Foamy viruses (FVs) are retroid viruses which use a replication strategy unlike those of other retroviruses and hepadnaviruses (S. F. Yu, D. N. Baldwin, S. R. Gwynn, S. Yendapilli, and M. L. Linial, Science 271:1579-1582, 1996). One of the striking differences between FVs and retroviruses is the presence of large amounts of linear genome-length DNA in FV-infected cells and in virions. We report here that large quantities of genome-length linear FV DNA accumulate in cells infected with FV, as determined by Southern blotting. To determine whether these unintegrated virus DNAs result solely from superinfection, we analyzed the occurrence of virus cDNA of the so-called human FV isolate (HFV) in cells transfected with a virus mutant deficient in the envelope gene and in cells which are resistant to superinfection due to stable expression of the envelope protein. We show that the synthesis of viral cDNA is independent of superinfection and that HFV synthesizes cDNA intracellularly as a late event in the replication cycle. To further confirm this finding, we performed inhibition studies with the reverse transcriptase inhibitor zidovudine (AZT). While AZT had no effect or only a minor effect on virus titers when added to cells prior to virus infection, viral titers were reduced by 3 or 4 orders of magnitude when the virus was produced from cells in the presence of AZT. Our results are most compatible with the hypothesis that the functional nucleic acid of the extracellular HFV consists of largely double-stranded linear DNA.
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.
The foamy virus (FV) subgroup of Retroviridae reverse transcribe their RNA (pre-)genome late in the replication cycle before leaving an infected cell. We studied whether a marker gene-transducing FV vector is able to shuttle to the nucleus and integrate into host cell genomic DNA. While a potential intracellular retrotransposition of vectors derived from other retroviruses was below the detection limit of our assay, we found that up to 5% of cells transfected with the FV vector were stably transduced, harboring 1 to~10 vector integrants. Generation of the integrants depended on expression of functional capsid, reverse transcriptase and integrase proteins, and did not involve an extracellular step. PCR analysis of the U3 region of the 5¢ long terminal repeat and determination of proviral integration sites showed that a reverse transcription step had taken place to generate the integrants. Co-expression of a mutated envelope allowing particle egress and avoiding extracellular infection resulted in a signi®cantly increased rescue of cells harboring integrants, suggesting that accumulation of proviruses via intracellular retrotransposition represents an integral part of the FV replication strategy.
The Gag protein of human foamy virus (HFV) lacks Cys-His boxes present in the nucleocapsid (NC) domains of other retroviruses; instead it contains three glycine-arginine-rich motifs (GR boxes). We have expressed the carboxyl end of HFV Gag containing the GR boxes (the NC domain equivalent) and analyzed its nucleic acid binding properties. Our results show that the NC domain of HFV Gag binds with high affinity to both RNA and DNA, in a sequence-independent manner, as determined by filter binding assays. Analysis of a mutant containing a heterologous sequence in place of GR box I indicates that this motif is required for nucleic acid binding and for viral replication. A mutant in GR box II still binds to RNA and DNA in vitro, but virus containing this mutation does not replicate and no nuclear staining of the Gag protein is found in transfected cells. Surprisingly, a revertant from this mutant that completely lacks GR box II and exhibits very little nuclear transport of Gag can readily replicate in tissue culture. This finding thus provides a direct evidence that although the sequences in GR box II can serve as a nuclear transport signal, they are not required for HFV replication and it is unlikely that nuclear localization of Gag protein plays any critical role during viral infection. Taken together, our results suggest that the Gag protein of HFV may be more analogous to the core protein of the hepatitis B virus family than to conventional retroviral Gag protein.
Foamy viruses (FVs) express the Gag protein as a precursor with a molecular mass of 74 kDa (pr74) from which a 70-kDa protein (p70) is cleaved by the viral protease. To gain a better understanding of FV Gag protein processing and function, we have generated and analyzed mutants in the C-terminal gag region of an infectious molecular clone. Our results show that p70 is an N-terminal cleavage product of pr74. However, we were unable to identify a p4 molecule. A virus mutant expressing p70 only was found to be replication competent, albeit at very low titers compared to those of wild-type virus. A strong tendency to synthesize and cleave a pr74 molecule was deduced from the occurrence of revertants upon transfection of this mutant. Substitution of the p6 gag domain of human immunodeficiency virus type 1 for the p4 domain of FV resulted in a stable chimeric virus which replicated to titers 10 times lower than those of wild-type virus. FV Gag protein was found to be phosphorylated at serine residues. Mutagenesis of serines conserved in the p4 domain had no influence on viral replication in cell culture. The p70/p74 Gag cleavage was found to be required for viral infectivity, since mutagenesis of the putative cleavage site led to replication-incompetent virus. Interestingly, the cleavage site mutants were defective in the intracellular cDNA synthesis of virion DNA, which indicates that correct FV particle formation and the generation of virion DNA are functionally linked.
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