Mammalian genomes contain active recombinase recognition sites

Recombinases derived from microorganisms mediate efficient site-specific recombination. For example, the Cre recombinase from bacteriophage P1 efficiently carries out recombination at its loxP target sites. While this enzyme can function in mammalian cells, the 34bp loxP site is expected to be absent from mammalian genomes. We have discovered that sequences from the human and mouse genomes surprisingly divergent from loxP can support Cre-mediated recombination at up to 100% of the efficiency of the native loxP site in bacterial assays. Transient assays in human cells demonstrate that such pseudo-lox sites also support Cre-mediated integration and excision in the human cell environment. Pseudo sites for Cre and other recombinases may be useful for site-specific insertion of exogenous genes into mammalian genomes during gene therapy and other genetic engineering processes.     

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.     

Targeted insertion of exogenous DNA into the eukaryotic genome by the Cre recombinase

Cre is a 38-kD protein from bacteriophage P1 that catalyzes site-specific recombination between 34-bp loxP sequences. Our previous work has shown that Cre can perform site-specific excisive recombination not only in prokaryotes, but also in eukaryotes such as yeast and cultured mammalian cells. In this work we show that intermolecular Cre-mediated recombination can specifically direct the integration of a loxP-containing circular DNA into a chromosomal loxP site, both in yeast and in mammalian cells. The resulting integrants are predominantly simple single-copy insertions. Cre-mediated recombination thus provides a simple way to direct single-copy site-specific integration of exogenous DNA into the eukaryotic genome.     

Studies on the properties of P1 site-specific recombination: evidence for topologically unlinked products following recombination

Bacteriophage P1 encodes its own site-specific recombination system consisting of a site at which recombination takes place called loxP and a recombinase called Cre. A number of lambda and plasmid substrates containing two loxP sites have been constructed. Using these substrates we have shown both in vivo and in vitro that a fully functional loxP site is composed of no more than 60 bp. In vitro, when an extract containing Cre is used, recombination between loxP sites on supercoiled, nicked-circle or linear DNA occurs efficiently. The most surprising result from the in vitro studies is that 50% of the products of recombination between loxP sites on a supercoiled DNA substrate are present as free supercoiled circles. The ability to produce free products starting with a supercoiled substrate suggests a rather unique property of Cre-mediated lox recombination, the implications of which are discussed in terms of possible effects of the protein on the topology of the DNA molecule.     

Genome engineering of Toxoplasma gondii using the site-specific recombinase Cre.

Site-specific DNA recombinases from bacteriophage and yeasts have been developed as novel tools for genome engineering both in prokaryotes and eukaryotes. The 38kDa Cre protein efficiently produces both inter- and intramolecular recombination between specific 34bp sites called loxP. We report here the in vivo use of Cre recombinase to manipulate the genome of the protozoan parasite Toxoplasma gondii. Cre catalyzes the precise removal of transgenes from T. gondii genome when flanked by two directly repeated loxP sites. The efficiency of excision has been determined using LacZ as reporter and indicates that it can easily be applied to the removal of undesired sequences such as selectable marker genes and to the determination of gene essentiality. We have also shown that the reversibility of the recombination reaction catalyzed by Cre offers the possibility to target site-specific integration of a loxP-containing vector in a chromosomally placed loxP target in the parasite. In mammalian systems, the Cre recombinase can be regulated by hormone and is used for inducible gene targeting. In T. gondii, fusions between Cre recombinase and the hormone-binding domain of steroids are constitutively active, hampering the utilization of this mode of post-translational regulation as inducible gene expression system.     

A directional strategy for monitoring Cre-mediated recombination at the cellular level in the mouse

Functional redundancies, compensatory mechanisms, and lethal phenotypes often prevent the full analysis of gene functions through generation of germline null mutations in the mouse. The use of site-specific recombinases, such as Cre, which catalyzes recombination between loxP sites, has allowed the engineering of mice harboring targeted somatic mutations, which are both temporally controlled and cell-type restricted. Many Cre-expressing mouse lines exist, but only a few transgenic lines are available that harbor a reporter gene whose expression is dependent on a Cre-mediated event. Moreover, their use to monitor gene ablation at the level of individual cells is often limited, as in some tissues the reporter gene may be silenced, be affected by position-effect variegation, or reside in a chromatin configuration inaccessible for recombination. Thus, one cannot validly extrapolate from the expression of a reporter transgene to an identical ablation pattern for the conditional allele of a given gene. By combining the ability of Cre recombinase to invert or excise a DNA fragment, depending on the orientation of the flanking loxP sites, and the availability of both wild-type (WT) and mutant loxP sites, we designed a Cre-dependent genetic switch (FLEx switch) through which the expression of a given gene is turned off, while the expression of another one is concomitantly turned on. We demonstrate the efficiency and reliability of this switch to readily detect, in the mouse, at the single cell level, Cre-mediated gene ablation. We discuss how this strategy can be used to generate genetic modifications in a conditional manner.     

