Replication and regulation of primate foamy viruses

A new indicator cell line established to monitor bovine foamy virus infection

In order to improve the accuracy for quantitating the bovine foamy virus (BFV) in vitro, we developed a baby hamster kidney cell (BHK)-21-derived indicator cell line containing a plasmid that encodes the firefly luciferase driven by the BFV long terminal repeat promoter (LTR, from -7 to 1012). The BFV titer could be determined by detecting the luciferase expression since the viral trans-activator BTas protein activates the promoter activity of the LTR. One clone, designated BFVL, was selected from ten neomycin-resistant clones. BFVL showed a specific and inducible dose- and time-dependent luciferase activity in response to BFV infection. Although the changes in luciferase activity of BFVL peaked at 84 h post infection, it was possible to differentiate infected and uninfected cells at 48 h post infection. A linear relationship was established between the multiplicity of infection (MOI) of BFV and the activated ratio of luciferase expression in BFVL. Moreover, the sensitivity of the BFVL-based assay for detecting infectious BFV was 10,000 times higher than the conventional CPE-based assay at 48 h post infection. These findings suggest that the BFVL-based assay is rapid, easy, sensitive, quantitative and specific for detection of BFV infection.

Simian foamy virus infection in humans: prevalence and management

Simian foamy viruses (SFVs) are highly prevalent in all nonhuman primate species and can infect humans following occupational and non-occupational exposure to infected animals and their tissues, blood or body fluids. Virus transmission results in a stable, persistent infection that seems to be latent. SFV infections are thus far nonpathogenic, with no evidence of adverse clinical outcome in their natural nonhuman primate hosts or by experimental injection in animals and upon cross-species transmission in humans. Since the emergence of pathogenic viruses from nonpathogenic viruses upon cross-species infection is well-documented for several retroviruses, it is prudent to take necessary precautions to deter SFV infections in humans. These steps will help prevent the emergence of a novel pathogen and reduce the risk of transmission of another potential pathogenic human retrovirus.

Role of the foamy virus Pol cleavage site in viral replication

Foamy virus Pol precursor protein processing by the viral protease occurs at only one site, releasing a protease-reverse transcriptase and an integrase protein. To examine whether the cleavage of the Pol precursor protein is necessary for enzymatic activities and efficient viral replication, several mutations were generated around the cleavage site. All cleavage site mutants synthesize wild-type levels of Pol precursor protein. Mutants containing more than two amino acid substitutions around the cleavage site exhibit no detectable Pol processing. The Pol cleavage site is not required for the production of infectious particles in a single round of infection, but is important for subsequent rounds of viral infection. Mutations around the cleavage site affected the enzymatic activities of the protease and reverse transcriptase and prevented replication after two rounds of infection. Interestingly, Pol encapsidation is significantly reduced in some of the mutants.

Inhibition of simian immunodeficiency virus by foamy virus vectors expressing siRNAs

Viral vectors available for gene therapy are either inefficient or suffer from safety concerns for human applications. Foamy viruses are non-pathogenic retroviruses that offer several unique opportunities for gene transfer in various cell types from different species. In this report, we describe the use of simian foamy virus type 1 (SFV-1) vector to examine the efficacy of therapeutic genes. Hairpin short-interfering RNA (siRNA) that targets the simian immunodeficiency virus (SIV) rev/env was placed under the control of the PolIII U6 snRNA promoter for expression and screened for silencing target genes using cognate target-reporter fusions. We have identified an effective siRNA (designated R2) which reduces the rev and env gene expression by 89% and 95%, respectively. Using the simian foamy virus type 1 (SFV-1) based vector, we delivered the PolIII expressed R2 siRNA into cultured cells and challenged with SIV. The results show that the R2 siRNA is a potent inhibitor of SIV replication as determined by p27 expression and reverse transcriptase assays. Vectors based on a non-pathogenic SFV-1 vector may provide a safe and efficient alternative to currently available vectors, and the SIV model will help devise protocols for effective anti-HIV gene therapy.

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.

Structural and evolutionary analysis of an orangutan foamy virus

The full-length proviral genome of a foamy virus infecting a Bornean orangutan was amplified, and its sequence was analyzed. Although the genome showed a clear resemblance to other published foamy virus genomes from apes and monkeys, phylogenetic analysis revealed that simian foamy virus SFVora was evolutionarily equidistant from foamy viruses from other hominoids and from those from Old World monkeys. This finding suggests an independent evolution within its host over a long period of time.

Establishment of a GFP-based indicator cell line to quantitate feline foamy virus

To quantitate infectious feline foamy virus (FeFV), Crandell feline kidney (CRFK) cells were transfected with the gfp gene under the control of the FeFV long terminal repeat (LTR) for establishing an indicator cell line named FFG cells. The FeFV activates promoter activity of the LTR to express green fluorescent protein (GFP) upon infection. The titers determined by GFP-positive FFG cells (GFP-based assay) were higher than those determined by the cytopathic effects-positive CRFK cells (CPE-based assay). The titers determined by the GFP-based assay reached a plateau at 3-4 days post infection (d.p.i.), while those by the CPE-based assay reached 6-8 d.p.i. When stock viruses of various FeFV strains were titrated by both assays, titers determined by both assays correlated well with each other. The results show that the GFP-based assay is simpler and more rapid and sensitive than the CPE-based assay. Using the GFP-based assay, we examined the in vitro host range of FeFV. It was found that FeFV can productively infect various cell lines derived from cats, dogs, chickens, a human and a bat.

