Flp Variants Research Articles

Target-specific variants of Flp recombinase mediate genome engineering reactions in mammalian cells.

Genome engineering relies on DNA-modifying enzymes that are able to locate a DNA sequence of interest and initiate a desired genome rearrangement. Currently, the field predominantly utilizes site-specific DNA nucleases that depend on the host DNA repair machinery to complete a genome modification task. We show here that genome engineering approaches that employ target-specific variants of the self-sufficient, versatile site-specific DNA recombinase Flp can be developed into promising alternatives. We demonstrate that the Flp variant evolved to recombine an FRT-like sequence, FL-IL10A, which is located upstream of the human interleukin-10 gene, and can target this sequence in the model setting of Chinese hamster ovary and human embryonic kidney 293 cells. This target-specific Flp variant is able to perform the integration reaction and, when paired with another recombinase, the dual recombinase-mediated cassette exchange reaction. The efficiency of the integration reaction in human cells can be enhanced by 'humanizing' the Flp variant gene and by adding the nuclear localization sequence to the recombinase.

Binding and Catalytic Contributions to Site Recognition by Flp Recombinase

Flp catalyzes site-specific recombination in a highly sequence-specific manner despite making few direct contacts to the bases within its binding site. Sequence discrimination could take place in the binding and/or the catalytic steps. In this study, we independently measure the binding affinity and initial cleavage rate of Flp recombinase with approximately 20 designed alternate target DNA sequences. Our results show that Flp specificity is largely, although not entirely, imparted at the binding step and is the result of a combination of direct and indirect readout. The Flp binding site includes an A/T-rich region that displays a characteristically narrow minor groove. We find that many A --> T changes are tolerated at the binding step, whereas C or G substitutions tend to decrease binding affinity. The effects of the latter can be alleviated by replacing guanine with inosine, which removes the N2 amino group that protrudes into the minor groove. Some A --> T changes reduce binding affinity, due to clashing with nearby residues, reinforcing that specificity requires avoiding negative contacts as well as creating positive ones. A tracts, which can lead to unusually rigid DNA structure, are tolerated during the binding step when placed within the region where the minor groove is already narrow. However, most A tracts slow catalysis more than C or G substitutions. Understanding what kind of sequence variation is tolerated in the binding and catalytic steps helps us understand how the target DNA is recognized by Flp and will be useful in guiding the design of Flp variants with altered specificities.

Evolution of variants of yeast site-specific recombinase Flp that utilize native genomic sequences as recombination target sites

As a tool in directed genome manipulations, site-specific recombination is a double-edged sword. Exquisite specificity, while highly desirable, makes it imperative that the target site be first inserted at the desired genomic locale before it can be manipulated. We describe a combination of computational and experimental strategies, based on the tyrosine recombinase Flp and its target site FRT, to overcome this impediment. We document the systematic evolution of Flp variants that can utilize, in a bacterial assay, two sites from the human interleukin 10 gene, IL10, as recombination substrates. Recombination competence on an end target site is acquired via chimeric sites containing mixed sequences from FRT and the genomic locus. This is the first time that a tyrosine site-specific recombinase has been coaxed successfully to perform DNA exchange within naturally occurring sequences derived from a foreign genomic context. We demonstrate the ability of an Flp variant to mediate integration of a reporter cassette in Escherichia coli via recombination at one of the IL10-derived sites.

Recombination of Hybrid Target Sites by Binary Combinations of Flp Variants: Mutations that Foster Interprotomer Collaboration and Enlarge Substrate Tolerance

Strategies of directed evolution and combinatorial mutagenesis applied to the Flp site-specific recombinase have yielded recombination systems that utilize bi-specific hybrid target sites. A hybrid site is assembled from two half-sites, each harboring a distinct binding specificity. Satisfying the two specificities by a binary combination of Flp variants, while necessary, may not be sufficient to elicit recombination. We have identified amino acid substitutions that foster interprotomer collaboration between partner Flp variants to potentiate strand exchange in hybrid sites. One such substitution, A35T, acts specifically in cis with one of the two partners of a variant pair, Flp(K82M) and Flp(A35T, R281V). The same A35T mutation is also present within a group of mutations that rescue a Flp variant, Flp(Y60S), that is defective in establishing monomer–monomer interactions on the native Flp target site. Strikingly, these mutations are localized to peptide regions involved in interdomain and interprotomer interactions within the recombination complex. The same group of mutations, when transferred to the context of wild-type Flp, can relax its specificity to include non-native target sites. The hybrid Flp systems described here mimic the naturally occurring XerC/XerD recombination system that utilizes two recombinases with distinct DNA binding specificities. The ability to overcome the constraints of binding site symmetry in Flp recombination has important implications in the targeted manipulations of genomes.

