Identification of Cre residues involved in synapsis,isomerization, and catalysis

The Cre protein of bacteriophage P1 is a tyrosine recombinase and catalyzes recombination via formation of a covalent protein-DNA complex and a Holliday junction intermediate. Several co-crystal structures of Cre bound to its target lox site have provided novel insights into its biochemical activities. We have used these structures to guide the mutagenesis of several Cre residues that contact the lox spacer region and/or are involved in intersubunit protein-protein interactions. None of the mutant proteins had significant defects in DNA binding, DNA bending, or strand-specific initiation of recombination. We have identified novel functions of several amino acids that are involved in three aspects of the Cre reaction. 1) Single mutation of several NH2-terminal basic residues that contact the spacer region of loxP caused the accumulation of Holliday junction (HJ) intermediates but only a modest impairment of recombination. These residues may be involved in the isomerization of the Holliday intermediate. 2) We identified three new residues (Arg-118, Lys-122, and Glu-129) that are involved in synapsis. Cre R118A, K122A, and E129Q were catalytically competent. 3) Mutations E129R, Q133H, and K201A inactivated catalysis by the protein. The function of these Cre residues in recombination is discussed.     

Multiplex Cre/lox recombination permits selective site-specific DNA targeting to both a natural and an engineered site in the yeast genome.

Variant lox sites having an altered spacer region (heterospecific lox sites) are not proficient for Cre-mediated recombination with the canonical 34 bp loxP site, but can recombine with each other. By placing different heterospecific lox sites at different genomic locations, Cre can catalyze independent DNA recombination events at multiple loci in the same cell without concern that unwanted inter-locus recombination events will be generated. Such heterospecific lox sites also allow Cre to specifically target efficient integration of exogenous DNA to endogenous lox-like sequences that naturally occur in the genome. Specific targeting occurs only with a DNA vector carrying a heterospecific lox site in which the spacer region has been redesigned to match the 'spacer' region of the targeted chromosomal element. Moreover, in cells expressing a catalytically active Cre recombinase, naturally occurring lox-like sequences can exhibit almost 20% mitotic recombination. Thus, in the same cell, heterospecific lox sites can be used independently at multiple loci for integration, for deletion and for enhanced mitotic recombination, thereby increasing the repertoire of genomic manipulations catalyzed by the Cre recombinase.     

Bacteriophage P1 Cre-loxP site-specific recombination. Site-specific DNA topoisomerase activity of the Cre recombination protein

Site-specific recombination in bacteriophage P1 occurs between two loxP sites in the presence of the Cre recombination protein. The structure of the 34-base pair loxP site consists of two 13-base pair inverted repeats separated by an 8-base pair spacer region. A mutation in the loxP site has been constructed which deletes one of the internal bases of the spacer region at the axis of dyad symmetry. This mutant loxP site shows a 10-fold reduction in recombination activity with a wild-type site both in vivo and in vitro. This low level of intramolecular recombination between a wild-type loxP site and the mutant loxP501 site is observed in vitro only when the DNA substrate is supercoiled. The majority of the supercoiled substrate is relaxed by the Cre protein, and on longer incubations, single-stranded nicks accumulate in the DNA. We have determined that these nicks occur in both the wild-type and the mutant sites. The positions of these nicks correspond to the positions of cleavage found during recombination of two wild-type sites, suggesting that the Cre protein is attempting to carry out recombination with the mutant site but most of the time this reaction is abortive. We have determined that the Cre protein relaxes a supercoiled topoisomer of a DNA substrate containing one wild-type site and one mutant site to yield a distribution of topoisomers whose linking numbers differ by steps of one, indicating that Cre can act as a type I topoisomerase.     

Stoichiometry of the Cre recombinase bound to the lox recombining site.

The site-specific recombinase Cre from bacteriophage P1 binds and carries out recombination at a 34 bp lox site. The lox site consists of two 13 bp inverted repeats, separated by an 8 bp spacer region. Both the palindromic nature of the site and the results of footprinting and band shift experiments suggest that a minimum of two Cre molecules bind to a lox site. We report here experiments that demonstrate the absolute stoichiometry of the Cre-lox complex to be one molecule of Cre bound per inverted repeat, or two molecules per lox site.     

