alternative vector system for gene transfer with the potential to overcome the concerns of the current vectors. Foamy viruses are nonpathogenic and have a broad host range with the ability to infect various types of cells from different species. Foamy virus replication is distinct and may provide an edge for foamy virus vector usage over other retroviral vectors. These features offer the foamy vectors unique opportunities to deliver several genes into a number of different cell types in vivo safely and efficiently. The principal problems for the design of foamy virus vectors have been solved, and several foamy virus vectors that efficiently transduce a variety of cell types are available. This chapter reviews specific features of foamy virus vector systems and recent advances in the development and use of these vectors.

A new indicator cell line to monitor human foamy virus infection and stability in vitro

In order to determine the human foamy virus (HFV) infection in vitro conveniently, we developed a baby hamster kidney cell (BHK)-21-derived indicator cell line (BHK-HFVLTR-EGFP) containing a plasmid that encodes the enhanced green fluorescent protein (EGFP) driven by the HFV long terminal repeat promoter. The viral trans-activator Bel-1 protein can induce EGFP expression, so the HFV titer could be determined by counting the corresponding EGFP-positive cells. This foamy-virus-activated EGFP expression (FAE) assay was about 50 times more sensitive than the traditional focus plaque assay by end-point dilution. Additionally, the results of the FAE assay can be obtained rapidly within 2 days, whereas the determination of focus developing needs 2 weeks. Moreover, a linear relationship was found between the fluorescence intensity and the titer of inoculated HFV. In brief, the FAE assay is a rapid, easy, sensitive and quantitative method for monitoring and investigating HFV infection. Using the indicator cell line BHK-HFVLTR-EGFP, we examined the effects of repeated freeze-and-thaw cycles and temperature on HFV stability by the FAE assay. Such information about HFV infection and stability would be valuable for HFV applications.

Survival of spumavirus, a primate retrovirus, in laboratory media and water

The persistence of a previously characterized spumavirus strain (strain SV-522) was investigated utilizing various laboratory media and waters, including Eagle's minimal essential medium (EMEM) plus 0% fetal bovine serum (EMEM-0%), EMEM-2%, EMEM-10%, Chlamydia transport medium (CTM), phosphate-buffered saline, distilled, estuarine, and marine water, human serum, and the germicides, ethyl alcohol (70%) and sodium hypochlorite (10%). Experiments were performed at 4 degrees C and/or 23 degrees C. Infectivity endpoints were determined in stock aliquots upon initiation of testing and then after 3, 5, 7, and 10 days. The virus was reisolated from all diluents after 5 days at 23 degrees C and in EMEM-10% after 7 days. The virus was detected in CTM, EMEM-2%, EMEM-10%, and estuarine and marine waters after 7 days at 4 degrees C. Differences in the persistence of the virus may be ascribed to temperature and organic load. Water ionic strengths (e.g., estuarine vs. marine water) had no effect on modifying persistence of viral particles. Infectivity of spumavirus was undetectable after 30 s in 70% ethanol or 10% sodium hypochlorite. After 30 min at 23 degrees C, spumavirus infectivity in normal but not heat-inactivated human serum increased by almost 100-fold. Persistence of infectivity of primate spumavirus after 7 days in media and waters, and the agent's infectious potential in the human host, emphasize a need for cautious recognition during the manipulation of primate cells/organs and in the handling of primates themselves.

A quantitative assay for measuring human foamy virus using an established indicator cell line

In order to improve the accuracy for detecting human foamy virus (HFV), an indicator cell line was established by co-transfecting baby hamster kidney-21 cells with two plasmids: one containing a G418 antibiotic resistance marker and the other including the luc gene which was placed downstream of the inducible HFV long terminal repeat promoter (from -533 to +20). Among 11 independent subclones, IdB14 was found to be stable with a low basal level of luciferase activity. Although the changes in luciferase activity in infected clones showed time-dependency and peaked at day 8, it is possible to differentiate infected and uninfected cells on day 2. The sensitivity of the foamy virus activated luciferase (FAL) assay was 400 times higher than the end-point syncytium formation by TCID(50). The HFV LTR promoter in the IdB14 cell line was specific for this virus. Moreover, a linear relationship was found between the MOI and the activated intensity of luciferase expression. These findings suggest that the FAL assay using the IdB14 indicator cell line is a simple and useful technique for rapid diagnosis and quantitation of active HFV infection.

