Identification of the simian foamy virus transcriptional transactivator gene (taf)

Non-simian foamy viruses: molecular virology, tropism and prevalence and zoonotic/interspecies transmission

Within the field of retrovirus, our knowledge of foamy viruses (FV) is still limited. Their unique replication strategy and mechanism of viral persistency needs further research to gain understanding of the virus-host interactions, especially in the light of the recent findings suggesting their ancient origin and long co-evolution with their nonhuman hosts. Unquestionably, the most studied member is the primate/prototype foamy virus (PFV) which was originally isolated from a human (designated as human foamy virus, HFV), but later identified as chimpanzee origin; phylogenetic analysis clearly places it among other Old World primates. Additionally, the study of non-simian animal FVs can contribute to a deeper understanding of FV-host interactions and development of other animal models. The review aims at highlighting areas of special interest regarding the structure, biology, virus-host interactions and interspecies transmission potential of primate as well as non-primate foamy viruses for gaining new insights into FV biology.

Preparation of simian foamy virus type-1 vectors

Foamy viruses (FVs) are nonpathogenic retroviruses that offer opportunities for efficient and safe gene transfer in various cell types from different species. These viruses have unique replication mechanisms that are distinct from other retroviruses, which may give an advantage to FV-mediated gene transfer. This protocol describes a method for simian foamy virus type-1 (SFV-1) vector preparation and concentration. A transient transfection of vector and packaging constructs allows generation of the SFV-1 vector with titers of 10(7)/mL. The vectors can be further concentrated by 100-200-fold without significant loss of vector titer.

Identification and functional characterization of BTas transactivator as a DNA-binding protein

The genome of bovine foamy virus (BFV) encodes a transcriptional transactivator, namely BTas, that remarkably enhances gene expression by binding to the viral long-terminal repeat promoter (LTR) and internal promoter (IP). In this report, we characterized the functional domains of BFV BTas. BTas contains two major functional domains: the N-terminal DNA-binding domain (residues 1-133) and the C-terminal activation domain (residues 198-249). The complete BTas responsive regions were mapped to the positions -380/-140 of LTR and 9205/9276 of IP. Four BTas responsive elements were identified at the positions -368/-346, -327/-307, -306/-285 and -186/-165 of the BFV LTR, and one element was identified at the position 9243/9264 of the BFV IP. Unlike other foamy viruses, the five BTas responsive elements in BFV shared obvious sequence homology. These data suggest that among the complex retroviruses, BFV appears to have a unique transactivation mechanism.

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.

Foamy virus transactivation and gene expression

An overview of the pattern and mechanisms of spuma or foamy virus (FV) gene expression is presented. FVs are complex retroviruses with respect to their genetic outfit and the elements used to control and regulate expression of the viral genome. The increased insight into transcriptional and posttranscriptional mechanisms has revealed that the FVs are distinct, unconventional retroviruses clearly apart from the orthoretroviruses. Although less characterized than the orthoretroviruses, FVs have several unique features that are important for construction and assembly of FV-based vectors for targeted gene delivery and vaccination purposes. Some of these distinguishing features are directly related to the FV-specific mechanisms of gene expression and include (1) the presence of an internal, functional active second transcription unit for expression of the nonstructural genes, (2) the utilization of a subgenomic, spliced transcript for Pol protein expression, and (3) distinct but not yet understood mechanisms for the nuclear exit of defined transcripts and thus an additional level of posttranscriptional control of gene expression. Finally, the interactions of the viral transactivator not only with both viral promoters but also with regulatory elements controlling the expression of defined cellular genes are an important issue with respect to vector development and the apparent apathogenicity of FVs in their natural hosts.

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.

Historical perspective of foamy virus epidemiology and infection

Foamy viruses (FV) are complex retroviruses which are widespread in many species. Despite being discovered over 40 years ago, FV are among the least well characterized retroviruses. The replication of these viruses is different in many interesting respects from that of all other retroviruses. Infection of natural hosts by FV leads to a lifelong persistent infection, without any evidence of pathology. A large number of studies have looked at the prevalence of primate foamy viruses in the human population. Many of these studies have suggested that FV infections are prevalent in some human populations and are associated with specific diseases. More recent data, using more rigorous criteria for the presence of viruses, have not confirmed these studies. Thus, while FV are ubiquitous in all nonhuman primates, they are only acquired as rare zoonotic infections in humans. In this communication, we briefly discuss the current status of FV research and review the history of FV epidemiology, as well as the lack of pathogenicity in natural, experimental, and zoonotic infections.

