Quantitative methods to study helicase, DNA polymerase, and exonuclease coupling during DNA replication

• Published in: Methods in enzymology Vol. 672; p. 75
• Main Authors: Singh, Anupam, Patel, Smita S
• Format: Journal Article
• Language: English
• Published: United States 2022
• Subjects: DNA; DNA Helicases - metabolism; DNA Replication; DNA-Directed DNA Polymerase - metabolism; Exonucleases - metabolism; Helicase-polymerase coupling; DNA polymerase; Exonuclease activity; Replicative helicase; Pre-steady state kinetics
• ISSN: 1557-7988
• DOI: 10.1016/bs.mie.2022.03.011

Genome replication is accomplished by highly regulated activities of enzymes in a multi-protein complex called the replisome. Two major enzymes, DNA polymerase and helicase, catalyze continuous DNA synthesis on the leading strand of the parental DNA duplex while the lagging strand is synthesized discontinuously. The helicase and DNA polymerase on their own are catalytically inefficient and weak motors for unwinding/replicating double-stranded DNA. However, when a helicase and DNA polymerase are functionally and physically coupled, they catalyze fast and highly processive leading strand DNA synthesis. DNA polymerase has a 3'-5' exonuclease activity, which removes nucleotides misincorporated in the nascent DNA. DNA synthesis kinetics, processivity, and accuracy are governed by the interplay of the helicase, DNA polymerase, and exonuclease activities within the replisome. This chapter describes quantitative biochemical and biophysical methods to study the coupling of these three critical activities during DNA replication. The methods include real-time quantitation of kinetics of DNA unwinding-synthesis by a coupled helicase-DNA polymerase complex, a 2-aminopurine fluorescence-based assay to map the precise positions of helicase and DNA polymerase with respect to the replication fork junction, and a radiometric assay to study the coupling of DNA polymerase, exonuclease, and helicase activities during processive leading strand DNA synthesis. These methods are presented here with bacteriophage T7 replication proteins as an example but can be applied to other systems with appropriate modifications.