Structural and Functional Aspects of Foamy Virus Protease-Reverse Transcriptase

Reverse transcription describes the process of the transformation of single-stranded RNA into double-stranded DNA via an RNA/DNA duplex intermediate, and is catalyzed by the viral enzyme reverse transcriptase (RT). This event is a pivotal step in the life cycle of all retroviruses. In contrast to orthoretroviruses, the domain structure of the mature RT of foamy viruses is different, i.e., it harbors the protease (PR) domain at its N-terminus, thus being a PR-RT. This structural feature has consequences on PR activation, since the enzyme is monomeric in solution and retroviral PRs are only active as dimers. This review focuses on the structural and functional aspects of simian and prototype foamy virus reverse transcription and reverse transcriptase, as well as special features of reverse transcription that deviate from orthoretroviral processes, e.g., PR activation.

Prototype foamy virus integrase is promiscuous for target choice

Retroviruses have two essential activities: reverse transcription and integration. The viral protein integrase (IN) covalently joins the viral cDNA genome to the host DNA. Prototype foamy virus (PFV) IN has become a model of retroviral intasome structure. However, this retroviral IN has not been well-characterized biochemically. Here we compare PFV IN to previously reported HIV-1 IN activities and discover significant differences. PFV IN is able to utilize the divalent cation calcium during strand transfer while HIV-1 IN is not. HIV-1 IN was shown to completely commit to a target DNA within 1 min, while PFV IN is not fully committed after 60 min. These results suggest that PFV IN is more promiscuous compared to HIV-1 IN in terms of divalent cation and target commitment.

Nuclear localization signals in prototype foamy viral integrase for successive infection and replication in dividing cells

We identified four basic amino acid residues as nuclear localization signals (NLS) in the C-terminal domain of the prototype foamy viral (PFV) integrase (IN) protein that were essential for viral replication. We constructed seven point mutants in the C-terminal domain by changing the lysine and arginine at residues 305, 308, 313, 315, 318, 324, and 329 to threonine or proline, respectively, to identify residues conferring NLS activity. Our results showed that mutation of these residues had no effect on expression assembly, release of viral particles, or in vitro recombinant IN enzymatic activity. However, mutations at residues 305 (R → T), 313(R → T), 315(R → P), and 329(R → T) lead to the production of defective viral particles with loss of infectivity, whereas non-defective mutations at residues 308(R → T), 318(K → T), and 324(K → T) did not show any adverse effects on subsequent production or release of viral particles. Sub-cellular fractionation and immunostaining for viral protein PFV-IN and PFV-Gag localization revealed predominant cytoplasmic localization of PFV-IN in defective mutants, whereas cytoplasmic and nuclear localization of PFV-IN was observed in wild type and non-defective mutants. However sub-cellular localization of PFV-Gag resulted in predominant nuclear localization and less presence in the cytoplasm of the wild type and non-defective mutants. But defective mutants showed only nuclear localization of Gag. Therefore, we postulate that four basic arginine residues at 305, 313, 315 and 329 confer the karyoplilic properties of PFV-IN and are essential for successful viral integration and replication.

Directed DNA shuffling of retrovirus and retrotransposon integrase protein domains

Chimeric proteins are used to study protein domain functions and to recombine protein domains for novel or optimal functions. We used a library of chimeric integrase proteins to study DNA integration specificity. The library was constructed using a directed shuffling method that we adapted from fusion PCR. This method easily and accurately shuffles multiple DNA gene sequences simultaneously at specific base-pair positions, such as protein domain boundaries. It produced all 27 properly-ordered combinations of the amino-terminal, catalytic core, and carboxyl-terminal domains of the integrase gene from human immunodeficiency virus, prototype foamy virus, and Saccharomyces cerevisiae retrotransposon Ty3. Retrotransposons can display dramatic position-specific integration specificity compared to retroviruses. The yeast retrotransposon Ty3 integrase interacts with RNA polymerase III transcription factors to target integration at the transcription initiation site. In vitro assays of the native and chimeric proteins showed that human immunodeficiency virus integrase was active with heterologous substrates, whereas prototype foamy virus and Ty3 integrases were not. This observation was consistent with a lower substrate specificity for human immunodeficiency virus integrase than for other retrovirus integrases. All eight chimeras containing the Ty3 integrase carboxyl-terminal domain, a candidate targeting domain, failed to target strand transfer in the presence of the targeting protein, suggesting that multiple domains of the Ty3 integrase cooperate in this function.

Retroviral intasomes: progress and questions

In this issue of Structure, Gupta and colleagues apply a combination of biophysical approaches to study the solution properties of prototype foamy virus (PFV) integrase alone and in complex with viral DNA ends (intasome). The results complement and extend previous structural studies of PFV intasomes by X-ray crystallography and highlight the synergy of solution and crystallographic approaches to the study of nucleoprotein complexes.

Solution conformations of prototype foamy virus integrase and its stable synaptic complex with U5 viral DNA

Using small-angle X-ray and neutron scattering (SAXS/SANS), in combination with analytical centrifugation and light scattering, we have determined the solution properties of PFV IN alone and its synaptic complex with processed U5 viral DNA and related these properties to models derived from available crystal structures. PFV IN is a monomer in solution, and SAXS analysis indicates an ensemble of conformations that differ from that observed in the crystallographic DNA-bound state. Scattering data indicate that the PFV intasome adopts a shape in solution that is consistent with the tetrameric assembly inferred from crystallographic symmetry, and these properties are largely preserved in the presence of divalent ions and clinical strand transfer inhibitors. Using contrast variation methods, we have reconstructed the solution structure of the PFV intasome complex and have located the distal domains of IN that were unresolved by crystallography. These results provide important insights into the architecture of the retroviral intasome.