An engineered lox sequence containing part of a long terminal repeat of HIV-1 permits Cre recombinase-mediated DNA excision.

In our previous report, one 34-bp sequence from a long terminal repeat (LTR) of human immunodeficiency virus type 1 (HIV-1) clone, loxLTR-1, was proposed as a target site for site-specific excision by modified Cre recombinase. To support this suggestion, an engineered lox sequence, designated loxIL1, was made. This variant lox has the corresponding sequence of loxLTR-1 at the spacer region and the last two bases of inverted repeat sequence. Through in vitro recombination assay, loxIL1 also allowed the wild-type Cre to specifically recombine the sequence. An in vitro DNA binding experiment with mutants CreK244R and CreK244L revealed that lysine 244 of Cre plays an important role in interaction with the engineered lox. This result suggests that loxLTR-1 would be a candidate for antiviral strategy using site-specific recombinase.     

Sequence of the loxP site determines the order of strand exchange by the Cre recombinase

Conservative site-specific recombinases of the integrase family carry out recombination via a Holliday intermediate. The Cre recombinase, a member of the integrase family, was previously shown to initiate recombination by cleaving and exchanging preferentially on the bottom strand of its loxP target sequence. We have confirmed this strand bias for an intermolecular recombination reaction that used wild-type loxP sites and Cre protein. We have examined the sequence determinants for this strand preference by selectively mutating the two asymmetric scissile base-pairs in the lox site (those immediately adjacent to the sites of cleavage by Cre). We found that the initial strand exchange occurs preferentially next to the scissile G residue. Resolution of the Holliday intermediate thus formed takes place preferentially next to the scissile A residue. Lys86, which contacts the scissile nucleotides in the Cre-lox crystal structures, was important for establishing the strand preference in the resolution of the loxP-Holliday intermediate, but not for the initiation of recombination between loxP sites.     

Sequential deletion of Pichia pastoris genes by a self-excisable cassette

A rapid and convenient method is presented for unmarked gene deletions in Pichia pastoris. Cre/mutated lox system, Zeocin(?) (Invitrogen) resistance marker and homologous arms were spliced together by fusion PCR to generate the gene disruption cassettes (homologous region-lox71-Cre-ZeoR-lox66-homologous region), which could be integrated into the P. pastoris genome via homologous recombination. After transferring double-cross-over recombinants to methanol induction medium, transient expression of Cre recombinase caused the recombination of lox71-Cre-ZeoR-lox66 fragment into a double-mutant lox72 site, thus excising the Cre-ZeoR cassette from the P. pastoris genome. As the double-mutant lox72 site displays strongly reduced binding affinity for Cre recombinase, this method could be used sequentially to disrupt P. pastoris genes without introducing selectable markers. The effectiveness of this strategy was verified by introducing both single and double gene deletions into the P. pastoris genome.     

A simple analysis system for the estimation of recombination efficiency using fluorescence-activated cell sorting

A simple and accurate analysis system for the estimation of recombination efficiency in vivo using fluorescence-activated cell sorting (FACS) was designed and was subsequently used to compare the efficiency of recombination related to different spacer mutants. F(3) and F(5) mutant sequences were used for Flpe-mediated cassette exchange, and m2 and lox2272 mutant sequences were used for Cre-mediated cassette exchange due to their high incompatibility with wild-type sequences. The incompatibilities with wild-type were almost the same between mutant sequences. However, the recombination efficiencies were different. F(3) and m2 could mediate more efficient recombination than F(5) and lox2272, respectively. These results are consistent with the fact that the sequence of spacer region affects not only the reactivity upon wild-type sequence but also the recombination efficiency. It was also confirmed that the recombination process was mediated in a site-specific manner through PCR analysis using different sizes of exchange cassettes. In this experiment, the feasibility of the FACS analysis system for the estimation of recombination efficiency was verified. This system should be readily applicable for estimating recombination efficiency of other various mutant candidates, which will contribute to more precise and efficient site-specific recombination.     