Recombination of Hybrid Target Sites by Binary Combinations of Flp Variants: Mutations that Foster Interprotomer Collaboration and Enlarge Substrate Tolerance

Strategies of directed evolution and combinatorial mutagenesis applied to the Flp site-specific recombinase have yielded recombination systems that utilize bi-specific hybrid target sites. A hybrid site is assembled from two half-sites, each harboring a distinct binding specificity. Satisfying the two specificities by a binary combination of Flp variants, while necessary, may not be sufficient to elicit recombination. We have identified amino acid substitutions that foster interprotomer collaboration between partner Flp variants to potentiate strand exchange in hybrid sites. One such substitution, A35T, acts specifically in cis with one of the two partners of a variant pair, Flp(K82M) and Flp(A35T, R281V). The same A35T mutation is also present within a group of mutations that rescue a Flp variant, Flp(Y60S), that is defective in establishing monomer–monomer interactions on the native Flp target site. Strikingly, these mutations are localized to peptide regions involved in interdomain and interprotomer interactions within the recombination complex. The same group of mutations, when transferred to the context of wild-type Flp, can relax its specificity to include non-native target sites. The hybrid Flp systems described here mimic the naturally occurring XerC/XerD recombination system that utilizes two recombinases with distinct DNA binding specificities. The ability to overcome the constraints of binding site symmetry in Flp recombination has important implications in the targeted manipulations of genomes.

Stepwise Manipulation of DNA Specificity in Flp Recombinase: Progressively Adapting Flp to Individual and Combinatorial Mutations in its Target Site

The Flp protein from Saccharomyces cerevisiae is one of the site-specific tyrosine family recombinases that are used widely in genomic engineering. As a first step towards mediating directed DNA rearrangements at non-native Flp recombination targets ( mFRTs), we have evolved three separate groups of Flp variants that preferentially act on mFRTs containing substitutions at the first, seventh or both positions of the Flp-binding elements. The variants that recombine the double-mutant mFRT contain a subset of the mutations present in those that are active on the single-mutant mFRTs, plus additional mutations. Specificity for and discrimination between target sites, effected primarily by amino acid residues that contact DNA, can be modulated by those that do not interact with DNA or with a DNA-contacting residue. The degree of modulation can range from relaxed DNA specificity to almost completely altered specificity. Our results suggest that combined DNA shuffling and mutagenesis of libraries of Flp variants active on distinct mFRTs can yield variants that can recombine mFRTs containing combinations of the individual mutations.

A dual reporter screening system identifies the amino acid at position 82 in Flp site-specific recombinase as a determinant for target specificity.

We have developed a dual reporter screen in Escherichia coli for identifying variants of the Flp site-specific recombinase that have acquired reactivity at an altered target site (mFRT). In one reporter, the lacZalpha gene segment is flanked by mFRTs in direct orientation. In the other, the red fluorescence protein (RFP) gene is flanked by the native FRTs. Hence, the color of a colony on an X-gal indicator plate indicates the recombination potential of the variant Flp protein expressed in it: blue if no recombination or only FRT recombination occurs, red if only mFRT recombination occurs and white if both FRT and mFRT recombinations occur. The scheme was validated by identification and in vivo characterization of Flp variants that show either relaxed specificity (active on FRT and mFRT) or moderately shifted specificity toward mFRT. We find that alteration of Lys-82 to Met, Thr, Arg or His enables the corresponding Flp variants to recombine FRT sites as well as altered FRT sites containing a substitution of G-C by C-G at position 1 of the Flp binding element (mFRT11). In contrast, wild-type Flp has no detectable activity on mFRT11. When Lys-82 is replaced by Tyr, the resulting Flp variant shows a small but reproducible preference for mFRT11 over FRT. However, this preference for mFRT11 is nearly lost when Tyr-82 is substituted by Phe.

DNA recombination and RNA cleavage activities of the Flp protein: roles of two histidine residues in the orientation and activation of the nucleophile for strand cleavage

Using a combination of DNA and hybrid DNA-RNA substrates, we have analyzed the mechanism of phosphoryl transfer by the Flp site-specific recombinase in three different reactions: DNA strand breakage and joining, and two types of RNA cleavage activities. These reactions were then used to characterize Flp variants altered at His309 and His345, amino acid residues that are in close proximity to two key catalytic residues (Arg308 and Tyr343). These histidine residues are important for strand cutting by Tyr343, the active-site nucleophile of Flp, but neither residue contributes to the type II RNA cleavage activity or to the strand-joining reaction in a pre-cleaved substrate. Strand cleavage reactions using small, diffusible nucleophiles indicate that this histidine pair contributes to the correct positioning and activation of Tyr343 within the shared active site of Flp. The implications of these results are evaluated against the recently solved crystal structure of Flp in association with a Holliday junction.