Persistent zoonotic infection of a human with simian foamy virus in the absence of an intact orf-2 accessory gene

Although foamy viruses (FVs) are endemic among nonhuman primates, FV infection among humans is rare. Recently, simian foamy virus (SFV) infection was reported in 4 of 231 individuals occupationally exposed to primates (1.8%). Secondary transmission to spouses has not been seen, suggesting that while FV is readily zoonotic, humans may represent dead-end hosts. Among different simian species, SFV demonstrates significant sequence diversity within the U3 region of the long terminal repeat (LTR) and 3' accessory open reading frames (ORFs). To examine if persistent human SFV infection and apparent lack of secondary transmission are associated with genetic adaptations in FV regulatory regions, we conducted sequence analysis of the LTR, internal promoter, ORF-1, and ORF-2 on a tissue culture isolate and peripheral blood mononuclear cell samples from a human infected with SFV of African green monkey origin (SFV-3). Compared to the prototype SFV-3 sequence, the LTR, internal promoter, and FV transactivator (ORF-1) showed sequence conservation, suggesting that FV zoonosis is not dependent on host-specific adaptation to these transcriptionally important regions. However, ORF-2 contains a number of deleterious mutations predicted to result in premature termination of protein synthesis. ORF-2 codes in part for the 60-kDa Bet fusion protein, proposed to be involved in the establishment of persistent cellular SFV infections. These results suggest that persistent human infection by SFV and reduced transmissibility may be influenced by the absence of a functional ORF-2.

Derivation and functional characterization of a consensus DNA binding sequence for the tas transcriptional activator of simian foamy virus type 1

Although DNA binding sites specific for the Bel-1 and Tas transcriptional activators, encoded, respectively, by the human and simian foamy viruses, have been mutationally defined, they show little evident sequence identity. As a result, the sequence determinants for DNA binding by both Bel-1 and Tas have remained unclear. Here, we report the use of a novel in vivo randomization and selection strategy to identify a Tas DNA binding site consensus. This approach takes advantage of the fact that Tas can effectively activate gene expression in yeast cells via a Tas DNA binding site derived from the simian foamy virus type 1 (SFV-1) internal promoter. The defined Tas DNA binding site consensus extends over approximately 25 bp and contains a critical core sequence of approximately 5 bp. Positions adjacent to this core sequence, while clearly also subject to selection, show a significantly higher level of sequence variation. Surprisingly, the wild-type SFV-1 internal promoter Tas DNA binding site fails to conform to the consensus at several positions. Further analysis demonstrated that the consensus sequence bound Tas more effectively than did the wild-type sequence in vitro and could mediate an enhanced Tas response in vivo when substituted into the SFV-1 internal promoter context. These findings explain the limited sequence identity observed for mutationally defined Tas or Bel-1 response elements and should facilitate the identification of Tas DNA target sites located elsewhere in the SFV-1 genome.

Characterization of a human foamy virus 170-kilodalton Env-Bet fusion protein generated by alternative splicing

Primate foamy viruses (FVs) express, in addition to the 130-kDa envelope protein, a 170-kDa glycoprotein, which reacts with antisera specific for the envelope and Bel proteins. We determined the exact nature of this 170-kDa glycoprotein by using the molecularly cloned human FV (HFV). Radioimmunoprecipitation analysis of 293T cells transfected with appropriate expression constructs by using antisera specific for the HFV Env, Bel1, and Bel2 proteins, as well as reverse transcription-PCR analysis of HFV-infected cells, demonstrated that this protein is an Env-Bet fusion protein that is secreted into the supernatant. However, it is only loosely associated, or not associated, with viral particles. gp170 is generated by an alternatively spliced Env mRNA using a splice donor and splice acceptor pair localized within the env open reading frame (ORF), which is normally used to generate Bell and Bet transcripts derived from the internal promoter within the env ORF. gp170 is expressed at a level 30 to 50% of the Env precursor gp130. However, it alone does not confer infectivity to HFV particles, because capsids derived from proviruses expressing only the gp170 were not released into the supernatant. In contrast, viruses derived from proviral clones deficient in gp170 expression showed similar in vitro infectivity and replication kinetics to wild-type virus. Furthermore, both types of viruses were inactivated to a similar extent by neutralizing sera, indicating that shedding of gp170 probably does not affect the humoral immune response in the infected host.