Gene tagging and gene replacement using recombinase-mediated cassette exchange in Schizosaccharomyces pombe

Cre/lox site-specific recombination systems provide important tools for genetic manipulation. Here we present an efficient method for gene tagging and gene replacement using Cre recombinase-mediated cassette exchange (RMCE). The cassette consists of the S. pombe ura4(+) selectable marker flanked by a wild-type loxP site at one end and by a modified heterospecific lox site (loxM3) at the other. The cassette is stable because the flanking lox sites cannot recombine with each other. Following integration of the cassette at the chosen chromosomal locus, exchange is achieved by introducing a Cre-expression plasmid containing an equivalent cassette containing the required tag or gene sequence. Recombinants are selected by uracil prototrophy using the reagent 5-fluoroorotic acid (5-FOA). The cassette exchange system provides for repetitive integrations at the same locus, allowing different protein tags or gene sequences to be integrated quickly and efficiently. We have established a range of reagents and verified utility by C-terminally tagging the S. pombe rad4 and swi1 genes with yEGFP and the yEGFP derivatives yECFP and yECitrine and by transferring the coding sequence for both genes.     

Characterization of Cre-loxP interaction in the major groove: hint for structural distortion of mutant Cre and possible strategy for HIV-1 therapy

Although the crystal structure of Cre recombinase complexed with DNA, named loxA, was elucidated a couple of years ago, it has not yet been determined which amino acids of the protein are involved in the specific Cre-loxP interaction. Arg259 and Gln90 interact with DNA substrate in the major groove from which the specificity of protein-DNA interaction comes. In this study, we substituted these residues for other amino acids. Also, two mutated DNA substrates were constructed. In each mutant, one of the bases that interact with Arg259 or Gln90 was changed into another base. In vitro binding assays and recombination assays of variant lox sites with wild-type and mutant-type Cre revealed that Arg259 plays a key role in Cre-loxP binding but Gln90 does not. However, the recombination activity still remained intact, although the binding between Cre and DNA substrate was not ensured.     

Site-specific recombination in Zea mays

The elimination of marker genes after selection is recommended for the commercial use of genetically modified plants. We compared the applicability of the two site-specific recombination systems Cre/lox and Flp/FRT for marker gene elimination in maize plants. The selection marker gene pat surrounded by two identically directed lox or FRT sites was introduced into maize. Sexual crossing with plants harboring the corresponding constitutively expressed recombinase led to the precise and complete excision of the lox-flanked marker gene in the F₁ progeny, whereas Flp-mediated recombination of FRT sequences occurred rarely. Further examination of site-specific integration was done by biolistic bombardment of immature embryos harboring only one lox site with a lox.uidA sequence with results indicating directed integration.     

A randomized library approach to identifying functional lox site domains for the Cre recombinase

The bacteriophage P1 Cre/loxP site-specific recombination system is a useful tool in a number of genetic engineering processes. The Cre recombinase has been shown to act on DNA sequences that vary considerably from that of its bacteriophage recognition sequence, loxP. However, little is known about the sequence requirements for functional lox-like sequences. In this study, we have implemented a randomized library approach to identify the sequence characteristics of functional lox site domains. We created a randomized spacer library and a randomized arm library, and then tested them for recombination in vivo and in vitro. Results from the spacer library show that, while there is great plasticity, identity between spacer pairs is the most important factor influencing function, especially in in vitro reactions. The presence of one completely randomized arm in a functional loxP recombination reaction revealed that only three wild-type loxP arms are necessary for successful recombination in Cre-expressing bacteria, and that there are nucleotide preferences at the first three and last three positions of the randomized arm for the most efficiently recombined sequences. Finally, we found that in vitro Cre recombination reactions are much more stringent for evaluating which sequences can support efficient recombination compared to the 294-CRE system.     