Mechanism of site-specific recombination. Logic of assembling recombinase catalytic site from fractional active sites

The active nucleophilic species in the strand cleavage and strand exchange steps of site-specific recombination by the Flp protein are the active site tyrosine (Tyr-343) of Flp and the 5'-hydroxyl of Flp-nicked DNA, respectively. The target phosphodiester, activated by Flp, can be cleaved by an exogenous nucleophile derived, for example, from H2O2. Flp variants that are defective in the phosphate activation step and cannot sustain Tyr-343-mediated cleavage also fail to elicit H2O2-mediated cleavage. An Flp mutant lacking Tyr-343, (Flp(Y343F)), can carry out both the strand cleavage and strand exchange reactions in the presence of a age and strand exchange reactions in the presence of a tyrosine analog. These results are consistent with a cis-activation/trans-nucleophilic attack paradigm for strand breakage and strand union. The proposed model conceptually unifies the chemistry and enzymology of the two partial reactions of recombination. The mechanism of Flp action has strong implications for phosphoryl transfer reactions in other site-specific DNA recombination systems and in RNA splicing.

Functional analysis of Box II mutations in yeast site-specific recombinases Flp and R: Significance of amino acid conservation within the Int family and the yeast sub-family

The site-specific recombinases Flp and R from Saccharomyces cerevisiae and Zygosaccharomyces rouxii, respectively, are related proteins that share approximately 30% amino acid matches. They exhibit a common reaction mechanism that appears to be conserved within the larger Integrase family of site-specific recombinases. Two regions of the proteins, designated as Box I and Box II, harbor, in addition to amino acid conservation, a significantly high degree of nucleotide sequence homology within their coding segments. Box II also contains two amino acids, a histidine and an arginine, that are invariant throughout the Int family. We have performed functional analysis of Flp and R variants carrying point mutations within the Box II segment. Several positions within Box II can tolerate substitutions with no effect, or only modest effects on recombination. Alterations of the Int family residues, His305 and Arg3O8, in the R protein lead to the arrest of recombination at the strand cleavage or the strand exchange step. This is very similar to previously observed “step-arrest” phenotypes in Flp variants altered at these positions and has strong implications for the catalytic mechanism of recombination. Flp and R variants at His305 and His309 can be complemented in half-site strand transfer by a corresponding Tyr343 to phenylalanine variant. In contrast to Arg308 Flp variants, which are efficiently complemented in half-site strand transfer by Flp(Y343F), no strong complementation has been observed between Arg308 variants of R and R (Y343F).

Functional analysis of box I mutations in yeast site-specific recombinases Flp and R: pairwise complementation with recombinase variants lacking the active-site tyrosine.

The site-specific recombinases Flp and R from Saccharomyces cerevisiae and Zygosaccharomyces rouxii, respectively, are related proteins that belong to the yeast family of site-specific recombinases. They share approximately 30% amino acid matches and exhibit a common reaction mechanism that appears to be conserved within the larger integrase family of site-specific recombinases. Two regions of the proteins, designated box I and box II, also harbor a significantly high degree of homology at the nucleotide sequence level. We have analyzed the properties of Flp and R variants carrying point mutations within the box I segment in substrate-binding, DNA cleavage, and full-site and half-site strand transfer reactions. All mutations abolish or seriously diminish recombinase function either at the substrate-binding step or at the catalytic steps of strand cleavage or strand transfer. Of particular interest are mutations of Arg-191 of Flp and R, residues which correspond to one of the two invariant arginine residues of the integrase family. These variant proteins bind substrate with affinities comparable to those of the corresponding wild-type recombinases. Among the binding-competent variants, only Flp(R191K) is capable of efficient substrate cleavage in a full recombination target. However, this protein does not cleave a half recombination site and fails to complete strand exchange in a full site. Strikingly, the Arg-191 mutants of Flp and R can be rescued in half-site strand transfer reactions by a second point mutant of the corresponding recombinase that lacks its active-site tyrosine (Tyr-343). Similarly, Flp and R variants of Cys-189 and Flp variants at Asp-194 and Asp-199 can also be complemented by the corresponding Tyr-343-to-phenylalanine recombinase mutant.

