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<p>Abstract</p> <p>Background</p> <p>Foamy viruses (FVs) are the most genetically stable viruses of the retrovirus family. This is in contrast to the <it>in vitro </it>error rate found for recombinant FV reverse transcriptase (RT). To investigate the accuracy of FV genome copying <it>in vivo </it>we analyzed the occurrence of mutations in HEK 293T cell culture after a single round of reverse transcription using a replication-deficient vector system. Furthermore, the frequency of FV recombination by template switching (TS) and the cross-packaging ability of different FV strains were analyzed.</p> <p>Results</p> <p>We initially sequenced 90,000 nucleotides and detected 39 mutations, corresponding to an <it>in vivo </it>error rate of approximately 4 × 10^-4per site per replication cycle. Surprisingly, all mutations were transitions from G to A, suggesting that APOBEC3 activity is the driving force for the majority of mutations detected in our experimental system. In line with this, we detected a late but significant APOBEC3G and 3F mRNA by quantitative PCR in the cells. We then analyzed 170,000 additional nucleotides from experiments in which we co-transfected the APOBEC3-interfering foamy viral <it>bet </it>gene and observed a significant 50% drop in G to A mutations, indicating that APOBEC activity indeed contributes substantially to the foamy viral replication error rate <it>in vivo</it>. However, even in the presence of Bet, 35 out of 37 substitutions were G to A, suggesting that residual APOBEC activity accounted for most of the observed mutations. If we subtract these APOBEC-like mutations from the total number of mutations, we calculate a maximal intrinsic <it>in vivo </it>error rate of 1.1 × 10^-5per site per replication. In addition to the point mutations, we detected one 49 bp deletion within the analyzed 260000 nucleotides.</p> <p>Analysis of the recombination frequency of FV vector genomes revealed a 27% probability for a template switching (TS) event within a 1 kilobase (kb) region. This corresponds to a 98% probability that FVs undergo at least one additional TS event per replication cycle. We also show that a given FV particle is able to cross-transfer a heterologous FV genome, although at reduced efficiency than the homologous vector.</p> <p>Conclusion</p> <p>Our results indicate that the copying of the FV genome is more accurate than previously thought. On the other hand recombination among FV genomes appears to be a frequent event.</p>