The Cre recombinase cleaves the lox site in trans

Targeted expression in zebrafish primordial germ cells by Cre/loxP and Gal4/UAS systems

In zebrafish and other vertebrates, primordial germ cells (PGCs) are a population of embryonic cells that give rise to sperm and eggs in adults. Any type of genetically manipulated lines have to be originated from the germ cells of the manipulated founders, thus it is of great importance to establish an effective technology for highly specific PGC-targeted gene manipulation in vertebrates. In the present study, we used the Cre/loxP recombinase system and Gal4/UAS transcription system for induction and regulation of mRFP (monomer red fluorescent protein) gene expression to achieve highly efficient PGC-targeted gene expression in zebrafish. First, we established two transgenic activator lines, Tg(kop:cre) and Tg(kop:KalTA4), to express the Cre recombinases and the Gal4 activator proteins in PGCs. Second, we generated two transgenic effector lines, Tg(kop:loxP-SV40-loxP-mRFP) and Tg(UAS:mRFP), which intrinsically showed transcriptional silence of mRFP. When Tg(kop:cre) females were crossed with Tg(kop:loxP-SV40-loxP-mRFP) males, the loxP flanked SV40 transcriptional stop sequence was 100 % removed from the germ cells of the transgenic hybrids. This led to massive production of PGC-specific mRFP transgenic line, Tg(kop:loxP-mRFP), from an mRFP silent transgenic line, Tg(kop:loxP-SV40-loxP-mRFP). When Tg(kop:KalTA4) females were crossed with Tg(UAS:mRFP) males, the hybrid embryos showed PGC specifically expressed mRFP from shield stage till 25 days post-fertilization (pf), indicating the high sensitivity, high efficiency, and long-lasting effect of the Gal4/UAS system. Real-time PCR analysis showed that the transcriptional amplification efficiency of the Gal4/UAS system in PGCs can be about 300 times higher than in 1-day-pf embryos. More importantly, when the UAS:mRFP-nos1 construct was directly injected into the Tg(kop:KalTA4) embryos, it was possible to specifically label the PGCs with high sensitivity, efficiency, and persistence. Therefore, we have established two targeted gene expression platforms in zebrafish PGCs, which allows us to further manipulate the PGCs of zebrafish at different levels.

Efficient sequential repetitive gene deletions in Neurospora crassa employing a self-excising β-recombinase/six cassette

Despite its long-standing history as a model organism, Neurospora crassa has limited tools for repetitive gene deletions utilizing recyclable self-excising marker systems. Here we describe, for the first time, the functionality of a bacterial recombination system employing β-recombinase acting on six recognition sequences (β-rec/six) in N. crassa, which allowed repetitive site-specific gene deletion and marker recycling. We report generating the mus-51 deletion strain using this system, recycling the marker cassette, and subsequently deleting the global transcriptional regulator gene cre-1.

[Progress in Cre/lox site-specific recombination system in higher eukaryotes]

Cre/lox system derived from P1 bacteriaphage can quickly and effectively achieve gene insertion, deletion, replacement, and inversion by means of site-specific recombination. As one of the most important tools for gene targeting at present, Cre/lox system has been widely used in Arabidopsis thaliana, Oryza sativa L., Mus musculus, Drosophila melanogaster, Danio rerio, and other higher eukaryotic organisms. This review roundly described the basic profile of Cre/lox system, and its application in higher eukaryotes. In addition, we also discussed the main problems and developmental trend of the Cre/lox system in this review, which can be a good reference for using Cre/lox system to realize the gene manipulations of the different high eukaryotic organisms.