Minimal size of prototype foamy virus integrase for nuclear localization

We have reported previously that the prototype foamy virus (PFV) integrase (IN) has a strong nuclear localization signal (NLS) in its C-terminal domain, in particular in a region of aa 306-334 including highly karyophilic arginines or lysines at positions 308, 313, 318, 324, and 329. In this study, we used various mutants of the C-terminal domain to further analyze its karyophilic determinants. Plasmids expressing these mutants fused to maltose binding protein (MBP) and enhanced green fluorescent protein (EGFP) were transfected to COS-1 cells and subcellular localization of these fluorescent fusion proteins was determined by fluorescent microscopy. The results revealed that a maximum karyophilicity was exhibited by a region longer than the previously described one of 29 aa (aa 306-334), in particular by a 64 aa region (aa 289-352) with Arg341 and Lys349 as critical determinants.

Structural biology of retroviral DNA integration

Three-dimensional macromolecular structures shed critical light on biological mechanism and facilitate development of small molecule inhibitors. Clinical success of raltegravir, a potent inhibitor of HIV-1 integrase, demonstrated the utility of this viral DNA recombinase as an antiviral target. A variety of partial integrase structures reported in the past 16 years have been instrumental and very informative to the field. Nonetheless, because integrase protein fragments are unable to functionally engage the viral DNA substrate critical for strand transfer inhibitor binding, the early structures did little to materially impact drug development efforts. However, recent results based on prototype foamy virus integrase have fully reversed this trend, as a number of X-ray crystal structures of active integrase-DNA complexes revealed key mechanistic details and moreover established the foundation of HIV-1 integrase strand transfer inhibitor action. In this review we discuss the landmarks in the progress of integrase structural biology during the past 17 years.

Structural studies of the catalytic core of the primate foamy virus (PFV-1) integrase

Retroviral integrases are vital enzymes in the viral life cycle and thus are important targets for antiretroviral drugs. The structure of the catalytic core domain of the integrase from human foamy virus, which is related to HIV-1, has been solved. The structure of the protein is presented in two different crystal forms, each containing several molecules in the asymmetric unit, with and without the essential manganese or magnesium ion, and the structures are compared in detail. This allows regions of high structural variability to be pinpointed, as well as the effect of divalent cations on the conformation of the catalytic site.

In vitro fidelity of the prototype primate foamy virus (PFV) RT compared to HIV-1 RT

We compared the in vitro fidelity of wild-type human immunodeficiency virus type-1 (HIV-1) reverse transcriptase (RT) and the prototype foamy virus (PFV) RT. Both enzymes had similar error rates for single nucleotide substitutions; however, PFV RT did not appear to make errors at specific hotspots, like HIV-1 RT. In addition, PFV RT made more deletions and insertions than HIV-1 RT. Although the majority of the missense errors made by HIV-1 RT and PFV RT are different, relatively few of the mutations caused by either enzyme can be explained by a misalignment/slippage mechanism. We suggest that the higher polymerase activity of PFV RT could contribute to the ability of the enzyme to jump to the same or a different template.

Effect of mutations on the dimer stability and the pH optimum of the human foamy virus protease

To explore the role of residues being close to the catalytic aspartates in the higher pH optimum and in the lower dimer stability of human foamy virus (HFV) protease (PR) in comparison with human immunodeficiency virus type 1 (HIV-1) protease, single (Q8R, H22L, S25T, T28D) and double (Q8R-T28D, H22L-T28D) mutants were created based on sequence alignments and on the molecular model of HFV PR. The wild-type and mutant enzymes were expressed in fusion with maltose binding protein in Escherichia coli and the fusion proteins were purified by affinity chromatography. Specificity constant of most mutants was lower, but the value of Q8R-T28D double mutant enzyme was higher than that of the wild-type HFV PR. Furthermore, urea denaturation at two pH values and pH optimum values showed an increased stability and pH optimum for most mutants. These results suggest that the mutated residues may not be responsible for the higher pH optimum of HFV PR, but they may contribute to the lower dimer stability as compared with that of HIV-1 PR.

The DNA-binding domain of the yeast Spt10p activator includes a zinc finger that is homologous to foamy virus integrase

The yeast SPT10 gene encodes a putative histone acetyltransferase that binds specifically to pairs of upstream activating sequence (UAS) elements found only in the histone gene promoters. Here, we demonstrate that the DNA-binding domain of Spt10p is located between residues 283 and 396 and includes a His(2)-Cys(2) zinc finger. The binding of Spt10p to the histone UAS is zinc-dependent and is disabled by a zinc finger mutation (C388S). The isolated DNA-binding domain binds to single histone UAS elements with high affinity. In contrast, full-length Spt10p binds with high affinity only to pairs of UAS elements with very strong positive cooperativity and is unable to bind to a single UAS element. This implies the presence of a "blocking" domain in full-length Spt10p, which forces it to search for a pair of UAS elements. Chromatin immunoprecipitation experiments indicate that, unlike wild-type Spt10p, the C388S protein does not bind to the promoter of the gene encoding histone H2A (HTA1) in vivo. The C388S mutant has a phenotype similar to that of the spt10Delta mutant: poor growth and global aberrations in gene expression. Thus, the C388S mutation disables the DNA-binding function of Spt10p in vitro and in vivo. The zinc finger of Spt10p is homologous to that of foamy virus integrase, perhaps suggesting that this integrase is also a sequence-specific DNA-binding protein.