The promiscuity of heterospecific lox sites increases dramatically in the presence of palindromic DNA

Heterospecific lox sites are mutated lox sites that in the presence of Cre recombinase recombine with themselves but not or much less with wildtype loxP. We here show that in Escherichia coli both lox511 and lox2272 sites become highly promiscuous with respect to loxP when in the presence of Cre one of the recombination partners is present in a larger stretch of an inverted repeat of non-lox DNA. In such a palindromic DNA configuration, also the occurrence of other DNA repeat-mediated recombination events is somewhat increased in the presence of Cre. The results indicate that in recombinase mediated cassette exchange or other double lox applications based on the exclusivity of heterospecific lox sites, or in research combining Cre-lox approaches with hairpin RNA for gene silencing, the presence of duplicated DNA around lox sites has to be taken into account. It is proposed that the presence of palindromic non-lox DNA interferes with the homology search of the Cre enzyme prior to the actual recombination event.     

Role of nucleotide sequences of loxP spacer region in Cre-mediated recombination

The Cre recombinase mediates precise site-specific recombination between a pair of loxP sequences through an intermediate containing Holiday junction. The recombination junction in the loxP sequence is located within the asymmetric 8-nucleotide spacer region. To examine the role of each nucleotide sequence of the spacer region in the recombination process, we synthesized a complete set of 24 loxP spacer mutants with single-base substitutions and 30 loxP spacer mutants with double-base substitutions. Each synthesized loxP mutant was ligated at both ends of a linear DNA or to one end of a DNA-containing wild-type loxP at the other end and their recombination efficiencies were analyzed with an in vitro system. The sequence identity of the right two nucleotides and left four nucleotides in the central six bases of the spacer region was found to be essential for formation and resolution, respectively, of the intermediate product. Furthermore, even when homology was maintained, the recombination efficiencies were lower than that of wild-type loxP and varied among mutants. Based on this knowledge, we identified two loxP mutants with double-base substitutions, mutants 5171 and 2272, which recombine efficiently with an identical mutant but not with the other mutant or wild-type loxP.     

Cre induces an asymmetric DNA bend in its target loxP site

Cre initiates recombination by preferentially exchanging the bottom strands of the loxP site to form a Holliday intermediate, which is then resolved on the top strands. We previously found that the scissile AT and GC base pairs immediately 5' to the scissile phosphodiester bonds are critical in determining this order of strand exchange. We report here that the scissile base pairs also influence the Cre-induced DNA bends, the position of which correlates with the initial site of strand exchange. The binding of one Cre molecule to a loxP site induces a approximately 35 degrees asymmetric bend adjacent to the scissile GC base pair. The binding of two Cre molecules to a loxP site induces a approximately 55 degrees asymmetric bend near the center of the spacer region with a slight bias toward the scissile A. Lys-86, which contacts the scissile nucleotides, is important for establishing the bend near the scissile GC base pair when one Cre molecule is bound but has little role in positioning the bend when two Cre molecules are bound to a loxP site. We present a model relating the position of the Cre-induced bends to the order of strand exchange in the Cre-catalyzed recombination reaction.     

Mechanism of strand cleavage and exchange in the Cre-lox site-specific recombination system

The bacteriophage P1 recombinase Cre mediates site-specific recombination between loxP sites. The loxP site consists of two 13 base-pair inverted repeats separated by an eight base-pair spacer region. When DNA containing the loxP site is incubated with Cre, specific cleavages occur within the spacer region, creating a six base-pair staggered cut. The cuts are centered on the axis of dyad symmetry of the loxP site, resulting in a 5' protruding terminus: 5' A decreases T-G-T-A-T-G C 3' T A-C-A-T-A-C increases G. At the point of cleavage, Cre becomes covalently attached to a 3' PO4, and produces a free 5' OH. A series of experiments were carried out in which a radioactively labeled loxP site is recombined with an unlabeled loxP site to locate the point at which strand exchange takes place during recombination. The points of strand exchange coincide with the sites at which Cre cleavage of the DNA backbone had been detected.     

The role of the loxP spacer region in P1 site-specific recombination.

