Abstract
The ability of wild type and mutant T4 DNA polymerases to discriminate in the utilization of the base analog 2-aminopurine (2AP) and the fluorescence of 2AP were used to determine how DNA polymerases distinguish between correct and incorrect nucleotides. Because T4 DNA polymerase incorporates dTMP opposite 2AP under single-turnover conditions, it was possible to compare directly the kinetic parameters for incorporation of dTMP opposite template 2AP to the parameters for incorporation of dTMP opposite template A without the complication of enzyme dissociation. The most significant difference detected was in the K(d) for dTTP, which was 10-fold higher for incorporation of dTMP opposite template 2AP (approximately 367 microm) than for incorporation of dTMP opposite template A (approximately 31 microm). In contrast, the dTMP incorporation rate was reduced only about 2-fold from about 318 s(-1) with template A to about 165 s(-1) for template 2AP. Discrimination is due to the high selectivity in the initial nucleotide-binding step. T4 DNA polymerase binding to DNA with 2AP in the template position induces formation of a nucleotide binding pocket that is preshaped to bind dTTP and to exclude other nucleotides. If nucleotide binding is hindered, initiation of the proofreading pathway acts as an error avoidance mechanism to prevent incorporation of incorrect nucleotides.
Highlights
Be an obvious mechanism for determining base pair specificity, this mechanism alone is not adequate
The most significant difference detected was in the Kd for dTTP, which was 10-fold higher for incorporation of dTMP opposite template 2AP (ϳ367 M) than for incorporation of dTMP opposite template A (ϳ31 M)
Results from numerous studies are consistent with the proposal that DNA polymerases discriminate between inserting correct or incorrect nucleotides based on the geometry of the base pair
Summary
Be an obvious mechanism for determining base pair specificity, this mechanism alone is not adequate. Results from numerous studies are consistent with the proposal that DNA polymerases discriminate between inserting correct or incorrect nucleotides based on the geometry of the base pair. Structural studies of nucleotide pre-incorporation complexes formed with several DNA polymerases suggest that DNA polymerases may assess the geometry of the newly forming base pair by “closing down” on the primer-terminal region to make several tight contacts that are in position to distinguish between correct and incorrect base pairs (6 –9). There are at least three potential steps in which the DNA polymerase can assert specificity for the correct base pair (reviewed in Ref. 14): initial dNTP binding, post-binding selection by an induced-fit mechanism, and the chemical step of phosphodiester bond formation (see Fig. 1, Steps 2– 4). Because the T4 DNA polymerase is a member of a large family of protein sequence-related DNA polymerases, including eukaryotic DNA polymerases ␦ and ⑀, studies reported here likely have broad implications in understanding the accuracy of DNA replication in many organisms
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