A novel function for spumaretrovirus integrase: an early requirement for integrase-mediated cleavage of 2 LTR circles

Retroviral integration is central to viral persistence and pathogenesis, cancer as well as host genome evolution. However, it is unclear why integration appears essential for retrovirus production, especially given the abundance and transcriptional potential of non-integrated viral genomes. The involvement of retroviral endonuclease, also called integrase (IN), in replication steps apart from integration has been proposed, but is usually considered to be accessory. We observe here that integration of a retrovirus from the spumavirus family depends mainly on the quantity of viral DNA produced. Moreover, we found that IN directly participates to linear DNA production from 2-LTR circles by specifically cleaving the conserved palindromic sequence found at LTR-LTR junctions. These results challenge the prevailing view that integrase essential function is to catalyze retroviral DNA integration. Integrase activity upstream of this step, by controlling linear DNA production, is sufficient to explain the absolute requirement for this enzyme. The novel role of IN over 2-LTR circle junctions accounts for the pleiotropic effects observed in cells infected with IN mutants. It may explain why 1) 2-LTR circles accumulate in vivo in mutants carrying a defective IN while their linear and integrated DNA pools decrease; 2) why both LTRs are processed in a concerted manner. It also resolves the original puzzle concerning the integration of spumaretroviruses. More generally, it suggests to reassess 2-LTR circles as functional intermediates in the retrovirus cycle and to reconsider the idea that formation of the integrated provirus is an essential step of retrovirus production.

Characterization of the functional domains of human foamy virus integrase using chimeric integrases

Retroviral integrases insert viral DNA into target DNA. In this process they recognize their own DNA specifically via functional domains. In order to analyze these functional domains, we constructed six chimeric integrases by swapping domains between HIV-1 and HFV integrases, and two point mutants of HFV integrase. Chimeric integrases with the central domain of HIV-1 integrase had strand transfer and disintegration activities, in agreement with the idea that the central domain determines viral DNA specificity and has catalytic activity. On the other hand, chimeric integrases with the central domain of HFV integrase did not have any enzymatic activity apart from FFH that had weak disintegration activity, suggesting that the central domain of HFV integrase was defective catalytically or structurally. However, these inactive chimeras were efficiently complemented by the point mutants (D164A and E200A) of HFV integrase, indicating that the central domain of HFV integrase possesses potential enzymatic activity but is not able to recognize viral or target DNA without the help of its homologous N-terminal and C-terminal domains.

Amino acid preferences for a critical substrate binding subsite of retroviral proteases in type 1 cleavage sites

The specificities of the proteases of 11 retroviruses representing each of the seven genera of the family Retroviridae were studied using a series of oligopeptides with amino acid substitutions in the P2 position of a naturally occurring type 1 cleavage site (Val-Ser-Gln-Asn-Tyr Pro-Ile-Val-Gln; the arrow indicates the site of cleavage) in human immunodeficiency virus type 1 (HIV-1). This position was previously found to be one of the most critical in determining the substrate specificity differences of retroviral proteases. Specificities at this position were compared for HIV-1, HIV-2, equine infectious anemia virus, avian myeloblastosis virus, Mason-Pfizer monkey virus, mouse mammary tumor virus, Moloney murine leukemia virus, human T-cell leukemia virus type 1, bovine leukemia virus, human foamy virus, and walleye dermal sarcoma virus proteases. Three types of P2 preferences were observed: a subgroup of proteases preferred small hydrophobic side chains (Ala and Cys), and another subgroup preferred large hydrophobic residues (Ile and Leu), while the protease of HIV-1 preferred an Asn residue. The specificity distinctions among the proteases correlated well with the phylogenetic tree of retroviruses prepared solely based on the protease sequences. Molecular models for all of the proteases studied were built, and they were used to interpret the results. While size complementarities appear to be the main specificity-determining features of the S2 subsite of retroviral proteases, electrostatic contributions may play a role only in the case of HIV proteases. In most cases the P2 residues of naturally occurring type 1 cleavage site sequences of the studied proteases agreed well with the observed P2 preferences.

Ancient co-speciation of simian foamy viruses and primates

Although parasite-host co-speciation is a long-held hypothesis, convincing evidence for long-term co-speciation remains elusive, largely because of small numbers of hosts and parasites studied and uncertainty over rates of evolutionary change. Co-speciation is especially rare in RNA viruses, in which cross-species transfer is the dominant mode of evolution. Simian foamy viruses (SFVs) are ubiquitous, non-pathogenic retroviruses that infect all primates. Here we test the co-speciation hypothesis in SFVs and their primate hosts by comparing the phylogenies of SFV polymerase and mitochondrial cytochrome oxidase subunit II from African and Asian monkeys and apes. The phylogenetic trees were remarkably congruent in both branching order and divergence times, strongly supporting co-speciation. Molecular clock calibrations revealed an extremely low rate of SFV evolution, 1.7 x 10(-8) substitutions per site per year, making it the slowest-evolving RNA virus documented so far. These results indicate that SFVs might have co-speciated with Old World primates for at least 30 million years, making them the oldest known vertebrate RNA viruses.