Control of Cre recombination by regulatory elements from Xer recombination systems

Site-specific recombination by the Cre recombinase takes place at a simple DNA site (loxP), requires no additional proteins and gives topologically simple recombination products. In contrast, cer and psi sites for Xer recombination contain approximately 150 bp of accessory sequences, require accessory proteins PepA, ArgR and ArcA, and the products are specifically linked to form a four-noded catenane. Here, we use hybrid sites consisting of accessory sequences of cer or psi fused to loxP to probe the function of accessory proteins in site-specific recombination. We show that PepA instructs Cre to produce four-noded catenane, but is not required for recombination at these hybrid sites. Mutants of Cre that require PepA and accessory sequences for efficient recombination were selected. PepA-dependent Cre gave products with a specific topology and displayed resolution selectivity. Our results reveal that PepA acts autonomously in the synapsis of psi and cer accessory sequences and is the main architectural element responsible for intertwining accessory site DNA. We suggest that accessory proteins can activate recombinases simply by synapsing the regulatory DNA sequences, thus bringing the recombination sites together with a specific geometry. This may occur without the need for protein-protein interactions between accessory proteins and the recombinases.     

Cre重组酶结构与功能的研究进展

Cre/loxP定位重组系统来源于噬菌体P₁,由Cre重组酶和loxP位点两部分组成。在Cre重组酶的介导下,设定的DNA片段可以被切除,可以发生倒位,亦可造成定点的整合。由于其作用方式高效简单,Cre/loxP定位重组系统已在特定基因的删除、基因功能的鉴定、外源基因的整合、基因捕获及染色体工程等方面得到了有效的利用,在转基因的酵母、植物、昆虫、哺乳动物的体内外DNA重组方面成为一个有力的工具。这里就Cre重组酶的结构、功能及该定位重组系统的应用等方面的研究进行了综述。     

Bacteriophage P1 site-specific recombination. Purification and properties of the Cre recombinase protein

Bacteriophage P1 encodes a site-specific recombination system that consists of a site (loxP) at which recombination occurs and a gene, cre, whose protein product is essential for recombination. The loxP-Cre recombination event can be studied in greater detail by the use of an in vitro system that efficiently carries out recombination between two loxP sites. This paper presents a purification and characterization of the Cre protein (Mr = 35,000), which is the only protein required for the in vitro reaction. No high energy cofactors are needed. The purified Cre protein binds to loxP-containing DNA and makes complexes that are resistant to heparin. Cre efficiently converts 70% of the DNA substrate to products and appears to act stoichiometrically. The action of Cre on a loxP2 supercoiled substrate containing two directly repeated loxP sites results in product molecules that are topologically unlinked. Several models to account for the ability of Cre to produce free supercoiled products are discussed.     

Synapsis of loxP sites by Cre recombinase

Cre recombinase catalyzes site-specific recombination between 34-bp loxP sites in a variety of topological and cellular contexts. An obligatory step in the recombination reaction is the association, or synapsis, of Cre-bound loxP sites to form a tetrameric protein assembly that is competent for strand exchange. Using analytical ultracentrifugation and electrophoresis approaches, we have studied the energetics of Cre-mediated synapsis of loxP sites. We found that synapsis occurs with a high affinity (Kd = 10 nM) and is pH-dependent but does not require divalent cations. Surprisingly, the catalytically inactive Cre K201A mutant is fully competent for synapsis of loxP sites, yet the inactive Y324F and R173K mutants are defective for synapsis. These findings have allowed us to determine the first crystal structures of a pre-cleavage Cre-loxP synaptic complex in a configuration representing the starting point in the recombination pathway. When combined with a quantitative analysis of synapsis using loxP mutants, the structures explain how the central 8 bp of the loxP site are able to dictate the order of strand exchange in the Cre system.     