Transduction of umbilical cord blood CD34+ NOD/SCID-repopulating cells by simian foamy virus type 1 (SFV-1) vector

Foamy viruses are nonpathogenic retroviruses that offer unique opportunities for gene transfer into various cell types including hematopoietic stem cells. We used a simian foamy virus type 1 vector (SFV-1) containing a LacZ reporter gene with a titer of 1-5 x 10(6) viral particles/ml that was free of replication-competent retrovirus to transduce human umbilical cord blood CD34+ cells. Transduced CD34+ cord blood cells were transplanted into NOD/SCID mice and plated in serum-free methylcellulose culture to determine the transduction efficiency of human hematopoietic progenitor cells. A transduction efficiency of about 20% was obtained. At 6-10 weeks posttransplantation, human hematopoietic cell engraftment and marking were determined. Marrow from transplanted mice demonstrated human cell engraftment by the presence of human (CD45+) cells containing both CD19+ lymphoid and CD33+ myeloid cells. Serial sampling of NOD/SCID bone marrow revealed the presence of 6.7-14.0% CD45+ cells at 6 weeks posttransplant as compared to 3.6-27.2% CD45+ cells at 9-10 weeks posttransplant. Human progenitors examined from NOD/SCID bone marrow cells 9 weeks posttransplant revealed from 7.4 to 25.9% of the colonies exhibiting X-gal staining. Our study demonstrates the ability of a simian foamy virus vector to transduce the SCID-repopulating cell and offers a promising new gene delivery system for use in hematopoietic stem cell gene therapy.

A minimal genome simian foamy virus type 1 vector system with efficient gene transfer

Foamy viruses have several inherent features for the opportunity to develop efficient and versatile vectors for gene therapy. We have constructed a series of vectors and helper plasmids based on simian foamy virus type 1 (SFV-1) to establish the minimum vector genome required for efficient gene transduction. To characterize the efficiency of gene transduction by these vectors, the green fluorescent protein (GFP) coding sequence is linked to the human cytomegalovirus immediate gene promoter. Several deletion analyses of SFV-1 vectors revealed that the minimum genome with efficient GFP transduction contained the 5' untranslated region extending to the first 637 nucleotides of the gag gene, a 596 nucleotides of pol sequence from position 3137-3733, the 3' pol region at position 5200-5693, the 3' end polypurine tract, and the 3' LTR. An additional 1131 nucleotides can be removed from the 3' end LTR without affecting the efficiency of vector transduction. SFV-1 vector can therefore accommodate a minimum 8930 base-size heterologous DNA fragment. Furthermore, the efficiency of SFV-1 vector transduction was analyzed using different packaging plasmids. GFP transduction with packaging plasmid that contained the 5' R-U5 region of the LTR was compared with helper plasmids that had deletions in this region except for 22 nucleotides (positions 21-41), the first 61, 77, or 140 nucleotides of the R of the LTR. Transduction efficiencies were significantly reduced with the deletion mutations implicating that for optimum SFV-1 vector productions a packaging construct that includes the 5' R-U5 is required.

Genetic analyses of feline foamy virus isolates from domestic and wild feline species in geographically distinct areas

To know the genetic diversities and phylogenetic relationship among feline foamy virus (FeFV) isolates from domestic cats (Felis catus) and FeFV-related viruses from the Iriomote cats (Felis iriomotensis) and leopard cats (Felis bengalensis) in geographically distinct areas, we sequenced a partial gag-pol region of 17 strains and a partial env region of nine strains, and the U3 region of long terminal repeat of three strains of the viruses. FeFV-related viruses from the feral cats were quite similar to the FeFV from domestic cats in the sequenced regions. In the partial gag region, the identities of nucleotide sequences among the isolates were from 94 to 99%. In the partial env gene, the isolates were divided into two distinct genotypes (F17- and FUV-types) as reported by Winkler et al. (Virology 247 (1999) 144-151). More than 94% nucleotide identities were observed in the env region within a particular env genotype and about 75% nucleotide identities were noted between the two genotypes.

Efficacy of dideoxynucleosides against human foamy virus and relationship to its reverse transcriptase amino acid sequence and structure

Human foamy virus (HFV), a retrovirus of simian origin which occasionally infects humans, is the basis of retroviral vectors in development for gene therapy. Clinical considerations of how to treat patients developing an uncontrolled infection by either HFV or HFV-based vectors need to be raised. We determined the susceptibility of the HFV to dideoxynucleosides and found that only zidovudine was equally efficient against the replication of human immunodeficiency virus type 1 (HIV-1) and HFV. By contrast, zalcitabine (ddC), lamivudine (3TC), stavudine (d4T), and didanosine (ddI) were 3-, 3-, 30-, and 46-fold less efficient against HFV than against HIV-1, respectively. Some amino acid residues known to be involved in HIV-1 resistance to ddC, 3TC, d4T, and ddI were found at homologous positions of HFV reverse transcriptase (RT). These critical amino acids are located at the same positions in the three-dimensional structure of HIV-1 and HFV RT, suggesting that both enzymes share common patterns of inhibition.

The efficiency of simian foamy virus vector type-1 (SFV-1) in nondividing cells and in human PBLs

Current retroviral vectors based on murine leukemia virus (MuLV) are unable to efficiently transduce nondividing cells. Lentiviruses, such as the human immunodeficiency virus 1 (HIV-1) are efficient at transducing nondividing, growth-arrested, and post-mitotic cells, but due to complex safety considerations, they may have limited potential for human clinical gene transfer. For this reason, alternatives to MuLV and HIV-1 vectors need to be explored. In this paper, we have found that simian foamy virus vector (SFV-1) containing a CMV-LacZ expression cassette is able to efficiently transduce multiple cell types of various species that include epithelial, lymphoid, and hematopoietic-derived human cell lines and fibroblast cell lines of several species. Previously it was reported that foamy virus replication is cell cycle dependent (P. D. Bieniasz, R. A. Weiss, and M. O. McClure, 1995. J. Virol. 69, 7295-7299). However, others studies demonstrated nuclear import of viral DNA in arrested cells (A. Saibi, F. Puvion-Dutilleul, M. Schmid, J. Peries, and H. d. The 1997. J. Virol. 71, 1155-1161). Here, we show efficient LacZ transduction by SFV-1 vectors in several chemically arrested cell lines and terminally differentiated human neurons. SFV-1 vector can transduce cell lines arrested in G1/S phase of the cell cycle by aphidicolin treatment with similar efficiencies to that of dividing cells. The terminally differentiated human neural cell line, NT2N, was transduced with 30-50% efficiency, corroborating our data obtained with the arrested cell lines. To further examine whether the SFV-1 vector can efficiently deliver a gene into clinically important cells for gene therapy, we transduced primary human peripheral blood cells (PBLs) in the presence and absence of phytohemagglutanin (PHA) stimulation. We observed 81% transduction efficiency in non-stimulated PBLs and 87% in PHA-stimulated PBLs with vector infection carried out twice in 8 hours intervals at a multiplicity of infection of 1. Together, these data indicate that SFV-1 based retroviral vectors may provide a safe, efficient alternative to current onco- and lentiviral vectors for gene transfer in cells from a broad spectrum of lineages across species boundaries.