Characterization of the polymerase and RNase H activities of human foamy virus reverse transcriptase

Foamy virus (FV) replication, while related to that of orthoretroviruses, differs at a number of steps. Several of these differences involve the reverse transcriptase (RT). There appear to be fewer RTs present in FV than in orthoretroviruses; we previously proposed that the polymerase of FV RT was more active than orthoretroviral RTs to compensate for the numerical difference. Here we present further characterization of the RT of FV. The polymerase activity of FV RT was greater than that of human immunodeficiency virus type 1 RT in a variety of assays. We also examined the RNase H activity of FV RT, and we propose that FV RT has a basic loop in the RNase H domain. Although the sequence of the basic loop of FV RT is different from the basic loop of either Moloney leukemia virus RNase H or Escherichia coli RNase H, the FV RT basic loop appears to have a similar function.

Proteolytic processing of foamy virus Gag and Pol proteins

The foamy viral proteases (FV PRs) are set apart from other retroviral processing enzymes by unique features. The first remarkable property is that FV PRs are enzymatically active as high-molecular-mass Pro-Pol proteins. Hence there exist multiple forms of active FV PRs that likely contribute to cleavage site specificity. A FV PR of low molecular size is not detectable in purified virions, in contrast to PRs of other retroviruses that are found in virus particles. Because the major part of Pol remains attached to the amino-terminal enzymatically active PR protein region, the FV-specific way of expressing Pro-Pol polyproteins from a pol-specific transcript provides for the incorporation of Pro-Pol and IN into virus particles. Proteolytic processing of Gag and Pol proteins is incomplete and delayed. Another novel feature is that the catalytic center of the active dimers of cat FV PR consists of D-S/T-Q instead of D-S/T-G, an unprecedented feature of this enzyme. The temporal and spatial control and the factors that regulate FV PRs remain to be elucidated.

Screening for simian foamy virus infection by using a combined antigen Western blot assay: evidence for a wide distribution among Old World primates and identification of four new divergent viruses

Simian foamy viruses (SFVs) belong to a genetically and antigenically diverse class of retroviruses that naturally infect a wide range of nonhuman primates (NHPs) and can also be transmitted to humans occupationally exposed to NHPs. Current serologic detection of SFV infection requires separate Western blot (WB) testing by using two different SFV antigens [SFV(AGM) (African green monkey) and SFV(CPZ) (chimpanzee)]. However, this method is labor intensive and validation is limited to only small numbers of NHPs. To facilitate serologic SFV testing, we developed a WB assay that combines antigens from both SFV(AGM) and SFV(CPZ). The combined-antigen WB (CA-WB) assay was validated with 145 serum samples from 129 NHPs (32 African and Asian species) and 16 humans, all with known SFV infection status determined by PCR. Concordant CA-WB results were obtained for all 145 PCR-positive or -negative primate and human specimens, giving the assay a 100% sensitivity and specificity. In addition, no reactivity was observed in sera from persons positive for human immunodeficiency virus or human T cell lymphotropic virus (HIV/HTLV) (n = 25) or HIV/HTLV-negative U.S. blood donors (n = 100). Using the CA-WB assay, we screened 360 sera from 43 Old World primate species and found an SFV prevalence of about 68% in both African and Asian primates. We also isolated SFV from the blood of four seropositive primates (Allenopithecus nigroviridis, Trachypithecus françoisi, Hylobates pileatus, and H. leucogenys) not previously known to be infected with SFV. Phylogenetic analysis of integrase sequences from these isolates confirmed that all four SFVs represent new, distinct, and highly divergent lineages. These results demonstrate the ability of the CA-WB assay to detect infection in a large number of NHP species, including previously uncharacterized infections with divergent SFVs.

Human foamy virus integrase fails to catalyse the integration of a circular DNA molecule containing an LTR junction sequence

The presence of closed circular forms of the linear DNA genome of human foamy virus (HFV) has not been established. The ability of the HFV integrase (IN) to catalyse the integration of these circular forms (termed 2 long terminal repeat (LTR) circles) was investigated, with a view to producing a novel hybrid vector. To this end, a construct was made containing, in addition to the enhanced green fluorescent protein (eGFP) marker gene, the last 27 bp of the 3' U5 LTR region of HFV fused to the first 28 bp of the 5' U3 LTR, the latter representing a 2LTR circle. Marker gene expression following transfection of both 293 and 293T cells indicated that the level of integration was not significantly increased by the HFV IN. Moreover, correctly integrated provirus-like forms of the input plasmid could not be detected by PCR. Taken together, these results show that the HFV IN is not able to integrate a circular molecule containing an LTR junction and, hence, the technique is not exploitable as a tool to produce hybrid vectors for gene therapy.

