Complementarity between RNA dimerization elements favors formation of functional heterozygous murine leukemia viruses

Effects of identity minimization on Moloney murine leukemia virus template recognition and frequent tertiary template-directed insertions during nonhomologous recombination

Homology requirements for Moloney murine leukemia virus recombination were addressed in this study by monitoring titer defects observed when acceptor/donor template identity lengths were systematically reduced. Recombination acceptors with at least 16 contiguous bases of donor template identity were recognized as efficiently as longer acceptors. In contrast, a sharp 1-log titer drop was observed for an acceptor of only 15 bases long, with an additional 1-log titer decline for an 8-base acceptor and further decreases for shorter acceptors. Eighty-three independent nonhomologous recombination products were sequenced to examine recombination template selection in the absence of significant sequence identity. These replication products contained a total of 152 nonhomologous crossover junctions. Forced copy choice models predict that forced nonhomologous recombination should result in DNA synthesis to the donor template's 5' end, followed by microidentity-guided acceptor template selection. However, only a single product displayed this structure. The majority of examined nonhomologous recombination products contained junction-associated sequence insertions. Most insertions resulted from the use of one or more tertiary templates, recognizable as discontiguous portions of viral or host RNA or minus-strand DNA. The donor/acceptor template microidentity evident at most crossovers reconfirmed the remarkable capability of the reverse transcription machinery to recognize short regions of sequence identity. These results demonstrate that recruitment of discontiguous host or viral sequences is a common way for retroviruses to resolve nonhomologous recombination junctions and provide experimental support for the role of splinting templates in the generation of retroviral insertions.

The SL1-SL2 (stem-loop) domain is the primary determinant for stability of the gamma retroviral genomic RNA dimer

Retroviral genomes are assembled from two sense-strand RNAs by noncovalent interactions at their 5' ends, forming a dimer. The RNA dimerization domain is a potential target for antiretroviral therapy and represents a compelling RNA folding problem. The fundamental dimerization unit for the Moloney murine sarcoma gamma retrovirus spans a 170-nucleotide minimal dimerization active sequence. In the dimer, two self-complementary sequences, PAL1 and PAL2, form intermolecular duplexes, and an SL1-SL2 (stem-loop) domain forms loop-loop base pairs, mediated by GACG tetraloops, and extensive tertiary interactions. To develop a framework for assembly of the retroviral RNA dimer, we quantified the stability of and established nucleotide resolution secondary structure models for sequence variants in which each motif was compromised. Base pairing and tertiary interactions between SL1-SL2 domains contribute a large free energy increment of -10 kcal/mol. In contrast, even though the PAL1 and PAL2 intermolecular duplexes span 10 and 16 bp in the dimer, respectively, they contribute only -2.5 kcal/mol to stability, roughly equal to a single new base pair. First, these results emphasize that the energetic costs for disrupting interactions in the monomer state nearly balance the PAL1 and PAL2 base pairing interactions that form in the dimer. Second, intermolecular duplex formation plays a biological role distinct from simply stabilizing the structure of the retroviral genomic RNA dimer.

Co-localization of gammaretroviral RNAs at their transcription site favours co-packaging

A retroviral vector-rescue system in which co-packaging of the two co-expressed vectors is required for transduction of one of the vectors has been established previously. By using this rescue system, two distinct packaging-cell populations have been generated. One cell population expressed retroviral RNA from co-localized transcription sites, resulting in local and overlapping accumulation of both RNA transcripts. In the other cell population, the two transcription cassettes were introduced separately, leading to distinct transcription sites of the two RNAs and no significant co-localization of the RNAs. Titre measurements from the two distinct cell populations showed large differences in rescue titre, which is an indirect measure of co-packaging efficiency. Thus, the cell populations with overlapping RNA accumulation gave rise to 15-80-fold-higher rescue titres than cell populations with non-overlapping RNA accumulation. These data show that the spatial position of proviral transcription sites affects the level of retroviral RNA co-packaging and suggest that there is already a linkage of RNAs for co-packaging at the transcription site. It is hypothesized that this linkage is due to RNA dimerization taking place at the transcription site.