Bending-incompetent variants of Flp recombinase mediate strand transfer in half-site recombinations: role of DNA bending in recombination

One key feature of the interaction of Flp recombinase with its target site ( FRT) is the large bend introduced in the substrate as a result of protein binding. The extent of bending was found to depend on the phasing and spacing of the Flp monomers occupying the two Flp-binding elements ( FBE) bordering the strand-exchange region (spacer) of the substrate. The relative mobilities of the Flp complexes formed by the two permuted substrate fragments, containing the FRT site near the end or in the middle, corresponded to a DNA bend of approx. 140° when each of the two FBEs flanking the spacer was occupied by a protein monomer. The estimated bend angle was the same when the reference DNA fragment with the FRT site at the end was substituted by one with the site in the middle, but containing a 4-bp insertion within the spacer. We used a combination of wild-type Flp and Flp variants that were competent or incompetent in DNA bending, together with full, or half FRT sites, to ask whether bending is a conformational requirement for catalysis, namely cleavage and exchange of strands. We obtained the following results: in full-site ( FRT) vs. full-site recombinations or in full-site vs. half-site (half FRT) recombinations, there was a large difference in the reactivity between Flp and a bending-incompetent Flp variant. This difference virtually disappeared when reactions were done with half- FRT sites. We conclude that bending is not a prerequisite for catalysis, but represents the manner in which the substrate accommodates the Flp protomer-protomer interactions that are pertinent to catalysis.

Functional analysis of box I mutations in yeast site-specific recombinases Flp and R: pairwise complementation with recombinase variants lacking the active-site tyrosine.

The site-specific recombinases Flp and R from Saccharomyces cerevisiae and Zygosaccharomyces rouxii, respectively, are related proteins that belong to the yeast family of site-specific recombinases. They share approximately 30% amino acid matches and exhibit a common reaction mechanism that appears to be conserved within the larger integrase family of site-specific recombinases. Two regions of the proteins, designated box I and box II, also harbor a significantly high degree of homology at the nucleotide sequence level. We have analyzed the properties of Flp and R variants carrying point mutations within the box I segment in substrate-binding, DNA cleavage, and full-site and half-site strand transfer reactions. All mutations abolish or seriously diminish recombinase function either at the substrate-binding step or at the catalytic steps of strand cleavage or strand transfer. Of particular interest are mutations of Arg-191 of Flp and R, residues which correspond to one of the two invariant arginine residues of the integrase family. These variant proteins bind substrate with affinities comparable to those of the corresponding wild-type recombinases. Among the binding-competent variants, only Flp(R191K) is capable of efficient substrate cleavage in a full recombination target. However, this protein does not cleave a half recombination site and fails to complete strand exchange in a full site. Strikingly, the Arg-191 mutants of Flp and R can be rescued in half-site strand transfer reactions by a second point mutant of the corresponding recombinase that lacks its active-site tyrosine (Tyr-343). Similarly, Flp and R variants of Cys-189 and Flp variants at Asp-194 and Asp-199 can also be complemented by the corresponding Tyr-343-to-phenylalanine recombinase mutant.

Tyr60 variants of Flp recombinase generate conformationally altered protein-DNA complexes: Differential activity in full-site and half-site recombinations

The tyrosine at position 60 of the Flp recombinase of the Saccharomyces cerevisiae plasmid, 2 μ circle, is invariant among site-specific recombinases of the “yeast plasmid family”. Alterations of this residue give rise to Flp variants that show no recombination activity when assayed in vivo in Escherichia coli. Upon purification, they bind substrate, execute DNA cleavage and catalyze recombination. The efficiency of strand cleavage follows the order: Flp(Y60F) > Flp > Flp(Y60S) > Flp(Y60D); efficiency of recombination between Flp sites on a linear substrate and a circular one follows the order: Flp > Flp(Y60F) > Flp(Y60S) > Flp(Y60D). Methylation footprints of the DNA-protein complexes formed by two of the Flp variants, Flp(Y60S) and Flp(Y60D), do not show hypermethylation of the G residues within the substrate core that is characteristic of complexes formed by wild-type Flp. The third variant, Flp(Y60F), causes significant distortion (although less than wildtype Flp) of the substrate core, as indicated by enhanced G-methylation. Binding profiles with circularly permuted substrates indicate that Flp(Y60S) and Flp(Y60D), but not Flp(Y60F), are defective in bending substrate DNA. In recombination between two Flp half-sites, the variant proteins are significantly more active than in normal full-site recombination.

Functional analysis of Arg-308 mutants of Flp recombinase. Possible role of Arg-308 in coupling substrate binding to catalysis.

The arginine residue at position 308 in the Flp recombinase corresponds to the only invariant arginine within the Int family of recombinases. Alterations of this residue result in Flp variants that retain substrate recognition, but form weaker protein-DNA complexes than wild type Flp. Furthermore, their DNA cleavage activity is significantly diminished. A conservative change of R308K results in a functional Flp variant; however, this protein has a lowered temperature optimum for recombination. The Arg-308 mutants can be stabilized on the DNA substrate through cooperativity with a partner Flp mutant that is tight binding. Thus, interactions between Flp monomers must be a relevant feature of the normal recombination reaction.