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.

Simian foamy virus type 1 (SFV-1) induces apoptosis

Foamy virus infection causes cytopathology in several cell types from different species. The mechanism of cell killing by foamy viruses is not known. In this report, the mechanism of cell death induced by simian foamy virus type 1 (SFV-1) infection was investigated in fibroblast and lymphoid derived cells lines. Infected L-929 (fibroblast) and Raji (B cell) cells showed chromatin condensation, chromatin cleavage into nucleosome oligomers, and ultrastructural changes consistent with apoptosis. These data suggest that SFV-1 induced apoptotic cell death in different cell lines from different species. The degree of apoptotic cell death in both L-929 and Raji cell lines correlated with increased virus replication. Apoptosis, therefore, is one mechanism by which SFV-1 causes cell death.

The simian foamy virus type 1 transcriptional transactivator (Tas) binds and activates an enhancer element in the gag gene

Simian and human foamy viruses (SFV and HFV) encode a transcriptional transactivator, Tas, which governs the levels of viral transcripts initiated by both the promoter in the long terminal repeat (LTR) and the internal promoter (IP) located within the env gene of these viruses. Tas-responsive target elements,(TRE) LTR in the LTR and (TRE) IP in the env gene, are located 5' of the TATA box in both viral promoters and function as orientation- and position-independent enhancers. We have identified a strong Tas-responsive element, designated TRE (GP), near the 3' end of the gag gene and preceding the pol gene of SFV-1. In transient-expression assays with plasmids containing reporter genes, a 59-bp DNA fragment containing TRE (GP) (nucleotides 2224 to 2282) functioned as an enhancer element, dependent on Tas, in several cell types and in the context of a heterologous basal promoter. DNase footprinting revealed that the fusion protein glutathione S-transferase-Tas, purified from genetically engineered bacteria, interacts with about 40 hp (nucleotides 2237 to 2279) in the TRE (GP). A low degree of sequence homology was noted between TRE (GP) and TRE (IP). In virus-infected cells, novel transcripts with 5' ends immediately upstream from the reverse transcriptase translation frame (nucleotides 2611 to 5778) were identified. Upstream of the start site for these transcripts is a TATA box (nucleotides 2575 to 2579), which was required for transcription in transient-expression assays. Although a spliced mRNA initiated in the viral LTR is implicated in the synthesis of the HFV Pol polyprotein which encodes protease, reverse transcriptase, and integrase, it is possible that SFV-1 contains a promoter within the pol gene for initiating a reverse transcriptase transcript. Taken together, these studies define a novel Tas-responsive enhancer element, which binds the viral transactivator, and a potential promoter within the pol gene.

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.

Isolation and characterization of infectious full-length DNA clones of chimpanzee foamy viruses SFV6 and SFV7: evidence for a Taf-dependent internal promoter

We have cloned complete viral genomes directly from Hirt supernatant DNAs of simian foamy virus types 6 and 7 (SFV6 and SFV7) -infected cells. These clones were shown to be infectious by transfection into cells and subsequent infection of susceptible cells either by cocultivation or by passage of cell-free supernatants. The presence of virus particles, suggested by a typical cytopathic effect, was confirmed by electron microscopy. These viruses were characterized at different levels of the replication cycle. The proviral genomes revealed a taf deletion comparable to that previously described in the human foamy virus (HFV) bel1 gene. Analysis of viral RNAs revealed similar patterns of transcripts for SFV6- and SFV7-infected cells, with predominant expression of accessory genes. Characteristic major viral polypeptides were identified by radioimmunoprecipitation for both isolates. Sequences homologous to the gene encoding Taf and to a potential internal promoter were identified in the infectious clones and subcloned into expression vectors. Their functional properties were tested by transfection assays, which provided evidence for the presence of a Taf-dependent internal promoter in both SFV6 and SFV7 isolates.