An endoplasmic reticulum retrieval signal partitions human foamy virus maturation to intracytoplasmic membranes

Among all retroviruses, foamy viruses (FVs) are unique in that they regularly mature at intracytoplasmic membranes. The envelope glycoprotein of FV encodes an endoplasmic reticulum (ER) retrieval signal, the dilysine motif (KKXX), that functions to localize the human FV (HFV) glycoprotein to the ER. This study analyzed the function of the dilysine motif in the context of infectious molecular clones of HFV that encoded mutations in the dilysine motif. Electron microscopy (EM) demonstrated virion budding both intracytoplasmically and at the plasma membrane for the wild-type and mutant viruses. Additionally, mutant viruses retained their infectivity, but viruses lacking the dilysine signal budded at the plasma membrane to a greater extent than did wild-type viruses. Interestingly, this relative increase in budding across the plasma membrane did not increase the overall release of viral particles into cell culture media as measured by protein levels in viral pellets or infectious virus titers. We conclude that the dilysine motif of HFV imposes a partial restriction on the site of viral maturation but is not necessary for viral infectivity.

Detection of bovine retrospumavirus by the polymerase chain reaction

A polymerase chain reaction (PCR) assay was developed for detection of bovine retrospumavirus (bovine syncytial virus; BSV) provirus DNA. Two different sets of oligonucleotide primers complementary to sequences located in the gag and the pol/env gene regions were used and compared for their ability to amplify the targeted BSV sequences by PCR. The results obtained from this study have shown that it is possible to amplify the BSV provirus DNA sequences not only from total DNA of BSV-infected cell cultures, but also from total DNA of various tissues and peripheral blood mononuclear cells (PBMCs) that were collected from two rabbits experimentally infected with BSV. Sensitivities of the PCR for amplification of BSV gag and pol/env nucleic acid sequences from cell culture total DNA were 10 ng and 10 pg of DNA, respectively, as determined by the analysis of the amplified PCR products on ethidium bromide-stained agarose gels. The specificity of the PCR for both primer sets tested was confirmed when the amplified cDNA products of the expected size reacted positively with the corresponding virus-specific digoxigenin-labeled cDNA probes in Southern blot chemiluminescent hybridization assays. No amplification was obtained when the BSV-specific primers were used in the PCR with DNA material specific to either bovine leukemia virus (BLV) or bovine immunodeficiency virus (BIV) provirus genomic DNA. No cross-hybridization was obtained when the BSV-specific cDNA probes were allowed to react with BLV or BIV provirus DNA. The PCR targeting the gag and pol/env gene regions of the BSV provirus genome may be an alternative to conventional methods for the confirmation of the presence of BSV in cell cultures used for virus isolation, and for the diagnosis of BSV infection from bovine peripheral blood leukocytes.

Identification and functional characterization of a high-affinity Bel-1 DNA binding site located in the human foamy virus internal promoter

The transcription of genes carried by primate foamy viruses is dependent on two distinct promoter elements. These are the long terminal repeat (LTR) promoter, which regulates expression of the viral structural proteins, and a second internal promoter, located towards the 3' end of the env gene, that directs expression of the viral auxiliary proteins. One of these auxiliary proteins is a potent transcriptional transactivator, termed Bel-1 in human foamy virus (HFV) and Tas or Taf in the related simian foamy viruses, that is critical for foamy virus replication. Previously, it has been demonstrated that the LTR promoter element of HFV contains a DNA binding site for Bel-1 that is critical for transcriptional activation (F. He, W. S. Blair, J. Fukushima, and B. R. Cullen, J. Virol. 70:3902-3908, 1996). Here, we extended this earlier work by using methylation interference analysis to identify and characterize the Bel-1 DNA binding sites located in the HFV LTR and internal promoter elements. Based on these data, we propose a minimal, 25-bp DNA binding site for Bel-1, derived from the HFV internal promoter element, and show that this short DNA sequence mediates efficient Bel-1 binding both in vitro and in vivo. We further demonstrate that, as determined by both in vitro and in vivo assays, the Bel-1 target site located within the HFV internal promoter binds Bel-1 with a significantly higher affinity than the cap-proximal Bel-1 target site located in the LTR promoter. This result may provide a mechanistic explanation for the observation that the internal promoter is activated significantly earlier than the LTR promoter during the foamy virus life cycle.