The lox-Cre site-specific recombination system of bacteriophage P1 is comprised of a site on the DNA where recombination occurs called loxP, and a protein, Cre, which mediates the reaction. The loxP site is 34 base pairs (bp) in length and consists of two 13 bp inverted repeats separated by an 8 bp spacer region. Previously it has been shown that the cleavage and strand exchange of recombining loxP sites occurs within this spacer region. We report here an analysis of various base substitution mutations within the spacer region of loxP, and conclude the following: Homology is a requirement for efficient recombination between recombining loxP sites. There is at least one position within the spacer where a base change drastically reduces recombination even when there is homology between the two recombining loxP sites. When two loxP sites containing symmetric spacer regions undergo Cre-mediated recombination in vitro, the DNA between the sites undergoes both excision and inversion with equal frequency.     

Evidence for a second conserved arginine residue in the integrase family of recombination proteins.

This study was designed to search for new regions of similarity in the integrase family of recombination proteins which consists of 28 members found in bacteria and yeast. A computer method based on an information content analysis has been used to align local regions of homology in the set of unaligned protein sequences from this family. Among the aligned regions with high information content were those containing the known conserved histidine, arginine and tyrosine residues. In addition, a new region was identified containing another arginine residue that appears to be conserved in all members of the family. To test further the importance of this newly identified arginine residue, mutants in the Cre protein from phase P1, a member of this integrase family, have been constructed which alter this residue. The mutations which change arginine to lysine and arginine to cysteine depress catalytic activity but not site-specific binding to the lox site. This result is expected for a conserved active site residue. This computer analysis also provides a means for searching for new members of the integrase family.     

Balancer-Cre transgenic mouse germ cells direct the incomplete resolution of a tri-loxP-targeted Cyp1a1 allele, producing a conditional knockout allele

To generate conditional alleles, genes are commonly engineered to contain recognition sites for bacteriophage recombinases, such as Cre recombinase. When such motifs (lox sites) flank essential gene sequences, and provided that Cre recombinase is expressed, Cre recombinase will excise the flanked sequence-creating a conditional knockout allele. Targeted conditional alleles contain a minimum of three lox sites. It would be desirable to have Cre recombinase perform partial resolution (i.e., recombination some of the time between only the two lox sites flanking the marker gene). Here we report use of the commercially available Balancer2-Cre transgenic mouse line to carry out this function from a tri-loxP-site-containing cytochrome p450 1A1 (Cyp1a1) targeted allele. Such incomplete resolution of this complex locus occurred progressively with age in germ cells of male mice; the conditional Cyp1a1 gene was recovered in offspring from mice containing the targeted Cyp1a1 allele and the Cre recombinase transgene. Removal of the marker gene resulted in a conditional Cyp1a1 allele whose expression was indistinguishable from that of the wild-type allele.     

Cre/lox system and PCR-based genome engineering in Bacillus subtilis

We have developed a fast and accurate method to engineer the Bacillus subtilis genome that involves fusing by PCR two flanking homology regions with an antibiotic resistance gene cassette bordered by two mutant lox sites (lox71 and lox66). The resulting PCR products were used directly to transform B. subtilis, and then transient Cre recombinase expression in the transformants was used to recombine lox71 and lox66 into a double-mutant lox72 site, thereby excising the marker gene. The mutation process could also be accomplished in 2 days by using a strain containing a cre isopropyl-beta-d-thiogalactopyranoside (IPTG)-inducible expression cassette in the chromosome as the recipient or using the lox site-flanked cassette containing both the cre IPTG-inducible expression cassette and resistance marker. The in vivo recombination efficiencies of different lox pairs were compared; the lox72 site that remains in the chromosome after Cre recombination had a low affinity for Cre and did not interfere with subsequent rounds of Cre/lox mutagenesis. We used this method to inactivate a specific gene, to delete a long fragment, to realize the in-frame deletion of a target gene, to introduce a gene of interest, and to carry out multiple manipulations in the same background. Furthermore, it should also be applicable to large genome rearrangement.