Restoration of catalytic functions in Cre recombinase mutants by electrostatic compensation between active site and DNA substrate

Two conserved catalytic arginines, Arg-173 and Arg-292, of the tyrosine site-specific recombinase Cre are essential for the transesterification steps of strand cleavage and joining in native DNA substrates containing scissile phosphate groups. The active site tyrosine (Tyr-324) provides the nucleophile for the cleavage reaction, and forms a covalent 3′-phosphotyrosyl intermediate. The 5′-hydroxyl group formed during cleavage provides the nucleophile for the joining reaction between DNA partners, yielding strand exchange. Previous work showed that substitution of the scissile phosphate (P) by methylphosphonate (MeP) permits strand cleavage by a Cre variant lacking Arg-292. We now demonstrate that MeP activation and cleavage are not blocked by substitution of Arg-173 or even simultaneous substitutions of Arg-173 and Arg-292 by alanine. Furthermore, Cre(R173A) and Cre(R292A) are competent in strand joining, Cre(R173A) being less efficient. No joining activity is detected with Cre(R173A, R292A). Consistent with their ability to cleave and join strands, Cre(R173A) and Cre(R292A) can promote recombination between two MeP-full-site DNA partners. These findings shed light on the overall contribution of active site electrostatics, and tease apart distinctive contributions of the individual arginines, to the chemical steps of recombination. They have general implications in active site mechanisms that promote important phosphoryl transfer reactions in nucleic acids.

Reactions of Cre with methylphosphonate DNA: similarities and contrasts with Flp and vaccinia topoisomerase

BACKGROUND

Reactions of vaccinia topoisomerase and the tyrosine site-specific recombinase Flp with methylphosphonate (MeP) substituted DNA substrates, have provided important insights into the electrostatic features of the strand cleavage and strand joining steps catalyzed by them. A conserved arginine residue in the catalytic pentad, Arg-223 in topoisomerase and Arg-308 in Flp, is not essential for stabilizing the MeP transition state. Topoisomerase or its R223A variant promotes cleavage of the MeP bond by the active site nucleophile Tyr-274, followed by the rapid hydrolysis of the MeP-tyrosyl intermediate. Flp(R308A), but not wild type Flp, mediates direct hydrolysis of the activated MeP bond. These findings are consistent with a potential role for phosphate electrostatics and active site electrostatics in protecting DNA relaxation and site-specific recombination, respectively, against abortive hydrolysis.

METHODOLOGY/PRINCIPAL FINDINGS

We have examined the effects of DNA containing MeP substitution in the Flp related Cre recombination system. Neutralizing the negative charge at the scissile position does not render the tyrosyl intermediate formed by Cre susceptible to rapid hydrolysis. Furthermore, combining the active site R292A mutation in Cre (equivalent to the R223A and R308A mutations in topoisomerase and Flp, respectively) with MeP substitution does not lead to direct hydrolysis of the scissile MeP bond in DNA. Whereas Cre follows the topoisomerase paradigm during the strand cleavage step, it follows the Flp paradigm during the strand joining step.

CONCLUSIONS/SIGNIFICANCE

Collectively, the Cre, Flp and topoisomerase results highlight the contribution of conserved electrostatic complementarity between substrate and active site towards transition state stabilization during site-specific recombination and DNA relaxation. They have potential implications for how transesterification reactions in nucleic acids are protected against undesirable abortive side reactions. Such protective mechanisms are significant, given the very real threat of hydrolytic genome damage or disruption of RNA processing due to the cellular abundance and nucleophilicity of water.

A chimeric Cre recombinase with regulated directionality

From bacterial viruses to humans, site-specific recombination and transposition are the major pathways for rearranging genomes on both long- and short-time scales. The site-specific pathways can be divided into 2 groups based on whether they are stochastic or regulated. Recombinases Cre and lambda Int are well-studied examples of each group, respectively. Both have been widely exploited as powerful and flexible tools for genetic engineering: Cre primarily in vivo and lambda Int primarily in vitro. Although Cre and Int use the same mechanism of DNA strand exchange, their respective reaction pathways are very different. Cre-mediated recombination is bidirectional, unregulated, does not require accessory proteins, and has a minimal symmetric DNA target. We show that when Cre is fused to the small N-terminal domain of Int, the resulting chimeric Cre recombines complex higher-order DNA targets comprising >200 bp encoding 16 protein-binding sites. This recombination requires the IHF protein, is unidirectional, and is regulated by the relative levels of the 3 accessory proteins, IHF, Xis, and Fis. In one direction, recombination depends on the Xis protein, and in the other direction it is inhibited by Xis. It is striking that regulated directionality and complexity can be conferred in a simple chimeric construction. We suggest that the relative ease of constructing a chimeric Cre with these properties may simulate the evolutionary interconversions responsible for the large variety of site-specific recombinases observed in Archaea, Eubacteria, and Eukarya.