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.

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.

Structure and function of the long terminal repeat of the chimpanzee foamy virus isolates (SFV-6)

The complete long terminal repeat (LTR) nucleotide sequence of the chimpanzee foamy virus isolate SFV-6 was determined. Its 1761-bp size makes it the longest LTR reported to date among all retroviruses. Since the length of its LTR is similar to that of other simian isolates while its sequence homology is closer to that of HFV, SFV-6 genetic structure appears to be intermediate between simian and human foamy viruses. Transient expression assays demonstrate that SFV-6 encodes a transactivator of viral gene expression directed either by its own LTR or by heterologous promoters like HFV and HIV-1 LTRs. Our data also provide evidence for cross-transactivation between SFV-6 and HFV.

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.

Genetic analysis indicates that the human foamy virus Bel-1 protein contains a transcription activation domain of the acidic class

Human foamy virus encodes a nuclear regulatory protein, termed Bel-1, that serves as a potent activator of viral transcription. Mutational analysis has identified a small, discrete activation domain within Bel-1 that is highly active in both higher and lower eukaryotic cells. Here, we demonstrate that the activation domain of Bel-1 is highly dependent on the ADA2 transcriptional adaptor for biological activity in yeast cells, a property previously shown to be a hallmark of the VP16 class of acidic transcriptional activators (S. L. Berger, B. Pina, N. Silverman, G. A. Marcus, J. Agapite, J. L. Regier, S. J. Triezenberg, and L. Guarente, Cell 70:251-265, 1992). Using genetic selection in yeast cells, we have derived a set of point mutants within the Bel-1 activation domain that display a qualitatively similar loss in activation potential when examined in either yeast or human cells. These data indicate that the Bel-1 activation domain functions similarly in both lower and higher eukaryotes and strongly suggest that Bel-1 belongs to the VP16 class of acidic transcription factors.

Identification and characterization of the Bel 3 protein of human foamy virus

The human foamy virus (HFV) is a complex retrovirus that contains several regulatory and auxiliary bel genes besides the gag, pol, and env genes. In contrast to the gene products of bel 1 and bel 2/bet that were identified previously, the Bel 3 protein has not been described to date. Here we report the identification of Bel 3 in HFV-infected cells by immunoprecipitation, indirect immunofluorescence, and expression cloning under the control of a strong heterologous promoter. Bel 3 was immunoprecipitated with an antiserum directed against a bacterially expressed and purified form of recombinant Bel 3 antigen. Bel 3 was found to be expressed in low amounts in the cytoplasm of HFV-infected cells and to migrate with an apparent molecular mass of 19.4 kDa on electrophoresis in SDS-polyacrylamide gels, consistent with the calculated value of 18.2 kDa. Radioimmunoprecipitation of HFV-infected cell lysates with the hyperimmune serum against Bel 3 revealed at least two additional immunoreactive bands of 15.5 and 10.6 kDa. The results indicate that Bel 3 was labile, because it was partially degraded even at early time points after infection. On transfection and expression in transfected COS cells, recombinant Bel 3 was immunoprecipitated and migrated in three polypeptide bands of 18.7, 14.8, and 9.3 kDa under denaturing conditions. In the absence of reducing agents, the bacterially expressed and purified recombinant Bel 3 protein of 16.1 kDa can form homodimers of 30 kDa.