Mutation of the catalytic domain of the foamy virus reverse transcriptase leads to loss of processivity and infectivity

Foamy virus (FV) replication is resistant to most nucleoside analog reverse transcriptase (RT) inhibitors. In an attempt to create a 2',3'-dideoxy-3'-thiacytidine (3TC)-sensitive virus, the second residue in the highly conserved YXDD motif of simian foamy virus-chimpanzee (human isolate) [SFVcpz(hu)] RT was changed from Val (V) to Met (M). Unexpectedly, the resultant virus, SFVcpz(hu) RT-V313M, replicated poorly, and Met rapidly reverted to Val. Despite the presence of approximately 50% of wild-type RT activity in RT-V313M virions, full-length DNA products were not detected in transfected cells. Using purified recombinant enzymes, we found that the wild-type FV RT is significantly more processive than human immunodeficiency virus type 1 RT. However, the V313M mutant has about 40% of the wild-type level of FV RT activity and has a lower processivity than the wild-type FV enzyme. The V313M mutant RT is also relatively resistant to 3TC. These results suggest that the decrease in RT activity and processivity of FV RT-V313M prevents completion of reverse transcription and greatly diminishes viral replication.

Palindromic sequence plays a critical role in human foamy virus dimerization

The retroviral RNA genome is dimeric, consisting of two identical strands of RNA linked near their 5' ends by a dimer linkage structure. Previously it was shown that human foamy virus (HFV) RNA transcribed in vitro contained three sites, designated SI, SII, and SIII, which contributed to the dimerization process (O. Erlwein, D. Cain, N. Fischer, A. Rethwilm, and M. O. McClure, Virology 229:251-258, 1997). To characterize these sites further, a series of mutants were designed and tested for their ability to dimerize in vitro. The primer binding site and a G tetrad in SI were dispensable for dimerization. However, a mutant that changed the 3' end of SI migrated slower on nondenaturing gels than wild-type RNA dimers. The sequence composition of the SII palindrome, consisting of 10 nucleotides, proved to be critical for in vitro dimerization, since mutations within this sequence or replacement of the sequence with a different palindrome of equal length impaired in vitro dimerization. The length of the palindrome also seems to play an important role. A moderate extension to 12 nucleotides was tolerated, whereas an extension to 16 nucleotides or more impaired dimerization. When nucleotides flanking the palindrome were mutated in a random fashion, dimerization was unaffected. Changing the SIII sequence also led to decreased dimer formation, confirming its contribution to the dimerization process. Interesting mutants were cloned into the infectious molecular clone of HFV, HSRV-2, and were transfected into BHK-21 cells. Mutations in SII that reduced dimerization in vitro also abolished virus replication. In contrast, constructs containing mutations in SI and SIII replicated to some extent in cell culture after an initial drop in viral replication. Analysis of the SIM1 mutant revealed reversion to the wild type but with the insertion of an additional two nucleotides. Analysis of cell-free virions demonstrated that both replication-competent and replication-defective mutants packaged nucleic acid. Thus, efficient dimerization is a critical step for HFV to generate infectious virus, but HFV RNA dimerization is not a prerequisite for packaging.

Characterization of peptide substrates and viral enzyme that affect the cleavage site specificity of the human spumaretrovirus proteinase

Oligopeptides that correspond to proteolytic cleavage site junctions of the native Gag and Pol proteins are specifically cleaved by retroviral aspartate proteases (PRs). The role of the flap subdomain of the PR of the human spumaretrovirus (HSRV) and of substrate peptides in cleavage site specificity was analyzed by site-directed mutagenesis. Native and mutant peptides were subjected to proteolysis by the authentic and mutated recombinant viral enzyme. The results reveal that Glu residue 54 of the HSRV PR is an essential specificity determinant for proteolytic processing of the structural proteins. Peptides that represent in vivo cleavage sites were susceptible to proteolysis by the recombinant HSRV PR, but one peptide located at the junction between the PR and reverse transcriptase domains was completely resistant to cleavage. Thus the data indicate that a proteolytic cleavage between these domains does not occur in vivo. Naturally occurring and mutant forms of the cleavage-resistant peptide were therefore analyzed by circular dichroism to determine if differences existed in the secondary structures of the peptides that did or did not serve as substrates. The data show that differences in the secondary structure of the native and mutant peptides analyzed does not seem to play a crucial role for cleavage site specificity in HSRV PR. Instead highly conserved hydrophobic residues at distinct positions of the HSRV cleavage site junctions contribute to the specificity observed as reported for HIV-1 PR.

Primate foamy virus Pol proteins are imported into the nucleus

Mouse monoclonal antibodies (MAbs) that specifically detect the 127 kDa Pol precursor and the 85 kDa reverse transcriptase/RNase H (RT/RN) or pr127 and the 40 kDa integrase (IN) in immunoblot and immunofluorescence assays (IFA) were used to investigate the subcellular localization of primate foamy virus (PFV) proteins. IFA of cells infected with PFV using the anti-Pol MAbs and rabbit anti-capsid (Gag) serum revealed that both the Gag and Pol proteins are transported into the nucleus. Transfection of cells with eukaryotic expression constructs for pr127(Pol), p85(RT/RN) and p40(IN) served to show Gag-independent subcellular localization of Pol proteins. Interestingly, not only the Pol precursor and IN molecules were found to be localized to the nucleus, but also the RT/RN subdomain. It is therefore suggested that PFV cores bear at least three separate nuclear localization signals, one in Gag and two in Pol. The latter appear to be localized to the two Pol subdomains.