Protein-induced local DNA bends regulate global topology of recombination products

The tyrosine family of recombinases produces two smaller DNA circles when acting on circular DNA harboring two recombination sites in head-to-tail orientation. If the substrate is supercoiled, these circles can be unlinked or form multiply linked catenanes. The topological complexity of the products varies strongly even for similar recombination systems. This dependence has been solved here. Our computer simulation of the synapsis showed that the bend angles, phi, created in isolated recombination sites by protein binding before assembly of the full complex, determine the product topology. To verify the validity of this theoretical finding we measured the values of phi for Cre/loxP and Flp/FRT systems. The measurement was based on cyclization of the protein-bound short DNA fragments in solution. Despite the striking similarity of the synapses for these recombinases, action of Cre on head-to-tail target sites produces mainly unlinked circles, while that of Flp yields multiply linked catenanes. In full agreement with theoretical expectations we found that the values of phi for these systems are very different, close to 35 degrees and 80 degrees, respectively. Our findings have general implications in how small protein machines acting locally on large DNA molecules exploit statistical properties of their substrates to bring about directed global changes in topology.

A novel, topologically constrained DNA molecule containing a double Holliday junction: design, synthesis, and initial biochemical characterization

The double Holliday junction (dHJ) is a central intermediate to homologous recombination, but biochemical analysis of the metabolism of this structure has been hindered by the lack of a substrate that adequately replicates the endogenous structure. We have synthesized a novel dHJ substrate that consists of two small, double stranded DNA circles conjoined by two Holliday junctions (HJs). Its biochemical synthesis is based on the production of two pairs of single stranded circles from phagemids, followed by their sequential annealing with reverse gyrase. The sequence between the two HJs is identical on both strands, allowing the HJs to migrate without the generation of unpaired regions of DNA, whereas the distance between the HJs is on the order of gene conversion tracts thus far measured in Drosophila and mouse model systems. The structure of this substrate also provides similar topological constraint as would occur in an endogenous dHJ. Digestion of the dHJ substrate by T7 endonuclease I resolves the substrate into crossover and non-crossover products, as predicted by the Szostak model of double strand break repair. This substrate will greatly facilitate the examination of the mechanism of resolution of double Holliday junctions.

Modification of the Creator recombination system for proteomics applications--improved expression by addition of splice sites

Background

Recombinational systems have been developed to rapidly shuttle Open Reading Frames (ORFs) into multiple expression vectors in order to analyze the large number of cDNAs available in the post-genomic era. In the Creator system, an ORF introduced into a donor vector can be transferred with Cre recombinase to a library of acceptor vectors optimized for different applications. Usability of the Creator system is impacted by the ability to easily manipulate DNA, the number of acceptor vectors for downstream applications, and the level of protein expression from Creator vectors.

Results

To date, we have developed over 20 novel acceptor vectors that employ a variety of promoters and epitope tags commonly employed for proteomics applications and gene function analysis. We also made several enhancements to the donor vectors including addition of different multiple cloning sites to allow shuttling from pre-existing vectors and introduction of the lacZ alpha reporter gene to allow for selection. Importantly, in order to ameliorate any effects on protein expression of the loxP site between a 5' tag and ORF, we introduced a splicing event into our expression vectors. The message produced from the resulting 'Creator Splice' vector undergoes splicing in mammalian systems to remove the loxP site. Upon analysis of our Creator Splice constructs, we discovered that protein expression levels were also significantly increased.

