Vandana Purohit Basu scite author profile

We have developed a FRET-based assay for the fingers-closing conformational transition that occurs when a binary complex of DNA polymerase I (Klenow fragment) with a primer-template binds a complementary dNTP and have used this and other fluorescence assays to place the fingers-closing step within the reaction pathway. Because the rate of fingers-closing was substantially faster than the rate of nucleotide incorporation measured in chemical quench experiments, fingers-closing cannot be the ratelimiting prechemistry step defined by earlier kinetic studies. Experiments using Ca 2+ instead of Mg 2+ as the metal cofactor suggest instead that the prechemistry step may involve a change in metal ion occupancy at the polymerase active site. The use of ribonucleotide substrates shows there is a base discriminating step that precedes fingers-closing. This earlier step, detected by 2-AP fluorescence, is promoted by complementary nucleotides (ribo-as well as deoxyribo-) but is blocked by mismatches. The complementary rNTP blocks the subsequent fingers-closing step. Thus, discrimination against rNTPs occurs during the transition from open to closed conformations, whereas selection against mismatched bases is initiated earlier in the pathway, in the open complex. Mismatched dNTPs accelerate DNA release from the polymerase, suggesting the existence of an early intermediate in which DNA binding is destabilized relative to the binary complex; this could correspond to a conformation that allows an incoming dNTP to preview the template base. The early kinetic checkpoints identified by this study provide an efficient mechanism for the rejection of mismatched bases and ribose sugars and thus enhance polymerase throughput.

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Strand transfer events during HIV-1 reverse transcription

Basu

et al. 2008

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Proximity and Branch Migration Mechanisms in HIV-1 Minus Strand Strong Stop DNA Transfer

Song

Basu

Hanson

et al. 2008

Journal of Biological Chemistry

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Human immunodeficiency virus type 1 minus strand transfer was measured using a genomic donor-acceptor template system in vitro. Donor RNA D199, having the minimum region required for minus strong stop DNA synthesis, was previously shown to transfer with 35% efficiency to an acceptor RNA representing the 3 repeat region. Donor D520, having an additional 321-nucleotide segment extending into gag, transferred at 75% efficiency. In this study each transfer step was analyzed to account for the difference. Measurement of terminal transfer indicated that the 3 terminus of the cDNA generated using D520 is more accessible for transfer than that of D199. Nevertheless, acceptor competition experiments demonstrated that D520 has a greater preference for invasion-driven versus terminal transfer than D199. Competition mapping showed that the base of the transactivation response element is the primary invasion site for D520, important for efficient acceptor invasion. Acceptors complementary to the invasion and terminal transfer sites, but not the region between, allowed assessment of the significance of hybrid propagation by branch migration. These bipartite acceptors showed that with D520, invasion raises the local concentration of the acceptor for efficient terminal transfer by a proximity effect. However, with D199, invasion is relatively inefficient, and the cDNA 3 terminus is not very accessible. For most transfers that occurred, the acceptor accessed the cDNA 3 end by branch migration. Results suggest that both proximity and branch migration mechanisms contribute to transfers, with the proportion determined by donor-cDNA structure. D520 transfers better because it has greater accessibility for both invasion and terminus transfer.

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