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Mutability of DNA polymerase I: Implications for the creation of mutant DNA polymerases [An article from: DNA Repair] | ![Mutability of DNA polymerase I: Implications for the creation of mutant DNA polymerases [An article from: DNA Repair]](http://ecx.images-amazon.com/images/I/51FZ3K9Y7XL._SL160_.jpg)
 enlarge | Authors: E. Loh, L.a. Loeb
Publisher: Elsevier
Buy New: $8.95
Format: Html
Media: Digital
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Product Description
This digital document is a journal article from DNA Repair, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.
Description:
DNA polymerases of the Family A catalyze the addition of deoxynucleotides to a primer with high efficiency, processivity, and selectivity-properties that are critical to their function both in nature and in the laboratory. These polymerases tolerate many amino acid substitutions, even in regions that are evolutionarily conserved. This tolerance can be exploited to create DNA polymerases with novel properties and altered substrate specificities, using rational design and molecular evolution. These efforts have focused mainly on the Family A DNA polymerises -Taq, E. coli Pol I, and T7 - because they are widely utilized in biotechnology today. The redesign of polymerases often requires knowledge of the function of specific residues in the protein, including those located in six evolutionarily conserved regions. The most well characterized of these are motifs A and B, which regulate the fidelity of replication and the incorporation of nucleotide analogs such as dideoxynucleotides. Regions that remain to be more thoroughly characterized are motif C, which is critical for catalysis, and motifs 1, 2 and 6, all of which bind to DNA primer or template. Several recently identified mutants with abilities to incorporate nucleotides with bulky adducts have mutations that are not located within conserved regions and warrant further study. Analysis of these mutants will help advance our understanding of how DNA polymerases select bases with high fidelity.
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