Simian foamy virus infections in a baboon breeding colony

The prevalence, transmission, and variation of simian foamy viruses (SFVs) in baboons was investigated. Over 95% of adult baboons in the breeding colony as well as recently imported adult animals had high titers of anti-SFV serum IgG. Maternal antibody was detectable in infants' serum up to 6 months of age. Approximately 30% of infants in breeding harems experienced SFV infections by 1 year of age. Shedding of SFV in oral secretions was common, with 13% of samples from normal adult animals and 35% from immunosuppressed animals containing infectious SFV. SFV was isolated from three baboon subspecies (olive, yellow, and chacma baboons) and sequences from both the pol and the LTR regions of the provirus were amplified by PCR and sequenced. Phylogenetic analysis indicated that all baboon isolates formed a single lineage distinct from SFVs of other African monkey species. Within the baboon SFV lineage, two distinct clades were apparent, which consisted of isolates from yellow and olive baboons and isolates from chacma baboons. Competition ELISAs indicated that, while SFV isolates of these two groups were very closely related, antigenic differences do exist between them. SFV isolates from a drill and a mandrill were distinct from baboon SFV isolates, both genetically and antigenically.

Characterization of the humoral immune response and virus replication in cats experimentally infected with feline foamy virus

Cats were experimentally infected with cell culture-adapted feline foamy virus (FFV, spumaretrovirinae) isolate FUV. FFV was consistently recovered from peripheral blood leukocytes and throat samples of FFV-infected cats starting 2 to 3 weeks postinfection (p. i.), indicative of the establishment of persistent FFV infections. Viral persistence was established, even despite neutralizing antibodies that appeared early after infection. The humoral immune response toward FFV was quantitatively and qualitatively analyzed over time. FFV Gag-specific antibodies were first detected 2 weeks p. i. and increased further; reactivities to the other structural and nonstructural FFV proteins appeared slightly delayed. Reactivities against FFV Pol and Gag proteins were detectable by immunoblotting and radioimmunoprecipitation, whereas the latter techniques had to be employed for the unambiguous detection of FFV Env-, Bet-, and Bel 1-specific antibodies.

Mutational analysis of the 5' leader region of simian foamy virus type 1

The sequence within the 5' untranslated region of the retroviral genome contains important cis elements for many steps in viral replication. There is limited information available on the role of this region in foamy virus replication. Similar to other retroviruses, the 5' untranslated region of foamy viruses predicts extensive RNA secondary structure. Serial mutations that could change parts of the predicted secondary structure were introduced in the 5' leader sequence including the R-U5 region of simian foamy virus type 1 (SFV-1) to investigate their role in virus genome packaging and virus replication. Point mutations in the R-U5 regions at nucleotide positions 7-12 (I), 241-243 (B), and 256-257 (D) had no effect on virus replication. Base substitution mutation at positions 193-195 (C), however, severely impaired virus replication. Deletion of sequences in the leader region, between the primer-binding site and the gag gene, at positions 364-399 (d1), 397-435 (d2), or 364-435 (d3), which included sequences for RNA genome dimerization, also blocked SFV-1 replication. Interestingly, none of these mutations affected genome packaging or the synthesis of viral transcripts, suggesting that a step(s) of virus replication following packaging is affected. The region between the primer-binding site and the gag gene, therefore, is not essential for foamy virus genome packaging. Furthermore, the cis-acting elements for genome dimerization and packaging appear to be localized in separate regions for foamy viruses.

Construction of infectious feline foamy virus genomes: cat antisera do not cross-neutralize feline foamy virus chimera with serotype-specific Env sequences

Full-length genomes of the feline foamy virus (FFV or FeFV) isolate FUV were constructed. DNA clone pFeFV-7 stably directed the expression of infectious FFV progeny virus indistinguishable from wild-type, uncloned FFV isolate FUV. The env and bel 1 genes of pFeFV-7 were substituted for by corresponding sequences of the FFV serotype 951 since previous studies implicated a defined part of FFV Env protein as responsible for serotype-specific differences in serum neutralization (I. G. Winkler, R. M. Flügel, M. Löchelt, and R. L. P. Flower, 1998. Virology 247: 144-151). Recombinant virus derived from chimeric plasmid pFeFV-7/951 containing the hybrid env gene and the parental clone pFeFV-7 were used for neutralization studies. By means of a rapid titration assay for FFV infectivity, we show that progeny virus derived from plasmid pFeFV-7 was neutralized by FUV- but not by 951-specific antisera, whereas pFeFV-7/951-derived chimeric virus was neutralized by 951-specific antisera only. Both recombinant proviruses will be useful for repeated delivery of foreign genes for therapeutic gene applications into cats.

Nuclear localization of the functional Bel 1 transactivator but not of the gag proteins of the feline foamy virus

Interactions between host cells and foamy or spumaretroviruses are different from those of other known retroviruses. Previous work has suggested that the Gag and high-affinity DNA-binding Bel 1 transactivator of human foamy virus are localized in the nuclei of infected cells. Using two independent detection methods, we show here that the functionally active Bel 1 transactivator protein of feline foamy virus is of nuclear localization. In contrast to that reported for the human foamy virus Gag protein, the cat foamy virus Gag proteins exclusively localized in the cytoplasm close to perinuclear regions.

