By using single-molecule multiparameter fluorescence detection, fluorescence resonance energy transfer experiments, and newly developed data analysis methods, this study demonstrates directly the existence of three structurally distinct forms of reverse transcriptase (RT):nucleic acid complexes in solution. Single-molecule multiparameter fluorescence detection also provides first information on the structure of a complex not observed by x-ray crystallography. This species did not incorporate nucleotides and is structurally distinct from the other two observed species. We determined that the nucleic acid substrate is bound at a site far removed from the nucleic acid-binding tract observed by crystallography. In contrast, the other two states are identified as being similar to the x-ray crystal structure and represent distinct enzymatically productive stages in DNA polymerization. These species differ by only a 5-Å shift in the position of the nucleic acid. Addition of nucleoside triphosphate or of inorganic pyrophosphate allowed us to assign them as the educt and product state in the polymerization reaction cycle; i.e., the educt state is a complex in which the nucleic acid is positioned to allow nucleotide incorporation. The second RT:nucleic acid complex is the product state, which is formed immediately after nucleotide incorporation, but before RT translates to the next nucleotide.H IV-1 reverse transcriptase (RT) is a key enzyme in the life cycle of HIV. This multifunctional enzyme is responsible for the complex process of transcribing viral RNA into doublestranded DNA for integration into the host cell genome. The enzyme is a heterodimer composed of subunits which share a common N terminus and have subdomains referred to as fingers, palm, thumb, and connection ( Fig. 1). Although the subdomains of each subunit are structurally similar, the overall folding within the two subunits is quite different (1). The large subunit, p66, contains RNA-and DNA-dependent DNA polymerase as well as RNase H activities. The p51 subunit, which is inactive in the heterodimer but active in homodimers (2, 3), is thought to play a role in stabilizing the conformation of p66.Crystallographic studies of RT:nucleic acid primer͞template (p͞t) complexes have provided valuable insights into the structural features and conformational changes induced by p͞t binding (1, 4-7). To date, these crystallographic models have indicated a single p͞t-binding mode. In contrast, recent solutionbased kinetic studies on p͞t binding and nucleotide incorporation by RT suggest a heterogeneous mixture of several different binding modes (8). To confirm directly the existence of several species, and to obtain structural and functional information about each, we have used single-molecule spectroscopy to investigate RT:p͞t complexes in solution.Single-molecule techniques have proven to be valuable tools for resolving static and dynamic heterogeneity of an ensemble (9-13). For this investigation, we use a newly developed multiparameter fluorescence detection (MF...
Two mutants of HIV-1 reverse transcriptase (RT) associated with high-level resistance of the virus to AZT (RT-AZT: D67N, K70R, T215Y, K219Q, and M41L) or 3-TC (RT-3TC: M184V) were expressed in Escherichia coli and purified. None of these mutants showed significant changes in the affinity and kinetics of binding to a DNA/DNA primer/template. RT-AZT was investigated in detail with respect to its kinetics of incorporation of nucleotides. No change in the relative rates of TMP and AZTMP incorporation could be detected for RT-AZT with respect to wild type RT. These results imply that there is no increased discrimination against AZTTP in the mutant. This was found for DNA/DNA and DNA/RNA primer/template. Additionally, rapid kinetics of incorporation of 3'-amino-3'-deoxythymidine 5'-monophosphate (a possible metabolite of AZT) were investigated and compared with TMP incorporation, but no difference in its relative rates of incorporation between wild type RT and RT-AZT was detected. In contrast, the already very slow rate of incorporation of 3-TCMP seen with wild type enzyme was drastically reduced (by a factor of 23 and 36 with DNA/DNA primer/template and DNA/RNA primer/template, respectively) for RT-3TC, showing a clear correlation between in vitro and in vivo effects. The affinity of 3-TCTP to the RT-3TC-primer/template complex was not affected by the mutation M184V. A 1.6-fold cross-resistance to ddATP, the converted form of the prodrug ddI, could also be shown for RT-3TC, but no cross-resistance to ddCTP was detected. Additionally, rapid kinetics of AZTMP incorporation by RT-3TC were investigated. There was an indication of a slightly higher rate of incorporation of AZTMP by RT-3TC than wild type RT.
Template switching during reverse transcription promotes recombination in retroviruses. Efficient switches have been measured in vitro on hairpin-containing RNA templates by a two-step mechanism. Pausing of the reverse transcriptase (RT) at the hairpin base allowed enhanced cleavage of the initial donor RNA template, exposing regions of the cDNA and allowing the acceptor to base pair with the cDNA. This defines the first or docking step. The primer continued synthesis on the donor, transferring or locking in a second step. Here we determine the enzyme-dependent factors that influence template switching by comparing the RTs from human immunodeficiency virus, type 1 (HIV-1), and equine infectious anemia virus (EIAV). HIV-1 RT promoted transfers with higher efficiency than EIAV RT. We found that both RTs paused strongly at the base of the hairpin. While stalled, HIV-1 RT made closely spaced cuts, whereas EIAV RT made only a single cut. Docking occurred efficiently at the multiply cut but not at the singly cut site. HIV-1 nucleocapsid (NC) protein stimulated strand transfers. It improved RNase H activity of both RTs. It allowed the EIAV RT to make a distribution of cuts, greatly stimulating docking at the base of the hairpin. Most likely, it also promoted strand exchange, allowing transfers to be initiated from sites throughout the hairpin. Minor pause sites beyond the base of the hairpin correlated with the locking sites. The strand exchange properties of NC likely promote this step. We present a model that explains the roles of RNase H specificity, template structure, and properties of NC in the two-step transfer reaction.
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