We are attempting to understand the processes required to accurately replicate the repetitive DNA sequences whose instability is associated with several human diseases. Here we test the hypothesis that the contribution of exonucleolytic proofreading to frameshift fidelity during replication of repetitive DNA sequences diminishes as the number of repeats in the sequence increases. The error rates of proofreading-proficient T7, T4, and Pyrococcus furiosis DNA polymerases are compared to their exonuclease-deficient derivatives, for +1 and -1 base errors in homopolymeric repeat sequences of three to eight base pairs. All three exonuclease-deficient polymerases produce frameshift errors during synthesis at rates that increase as a function of run length, suggesting the involvement of misaligned intermediates. Their wild-type counterparts are all much more accurate, suggesting that the majority of the intermediates are corrected by proofreading. However, the contribution of the exonuclease to fidelity decreases substantially as the length of the homopolymeric run increases. For example, the exonuclease enhances the frameshift fidelity of T7 DNA polymerase in a run of three A.T base pairs by 160-fold, similar to its contribution to base substitution fidelity. However, in a run of eight consecutive A.T base pairs, the exonuclease only enhances frameshift fidelity by 7-fold. A similar pattern was observed with T4 and Pfu DNA polymerases. Thus, both polymerase selectivity and exonucleolytic proofreading efficiency are diminished during replication of repetitive sequences. This may place an increased relative burden on post-replication repair processes to reduce rates of addition and deletion mutations in organisms whose genome contains abundant simple repeat DNA sequences.
Triplet repeat sequence instability is associated with hereditary neurological diseases and with certain types of cancer. Here we study one form of this instability, deletion of triplet repeats during replication of template (CAG)(n)sequences by DNA polymerases. To monitor loss of triplet codons, we inserted (CAG)(9)and (CAG)(17)repeats into the lacZ sequence in M13mp2 and changed one repeat to a TAG codon to yield DNA substrates with colorless plaque phenotypes. Templates containing these inserts within gaps were copied and errors were scored as blue plaque Lac revertants whose DNA was sequenced to determine if loss of the TAG codon resulted from substitutions or deletions. DNA synthesis by either DNA polymerase beta or exonuclease-deficient T7 DNA polymerase produced deletions involving loss of from 1 to 8 of 9 or 15 of 17 repeats. Thus, these polymerases utilize misaligned template-primers containing from 3 to 45 extra template strand nucleotides. Deletion frequencies were much higher than substitution frequencies at the TAG codon in certain repeats, indicating that triplet repeats are at high risk for mutation in the absence of error correction. Proofreading-proficient T7 DNA polymerase generated deletions at 2- to 10-fold lower frequencies than did its exonuclease-deficient derivative. This suggests that misaligned triplet repeat sequences are subject to proofreading, but at reduced efficiency compared to editing of single-base mismatches.
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