Study of human foamy virus proviral integration in chronically infected murine cells

This report describes integration sites of human foamy virus (HFV) in chronically infected BALB/c murine cells that we isolated by inverse PCR and characterized. We show that integration of HFV proviral genome mainly occurs in highly repetitive and/or transcriptionally active regions and leads to the formation of a 4-bp cellular direct repeat sequence at each provirus extremity. As non-random deletions were previously described in the HFV be/1 transactivator gene as well as in the long terminal repeats (LTRs), these regions were verified in integrated HFV. The analysis reveals that, in the studied chronic state, the defective interfering virus (delta HFV) is the main integrated proviral form and is always associated with a small LTR. Our results show that HFV can use a classic retroviral integration process to enter the host cell genome and stress the importance of delta HFV and the short LTRs in the establishment of the chronic state of infection.

Detection of subgenomic cDNAs and mapping of feline foamy virus mRNAs reveals complex patterns of transcription

Feline foamy virus (FeFV) belongs to the group of spumaretroviruses that contain in addition to gag, pol, and env accessory genes collectively called bel genes. Primate FVs have been shown to utilize internal promoters in addition to the 5' LTR promoters. In contrast to other known retroviruses, the FV pol genes are expressed via spliced transcripts. Northern blot analysis and reverse transcription-coupled polymerase chain reactions (RT-PCR) were used to amplify, clone, and characterize cDNAs generated from subgenomic viral transcripts. Sequencing of the splice site junctions of the different FeFV mRNAs showed that singly and multiply spliced subgenomic transcripts were expressed in virus-infected cells. The relative amount of the spliced pol-specific transcripts was quantitated and FeFV pol mRNA found to be expressed at about one-half of that of the genomic mRNA. The major FeFV internal start site of transcription was identified at RNA position 7925. Comparison of the FeFV transcriptional patterns to those of the human foamy virus revealed that the FeFV bel 1 mRNA was expressed exclusively from the internal promoter in contrast to primate foamy viruses that use both the LTR and the internal promoter for Bel 1 expression. Unexpectedly, an env-bel 2 mRNA was identified in FeFV-infected cells. In addition, cDNAs from FeFV-infected cells were directly amplified by PCR without RT reactions and found to correspond to genomic and to a subset of different subgenomic FeFV mRNAs.

cis-Acting sequences required for simian foamy virus type 1 vectors

We have constructed a series of vectors based on simian foamy virus type 1 (SFV-1) to define the minimum cis-acting elements required for gene transfer. To characterize these vectors, we inserted the coding sequence of the bacterial lacZ gene linked to the cytomegalovirus immediate-early gene promoter. Introduction of a deletion mutation in the leader region between the 5' long terminal repeat and the start of the gag gene at position 1659 to 1694 completely abrogated gene transfer by the SFV-1 vector. Deletion of 39 nucleotides from position 1692 to 1731 in the leader region resulted in a significant reduction in the transducing-particle titer. Furthermore, we have identified a second cis-acting element located at the 3' end of the pol gene between position 6486 and 6975 to be critical for SFV-1 vector transduction. These results identify the two important cis-acting elements required for SFV-1 vector construction, and the finding of a cis-acting element in the pol gene is unique among retroviruses.

Characterization of provirus clones of simian foamy virus type 1

We have cloned proviral DNA of simian foamy virus type 1 (SFV-1) from linear unintegrated DNA (pSFV-1). Transfection of pSFV-1 induces cytopathology in several cell lines with supernatants from the transfected cell culture containing infectious viral particles. Electron microscopy of the transfected cells revealed foamy virus particles. Deletion analysis of pSFV-1 indicated that the transcriptional transactivator (tas) gene located between env and the long terminal repeat is critical for virus replication, whereas the second open reading frame (ORF-2) in this region is dispensable. Although the tas and ORF-2 regions of foamy viruses have significantly diverged, the results presented here suggested that the gene products have similar functions. Recombinant pSFV-1 containing the cat gene was able to transduce the heterologous gene, indicating the utility of SFV-1 as a vector. An infectious clone of SFV-1 which is distantly related to the human foamy virus will provide a means to understand the biology of this unique group of viruses.

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.

Regulation of gene expression by human foamy virus and potentials of foamy viral vectors

The hallmarks of the spumaretrovirus or human foamy virus (HFV) are summarized and discussed with special focus on the potentials to use HFV as a new retroviral vector system. The special features of HFV are the expression of pol by splicing and start of translation at a defined initiation codon. The first Met of Pol is conserved in the six known foamy virus genomic sequences. Another remarkable characteristic of HFV is the presence of a Gly-Arg-rich sequence instead of the Cys-Cys motif of the classical retroviral nuclecapsid proteins. The preferential budding of HFV into cytoplasmic vesicles and the potential to exploit it in the application of corresponding vector systems is discussed. In addition, recent reports of transducing marker genes into susceptible cells will be reviewed.

Human foamy virus reverse transcription that occurs late in the viral replication cycle

Foamy viruses (FVs) are retroid viruses which use a replication strategy unlike those of other retroviruses and hepadnaviruses (S. F. Yu, D. N. Baldwin, S. R. Gwynn, S. Yendapilli, and M. L. Linial, Science 271:1579-1582, 1996). One of the striking differences between FVs and retroviruses is the presence of large amounts of linear genome-length DNA in FV-infected cells and in virions. We report here that large quantities of genome-length linear FV DNA accumulate in cells infected with FV, as determined by Southern blotting. To determine whether these unintegrated virus DNAs result solely from superinfection, we analyzed the occurrence of virus cDNA of the so-called human FV isolate (HFV) in cells transfected with a virus mutant deficient in the envelope gene and in cells which are resistant to superinfection due to stable expression of the envelope protein. We show that the synthesis of viral cDNA is independent of superinfection and that HFV synthesizes cDNA intracellularly as a late event in the replication cycle. To further confirm this finding, we performed inhibition studies with the reverse transcriptase inhibitor zidovudine (AZT). While AZT had no effect or only a minor effect on virus titers when added to cells prior to virus infection, viral titers were reduced by 3 or 4 orders of magnitude when the virus was produced from cells in the presence of AZT. Our results are most compatible with the hypothesis that the functional nucleic acid of the extracellular HFV consists of largely double-stranded linear DNA.

