Stephen William Santoro

Directed evolution of the site specificity of Cre recombinase

Cre recombinase from bacteriophage P1 recognizes a 34-bp recombination site, loxP, with exquisite sequence specificity and catalyzes the site-specific insertion, excision, or rearrangement of DNA. To better understand the molecular basis of protein–DNA recognition and generate recombinases with altered specificities, we have developed a directed evolution strategy that can be used to identify recombinases that recognize variant loxP sites. To be selected, members of a library of Cre variants produced by targeted random mutagenesis must rapidly catalyze recombination, in vivo, between two variant loxP sites that are located on a reporter plasmid. Recombination results in an altered pattern of fluorescent protein expression that can be identified by flow cytometry. Fluorescence-activated cell sorting can be used either to screen positively for recombinase variants that recognize a novel loxP site, or negatively for variants that cannot recognize the wild-type loxP site. The use of positive screening alone resulted in a relaxation of recombination site specificity, whereas a combination of positive and negative screening resulted in a switching of specificity. One of the identified recombinases selectively recombines a novel recombination site and operates at a rate identical to that of wild-type Cre. Analysis of the sequences of the resulting Cre variants provides insight into the evolution of these altered specificities. This and other systems should contribute to our understanding of protein–DNA recognition and may eventually be used to evolve custom-tailored recombinases that can be used for gene study and inactivation.

An efficient system for the evolution of aminoacyl-tRNA synthetase specificity

A variety of strategies to incorporate unnatural amino acids into proteins have been pursued, but all have limitations with respect to technical accessibility, scalability, applicability to in vivo studies, or site specificity of amino acid incorporation. The ability to selectively introduce unnatural functional groups into specific sites within proteins, in vivo, provides a potentially powerful approach to the study of protein function and to large-scale production of novel proteins. Here we describe a combined genetic selection and screen that allows the rapid evolution of aminoacyl-tRNA synthetase substrate specificity. Our strategy involves the use of an “orthogonal” aminoacyl-tRNA synthetase and tRNA pair that cannot interact with any of the endogenous synthetase–tRNA pairs in Escherichia coli. A chloramphenicol-resistance (Cmr) reporter is used to select highly active synthetase variants, and an amplifiable fluorescence reporter is used together with fluorescence-activated cell sorting (FACS) to screen for variants with the desired change in amino acid specificity. Both reporters are contained within a single genetic construct, eliminating the need for plasmid shuttling and allowing the evolution to be completed in a matter of days. Following evolution, the amplifiable fluorescence reporter allows visual and fluorimetric evaluation of synthetase activity and selectivity. Using this system to explore the evolvability of an amino acid binding pocket of a tyrosyl-tRNA synthetase, we identified three new variants that allow the selective incorporation of amino-, isopropyl-, and allyl-containing tyrosine analogs into a desired protein. The new enzymes can be used to produce milligram-per-liter quantities of unnatural amino acid–containing protein in E. coli.