Abstract
Replicative DNA polymerases use a complex, multistep mechanism for efficient and accurate DNA replication as uncovered by intense kinetic and structural studies. Recently, single-molecule fluorescence spectroscopy has provided new insights into real time conformational dynamics utilized by DNA polymerases during substrate binding and nucleotide incorporation. We have used single-molecule Förster resonance energy transfer techniques to investigate the kinetics and conformational dynamics of Sulfolobus solfataricus DNA polymerase B1 (PolB1) during DNA and nucleotide binding. Our experiments demonstrate that this replicative polymerase can bind to DNA in at least three conformations, corresponding to an open and closed conformation of the finger domain as well as a conformation with the DNA substrate bound to the exonuclease active site of PolB1. Additionally, our results show that PolB1 can transition between these conformations without dissociating from a primer-template DNA substrate. Furthermore, we show that the closed conformation is promoted by a matched incoming dNTP but not by a mismatched dNTP and that mismatches at the primer-template terminus lead to an increase in the binding of the DNA to the exonuclease site. Our analysis has also revealed new details of the biphasic dissociation kinetics of the polymerase-DNA binary complex. Notably, comparison of the results obtained in this study with PolB1 with those from similar single-molecule studies with an A-family DNA polymerase suggests mechanistic differences between these polymerases. In summary, our findings provide novel mechanistic insights into protein conformational dynamics and substrate binding kinetics of a high fidelity B-family DNA polymerase.
Highlights
DNA polymerases use a multistep mechanism to faithfully replicate DNA
Multiple Conformational States Occur during DNA Binding— To investigate the dynamic interactions between polymerase B1 (PolB1) and a DNA substrate at the single-molecule level, we designed a Forster resonance energy transfer (FRET) system suitable for PolB1 by (i) starting with the previously characterized PolB1 exoϪ mutant, which has the three exonuclease active site residues (Asp-231, Glu-233, and Asp318) replaced with alanine to eliminate complications in data analysis due to the strong 3Ј 3 5Ј exonuclease activity of PolB1 [6], (ii) substituting three native cysteine residues (Cys-67, Cys538, and Cys-556) with serine to allow for introduction of a unique labeling site, and (iii) engineering a Ser to Cys substitution at position 588, a surface residue at the tip of the finger domain that would be accessible for attaching a Cy5 acceptor fluorophore
A primer extension assay showed that the PolB1 mutant (S588C, C67S, C538S, C556S, D231A, E233A, and D318A) containing the single cysteine for labeling retained a high level of DNA polymerase activity
Summary
DNA polymerases use a multistep mechanism to faithfully replicate DNA. Results: Replicative DNA polymerase PolB1 binds DNA in multiple conformations that are affected by nucleotide or mismatched DNA binding. Biochemical and biophysical studies have elucidated many details of the kinetic mechanism of nucleotide incorporation catalyzed by high fidelity DNA polymerases [1,2,3,4,5,6,7,8,9,10]. These studies have provided evidence for multiple checkpoints in the process of nucleotide selection [11]. The exonuclease activity is contained in a separate structural domain, and binding of a DNA primer containing 3Ј-mismatched nucleotide(s) to the exonuclease active site requires partial melting from the template strand and a repositioning of the duplex DNA [12, 23,24,25]
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