Characterization of the genome of feline foamy virus and its proteins shows distinct features different from those of primate spumaviruses

The genome of the feline foamy virus (FeFV) isolate FUV was characterized by molecular cloning and nucleotide sequence analysis of subgenomic proviral DNA. The overall genetic organization of FeFV and protein sequence comparisons of different FeFV genes with their counterparts from other known foamy viruses confirm that FeFV is a complex foamy virus. However, significant differences exist when FeFV is compared with primate foamy viruses. The FeFV Gag protein is smaller than that of the primate spumaviruses, mainly due to additional MA/CA sequences characteristic of the primate viruses only. Gag protein sequence motifs of the NC domain of primate foamy viruses assumed to be involved in genome encapsidation are not conserved in FeFV. FeFV Gag and Pol proteins were detected with monospecific antisera directed against Gag and Pol domains of the human foamy virus and with antisera from naturally infected cats. Proteolytic processing of the FeFV Gag precursor was incomplete, whereas more efficient proteolytic cleavage of the pre125Pro-Pol protein was observed. The active center of the FeFV protease contains a Gln that replaces an invariant Gly residue at this position in other retroviral proteases. Functional studies on FeFV gene expression directed by the promoter of the long terminal repeat showed that FeFV gene expression was strongly activated by the Bell/Tas transactivator protein. The FeFV Bell/Tas transactivator is about one-third smaller than its counterpart of primate spumaviruses. This difference is also reflected by a limited sequence similarity and only a moderate conservation of structural motifs of the different foamy virus transactivators analyzed.

Protein composition and morphology of human foamy virus intracellular cores and extracellular particles

Characterization of human foamy virus (HFV) gag-encoded precursors and the search for a Gag-Pol polyprotein and mature proteins derived from proteolytic processing were carried out in HFV-infected cells and with purified preassembled cores and extracellular virus by Western blotting and radioimmunoprecipitation using antisera against synthetic peptides corresponding to putative Gag and protease proteins. Precursor proteins, Pr78gag/74gag and Pr135pol, were found in the nucleus of epithelial and fibroblast cells 3-4 days after HFV infection. Kinetic analysis of HFV Pr78gag and Pr74gag indicated that Pr78gag is a precursor to Pr74gag. South-Western blot analysis indicated that Pr78gag and Pr74gag have properties associated with nucleic acid binding protein although they lack the typical zinc-finger motifs found in retroviral nucleocapsid proteins. Western blot analyses of preassembled HFV cores isolated from the cytoplasm of infected cells and purified by sucrose gradient centrifugation demonstrated the presence of Pr78gag/74gag and Pr135pol, but no proteolytically processed Gag proteins were observed. The majority of extracellular HFV particles were found to have pentagon-shaped cores, as observed intracellularly, and are believed to be the immature extracellular form of the virus. The highest concentration of extracellular particles, estimated by EM, Western blot, and reverse transcriptase assays were found in sucrose gradient fractions having a density of 1.21-1.24 g/cm3. Western blot analysis revealed that Pr78gag/74gag and Pr135pol were the major viral proteins associated with these extracellular particles, as only small amounts of putative proteolytically cleaved capsid (p32) were observed. Our results support the notion that Pol is translated independent of Gag in HFV-infected cells.

Replication of feline syncytial virus in feline T-lymphoblastoid cells and induction of apoptosis in the cells

Feline syncytial virus (FSV) was isolated from feline peripheral blood mononuclear cells of FSV-seropositive cats. When the susceptibility of feline T-lymphocytes to FSV was examined using three strains of FSV, FSV antigens were detected in the FSV-infected T-lymphoblastoid cells. Further, a diversity of biological properties, including replication kinetics and syncytia formation, was noted among the strains, and condensation of chromatin and the fragmentation of cellular DNA were observed in the infected cells. From these data, we conclude that FSV is lymphotropic and can induce apoptosis in the lymphocytes.

A sorting motif localizes the foamy virus glycoprotein to the endoplasmic reticulum

We recently identified an endoplasmic reticulum (ER) retrieval signal-the dilysine motif-in the glycoproteins of all five foamy viruses (FVs) for which sequences were available (P. A. Goepfert, G. Wang, and M. J. Mulligan, Cell 82:543-544, 1995). In the present study, expression of recombinant human FV (HFV) glycoprotein and analyses of oligosaccharide modifications and precursor cleavage indicated that the protein was localized to the ER. HFV glycoproteins encoding seven different dilysine motif mutations were then expressed. The results indicated that disruptions of the dilysine motif resulted in higher levels of forward transport of the HFV glycoprotein from the ER through the Golgi apparatus to the plasma membrane. We conclude that the dilysine motif is responsible for ER sorting of the FV glycoprotein. Signal-mediated ER localization has not previously been described for a retroviral glycoprotein.