Transcriptional mapping of the 3' end of the bovine syncytial virus genome

The bovine syncytial virus, a member of the retroviral subfamily Spumavirinae, causes a persistent, asymptomatic infection in cattle. Nucleotide sequence analysis of the viral genome revealed two overlapping reading frames in the 3' region, traditionally occupied by accessory-function genes in other complex retroviruses. In order to analyze the transcripts from the accessory-gene region, we designed oligonucleotide primers complementary to sequences within the 5' and 3' long terminal repeats (LTRs) for use with the PCR. Southern blot analysis of amplification products revealed eight major cDNA bands. Eleven distinct cDNA clones were subsequently isolated and characterized. The initial splice donor in each clone is located 49 bp downstream from the mRNA cap site in the 5' LTR. The primary splice acceptor site was located 17 bp upstream from the proximal 3' open reading frame known as BF-ORF1. A second major splice acceptor was localized to a region upstream of the second open reading frame, BF-ORF2. Clones were identified which spliced directly to each of these sites. Additional splice donor and acceptor sites within BF-ORF1 and BF-ORF2 and the 3' LTR were variously used to generate a complex array of multiply spliced transcripts. Each of these transcripts remained in frame and coded for a potential protein product.

The human foamy virus internal promoter directs the expression of the functional Bel 1 transactivator and Bet protein early after infection

The human foamy virus or spumaretrovirus (HFV) is a complex retrovirus that has the capacity to code not only for the three retroviral genes gag, pol, and env but, in addition, for at least three bel genes. The HFV provirus contains two different and functionally active promoters: the classical retroviral promoter in the 5' long terminal repeat and a recently identified second promoter in the env gene upstream of the bel genes. Both promoter/enhancers are strongly dependent on the HFV transcriptional transactivator protein Bel 1. Here we report that the internal promoter directs the synthesis of viral transcripts that code for functionally active Bel 1 and for Bet proteins that appeared early after HFV infection. The viral mRNAs of the internal promoter have a 112-nucleotide-long leader exon and were spliced predominantly at the first splice donor site in the 5' untranslated region. The data were obtained by transient expression assays, transactivation experiments, and RNA analyses of transcripts derived from HFV-infected cells. The results provide strong evidence for the crucial role the internal promoter plays during HFV infection in generating bel-specific transcripts.

Expression of the human foamy virus bel-1 transactivator in insect cells

The human foamy virus (HFV) bel-1 transactivator protein was expressed in insect cells by a recombinant baculovirus. For the generation of the recombinant baculovirus, Acbel-1, the bel-1 gene of an HFV mutant was used, that bears truncations in the bel-1 overlapping bel-2 open reading frame. Acbel-1 infected Sf9 cells produced high amounts of recombinant protein of the same electrophoretic mobility (36 kD) as bel-1 expressed in mammalian cells. The baculovirus expressed bel-1 protein was readily identified by a polyclonal rabbit serum directed against bel-1 in immunoblot assay. As in mammalian cells, bel-1 was predominantly localized to the nucleus of Acbel-1 infected insect cells. The baculovirus expressed bel-1 protein will be of use to determine the action of this novel viral transactivator more precisely.

Functional domains of the simian foamy virus type 1 transcriptional transactivator (Taf)

The genome of simian foamy virus type 1 encodes a transcriptional transactivator (Taf) that dramatically elevates gene expression directed by the viral long terminal repeat. In this report, we describe the functional domains of simian foamy virus type 1 Taf. Several taf mutants and fusion proteins of Taf and the DNA-binding domain of the Saccharomyces cerevisiae transcriptional transactivator GAL4 were used in this study. Taf contains two potent activation domains. One of the activation domains is located at the amino terminus (positions 1 to 48, with position 1 representing the initiator amino acid methionine) and contains several acidic amino acids. The second activation domain was mapped to a region at the carboxy terminus (positions 277 to 300). These two domains activate gene expression directed by the viral long terminal repeat independently of each other. No significant amino acid sequence homology between the activation domains is noted. Thus, Taf belongs in part to the family of acidic transcriptional transactivators. The activation domain at the carboxy terminus is conserved among foamy virus transactivators but is not related to other known transcriptional activators. Therefore, the mechanism of gene activation by the carboxy terminus of Taf may be novel. In addition, a potential binding domain rich in basic amino acids (positions 179 to 222) and a highly conserved sequence among foamy virus transactivators (positions 93 to 109) were found to be critical for Taf activity.