Measurements of DNA-loop formation via Cre-mediated recombination

The Cre-recombination system has become an important tool for genetic manipulation of higher organisms and a model for site-specific DNA-recombination mechanisms employed by the λ-Int superfamily of recombinases. We report a novel quantitative approach for characterizing the probability of DNA-loop formation in solution using time-dependent ensemble Förster resonance energy transfer measurements of intra- and inter-molecular Cre-recombination kinetics. Our method uses an innovative technique for incorporating multiple covalent modifications at specific sites in covalently closed DNA. Because the mechanism of Cre recombinase does not conform to a simple kinetic scheme, we employ numerical methods to extract rate constants for fundamental steps that pertain to Cre-mediated loop closure. Cre recombination does not require accessory proteins, DNA supercoiling or particular metal-ion cofactors and is thus a highly flexible system for quantitatively analyzing DNA-loop formation in vitro and in vivo.     

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.     

Preferential synapsis of loxP sites drives ordered strand exchange in Cre-loxP site-specific recombination

The bacteriophage P1 Cre recombinase catalyzes site-specific recombination between 34-base-pair loxP sequences in a variety of topological contexts. This reaction is widely used to manipulate DNA molecules in applications ranging from benchtop cloning to genome modifications in transgenic animals. Despite the simple, highly symmetric nature of the Cre-loxP system, there is strong evidence that the reaction is asymmetric; the 'bottom' strands in the recombining loxP sites are preferentially exchanged before the 'top' strands. Here, we address the mechanistic basis for ordered strand exchange in the Cre-loxP recombination pathway. Using suicide substrates containing 5'-bridging phosphorothioate linkages at both cleavage sites, fluorescence resonance energy transfer between synapsed loxP sites and a Cre mutant that can cleave the bridging phosphorothioate linkage but not a normal phosphodiester linkage, we showed that preferential formation of a specific synaptic complex between loxP sites imposes ordered strand exchange during recombination and that synapsis stimulates cleavage of loxP sites.     

Identification of cryptic lox sites in the yeast genome by selection for Cre-mediated chromosome translocations that confer multiple drug resistance.

The Cre recombinase efficiently causes site-specific DNA recombination at loxP sites placed into the eukaryotic genome. Since the loxP site of phage P1 is 34 base-pairs in size, the natural occurrence of this exact sequence is unlikely in any eukaryotic genome. However, related sequences may exist in eukaryotic genomes that could recombine at low efficiency with an authentic loxP site. This work identifies such cryptic lox sites in the yeast genome using a positive selection procedure that allows the detection of events occurring at a frequency of less than 1 x 10(-7). The selection is based on the disruption/reconstruction of the yeast gene YGL022. Disruption of YGL022 confers multiple drug sensitivity. Recombination events at a loxP site 5' to the structural gene restore expression of YGL022 and result in a multiple drug resistant phenotype. These drug resistant mutants all display chromosomal rearrangements resulting from low-frequency Cre-mediated recombination with an endogenous cryptic lox site. Ten such sites have been found and they have been mapped physically to a number of different yeast chromosomes. Although the efficiency of Cre-mediated recombination between loxP and such endogenous sites is quite low, it may be possible to redesign recombination substrates to improve recombination efficiency. Because of the greater complexity of the human and mouse genomes compared with yeast, an analogous situation is likely to exist in these organisms. The availability of such sites would be quite useful in the development of alternative strategies for gene therapy and in the generation of transgenic animals.     

Site-specific recombination by the bacteriophage P1 lox-Cre system. Cre-mediated synapsis of two lox sites

The bacteriophage P1-encoded recombinase Cre forms a simple DNA-protein complex at the specific recognition site loxP. Furthermore, Cre is able to mediate a synaptic union of two loxP sites. When two loxP sites are on the same linear DNA molecule, Cre binds the two sites together to form a circular protein-DNA complex. These complexes can be resolved into a linear DNA molecule and a closed circular DNA molecule, the end products of site-specific recombination.     

PepA and ArgR do not regulate Cre recombination at the bacteriophage P1 loxP site

In the lysogenic state, bacteriophage P1 is maintained as a low copy-number circular plasmid. Site-specific recombination at loxP by the phage-encoded Cre protein keeps P1 monomeric, thus helping to ensure stable plasmid inheritance. Two Escherichia coli DNA-binding proteins, PepA and ArgR, were recently reported to be necessary for maintenance or establishment of P1 lysogeny. PepA and ArgR bind to regulatory DNA sequences upstream of the ColE1 cer recombination site to regulate site-specific recombination by the XerCD recombinases. This recombination keeps ColE1 in a monomeric state and helps to ensure stable plasmid maintenance. It has been suggested that ArgR and PepA play a similar role in P1 maintenance, regulating Cre recombination by binding to DNA sequences upstream of loxP. Here, we show that ArgR does not bind to its proposed binding site upstream of loxP, and that Cre recombination at loxP in its natural P1 context is not affected by PepA and ArgR in vitro. When sequences upstream of loxP were mutated to allow ArgR binding, PepA and ArgR still had no effect on Cre recombination. Our results demonstrate that PepA requires specific DNA sequences for binding, and that PepA and ArgR have no direct role in Cre recombination at P1 loxP.     