Analysis of west African hunters for foamy virus infections

Foamy viruses are a genus of complex retroviruses that infect a wide variety of mammals. However, a clear association with any disease process has yet to be proven for these viruses. A higher human seroprevalence was reported in African populations, perhaps due to exposure to simian foamy viruses (SFV) endemic in primates. However, the earlier serologic surveys were not confirmed by studies employing nucleic acid amplification. Foamy virus infections of humans clearly do occur as rare zoonoses among primate center or laboratory workers exposed to captive primates or their blood. We sought to detect foamy virus infections in a cohort of humans also presumed to be exposed to SFV, i.e., West African hunters. We constructed recombinant vaccinia viruses that expressed human foamy virus (HFV) Gag or Env polyproteins in mammalian cells. The sera from 17 monkey hunters or several controls were tested in radioimmunoprecipitation assays (RIPAs) against the recombinant HFV proteins. Chimpanzee sera or HFV-positive human sera immunoprecipitated gp130, the HFV Env precursor, as well as p74, the HFV Gag polyprotein. None of the hunters' sera recognized both of these recombinant proteins. We then employed a nested polymerase chain reaction (PCR) analysis of the hunters' DNA but also failed to detect foamy virus infections. Therefore, by utilizing a recombinant RIPA and a nested PCR assay, we have not identified foamy virus infections occurring naturally in hunters exposed to wild monkeys in West Africa.

Inhibition of the in vitro infectivity and cytopathic effect of human foamy virus by dideoxynucleosides

Human foamy virus (HFV) is a human retrovirus that has not been clearly associated with human disease. In this study, we tested the capacity of nucleoside derivatives to inhibit the infectivity and cytopathic effect of HFV in T-lymphoblastoid cells in vitro. H9 cells showed a dramatic cytopathic effect 3 weeks after exposure to HFV. At this time, viral infection was demonstrated by detection of viral antigens by immunofluorescence staining, release of reverse transcriptase activity (RT) in the supernatant, detection of typical viral particles by electron microscopy, and presence of proviral DNA by Southern blot analysis. H9 cells were pretreated with dideoxycytidine (ddC), dideoxyinosine (ddI), or azidothymidine (AZT) at various concentrations before HFV infection. ddC could not completely suppress viral replication at low concentrations, and inhibited cell proliferation at higher concentrations. ddI partially inhibited the formation of giant cells at 10 microM, with 95% inhibition of RT in the supernatant. AZT induced a complete inhibition of cytopathic effect at concentrations > or = 1 microM, with more than 95% inhibition of RT in the supernatant. Moreover, the synthesis of proviral DNA was completely suppressed by 10 microM AZT. These results show that AZT and ddI can inhibit HFV replication in vitro.

The human foamy virus Bel-1 transcription factor is a sequence-specific DNA binding protein

The Bel-1 transcriptional transactivator encoded by human foamy virus (HFV) can efficiently activate gene expression directed by both the HFV long terminal repeat (LTR) and internal (Int) promoter elements. By DNA footprinting and gel retardation analysis, we demonstrate that Bel-1 can specifically bind to discrete sites in both the LTR and Int promoter elements in vitro. However, transactivation of the HFV LTR by Bel-1 was observed to require not only the promoter-proximal Bel-1 binding site identified in vitro but also additional promoter-distal sequences. These data suggest that Bel-1 binding is necessary but not sufficient for efficient transactivation of Bel-1-responsive promoters in mammalian cells and therefore raise the possibility that Bel-1 function may require the action of a cellular DNA binding protein(s). Importantly, these data demonstrate that Bel-1 is unique among retroviral regulatory proteins in being a sequence-specific DNA binding protein.

The human foamy virus pol gene is expressed as a Pro-Pol polyprotein and not as a Gag-Pol fusion protein

It has been reported recently that the human foamy virus (HFV) Pol polyprotein of 120 kDa is synthesized in the absence of the active HFV aspartic protease. To gain more information on how the 120-kDa Pro-Pol protein is synthesized, mutant HFV genomes were constructed and the resulting proviruses were analyzed with respect to HFV pol expression and infectivity. HFV proviruses that contain termination codons in the nucleocapsid domain of gag and thus lack a gag-pol overlap region assumed to be required for translational frameshifting, nevertheless expressed the 120-kDa Pro-Pol precursor, the 80-kDa reverse transcriptase/RNase H, and a 40-kDa integrase in amounts similar to those observed for wild-type genomes. Since a Gag-independent expression of authentic Pol proteins was detectable in cells transfected with eukaryotic HFV pol expression plasmids, the data indicate that the HFV Pol precursor of 120 kDa is expressed independently of Gag by a mechanism that does not rely on ribosomal frameshifting, since the postulated HFV Gag-Pol protein of 190 kDa was not detectable under the conditions used. Furthermore, replacement of the Met residue by Thr at position 9 in pol within the gag-pol overlap region resulted in strongly reduced HFV Pol polyprotein expression and infectivity of the resulting proviruses. This Met residue of pol conserved in foamy virus sequences is the likely candidate for translational initiation of the 120-kDa Pro-Pol polyprotein. trans complementation of the HFV mutant with the Met-to-Thr substitution in the pol gene by a eukaryotic plasmid that expressed the HFV Pro-Pol protein resulted in partial recovery of infectivity. When HFV pol was fused in frame to gag, an engineered 190-kDa Gag-Pol fusion protein was formed and the enzymatic activity of the HFV protease was partially retained. The results imply that HFV is the first retrovirus that expresses a Pol polyprotein without formation of a Gag-Pol fusion protein.

The transcriptional transactivator of simian foamy virus 1 binds to a DNA target element in the viral internal promoter

The transcriptional transactivator (Tas) of simian foamy virus type 1 strongly augments gene expression directed by both the promoter in the viral long terminal repeat and the newly discovered internal promoter located within the env gene. A region of 121 bp, located immediately 5' to the TATA box in the internal promoter, is required for transactivation by Tas. The present study aimed to identify the precise Tas-responsive target(s) in this region and to determine the role of Tas in transcriptional regulation. By analysis of both clustered-site mutations and hybrid promoters in transient expression assays in murine and simian cells, two separate sequence elements within this 121-bp region were shown to be Tas-dependent transcriptional enhancers. These targets, each < 30 bp in length and displaying no apparent sequence homology one to the other, are designated the promoter-proximal and promoter-distal elements. By means of the gel electrophoresis mobility-shift assays, using purified glutathione S-transferase-Tas fusion protein expressed in Escherichia coli, the target proximal to the TATA box exhibited strong binding to glutathione S-transferase-Tas, whereas the distal element appears not to bind. In addition, footprint analysis revealed that 26 bp in the promoter proximal element was protected by glutathione S-transferase-Tas from DNase I. We propose a model for transactivation of the simian foamy virus type 1 internal promoter in which Tas interacts directly with the proximal target element positioned immediately 5' to the TATA box. In this model, Tas attached to this element is presumed to interact with a component(s) of the cellular RNA polymerase II initiation complex and thereby enhance transcription directed by the viral internal promoter.