Conclusion

The development of new donor and acceptor vectors has increased versatility during the cloning process and made this system compatible with a wider variety of downstream applications. The modifications introduced in our Creator Splice system were designed to remove extraneous sequences due to recombination but also aided in downstream analysis by increasing protein expression levels. As a result, we can now employ epitope tags that are detected less efficiently and reduce our assay scale to allow for higher throughput. The Creator Splice system appears to be an extremely useful tool for proteomics.

Reverse gyrase functions as a DNA renaturase: annealing of complementary single-stranded circles and positive supercoiling of a bubble substrate

Reverse gyrase is a hyperthermophile-specific enzyme that can positively supercoil DNA concomitant with ATP hydrolysis. However, the DNA supercoiling activity is inefficient and requires an excess amount of enzyme relative to DNA. We report here several activities that reverse gyrase can efficiently mediate with a substoichiometric amount of enzyme. In the presence of a nucleotide cofactor, reverse gyrase can readily relax negative supercoils, but not the positive ones, from a plasmid DNA substrate. Reverse gyrase can completely relax positively supercoiled DNA, provided that the DNA substrate contains a single-stranded bubble. Reverse gyrase efficiently anneals complementary single-stranded circles. A substoichiometric amount of reverse gyrase can insert positive supercoils into DNA with a single-stranded bubble, in contrast to plasmid DNA substrate. We have designed a novel method based on phage-mid DNA vectors to prepare a circular DNA substrate containing a single-stranded bubble with defined length and sequence. With these bubble DNA substrates, we demonstrated that efficient positive supercoiling by reverse gyrase requires a bubble size larger than 20 nucleotides. The activities of annealing single-stranded DNA circles and positive supercoiling of bubble substrate demonstrate that reverse gyrase can function as a DNA renaturase. These biochemical activities also suggest that reverse gyrase can have an important biological function in sensing and eliminating unpaired regions in the genome of a hyperthermophilic organism.

Mutational analysis of the archaeal tyrosine recombinase SSV1 integrase suggests a mechanism of DNA cleavage in trans

The only tyrosine recombinase so far studied in archaea, the SSV1 integrase, harbors several changes in the canonical residues forming the catalytic pocket of this family of recombinases. This raised the possibility of a different mechanism for archaeal tyrosine recombinase. The residues of Int(SSV) tentatively involved in catalysis were modified by site-directed mutagenesis, and the properties of the corresponding mutants were studied. The results show that all of the targeted residues are important for activity, suggesting that the archaeal integrase uses a mechanism similar to that of bacterial or eukaryotic tyrosine recombinases. In addition, we show that Int(SSV) exhibits a type IB topoisomerase activity because it is able to relax both positive and negative supercoils. Interestingly, in vitro complementation experiments between the inactive integrase mutant Y314F and all other inactive mutants restore in all cases enzymatic activity. This suggests that, as for the yeast Flp recombinase, the active site is assembled by the interaction of the tyrosine from one monomer with the other residues from another monomer. The shared active site paradigm of the eukaryotic Flp protein may therefore be extended to the archaeal tyrosine recombinase Int(SSV).

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.

Vanadate-based transition-state analog inhibitors of Cre-LoxP recombination

Cre recombinase exchanges DNA strands at the LoxP recognition site via transphosphorylation reactions that involve pentacoordinate transition states. We demonstrate that meta-vanadate ion (VO(3)(-)) and appropriate DNA substrates assemble a transition-state analog-like complex in the Cre active site. Meta-vanadate inhibits recombination of LoxP-derived oligonucleotide substrates that contain a gap at either or both scissile phosphates, but does not inhibit reactions with intact LoxP. The 3(')-hydroxyl group of the gapped substrate is required for inhibition, suggesting that vanadate is ligated by three oxo ligands. Assembly of the inhibited complex is slow (t(1/2)=19min at 4mM NaVO(3)) and requires Cre, substrates, and meta-vanadate. Holliday junction intermediates accumulated at lower meta-vanadate concentrations, suggesting that the second strand exchange is inhibited more readily than the first. The apparent K(D) for meta-vanadate is 1.5-2mM and binding shows positive cooperativity. This methodology may have general application for mechanistic studies of recombinase/topoisomerase-mediated strand exchange reactions.