An active foamy virus integrase is required for virus replication

Foamy viruses (FVs) make use of a replication strategy which is unique among retroviruses and shows analogies to hepadnaviruses. The presence of an integrase (IN) and obligate provirus integration distinguish retroviruses from hepadnaviruses. To clarify whether a functional IN is required for FV replication, a mutant in the highly conserved DD35E motif of the active centre was analysed. This mutant was found to be able to express Gag and Pol protein precursors and cleavage products and to generate and deliver cDNA. However, this mutant was replication-deficient. The junctions of individual foamy proviruses with cellular DNA were sequenced. The findings suggest that FV integration is asymmetrical, because the proviruses started with what is believed to be the U3 end of the free linear DNA to generate the conventional TG dinucleotide, while apparently two nucleotides from the U5 end were cleaved to create the complementary CA dinucleotide. Alignment of known FV genome sequences indicated that this mechanism of integration is not restricted to the two FV isolates from which integrates were studied, but appears to be a common feature of this retrovirus subfamily. In conclusion, with respect to the necessity of a functionally active IN for virus replication FVs behave like other retroviruses; their mechanism of integration, however, is probably unique.

Comparison of enzymatic activities of the HIV-1 and HFV integrases to their U5 LTR substrates

The human immunodeficiency virus type 1 (HIV-1) and human foamy virus (HFV) integrase proteins were overexpressed in Escherichia coli, and purified to a near homogeneity by one- or two-step purification scheme. The endonucleolytic, integration, and disintegration activities for the HIV-1 and HFV integrases were characterized in vitro. The endonucleolytic activities for the HIV-1 and HFV integrases were found only on their own substrates, respectively, indicating that the cognate U5 LTR sequences in the substrates is critical for specific cleavage. However, the integration and disintegration activities showed less specificity on the substrate usage. Our results suggest that the disintegration activity have more preference for substrates based on Y-shaped structure rather than on viral donor DNA sequence.

Molecular characterization of proteolytic processing of the Pol proteins of human foamy virus reveals novel features of the viral protease

Spumaviruses, or foamy viruses, express a pol-specific transcript that codes for a Pol polyprotein that consists of the protease, reverse transcriptase, ribonuclease H, and the integrase domains. To delineate the proteolytic cleavage sites between the Pol subdomains, recombinant human foamy virus (HFV) Pol proteins were expressed, purified by affinity chromatography, and subjected to either HFV protease assays or autocatalytic processing. In control experiments, HFV protease-deficient mutant proteins in which the active site Asp was replaced by an Ala residue were used to rule out unspecific processing by nonviral proteases. Specific proteolytic cleavage products were isolated, and the cleavage sites were analyzed by amino acid sequencing. Peptides spanning the resulting cleavage sites were chemically synthesized and assayed with HFV protease, and the cleaved peptides were subjected to mass spectrometry. The cleavage site sequences obtained were in complete agreement with the amino-terminal sequences from amino acid sequencing of authentic cleavage products of the HFV Pol proteins. Analysis by fast-protein liquid chromatography of a short version of the active HFV protease revealed that the enzyme predominantly formed dimeric molecules.

Expression and molecular characterization of an enzymatically active recombinant human spumaretrovirus protease

The human foamy virus (HFV) protease (PR) was cloned into a modified thioredoxin fusion vector that carried a His-tag in the centrally located surface loop of the E. coli trxA protein, bacterially expressed as a soluble fusion protein, and subsequently purified by affinity chromatography. By using HFV Gag protein substrates, the purified recombinant HFV PR was enzymatically active whereas the corresponding active site PR mutant Asp/Ala was inactive. Incubation of synthetic peptides containing residues that flank the putative cleavage site with the recombinant HFV PR and subsequent matrix-assisted laser desorption ionization mass spectrometry of the cleavage products identified the proteolytic processing site of the HFV Gag precursor p74 and revealed that the peptide sequence RAVNTVTQ was cleaved between the Asn and Thr bond.

Expression of human foamy virus reverse transcriptase involves a spliced pol mRNA

In human foamy virus (HFV) the reverse transcriptase is expressed independently of the Gag protein as a 127-kDa Pol precursor molecule. Evaluating the mechanism of Pol expression we identified a spliced mRNA which uses the main 5' splice donor and a splice acceptor site located in the gag gene. The significance of this spliced transcript for HFV Pol expression was studied by constructing a virus with a mutated splice acceptor site. This virus was unable to express detectable Pol proteins after transient transfection. Replication of the mutant was studied by a sensitive assay based on HFV transactivator-stimulated expression of an integrated lacZ gene under control of the HFV long terminal repeat. Whereas in the first 2 weeks after transfection the mutant replicated 3 to 5 order of magnitude less well than wild-type virus, extracellular titers obtained thereafter were similar to those of wild-type virus. This increase in replication competence was accompanied by a reversion of the mutated splice acceptor site. The results underlined the importance of the spliced pol transcript for HFV replication and pointed to a second mechanism of Pol expression. Indicator gene assays suggest that this other mechanism is likely to be a transactivator-dependent cryptic promoter in the gag gene which gives rise to Pol-encoding transcripts.