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.

High susceptibility of U937-derived subclones to human immunodeficiency virus type 1 infection correlates with accumulation of unintegrated circular viral DNA

Our previous report showed that U937-derived subclones were differentiated into at least three types (high, middle, and low types), even in the subclones expressing similar levels of surface CD4, in terms of the kinetics of the appearance of viral antigens and virus production after infection with human immunodeficiency virus type 1 (HIV-1). Here we showed the evidence that high susceptibility to HIV-1 infection, which was confirmed by the profound expression of viral messages and antigens, was exclusively associated with a high number of the unintegrated extrachromosomal form of viral DNA, but not with the amounts of adsorbed virus RNA nor those of integrated DNA form. The difference in the amounts of extrachromosomal form of viral DNA was also observed in the culture with 3'-azido-3'-deoxythymidine (AZT), indicating that the susceptibility is essentially unrelated to multiple infection events. Thus, the susceptibility of U937-derived subclones to HIV-1 infection seems to be affected by the occurrence of specific events involved in the accumulation of unintegrated viral DNA after viral adsorption.

Cell tropism of the simian foamy virus type 1 (SFV-1)

Several cell lines representing different species and cell types were tested for simian foamy virus type 1 (SFV-1) infection. SFV-1 infections were monitored by polymerase chain reaction, reverse transcriptase, cytopathology, and immunofluorescent assays. All cells tested were permissive for SFV-1, demonstrating that SFV-1 has a broad host range with respect to species and cell types. Infected fibroblasts, epithelial cells, and neural cells all showed extensive cytopathology that is characteristic of foamy virus infection. No cytopathology was induced in T cell-derived Jurkats and Hut-78 cell lines. The cytopathic effects in B and macrophage originated cells were delayed by several days. Cytopathology in these cell lines was not as dramatic as seen in the infected fibroblast and epithelial cells. The reverse transcriptase values in the SFV-1 infected lymphoid and macrophage cell lines were severalfold lower than that of the fibroblasts and epithelial cells. Therefore, SFV-1 appears to establish a low level persistent infection in lymphoid and macrophage cell lines.

Mutational analysis of the reverse transcriptase and ribonuclease H domains of the human foamy virus

Human foamy or spuma virus (HFV) codes for a distinct set of pol gen products. To determine the minimal requirements for the HFV enzymatic activities, defined residues of the reverse transcriptase (RT) and ribo-nuclease H (RNase H) domain of the HFV pol gene were mutated by site-specific PCR mutagenesis. The mutant gene products were bacterially expressed, purified by Ni2+ chelate affinity chromatography and characterised by Western blotting. The enzymatic activities of the individual recombinant HFV pol mutant proteins were characterised by the situ RT, RNase H and RNase H assays. Two substitution mutants reached RT activity levels higher than that of the intact recombinant HFV RT-RH-His. When the catalytically essential D508 was substituted by A508, 5% of RNase H activity was retained while DNA polymerase activity increased 2-fold. A deletion of 11 amino acid residues in the hinge region completely abolished DNA polymerase while RNase H activity decreased 2-fold. A deletion mutant in the C-terminal RH domain showed no RNase H but retained RNase H activity indicating that the activities are genetically separable. The combined data reveal that the HFV DNA polymerase and RNase H activities are interdependent.

Analysis of the phylogenetic placement of different spumaretroviral genes reveals complex pattern of foamy virus evolution

Foamy or spumaviruses are complex retroviruses. Phylogenetic trees have been constructed previously for either the polymerase or integrase domains showed a clustering of the foamy viruses relatively distant from other retroviruses. The most related retrovirus was found to be murine leukemia virus, irrespective of the method used or foamy viral gene analyzed. We analyze bel genes of different foamy viruses and compared the corresponding phylogenetic trees with those obtained from the pol genes that were constructed with refined computer programs. In addition, the nucleocapsid protein sequence of foamy viruses was used for a comparative phylogenetic analysis. Known biological properties of the individual FV protein domains are discussed to ascertain the apparent phylogenetic relatedness.

Viruses, virulence and pathogenicity

Pathogenicity is a complex process with stringent requirements of both the host cell and the infecting virion. Among these requirements are a port of entry into host cells, a means of replication for the virus, and a means by which infection damages host cells. Damage to the host can result from multiple mechanisms including transformation, suppression of cellular metabolism, apoptosis, autoimmune responses directed against infected or uninfected tissues, or by molecular mimicry. In the attempt to identify new associations between viral infection and disease, investigators should be mindful that variable host factors as well as viral infection may be required for pathogenesis. Efforts to associate specific viral infections with specific diseases may be obscured by final common pathways through which multiple agents damage host cells in similar ways.