The carboxy-terminal transcription enhancement region of the human spumaretrovirus transactivator contains discrete determinants of the activator function

The bel1 gene of human spumaretrovirus (HSRV) encodes a 300-amino-acid nuclear protein termed Bel1 that is a potent activator of transcription from the cognate long terminal repeat (LTR). Bel1 can also efficiently activate the human immunodeficiency virus type 1 (HIV-1) LTR. We have previously shown that the amino-terminal 227-residue region (minimal activator region) of Bel1 can activate the HSRV LTR at low levels and that two distinct domains within the carboxy-terminal 73 residues, from residues 255 to 266 and 272 to 300, that bear little sequence homology can independently enhance the activity of the minimal activator domain (L. K. Venkatesh, C. Yang, P. A. Theodorakis, and G. Chinnadurai, J. Virol. 67:161-169, 1993). We now report on the further characterization of these two transcriptional enhancement regions. Mutational analysis of the region comprising residues 255 to 266 indicates that a cluster of leucine residues is critical to the function of this region. Also, residues 273 to 287, which are identical in sequence to a 15-amino-acid segment near the carboxy terminus of the simian foamy virus transcriptional activator Taf, can independently enhance the activity of the minimal activator region. To delineate the region(s) of Bel1 that could function autonomously as an activator domain, we tested the activity of chimeric proteins comprising either wild-type or functionally defective forms of Bel1 fused to the DNA binding domain, Gal4(1-147), of the yeast transcriptional activator Gal4 on a synthetic promoter comprising Gal4 DNA binding sites linked to the adenovirus E1B TATA box (minimal promoter). Gal4-Bel1 was found to activate basal transcription from the E1B TATA box at least 35-fold, and the region responsible for this activation function was localized to the carboxy-terminal 73 amino acids. When the transcriptional enhancement regions were tested for autonomous activator function as Gal4(1-147) chimeras, residues 272 to 300, but not 255 to 266, were found to activate transcription efficiently when targeted to the E1B TATA motif and also to HSRV and HIV-1 LTRs. The highly conserved region between amino acids 273 and 287 alone was found to activate transcription efficiently when targeted to the HSRV LTR but not to the E1B TATA box or the HIV-1 LTR. Thus, our results demonstrate that the carboxy-terminal 29-amino-acid region (residues 272 to 300) contributes to Bel1 transactivation by functioning as an autonomous activator of TATA motif-directed transcription in a manner similar to that of other modular transcriptional activators.(ABSTRACT TRUNCATED AT 400 WORDS)

The foamy virus family: molecular biology, epidemiology and neuropathology

The family of foamy viruses designates a group of retroviruses which share a specific morphology and provoke characteristic cytopathic effects in cultured cells. Like HTLV and HIV, foamy viruses are complex viruses encoding a number of ancillary genes in addition to gag, pol and env, including a transcriptional transactivator. Foamy viruses are endemic in various primate species, and human foamy viruses (HFV) have been isolated from patients with various neoplastic and degenerative diseases. Despite a growing body of knowledge on the biology of foamy viruses, it has not yet been possible to identify a disease specifically caused by foamy virus infection. After reviewing the epidemiology and molecular biology of the various animal foamy viruses, this article focuses on the pathogenic properties of HFV in transgenic mouse systems. HFV transgenes exhibit a striking neurotropism and elicit a progressive degenerative disease of the central nervous system and striated muscle. Similarly to patients with HIV-associated encephalopathy, HFV transgenic mice develop accumulations of syncytial giant cells in their brains. The relevance of these findings for human neuropathology is discussed.