A rapid streptavidin-capture ELISA specific for the detection of antibodies to feline foamy virus

We report a simple procedure for the rapid development of an ELISA with the potential for wide application to any defined protein antigen. The procedure involves the expression of protein encoded by a PCR product, using a commercially available T-vector that adds a biotin tag, and a single step purification by affinity for streptavidin for direct use in ELISA. In our experiments, a recombinant protein from the nucleocapsid domain of the feline foamy virus gag gene was expressed as a fusion protein with a biotin tag and then applied directly to streptavidin-coated ELISA wells. An extract from a clone with the insert in antisense orientation was used as a control. Non-specific reactions with antigen extracts from both sense and antisense clones were observed in 6 of the 376 (1.6%) sera tested. Antibody to feline foamy virus, which forms a stable persistent infection in cats, was detected in 107 of 201 (53%) Australian cats, but none of 175 sera from veterinarians. There was a 100% correlation between FeFV antibody detected by ELISA, immunoblot, serum neutralisation and virus isolation, confirming that this test is sensitive and specific.

Molecular biology of the human foamy virus

Foamy viruses also known as spumaretroviruses are complex retroviruses infecting cell lines with no apparent specific cellular tropism and induce the formation of multinucleated cells with numerous vacuoles. Far less well characterized than oncoviruses and lentiviruses, this class of viruses is thought to be innocuous in vivo. However, several important discoveries on foamy viruses brought new insights in the field of retrovirology.

Unexpected replication pathways of foamy viruses

Foamy viruses make up a distinct subgroup of retroviruses. They are widely distributed among nonhuman primates, felines, and bovines. In their natural hosts and in cases of rare zoonotic transmissions to humans foamy viruses cause persistent and apparently benign infections. While foamy viruses are not of medical importance in causing human or animal diseases, they may become valuable tools for somatic gene transfer in the future. However, a better understanding of the molecular biology of this virus group is a prerequisite for the development of foamy virus vectors. In this respect, recent research has revealed major differences between the foamy virus and the general retroviral replication strategies and some similarities to hepadnaviruses.

Foamy virus vectors

Human foamy virus (HFV) is a retrovirus of the spumavirus family. We have constructed vectors based on HFV that encode neomycin phosphotransferase and alkaline phosphatase. These vectors are able to transduce a wide variety of vertebrate cells by integration of the vector genome. Unlike vectors based on murine leukemia virus, HFV vectors are not inactivated by human serum, and they transduce stationary-phase cultures more efficiently than murine leukemia virus vectors. These properties, as well as their large packaging capacity, make HFV vectors promising gene transfer vehicles.

In vitro studies on interferon-inducing capacity and sensitivity to IFN of human foamy virus

We demonstrate in this article that human foamy virus (HFV) fails to induce interferon (IFN) production in two different human tissue culture cell lines: U373-MG and AV3. We also show the effect of human alpha-, beta- and gamma IFN on the multiplication cycle of HFV. Treatment of cells with 100 IU/ml of any IFN led to strong inhibition of an HFV-induced cytopathic effect. This effect was associated with a significant diminution of reverse transcriptase activity in supernatant fluids of IFN-treated infected cultures, and a substantial decrease in viral particle production, as detected by electron microscopy. All these effects were accompanied by strong inhibition of both viral proteins and RNA synthesis, as well as almost total disappearance of free and integrated proviral DNA. In light of our data, human IFN action on HFV seems to be mediated by a mechanism which differs from that observed in the case of other retroviruses (type C and D for instance); however, it evokes that described for HIV.