The human foamy virus internal promoter is required for efficient gene expression and infectivity

The human foamy or spumaretrovirus (HFV) is a complex retrovirus that codes for the three retroviral genes gag, pol, and env and the regulatory and accessory bel genes. A particular feature of HFV gene expression was recently described: not only does the HFV provirus contain the classical retroviral long terminal repeat promoter, a second functionally active promoter is present in the env gene upstream of the bel genes (M. Löchelt, W. Muranyi, and R. M. Flügel, 1993, Proc. Natl. Acad. Sci. USA 90, 7317-7321). Both, the HFV long terminal repeat promoter I and internal promoter II depend upon the HFV transcriptional transactivator Bel 1 for efficient gene expression. The internal promoter directs the synthesis of functionally active Bel 1 transactivator and Bet proteins that are expressed early after HFV infection. In this report, it is shown that mutation of the promoter II TATA box resulted in HFV proviral clones with a reduction in infectivity by a factor of approximately 100. Gene expression by promoter II TATA box mutant HFV proviruses was reduced. HFV proviruses with the mutated promoter II TATA box used cryptic start sites of transcription upstream of the original promoter II TATA box, resulting in an inefficient and less accurate transcriptional initiation. The reduced HFV structural gene expression by the mutated HFV proviruses was relieved by providing Bel 1 protein in trans. This demonstrates that HFV promoter II-directed Bel 1 expression is important for producing the high levels of Bel 1 that increases virus replication.

Markers of foamy virus infections in monkeys, apes, and accidentally infected humans: appropriate testing fails to confirm suspected foamy virus prevalence in humans

Foamy viruses (FVs) persist in healthy individuals of various mammalian species, including nonhuman primates. Laboratory markers of FV infection are (1) virus in throat epithelium or peripheral blood lymphocytes (PBLs), (2) proviral DNA sequences in PBLs and various solid organs, and (3) antibodies reactive to viral antigens on Western blots, in radioimmunoprecipitation tests, and in immunofluorescence assays. Using PCR and serological tests, we readily detected FV markers in naturally infected African green monkeys, rhesus monkeys, and chimpanzees, as well as in accidentally infected humans. Transmission of simian foamy viruses to humans (by bite or inadvertent laboratory infection) leads to viral markers, without affecting the recipient. Reports on FV-associated clinical disorders (e.g., thyroid or neurological) have remained controversial. In this study we failed to detect, by PCR, viral sequences in the samples from 223 patients, including 16 HIV-infected Africans, 46 Graves' disease patients, and 28 patients with the de Quervain's thyroiditis. Evaluation of 2688 sera from suspected high-risk areas (e.g., Central and East Africa, or high-risk groups such as HIV-infected individuals and patients with AIDS, thyroid, and neurological disorders) did not reveal FV-specific antibodies in a single case. Previously reported FV seroprevalence in various populations has never been verified by appropriate confirmatory tests. The strain of "human foamy virus" has remained a unique isolate. In conclusion, FVs are unlikely--at present--to circulate in human populations.

Phylogenesis and genetic complexity of the nonhuman primate retroviridae

The three known groups of nonhuman primate retroviruses (simian immunodeficiency virus, simian T cell lymphotropic/leukemic virus type I, and simian foamy virus) are thought to have equivalent human counterparts. This is clearly the case with human immunodeficiency virus types 1 and 2, the causative agents of acquired immunodeficiency syndrome, and with human T cell lymphotropic/leukemia virus type I (HTLV-I), which causes T cell leukemia and a progressive form of myelopathy (tropical spastic paraparesis/HTLV-I-associated myelopathy), and HTLV-II. However, the presence of spumaviruses (foamy viruses) in humans remains uncertain. Data accumulated in the last 5 years suggest the possibility that the human retroviruses are indeed the result of transmission of simian retroviruses to humans. In this article we attempt to parallel the genetic features of the simian retroviridae with their human counterparts and argue for the possibility of horizontal transmission of these viruses from monkeys to humans.

Nuclear localization of foamy virus Gag precursor protein

All foamy viruses give rise to a strong nuclear staining when infected cells are reacted with sera from infected hosts. This nuclear fluorescence distinguishes foamy viruses from all other retroviruses. The experiments reported here indicate that the foamy virus Gag precursor protein is transiently located in the nuclei of infected cells and this is the likely reason for the typical foamy virus nuclear fluorescence. By using the vaccinia virus expression system, a conserved basic sequence motif in the nucleocapsid domain of foamy virus Gag proteins was identified to be responsible for the nuclear transport of the gag precursor molecule. This motif was also found to be able to direct a heterologous protein, the Gag protein of human immunodeficiency virus, into the nucleus.

Characterization of the internal promoter of simian foamy viruses

Simian and human foamy viruses (HFV and SFV), genetically related members of the spumavirus genus of retroviruses, have complex genome structures which encode the gag, pol, and env genes for virion proteins as well as additional open reading frames. One of these open reading frames is a viral transactivator, encoded by genes designated taf for SFV and bel-1 for HFV, which augments transcription directed by the long terminal repeat (LTR) through cis-acting targets in the U3 domain of the LTR. Recently, an internal transcriptional promoter has been identified in sequences within the 3' end of the HFV env gene (M. Lochelt, W. Muranyi, and R. M. Flugel, Proc. Natl. Acad. Sci. 90:7317-7321, 1993). We have demonstrated by using transient expression assays in several tissue culture cell lines and by analyzing viral transcripts in infected cells that SFV-1 from a rhesus macaque and SFV-3 from an African green monkey also encode an internal promoter in the env gene. Transcription directed by the internal promoters of SFV-1 and SFV-3 is activated by the taf-1 and taf-3 gene products, respectively, in several cell types. The importance of a TATA box for the SFV-1 internal promoter was established by site-specific mutagenesis, and the 5' ends of transcripts initiating in the internal promoter have been determined. cis-acting sequences in the SFV-1 env gene required for the response to taf-1 are contained within a 121-bp element located 5' to the TATA box in the internal promoter. This taf-1-responsive element in the internal promoter functions in a position- and orientation-independent fashion in a heterologous promoter and thus has the properties of an enhancer which depends on taf-1 activity. Alignments reveal that the SFV-1 internal promoter and the SFV-1 LTR have little sequence relatedness. Cross-transactivation studies show that the transactivators of SFV-1 and HFV function on the internal promoter and LTR of the homologous virus but not on the heterologous virus. In summary, the genomes of simian and human foamy viruses direct viral transcription through both the promoter in the LTR and an internal promoter within the env gene, and each promoter contains unique enhancer-like elements regulated by the viral transactivator.