Mutational analysis of loxP sites for efficient Cre-mediated insertion into genomic DNA

The Cre/loxP system has been used in transgenic models primarily to excise DNA flanked by loxP sites for gene deletion. However, the insertion reaction is more difficult to control since the excision event is kinetically favored. Mutant loxP sites favoring integration were identified using a novel, bacterial screening system. Utilizing lambda integrase, mutant loxP sites were placed at the E. coli attB site and the excision-insertion ratios of incoming DNA plasmids carrying a second, complementary mutant loxP site were determined. Comparison of 50 mutant loxP sites combinations to the native loxP site revealed that mutations to the inner 6 bp of the Cre binding domain severely inhibited recombination, while those in the outer 8 bps were more tolerated. The most efficient loxP combinations resulted in 1421-fold and 1529-fold increases in relative integration rates over wild-type loxP sites. These loxP mutants could be exploited for site-directed "tag and insert" recombination experiments.

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.

Dynamics and DNA substrate recognition by the catalytic domain of lambda integrase

Bacteriophage lambda integrase (lambda-Int) is the prototypical member of a large family of enzymes that catalyze site-specific DNA recombination via the formation of a Holliday junction intermediate. DNA strand cleavage by lambda-Int is mediated by nucleophilic attack on the scissile phosphate by a conserved tyrosine residue, forming an intermediate with the enzyme covalently attached to the 3'-end of the cleaved strand via a phosphotyrosine linkage. The crystal structure of the catalytic domain of lambda-Int (C170) obtained in the absence of DNA revealed the tyrosine nucleophile at the protein's C terminus to be located on a beta-hairpin far from the other conserved catalytic residues and adjacent to a disordered loop. This observation suggested that a conformational change in the C terminus of the protein was required to generate the active site in cis, or alternatively, that the active site could be completed in trans by donation of the tyrosine nucleophile from a neighboring molecule in the recombining synapse. We used NMR spectroscopy together with limited proteolysis to examine the dynamics of the lambda-Int catalytic domain in the presence and absence of DNA half-site substrates with the goal of characterizing the expected conformational change. Although the C terminus is indeed flexible in the absence of DNA, we find that conformational changes in the tyrosine-containing beta-hairpin are not coupled to DNA binding. To gain structural insights into C170/DNA complexes, we took advantage of mechanistic conservation with Cre and Flp recombinases to model C170 in half-site and tetrameric Holliday junction complexes. Although the models do not reveal the nature of the conformational change required for cis cleavage, they are consistent with much of the available experimental data and provide new insights into the how trans complementation could be accommodated.

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.

Conservation of structure and function among tyrosine recombinases: homology-based modeling of the lambda integrase core-binding domain

Tyrosine recombinases participate in diverse biological processes by catalyzing recombination between specific DNA sites. Although a conserved protein fold has been described for the catalytic (CAT) domains of five recombinases, structural relationships between their core-binding (CB) domains remain unclear. Despite differences in the specificity and affinity of core-type DNA recognition, a conserved binding mechanism is suggested by the shared two-domain motif in crystal structure models of the recombinases Cre, XerD and Flp. We have found additional evidence for conservation of the CB domain fold. Comparison of XerD and Cre crystal structures showed that their CB domains are closely related; the three central alpha-helices of these domains are superposable to within 1.44 A. A structure-based multiple sequence alignment containing 25 diverse CB domain sequences provided evidence for widespread conservation of both structural and functional elements in this fold. Based upon the Cre and XerD crystal structures, we employed homology modeling to construct a three-dimensional structure for the lambda integrase CB domain. The model provides a conceptual framework within which many previously identified, functionally important amino acid residues were investigated. In addition, the model predicts new residues that may participate in core-type DNA binding or dimerization, thereby providing hypotheses for future genetic and biochemical experiments.

