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Conformational dynamics during high-fidelity DNA replication and translocation defined using a DNA polymerase with a fluorescent artificial amino acid

Tyler L. Dangerfield, Kenneth A. Johnson

2020Journal of Biological Chemistry22 citationsDOIOpen Access PDF

Abstract

) is much slower than chemistry. These parameters show that the conformational change selects a correct nucleotide for incorporation through an induced-fit mechanism. We also measured conformational changes occurring after chemistry and during pyrophosphorolysis, providing new insights into processive polymerization. Pyrophosphorolysis occurs via a conformational selection mechanism as the pyrophosphate binds to a rare pretranslocation state of the enzyme-DNA complex. Global data fitting was achieved by including experiments in the forward and reverse directions to correlate conformational changes with chemical reaction steps. This analysis provided well-constrained values for nine rate constants to establish a complete free-energy profile including the rates of DNA translocation during processive synthesis. Translocation does not follow Brownian ratchet or power stroke models invoking nucleotide binding as the driving force. Rather, translocation is rapid and thermodynamically favorable after enzyme opening and pyrophosphate release, and it appears to limit the rate of processive synthesis at 4 °C.

Topics & Concepts

DNA polymeraseDNADNA replicationReplication (statistics)FluorescenceDynamics (music)Chromosomal translocationPolymeraseBiophysicsComputational biologyBiologyCell biologyChemistryMolecular biologyGeneticsPhysicsGeneVirologyOpticsAcousticsDNA Repair MechanismsDNA and Nucleic Acid ChemistryBacterial Genetics and Biotechnology
Conformational dynamics during high-fidelity DNA replication and translocation defined using a DNA polymerase with a fluorescent artificial amino acid | Litcius