Altering the sequence specificity of HaeIII methyltransferase by directed evolution using in vitro compartmentalization

Altering the sequence specificity of HaeIII methyltransferase by directed evolution using in vitro compartmentalization

Engineering the specificity of DNA‐modifying enzymes has proven extremely challenging, as sequence recognition by these enzymes is poorly understood. Here we used directed evolution to generate a variant of HaeIII methyltransferase that efficiently methylates a novel target site. M.HaeIII methylates...

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Bibliographic Details
Published in:Protein engineering Vol. 17; no. 1; pp. 3 - 11
Main Authors: Cohen, Helen M., Tawfik, Dan S., Griffiths, Andrew D.
Format: Journal Article
Language:English
Published: England Oxford University Press 01-01-2004
Oxford Publishing Limited (England)
Subjects:
Amino Acid Sequence
Catalysis
Cytosine - chemistry
directed evolution/HaeIII methyltransferase/in vitro compartmentalization/sequence specificity/substrate promiscuity
DNA - chemistry
DNA Methylation
DNA-Cytosine Methylases - chemistry
DNA-Cytosine Methylases - genetics
Gene Library
Hydrogen Bonding
Kinetics
Methylation
Methyltransferases - metabolism
Models, Molecular
Molecular Sequence Data
Mutagenesis
Mutation
Oligonucleotides - chemistry
Plasmids - metabolism
Polymerase Chain Reaction
Protein Engineering - methods
Sequence Homology, Amino Acid
Substrate Specificity
Time Factors
compartmentalization/sequence specificity/substrate promiscuity
III methyltransferase
directed evolution
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Summary:Engineering the specificity of DNA‐modifying enzymes has proven extremely challenging, as sequence recognition by these enzymes is poorly understood. Here we used directed evolution to generate a variant of HaeIII methyltransferase that efficiently methylates a novel target site. M.HaeIII methylates the internal cytosine of the canonical sequence GGCC, but there is promiscuous methylation of a variety of non‐canonical sites, notably AGCC, at a reduced rate. Using in vitro compartmentalization (IVC), libraries of M.HaeIII genes were selected for the ability to efficiently methylate AGCC. A two‐step mutagenesis strategy, involving initial randomization of DNA‐contacting residues followed by randomization of the loop that lies behind these residues, yielded a mutant with a 670‐fold improvement in catalytic efficiency (kcat/KmDNA) using AGCC and a preference for AGCC over GGCC. The mutant methylates three sites efficiently (AGCC, CGCC and GGCC). Indeed, it methylates CGCC slightly more efficiently than AGCC. However, the mutant discriminates against other non‐canonical sites, including TGCC, as effectively as the wild‐type enzyme. This study provides a rare example of a laboratory‐evolved enzyme whose catalytic efficiency surpasses that of the wild‐type enzyme with the principal substrate.
Bibliography:local:gzh001
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4To whom correspondence should be addressed. e‐mail: griff@mrc‐lmb.cam.ac.uk
Received September 10, 2003; accepted September 23, 2003 Edited by Greg Winter
ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:1741-0126
0269-2139
1741-0134
DOI:10.1093/protein/gzh001