Your search keyword '"Gloeckner C"' showing total 2 results

1. Learning from directed evolution: Thermus aquaticus DNA polymerase mutants with translesion synthesis activity.

Author

Obeid S, Schnur A, Gloeckner C, Blatter N, Welte W, Diederichs K, and Marx A

Subjects

Directed Molecular Evolution, Models, Molecular, Mutant Proteins chemistry, Mutant Proteins genetics, Mutant Proteins metabolism, Protein Conformation, Taq Polymerase chemistry, Thermus chemistry, DNA Damage, Mutation, Taq Polymerase genetics, Taq Polymerase metabolism, Thermus enzymology, Thermus genetics

Abstract

DNA is being constantly damaged by endo- and exogenous agents such as reactive oxygen species, chemicals, radioactivity, and ultraviolet radiation. Additionally, DNA is inherently labile, and this can result in, for example, the spontaneous hydrolysis of the glycosidic bond that connects the sugar and the nucleobase moieties in DNA; this results in abasic sites. It has long been obscure how cells achieve DNA synthesis past these lesions, and only recently has it been discovered that several specialized DNA polymerases are involved in translesion synthesis. The underlying mechanisms that render one DNA polymerase competent in translesion synthesis while another DNA polymerase fails are still indistinct. Recently two variants of Taq DNA polymerase that exhibited higher lesion bypass ability than the wild-type enzyme were identified by directed-evolution approaches. Strikingly, in both approaches it was independently found that substitution of a single nonpolar amino acid side chain by a cationic side chain increases the capability of translesion synthesis. Here, we combined both mutations in a single enzyme. We found that the KlenTaq DNA polymerase that bore both mutations superseded the wild-type as well as the respective single mutants in translesion-bypass proficiency. Further insights in the molecular basis of the detected gain of translesion-synthesis function were obtained by structural studies of DNA polymerase variants caught in processing canonical and damaged substrates. We found that increased positive charge of the surface potential in the area proximal to the negatively charged substrates promotes translesion synthesis by KlenTaq DNA polymerase, an enzyme that has very limited naturally evolved capability to perform translesion synthesis. Since expanded positively charged surface potential areas are also found in naturally evolved translesion DNA polymerases, our results underscore the impact of charge on the proficiency of naturally evolved translesion DNA polymerases., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

2. Directed DNA polymerase evolution: effects of mutations in motif C on the mismatch-extension selectivity of thermus aquaticus DNA polymerase.

Author

Strerath M, Gloeckner C, Liu D, Schnur A, and Marx A

Subjects

Amino Acid Motifs, Base Sequence, DNA chemistry, Molecular Sequence Data, Polymerase Chain Reaction, Taq Polymerase chemistry, Amino Acids chemistry, DNA genetics, Evolution, Molecular, Mutation genetics, Taq Polymerase genetics, Thermus enzymology

Abstract

The selectivity of DNA polymerases for processing the canonical nucleotide and DNA substrate in favor of the noncanonical ones is the key to the integrity of the genome of every living species and to many biotechnological applications. The inborn ability of most DNA polymerases to abort efficient extension of mismatched DNA substrates adds to the overall DNA polymerase selectivity. DNA polymerases have been grouped into families according to their sequence. Within family A DNA polymerases, six motifs that come into contact with the substrates and form the active site have been discovered to be evolutionary highly conserved. Here we present results obtained from amino acid randomization within one motif, motif C, of thermostable Thermus aquaticus DNA polymerase. We have identified several distinct mutation patterns that increase the selectivity of mismatch extension. These results might lead to direct applications such as allele-specific PCR, as demonstrated by real-time PCR experiments and add to our understanding of DNA polymerase selectivity.

Published

2007