New Insights into DNA Polymerase Function Revealed by Phosphonoacetic Acid-Sensitive T4 DNA Polymerases

The bacteriophage T4 DNA polymerase (pol) and the closely related RB69 DNA pol have been, developed into model enzymes to study family B DNA pols. While all family B DNA pols have similar structures and share conserved protein motifs, the molecular mechanism underlying natural drug resistance of nonherpes family B DNA pols and drug sensitivity of herpes DNA pols remains unknown. In the present study, we constructed T4 phages containing G466S, Y460F, G466S/Y460F, P469S, and V475W mutations in DNA pol. These amino acid substitutions replace the residues in drug-resistant T4 DNA pol with residues found in drug-sensitive herpes family DNA pols. We investigated whether the T4 phages expressing the engineered mutant DNA pols were sensitive to the antiviral drug phosphonoacetic acid (PAA) and characterized the in vivo replication fidelity of the phage DNA pols. We found that G466S substitution marginally increased PAA sensitivity, whereas Y460F substitution conferred resistance. The phage expressing a double mutant G 466S/Y460F DNA pol was more PAA-sensitive. V475W T4 DNA pol was highly sensitive to PAA, as was the case with V478W RB69 DNA pol. However, DNA replication was severely compromised, which resulted in the selection of phages expressing more robust DNA pols that have strong ability to replicate DNA and contain additional amino acid substitutions that suppress PAA sensitivity. Reduced replication fidelity was observed in all mutant phages expressing PAA-sensitive DNA pols. These observations indicate that PAA sensitivity and fidelity are balanced in DNA pols that can replicate DNA in different environments.