Site-specific recombination in the replication terminus region of Escherichia coli: functional replacement of dif.

The replication terminus region of the Escherichia coli chromosome encodes a locus, dif, that is required for normal chromosome segregation at cell division. dif is a substrate for site-specific recombination catalysed by the related chromosomally encoded recombinases XerC and XerD. It has been proposed that this recombination converts chromosome multimers formed by homologous recombination back to monomers in order that they can be segregated prior to cell division. Strains mutant in dif, xerC or xerD share a characteristic phenotype, containing a variable fraction of filamentous cells with aberrantly positioned and sized nucleoids. We show that the only DNA sequences required for wild-type dif function in the terminus region of the chromosome are contained within 33 bp known to bind XerC and XerD and that putative active site residues of the Xer recombinases are required for normal chromosome segregation. We have also shown that recombination by the loxP/Cre system of bacteriophage P1 will suppress the phenotype of a dif deletion strain when loxP is inserted in the terminus region. Suppression of the dif deletion phenotype did not occur when either dif/Xer or loxP/Cre recombination acted at other positions in the chromosome close to oriC or within lacZ, indicating that site-specific recombination must occur within the replication terminus region in order to allow normal chromosome segregation.     

Sites of recombination are local determinants of meiotic homolog pairing in Saccharomyces cerevisiae

Trans-acting factors involved in the early meiotic recombination pathway play a major role in promoting homolog pairing during meiosis in many plants, fungi, and mammals. Here we address whether or not allelic sites have higher levels of interaction when in cis to meiotic recombination events in the budding yeast Saccharomyces cerevisiae. We used Cre/loxP site-specific recombination to genetically measure the magnitude of physical interaction between loxP sites located at allelic positions on homologous chromosomes during meiosis. We observed nonrandom coincidence of Cre-mediated loxP recombination events and meiotic recombination events when the two occurred at linked positions. Further experiments showed that a subset of recombination events destined to become crossover products increased the frequency of nearby Cre-mediated loxP recombination. Our results support a simple physical model of homolog pairing in budding yeast, where recombination at numerous genomic positions generally serves to loosely coalign homologous chromosomes, while crossover-bound recombination intermediates locally stabilize interactions between allelic sites.     

Altered directionality in the Cre-LoxP site-specific recombination pathway

The site-specific recombinase Cre must employ control mechanisms to impose directionality on recombination. When two recombination sites (locus of crossing over in phage P1, loxP) are placed as direct repeats on the same DNA molecule, collision between loxP-bound Cre dimers leads to excision of intervening DNA. If two sites are placed as inverted repeats, the intervening segment is flipped around. Cre catalyzes these reactions in the absence of protein co-factors. Current models suggest that directionality is controlled at two steps in the recombination pathway: the juxtaposition of loxP sites and the single-strand-transfer reactions within the synaptic complex. Here, we show that in Escherichia coli strain 294-Cre, directionality for recombination is altered when the expression of Cre is increased. This leads to deletion instead of inversion on substrates carrying two loxP sites as inverted repeats. The nucleotide sequence composition of loxP sites remaining in aberrant products indicates that site alignment and/or DNA strand transfer in the in vivo Cre-loxP recombination pathway are not always tightly controlled.     

Using an in vivo phagemid system to identify non-compatible loxP sequences

The site-specific recombination system of bacteriophage P1 is composed of the Cre recombinase that recognizes a 34-bp loxP site. The Cre/loxP system has been extensively used to manipulate eukaryotic genomes for functional genomic investigations. The creation of additional heterologous loxP sequences potentially expands the utility of this system, but only if these loxP sequences do not recombine with one another. We have developed a stringent in vivo assay to examine the degree of recombination between all combinations of each previously published heterologous loxP sequence. As expected, homologous loxP sequences efficiently underwent Cre-mediated recombination. However, many of the heterologous loxP pairs were able to support recombination with rates varying from 5 to 100%. Some of these loxP sequences have previously been reported to be non-compatible with one another. Our study also confirmed other heterologous loxP pairs that had previously been shown to be non-compatible, as well as defined additional combinations that could be used in designing new recombination vectors.