Identification of human endogenous retroviruses with complex mRNA expression and particle formation

Retroviruses comprise strains with considerable disease potential in animals and humans. In addition to exogenous strains transmitted horizontally, endogenous proviruses are transmitted through the germ line. Some of these endogenous retroviruses can be pathogenic in mice and possibly in other animal species. They may also be considered as mobile genetic elements with the potential to produce mutations. In humans, genomic DNA contains numerous endogenous retroviral sequences detected by their partial relatedness to animal retroviruses. However, all proviruses sequenced so far have been found to be defective. In this communication, we describe the expression of a family of human endogenous retrovirus sequences (HERV-K) in GH cells, a teratocarcinoma cell line producing the human teratocarcinoma-derived retrovirus (HTDV) particles previously described by us. Four viral mRNA species could be identified, including a full-length mRNA. The other three subgenomic mRNAs are generated by single or double splicing events. This expression pattern is reminiscent of the more complex control of virus gene regulation observed, for example, with lenti- or spumavirus strains, although HERV-K shows no sequence homology to human T-lymphotropic virus or human immunodeficiency virus. Sequence analysis of expressed HERV-K genomes revealed non-defective gag genes, a prerequisite for particle formation. Open reading frames were also observed in pol and env. Antisera raised against recombinant gag proteins of HERV-K stained HTDV particles in immunoelectron microscopy, linking them to the HERV-K family.

Functional organization of the Bel-1 trans activator of human foamy virus

Human foamy virus encodes a 300-amino-acid nuclear regulatory protein termed Bel-1 that is required for human foamy virus replication in culture. Bel-1 is a potent trans-activator of gene expression directed by the homologous HFV long terminal repeat as well as the long terminal repeat of human immunodeficiency virus type 1. We have used mutational analysis to define several discrete functional domains within Bel-1. The C-terminal approximately 50 amino acids of Bel-1 are shown to be essential for Bel-1 activity but can be effectively substituted by the C-terminal activation domain of VP16. We therefore conclude that the Bel-1 C terminus forms part of an activation domain. Mutations within a central, approximately 100-amino-acid segment of Bel-1 preclude trans-activation by either Bel-1 or the Bel-1/VP16 chimera. These sequences are therefore proposed to direct the interaction of Bel-1 with its viral DNA target sequences. A short Bel-1 segment located between the activation and binding domains is shown to mediate the nuclear localization of this regulatory protein. Although the functional organization of Bel-1 therefore appears comparable to that reported for other eukaryotic transcriptional activators, Bel-1 does not contain sequences homologous to known transcriptional activation or DNA-binding motifs.

Functional dissection of the human spumaretrovirus transactivator identifies distinct classes of dominant-negative mutants

The bel1 gene of human spumaretrovirus (HSRV) codes for a 300-amino-acid nuclear protein, termed Bel1, that can strongly activate transcription from the cognate long terminal repeat (LTR) by at least 200-fold. Bel1 can also activate human immunodeficiency virus type 1 (HIV-1) LTR expression. By using site-directed mutagenesis, we have identified distinct regions of Bel1 essential for HSRV LTR activation. The amino-terminal 55 residues, which comprise a highly acidic region followed by a short basic stretch, were dispensable for activation. The distribution of functionally defective mutants indicates that two distinct regions between residues 56 and 300 cooperate to confer full activator function. The larger, more amino-terminal region between residues 56 and 227 is sufficient to minimally activate the HSRV LTR. It contains a region between residues 88 and 110 that is strongly conserved between the simian and human spumavirus transactivators but otherwise lacks obvious homology to known transcriptional activators except for an Arg-rich nuclear localization sequence (NLS) between residues 211 and 225 that can be functionally substituted for by the NLS of the simian virus 40 large T antigen. The carboxy-terminal 73 residues contain two functionally redundant regions that can independently augment the activity of the more N-terminal minimal activator domain by 30- to 90-fold. Comparative analysis of the effect of Bel1 mutations on HSRV and HIV-1 LTR expression revealed a similar requirement of Bel1 domains for activation of the two LTRs. Bel1 is phosphorylated in vivo, and a nuclear localization-defective mutant lacking residues 211 to 222 was severely defective for phosphorylation, whereas various deletion mutations in residues 228 to 300 resulted in a four- to eightfold reduction in phosphate incorporation. When functionally defective bel1 mutants were examined for a dominant-negative phenotype, only mutants lacking a proline-rich basic region between residues 194 and 200 or the NLS between residues 211 and 222 that were found to occupy predominantly nuclear and cytoplasmic locations, respectively, could suppress wild-type Bel1 function efficiently. In identifying two classes of dominant-negative mutants with distinct subcellular localization phenotypes, the mutational analysis of Bel1 has revealed a feature unusual for known transcriptional activators.