Cre-loxP biochemistry

Cre recombinase is now widely used to carry out complex manipulations of DNA molecules both in vitro and in vivo. For in vitro experiments, there is a clear need for highly pure preparations of Cre and of Cre mutants that serve as controls or supply an altered activity or specificity. In vivo experiments utilizing Cre variants also often require in vitro characterization and some applications involve transfection of purified enzyme to achieve transient activity in the cell. This review outlines a detailed protocol for purification of native Cre and describes straightforward assays that can be used to test for recombination activity in vitro. The design of experiments to trap the intermediates of Cre-loxP site-specific recombination for biophysical studies is also presented. The methods described should be useful to any investigator with a need for purified Cre recombinase and should be broadly applicable to related site-specific recombination systems.

The order of strand exchanges in Cre-LoxP recombination and its basis suggested by the crystal structure of a Cre-LoxP Holliday junction complex

Cre recombinase uses two pairs of sequential cleavage and religation reactions to exchange homologous DNA strands between 34 base-pair (bp) LoxP recognition sequences. In the oligomeric recombination complex, a switch between "cleaving" and "non-cleaving" subunit conformations regulates the number, order, and regio-specificity of the strand exchanges. However, the particular sequence of events has been in question. From analysis of strand composition of the Holliday junction (HJ) intermediate, we determined that Cre initiates recombination of LoxP by cleaving the upper strand on the left arm. Cre preferred to react with the left arm of a LoxP suicide substrate, but at a similar rate to the right arm, indicating that the first strand to be exchanged is selected prior to cleavage. We propose that during complex assembly the cleaving subunit preferentially associates with the LoxP left arm, directing the first strand exchange to that side. In addition, this biased assembly would enforce productive orientation of LoxP sites in the recombination synapses. A novel Cre-HJ complex structure in which LoxP was oriented with the left arm bound by the cleaving Cre subunit suggested a physical basis for the strand exchange order. Lys86 and Lys201 interact with the left arm scissile adenine base differently than in structures that have a scissile guanine. These interactions are associated with positioning the 198-208 loop, a structural component of the conformational switch, in a configuration that is specific to the cleaving conformation. Our results suggest that strand exchange order and site alignment are regulated by an "induced fit" mechanism in which the cleaving conformation is selectively stabilized through protein-DNA interactions with the scissile base on the strand that is cleaved first.

Directional resolution of synthetic holliday structures by the Cre recombinase

The Cre recombinase of bacteriophage P1 cleaves its target site, loxP, in a defined order. Recombination is initiated on one pair of strands to form a Holliday intermediate, which is then resolved by cleavage and exchange of the other pair of strands to yield recombinant products. To investigate the influence of the loxP sequence on the directionality of resolution, we constructed synthetic Holliday (chi) structures containing either wild-type or mutant lox sites. We found that Cre preferentially resolved the synthetic wild-type chi structures on a particular pair of strands. The bias in the direction of resolution was dictated by the asymmetric loxP sequence since the resolution bias was abolished with symmetric lox sites. Systematic substitutions of the loxP site revealed that the bases immediately 5' to the scissile phosphodiester bonds were primarily responsible for the directionality of resolution. Interchanging these base pairs was sufficient to reverse the resolution bias. The Cre-lox co-crystal structures show that Lys(86) makes a base-specific contact with guanine immediately 5' to one of the scissile phosphates. Substituting Lys(86) with alanine resulted in a reduction of the resolution bias, indicating that this amino acid is important for establishing the bias in resolution.

An engineeredloxsequence 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.Key words: Cre/lox recombination system, sequence similarity, protein-DNA interaction, long terminal repeat, HIV-1 therapy.

Trans complementation of variant Cre proteins for defects in cleavage and synapsis

The Cre recombinase is a member of the integrase family of conservative site-specific recombinases. These proteins share five conserved catalytic residues, one of which is a tyrosine that acts as the nucleophile to attack the scissile phosphodiester bond in the DNA target. Recombination by the Cre recombinase takes place in a supramolecular structure called a synapse that consists of four molecules of Cre bound to two DNA target sequences called lox sites. The synapse is held together by an intricate network of protein-protein interactions. They bend the two sites into square planar structure that resembles a Holliday intermediate. We have studied three mutant Cre proteins that appear to have defects in synapsis (Cre A36V, Cre T41F, and Cre G314R). We found that they were unable to carry out strand cleavage but that cleavage occurred if they were mixed with a cleavage-defective Cre protein that lacks the catalytic nucleophilic tyrosine residue. The three variant proteins could also be complemented for the formation of a novel structure ("complexV"), which may be a cleaved synaptic intermediate. We suggest that these three mutant proteins have a defect in DNA bending and discuss the relationship between bending, synapsis, and cleavage.

