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Journal home Advance online publication Current issue Archive Press releases Supplements Focuses Conferences Guide to authors Online submission Permissions For referees Free online issue Contact the journal Subscribe Advertising work@npg naturereprints About this site For librarians   NPG Resources Bioentrepreneur Nature Reviews Drug Discovery Nature Nature Medicine Nature Genetics Nature Reviews Genetics Nature Methods Nature Chemical Biology news@nature.com Clinical Pharmacology & Therapeutics Nature Conferences NPG Subject areas Biotechnology Cancer Chemistry Clinical Medicine Dentistry Development Drug Discovery Earth Sciences Evolution & Ecology Genetics Immunology Materials Science Medical Research Microbiology Molecular Cell Biology Neuroscience Pharmacology Physics Browse all publications Article Nature Biotechnology  19, 1047 - 1052 (2001) doi:10.1038/nbt1101-1047 Alteration of Cre recombinase site specificity by substrate-linked protein evolution Frank Buchholz1 & A. Francis Stewart2 1  Hooper Research Foundation, University of California San Francisco (UCSF), 513 Parnassus Ave., San Francisco, CA 94143-0552, USA. 2  Genomics, Technische Universität Dresden, c/o MPI-CBG, Pfotenhauerstr. 108, 01307 Dresden, Germany. Correspondence should be addressed to Frank Buchholz fraenk@itsa.ucsf.eduDirected molecular evolution was applied to generate Cre recombinase variants that recognize a new DNA target sequence. Cre was adapted in a three-stage strategy to evolve recombinases to specifically recombine the new site. This complex multicycle task was made feasible by an improved directed-evolution procedure that relies on placing the recombination substrate next to the recombinase coding region. Consequently, those DNA molecules carrying the coding region for a successful recombinase are physically marked by the action of that recombinase on the linked substrate and are easily retrieved from a large background of unsuccessful candidates by PCR amplification. We term this procedure substrate-linked protein evolution (SLiPE). The method should facilitate the development of new recombinases and other DNA-modifying enzymes for applications in genetic engineering, functional genomics, and gene therapy.  Top Abstract Previous | Next Table of contents Full text Download PDF Send to a friend Save this link Open Innovation Challenges Protect Enzyme from In Planta Degradation Deadline: Jul 15 2009 Reward: $20,000 USD A proposal for stable expression of an enzyme in corn seed is desired. Fast Growth of Transformed Soybean Shoots Deadline: Jul 15 2009 Reward: $10,000 USD A method for accelerating growth of soybean shoots is desired. More Challenges Powered by: nature jobs Organic Chemistry & Chemical Biology Indian Institute of Chemical Biology Kolkata India Postdoctoral Fellowship University of Chicago Chicago, Illinois, USA More science jobs Post a job for free Figures & Tables Export citation Search buyers guide:   ADVERTISEMENT

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