Genomic organization and expression of simian foamy virus type 3 (SFV-3)

The complete nucleotide sequence of simian foamy virus type 3 (SFV-3) strain LK-3, isolated from an African green monkey, was determined. In addition to translation frames representing the gag, pol, and env genes, two open reading frames are located in the region between the env gene and the 3' long terminal repeat (LTR). Both SFV-3 and SFV-1 encode two open reading frames between env and the 3' LTR, whereas HFV encodes three open reading frames in this region. Northern blot analysis of cell cultures infected with SFV-3 revealed subgenomic RNAs for these open reading frames. The protease of SFV-3 is encoded by the pol gene in contrast to HFV which encodes the protease in the gag gene. Notably, the pol gene of SFV-3 in the +1 translational frame relative to the gag gene; this observation is in agreement with SFV-1, but differs for HFV and all other retrovirus genomes reported. Thus, gag-pol precursors of the SFVs appear to be expressed by a +1 frameshift. Nucleotide and deduced amino acid alignments of SFV-3, SFV-1, and HFV revealed an unexpected homology pattern; highest homologies are observed in the pol and env genes but low homologies are noted in the gag genes and the additional open reading frames. Analysis of phylogenetic trees confirms the classification of foamy viruses as a subfamily of retroviruses, distinct from the lentiviruses and oncoviruses.

cis-acting regulatory regions in the long terminal repeat of simian foamy virus type 1

Simian foamy virus type 1 (SFV-1), a member of the Spumavirinae subfamily of retroviruses, encodes a transcriptional transactivator (taf) that strongly augments gene expression directed by the viral long terminal repeat (LTR) (A. Mergia, K. E. S. Shaw, E. Pratt-Lowe, P. A. Barry, and P. A. Luciw, J. Virol. 65:2903-2909, 1991). This report describes cis-acting regulatory elements in the LTR that control viral gene expression. A series of LTR mutants and hybrid promoter constructs have been analyzed in transient expression assays for responsiveness to Taf. The targets for transactivation have been mapped to two regions of the U3 domain of the LTR, between positions -1196 and -880 and between positions -403 and -125 (+1 represents the transcription initiation site). No significant nucleotide sequence homology between these two regions is noted; thus, the SFV-1 taf gene acts through at least two distinct sequence elements in the LTR. The target contained between positions -403 and -125 acts independently of orientation, in different cell types and species, and in the context of a heterologous promoter. Thus, the target element between positions -403 and -125 has properties of a transcriptional enhancer. The observation that two distinct elements in the SFV-1 LTR are targets for transcriptional transactivation is novel with respect to observations for other retroviral systems. The R-U5 region of the SFV-1 LTR down-regulates transactivation by severalfold. Computer analysis of the R-U5 region revealed a secondary structure with a free-energy level of -74 kcal (ca. -310,000 J); this structural feature may account for the inhibitory effect on gene expression directed by the LTR. Taf of SFV-1 had no effect on gene expression directed by the LTR of the related human foamy virus, whereas Taf transactivates gene expression directed by the LTRs of the human and simian immunodeficiency viruses. Comparative functional analysis of Taf on homologous and heterologous LTRs may facilitate elucidation of the mechanism of transactivation of foamy viruses.

Transcription factor AP-1 modulates the activity of the human foamy virus long terminal repeat

The human foamy virus (HFV) contains within the U3 region of its long terminal repeat (LTR) three perfect consensus sequences for the binding of the inducible transcription factor AP-1. Results of DNase I footprint protection and gel retardation assays demonstrated that proteins in extracts of HeLa and BHK-21 cells as well as bacterially expressed Jun and Fos proteins bind to these AP-1 sites. By conducting transient expression assays using chloramphenicol acetyltransferase plasmids carrying LTR sequences with point-mutated AP-1 sites, it was found that the three AP-1 sites contribute to the optimal activity of the HFV promoter. It is shown that induction of the HFV LTR by 12-O-tetradecanoylphorbol-13-acetate (TPA) and serum factors is mediated through the AP-1 sites.