Active foamy virus proteinase is essential for virus infectivity but not for formation of a Pol polyprotein

To analyze proteolytic processing of foamy (spuma) retroviruses, two mutations were generated in the presumed active-site triplet Asp-Ser-Gly in the predicted proteinase (PR) region of the human foamy virus (HSRV). The mutations changed either the presumed catalytic aspartic acid residue to a catalytically incompetent alanine or the adjacent serine to a threonine found in most cellular and retroviral proteases at this position. Both mutations were cloned into the full-length infectious HSRV DNA clone. Wild-type and S/T mutant genomes directed the synthesis of particles with similar infectious titers, while the HSRV D/A PR mutant was noninfectious. Immunoblot analysis of transfected cells revealed identical patterns for the wild-type and for the S/T PR mutant. HSRV D/A mutant-transfected cells expressed only a single Gag polyprotein of 78 kDa instead of the 78-kDa-74-kDa doublet found in HSRV-infected or wild-type-transfected cells. Analysis with pol-specific antisera yielded a protein of approximately 120 kDa reactive with antisera against pol- but not gag-specific domains. No Gag-Pol polyprotein was detected in this study. Electron microscopy analysis of transfected cells showed heterogeneous particle morphology in the case of the D/A mutant, with particles of normal appearance and particles of aberrant size and shape. These results indicate that foamy viruses have an aspartic PR that is essential for infectivity but not for formation of the 120-kDa Pol polyprotein.

Molecular biological characterization of the human foamy virus reverse transcriptase and ribonuclease H domains

Foamy viruses form a separate group of retroviruses encoding a pol protein with at least four domains based on comparative sequence alignments. The polymerase and ribonuclease H domains of the human foamy virus (HFV) pol gene were expressed in Escherichia coli either individually or in combination. The histidine-tagged HFV fusion proteins were subsequently purified to near homogeneity by affinity Ni2+ chelate column chromatography. The polymerase and RNase H activities were characterized by performing conventional DNA polymerase and ribonuclease H assays and in situ gel assays. Six purified recombinant HFV proteins were enzymatically active either individually as DNA polymerase and ribonuclease H or as combined domains. The HFV enzymatic activities were characterized with respect to cation preferences and pH optima. Western blots with antibodies against the RNase H domain, in situ reverse transcriptase (RT), and RNase H gel assays showed that in HFV-infected cells pol proteins of 120 and 80 kDa were detectable. A novel activity band of 60 kDa was found in situ RT gel assays. Recombinant RNase H protein additionally purified by fast performance liquid chromatography was capable of removing the primer for minus-strand DNA synthesis when labeled tRNA(Lys1,2) model substrates were used. Specific cleavages occurred at the phosphodiester bonds one to three nucleotides 5' of the RNA-DNA junction. The results revealed biochemical properties of the HFV pol gene products that define functional domains of the HFV pol gene that are distinct but comparable to other retroviruses.

Analysis of cross reactivity of retrovirus proteases using a vaccinia virus-T7 RNA polymerase-based expression system

We have used the vaccinia virus-T7 RNA polymerase-based expression system for studies on the activity of proteases from various retroviruses on homologous and heterologous Gag polyproteins in eukaryotic cells. Proteases from human immunodeficiency virus (HIV) types 1 and 2, equine infectious anaemia virus, human T cell leukaemia virus type 1 and human spumavirus were produced and were shown to cleave their cognate Gag substrates produced in trans. Analysis of cross reactivity revealed that lentivirus proteases cleaved only lentivirus Gag proteins and oncovirus proteases acted primarily on oncovirus Gag proteins. The HIV-2 protease cleaved the HIV-1 Gag precursor almost as efficiently as HIV-1 protease. Expression of the 5' end of the human spumavirus pol gene revealed that it encodes a functional protease that acts specifically on the human spumavirus Gag polyprotein. This assay will allow further investigation on the activity and specificity of retrovirus proteases in eukaryotic cells.

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.

Characterization of the human spuma retrovirus integrase by site-directed mutagenesis, by complementation analysis, and by swapping the zinc finger domain of HIV-1

The human spuma retrovirus or foamy virus integrase (HFV IN) is an enzymatically active protein consisting of domains similar to other retroviral integrases: an amino-terminal HH-CC finger, a centrally located region with the conserved D, D-35-E protein motif required for catalytic activity and oligomerization, and at least one DNA binding domain implicated in the 3' DNA processing activity and integrase. Recombinant, purified HFV IN protein carrying 10 histidine residues displays a site-specific endonuclease, an integrase, and a disintegrase activity with oligonucleotide substrates that mimic the viral long terminal repeat (LTR) ends. Site-directed mutagenesis of conserved HFV IN residues of the catalytic domain had increased endonuclease and disintegrase activities. Deletion mutants at both ends of the HFV IN protein were generated, purified, and characterized. Unexpectedly, it was found that the HFV integrase and disintegrase activities require an intact NH2-terminal sequence and that COOH-terminal deletions led to an increase in disintegrase activity. The HH-CC finger of HFV IN was exchanged with that of the human immunodeficiency virus-1 (HIV-1) IN protein. The resulting chimeric IN had a 3' processing activity that utilized the HFV LTR instead of the HIV LTR, indicating that the central domain is crucial for substrate recognition. Functional complementation of the amino-terminal deletion mutant of HFV IN was achieved by a carboxyl-terminal deletion mutant of the chimeric IN, resulting in high levels of integrase activity.