Functional analysis of human spuma retrovirus genome

Human spuma retrovirus (HSRV) belongs to retroviruses that possess a complex genome organization. HSRV carries at least three extra genes in the region between env and the 3' long terminal repeat, which are not found in simple retroviruses. Via alternative splicing, these HSRV genes can encode several proteins. To genetically study the requirements of these viral proteins for viral replication in tissue cultures, a number of mutant viruses were constructed from an infectious molecular clone of HSRV. All mutants grew normally in the cell lines tested, except for those lacking transcriptional transactivator activity. By reporter-based transient assay systems, no Rev/Rex equivalent was detected in the HSRV proteins.

Establishment of carrier-state infection of a feline renal cell line with feline syncytial virus

Although feline syncytial virus (FSV) is normally highly cytopathogenic in Crandell feline kidney cells, a non-cytopathic persistent infection was established in the cells after cocultivation of the initially infected cells with uninfected cells 4 times. More than 90% of the persistently infected cells were positive for FSV antigen, and electron microscopy showed that the culture produced morphologically normal FSV. Virus from the carrier culture was infectious, however, the titer of the virus from the culture was lower than that from the cytocidally infected CRFK cells.

Simian foamy virus type 3 (SFV-3) in latently infected Vero cells: reactivation by demethylation of proviral DNA

Cell cultures latently infected with simian foamy virus type 3 (SFV-3) were established by suppressing lytic infection in Vero cells with 3'-azido-3'-deoxythymidine (AZT) and homologous antibodies (African green monkey serum immune to SFV-3). The resulting cell line, designated Vero-L, was shown to contain at least one copy per cell of SFV-3 DNA stably integrated at a defined site of the host cell genome. Sequencing of 669 bp at the integration site did not identify a coding region and revealed a 4-bp imperfect repeat in host cell DNA due to SFV-3 integration. Over 2 years of subcultivation, no spontaneous expression of proviral genes could be detected. However, the demethylating agent 5'-azacytidine reactivated lytic infection, proving conservation of the complete viral genome. Comparison of proviral DNA from latently and lytically infected cells supports the notion that methylation is instrumental in keeping SFV-3 infection in latency.

Chemical inhibition of foamyvirus in primary baboon (Papio cynocephalus) kidney cells

This report describes the conditions for the use of aluminum chloride (AlCl3) in growth and maintenance media for the suppression or inhibition of simian foamyviruses (SFV) in primary baboon kidney (BAK) and rabbit kidney (RK) cell cultures. When RK cells were planted in medium containing AlCl3, infected with SFV, and passaged, the growth of SFV was suppressed or inhibited by the presence of AlCl3. With this method, BAK cells yielded higher viral titers after infection with various viruses, thus making these cells more suitable for virological applications.

Replication of human syncytium-forming virus in human cells: effect of certain biological factors and selective chemicals

The growth characteristics of the human syncytium-forming virus (HSFV) were examined in several human cell lines of normal and malignant origins and composing of either fibroblastic or epithelial-like cells. Virus production occurred only in the fibroblastic diploid cell lines: HEF (human embryonic cells, Flow #5,000) and HFDL #645 (human fetal diploid lung), but not in the epithelial-like heteroploid cell lines: RA (a continuous line of human amnion), #999 (human bone marrow), and KB (carcinoma of the nasopharynx). While the single-cycle growth pattern of the virus in HEF and HFDL #645 cell lines were essentially similar, the virus yield per cell was greater in the HFDL #645 cells. Furthermore, the physiological state of the cell had a marked effect on virus production. Subconfluent actively growing HFDL #645 cells produced higher yields of virus than density-inhibited confluent HFDL #645 cell cultures. The replication of HSFV was inhibited by actinomycin D at concentrations that did not interfere with poliovirus replication (0.001 to 0.01 microgram/ml). Pretreatment and posttreatments of infected cell cultures with either the polycation polybrene (hexadimethrine bromide) or the synthetic glucocorticosteroid dexamethasone did not enhance HSFV production.

Feline syncytium-forming virus: DNA provirus size and structure

An infectious DNA assay has been used to investigate the size and structure of the genome of feline syncytium-forming virus (FSFV). The dose response between DNA extracted from FSFV-infected cells and plaque number on feline embryo cells followed two-hit kinetics and the mol. wt. of the proviral DNA was estimated as approx. 6 x 10(6).