Endonucleolytic cleavages and DNA-joining activities of the integration protein of human foamy virus

The bacterial expression plasmids, pET3b and pET16b, that contain the integrase domain of the human foamy virus (HFV) reverse transcriptase were constructed and expressed in Escherichia coli. The histidine-tagged HFV IN protein was purified to near homogeneity by single-step Ni2+ chelate affinity chromatography. HFV-specific proteins of 39 and 120 kDa from virus-infected cells reacted with antisera raised against the recombinant IN protein. Purified recombinant HFV IN protein was active as an endonuclease specifically cleaving two nucleotides from a 20-bp oligodeoxynucleotide substrate that mimics the authentic 5' ends of HFV DNA. Substrates with mutations relatively close to the cleavage site were less efficiently cleaved or not cleaved at all compared with the HFV U5 DNA end. The purified recombinant protein was active as integrase with double-stranded oligodeoxynucleotide substrates. The reverse reaction of DNA strand transfer, the disintegration activity, was shown by efficient cleavage of an intermediate Y-shaped oligodeoxynucleotide. In the presence of Mn2+ as the preferred divalent cation, oligodeoxynucleotides were specifically and efficiently cleaved. In contrast, endonucleolytic cleavages in the presence of Mg2+ ions led to a broad range of reaction products with the His-tagged HFV IN protein. After further purification of the HFV IN by cation-exchange chromatography, the unspecific degradation of oligonucleotide substrate in the presence of Mg2+ was not detectable.

Effects of human recombinant alpha and gamma and of highly purified natural beta interferons on simian Spumavirinae prototype (simian foamy virus 1) multiplication in human cells

The present study demonstrates the inhibitory effect of human recombinant interferons (r-Hu-IFN) alpha and gamma, and that of highly purified natural human interferon beta on the replication of simian foamy virus type 1 (SFV1) in human AV3-cell cultures. All IFN led to strong inhibition of the SFV1 cytopathic effect. Electron microscopy showed a 70 to 95% decrease in viral particles. Significant inhibition of virus-associated reverse transcriptase activity was found in supernatant fluids of infected IFN-treated cultures. Metabolic labelling of the virus confirmed the inhibition of extracellular release of SFV1. PAGE analysis of immunoprecipitates indicated a reduction in viral-specific protein bands. Altogether, these results indicate that the mechanism of inhibition of Spumavirinae infection by interferon differs from that described for the other Retroviridae, and particularly for types B, C and D viruses. Our data is of therapeutic interest since Spumavirinae have been linked to pathological processes such as de Quervain thyroiditis.

Simultaneous isolation of simian foamy virus and HTLV-III/LAV from chimpanzee lymphocytes following HTLV-III or LAV inoculation

Re-isolation of virus from HTLV-III B and LAV-infected chimpanzee also yielded a simian foamy virus. This virus, replicated in HTLV-III B and LAV-producing H 9 cells, had identical reverse transcriptase activity and caused similar cytopathic effects in H 9 cells.

Characterization of RNase H activity associated with reverse transcriptase in simian foamy virus type 1

Spumavirinae or foamy viruses have been shown to have a characteristic RNA-dependent DNA polymerase activity. We demonstrate here the existence of an RNase H activity that copurifies with the 81-kilodalton monomeric polypeptide, which carries the RNA-dependent DNA polymerase activity of simian foamy virus type 1. RNase H degrades RNA hybrid substrates; however, it does not solubilize single-stranded RNAs. Inactivation assays with heat, high levels of bivalent cations, ethidium bromide, and sodium fluoride suggest that the RNase H catalytic site could be topologically independent from the DNA polymerase catalytic site.

Reverse transcriptase from simian foamy virus serotype 1: purification and characterization

Chromatography on heparin-Sepharose, known for its affinity for nucleotide-binding polypeptides, was used to purify the viral RNA-dependent DNA polymerase (reverse transcriptase) from the core polypeptides of simian foamy virus type 1. This procedure allowed the recovery of highly purified enzyme with a high specific activity. The average molecular weight of this monomeric enzyme is 81,000 and is thus comparable to that found for other known primate retroviruses. Reverse transcriptase activity of simian foamy virus type 1 requires a ribonucleotide template as a primer or otherwise a DNA with 3'-OH ends. Other optimal conditions of activity are reviewed. Heat inactivation studies led to the concept of an enzyme with two loci, one specific for the substrate and the other for the template-primer.

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

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

Reverse transcriptase of foamy virus. Purification of the enzymes and immunological identification

Reverse transcriptase from foamy virus, strain H4188 was estimated and purified. The enzyme has the following characteristics: 1. The reaction utilized preferentially oligo (dT) poly (rA) as a primer-template; however, the synthetic primer-template oligo (dT) poly (dA) could also be used to some extent. 2. The reaction utilized oligo (dG) poly (rC) as a primer-template with very low efficiency. 3. The crude virus preparation had a detectable endogenous reaction using the four deoxyribonucleotides for DNA polymerization. 4. The cation requirement for the enzyme reaction was much more biased for Mn++ than for Mg++ ions. 5. The molecular weight of the partially-purified enzyme was estimated to be about 80,000. Aggregates of 240,000 daltons were also seen. The activity of this enzyme was not inhibited by antisera against the reverse transcriptases of various type C RNA viruses, namely, feline endogenous leukemia virus, RD 114, Woolly simian sarcoma virus (SSV-1) and avian myeloblastosis virus (AMV). Antiserum against Rauscher leukemia virus (RLV) enzyme was marginally active against foamy virus enzyme, perhaps indicating a slight cross-reaction. The biochemical characteristics of foamy virus reverse transcriptase seemed to be very close to those of the type C RNA viruses, but the immunological reaction proved that the foamy virus reverse transcriptase was distinct from the others.

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

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

The foamy viruses

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