Comparison of the antigens produced by foamy virus in a cytolytic and a persistent infection of HEp2 cells

The antigens from cytolytic infections of HEp2 cells by type I simian foamy virus produced two multicomponent precipitation lines when tested by immunodiffusion with the homologous hyperimmune rabbit antiserum. The antigens obtained from a non-productive infection of MK5 virus in HEp2 cells produced only those precipitation lines which corresponded with the inner lines obtained from the cytolytic infection. Similarly, hyperimmune rabbit antiserum against antigens extracted from the persistent infection lacked the antibody which was responsible for the outer lines of precipitation. Indirect immunofluorescence with acetone-fixed and unfixed cells using the homologous and heterologous sera confirmed the absence of antigens in the persistent infection and showed that an antigen is produced in the persistently infected cells which is either absent or present in very small amounts in cytolytically infected cells. Neutralization experiments and ether treatment suggested that the missing antigens in the persistent infection were the envelope components of foamy virus. It is proposed that the persistent infection has properties in common with some infections by RNA tumour viruses.

Feline syncytium-forming virus: identification of a virion associated reverse transcriptase and electron microscopical observations of infected cells

The maturation of feline syncytium-forming virus (FSFV), a member of the foamy virus sub-family (Spumavirinae), has been studied by electron microscopy of thin sections of infected feline embryo (FEA) cells. The initial event observed was formation of crescent-shaped nucleoids at the plasma membrane. As budding progressed, the nucleoid became circular in outline with an electron-lucent centre in fully mature extracellular particles. These observations suggested that the maturation of FSFV in fully permissive FEA cells resembled that of C-type RNA tumour viruses, rather thant the B-type mouse mammary tumour virus. In this respect FSFV may be distinct from other foamy viruses. However, like other foamy viruses FSFV possessed reverse transcriptase activity. Polymerase activity co-sedimented with infectivity in an equilibrium density gradient and exhibited a preference for poly(rA).oligo(dT)10 over poly(dA).oligo(dT)10 as exogenous template.

Factors affecting the growth and titration by immunofluorescence of simian foamy virus

This paper presents some observations concerned with the growth of simian foamy virus and some modifications which should be introduced to the fluorescence assay of foamy virus. The modified procedure is the most sensitive method described for the titration of foamy virus. Examination of the optimal conditions for the growth and titration by fluorescence assay of simian foamy virus showed that the virus was particularly sensitive to changes in virus and cell concentration. At the low cell concentrations employed previously a "saturation-type" response was obtained with high titre virus and virus adsorption efficiency was decreased as input virus was diluted. Maximum virus production was obtained with high cell concentrations at input multiplicities of 5 and 10. At high multiplicities of infection more than 90 per cent of the cells adsorbed virus but only 45 per cent became infected, this appeared to be related to cell DNA synthesis.

Isolation and characterization of a new simian foamy virus serotype from lymphocytes of a Papio cynocephalus baboon

A new type of syncytium-forming (foamy) virus was isolated from peripheral lymphocytes of a Papio cynocephalus baboon after cocultivation with a rhesus monkey cell line. The isolate was characterized by cytopathogenic effect, host range, electron microscopy, reverse transcriptase activity and physical and chemical properties. Seroneutralization tests indicate that the new isolate is antigenically distinct from the other nine known simian foamy virus serotypes.

Human foamy virus: further characterization, seroepidemiology, and relationship to chimpanzee foamy viruses

A foamy virus present in human nasopharyngeal carcinoma tissue was studied for a number of biological properties, including range of cellular susceptibility, growth curve, evolution of cytopathic effect in relation to cellular fusion and intracellular viral distribution, reverse transcriptase activity, and buoyant density. The virus was also studied immunologically and found to be closely related to the chimpanzee foamy viruses, particularly simian foamy virus type 6, with which it shares common antigens in complement-fixing, fluorescent, and neutralizing antibody tests. In view of this close immunological relationship and the failure to find antibody to the human isolate in sera from more than 250 humans, including 50 patients with nasopharyngeal carcinoma and Burkitt's lymphoma, it is suggested that the isolate is not a human representative of the foamy virus group but rather a variant strain of chimpanzee foamy virus.

Pelvic endometriosis and simian foamy virus infection in a pigtailed macaque

Pelvic endometriosis and simian foamy virus infection occurred in a pigtailed macaque. Diffuse omental, peritoneal, and intestinal implantation of endometrium resulted in massive adhesions between adjacent abdominal and pelvic viscera, with formation of a large mass in the right caudal quadrant of the abdomen. Simian foamy virus type 1 was isolated from ectopic endometrium and from the uterine wall but was considered to be merely epiphenomenal.

Further biological properties of the human syncytial virus

Some biological properties of the human syncytial virus have been examined. A 13-day plaque assay in whole human embryo fibroblasts (HEF) has been developed using a liquid (growth medium) overlay. The plaques were 0.7-2 mm in diameter and often showed a clear central zone with irregular edges. Pretreatment of HEF monolayers with the polycation DEAE-dextran for either 30 min or 1 h was found to enhance plaque formation by a factor of from 2- to 7-fold. The plaque assay procedure required cell cultures undergoing active cell division. Adsorption kinetics and growth cycle studies in HEF indicated a relatively long adsorption period (3 h) and a relatively prolonged latent period of 24 h. Even under optimal conditions, virus yields were low and did not exceed 1 PFU per infected cell. Like other animal syncytium-forming 'foamy' viruses, the human virus induced both intranuclear and cytoplasmic antigens detectable by immmunofluorescence and was also markedly labile to freezing and thawing.

Viral spread in the presence of neutralizing antibody: mechanisms of persistence in foamy virus infection

Several viruses were categorized on the basis of their ability to spread from cell to contiguous cell and form plaques in the presence of antiviral antibody. Herpes simplex virus, cytomegalovirus, and vaccinia, measles, and foamy viruses were able to spread in the presence of neutralizing antibody, whereas coxsackievirus, encephalomyocarditis virus, vesicular stomatitis virus, mumps virus, and simian virus 5 failed to spread. A detailed study of one of these virus groups (simian foamy viruses) suggested that the ability of these viruses to spread from cell to cell in the presence of antiviral antibody, the failure of antiviral antibody and complement to lyse infected cells, and the poor induction and relative resistance of these viruses to the antiviral action of interferon contribute to the persistent nature of this infection.

Virological studies of baboon (Papio hamadryas) lymphoma: isolation and characterization of foamyviruses

In accordance with a memorandum of understanding in cancer research between scientists in the USSR and the USA, virological studies were performed on two baboons from the Russian colony at the Institute of Experimental Pathology and Therapy at Sukhumi where several cases of leukemia have been observed over the past few years. Foamyvirus isolations were made from lymphoid cells of both of these monkeys, one of which had a confirmed case of lymphoma. The isolates were similar to each other serologically and morphologically, possessed characteristics typical of foamyviruses, and cross-reacted to a low level with antibody to simian foamyvirus type 1.

Isolation and characterization of lymphocyte associated foamy virus from a red uakari monkey (Cacajao rubicundus)

A syncytium-forming virus was isolated from the lymphocytes of a uakari monkey 70 days after establishing a lymphocyte/owl monkey kidney coculture in the wild. The morphology and morphogenesis of the virus, plus its physicochemical characteristics indicate that the agent is a foamy virus. An unusal cell alteration found in cultures infected with this foamy was the formation of eosinophilic intracytoplasmic inclusion in association with the syncytia. The agent was found to be antigenically distinct to other known simian foamy viruses.

[Induction, by 5-bromo-2'-deoxyuridine, of a "foamy" virus previously undetected in hamster cells transformed by SV40]

TSV5 clone 2 cells in normal conditions of culture contain only an expressed RNA virus (R-type virus). However, exposure of the cells to 5-bromo-2'-deoxyuridine with dexamethasone, induced synthesis of a syncitium-forming ("Foamy") virus. In other hamster cell lines, the same treatment fails to induce a "foamy" virus. The origin of this "foamy" virus is discussed.

The foamy viruses

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