Chimeras of the Flp and Cre recombinases: tests of the mode of cleavage by Flp and Cre

The Flp and Cre recombinases are members of the integrase family of tyrosine recombinases. Each protein consists of a 13 kDa NH(2)-terminal domain and a larger COOH-terminal domain that contains the active site of the enzyme. The COOH-terminal domain also contains the major determinants for the binding specificity of the recombinase to its cognate DNA binding site. All family members cleave the DNA by the attachment of a conserved nucleophilic tyrosine residue to the 3'-phosphate group at the sites of cleavage. In order to gain further insights into the determinants of the binding specificity and modes of cleavage of Flp and Cre, we have made chimeric proteins in which we have fused the NH(2)-terminal domain of Flp to the COOH-terminal domain of Cre ("Fre") and the NH(2)-terminal domain of Cre to the COOH-terminal domain of Flp ("Clp"). These chimeras have novel binding specificities in that they bind strongly to hybrid sites containing elements from both the Flp and Cre DNA targets but poorly to the native target sites. In this study we have taken advantage of the unique binding specificities of Fre and Clp to examine the mode of cleavage by Cre, Flp, Fre and Clp. We find that the COOH-terminal domain of the recombinases determines their mode of cleavage. Thus Flp and Clp cleave in trans whereas Cre and Fre cleave in cis. These results agree with the studies of Flp and with the cocrystal structure of Cre bound to its DNA target site. They disagree with our previous findings that Cre could carry out trans cleavage. We discuss the variations in the experimental approaches in order to reconcile the different results.

DNA recognition, strand selectivity, and cleavage mode during integrase family site-specific recombination

We have probed the association of Flp recombinase with its DNA target using protein footprinting assays. The results are consistent with the domain organization of the Flp protein and with the general features of the protein-DNA interactions revealed by the crystal structures of the recombination intermediates formed by Cre, the Flp-related recombinase. The similarity in the organization of the Flp and Cre target sites and in their recognition by the respective recombinases implies that the overall DNA-protein geometry during strand cleavage in the two systems must also be similar. Within the functional recombinase dimer, it is the interaction between two recombinase monomers bound on either side of the strand exchange region (or spacer) that provides the allosteric activation of a single active site. Whereas Cre utilizes the cleavage nucleophile (the active site tyrosine) in cis, Flp utilizes it in trans (one monomer donating the tyrosine to its partner). By using synthetic Cre and Flp DNA substrates that are geometrically restricted in similar ways, we have mapped the positioning of the active and inactive tyrosine residues during cis and trans cleavage events. We find that, for a fixed substrate geometry, Flp and Cre cleave the labile phosphodiester bond at the same spacer end, not at opposite ends. Our results provide a model that accommodates local heterogeneities in peptide orientations in the two systems while preserving the global functional architecture of the reaction complex.

Investigation of Schizosaccharomyces pombe as a cloning host for human telomere and alphoid DNA

The fission yeast Schizosaccharomyces pombe (Sch. pombe) has been proposed as a possible cloning host for both mammalian artificial chromosomes (MACs) and mammalian genomic libraries, due to the large size of its chromosomes and its similarity to higher eukaryotic cells. Here, it was investigated for its ability to form telomeres from human telomere sequence and to stably maintain long stretches of alphoid DNA. Using linear constructs terminating in the telomere repeat, T2AG3, human telomere DNA was shown to efficiently seed telomere formation in Sch. pombe. Much of the human telomeric sequence was removed on addition of Sch. pombe telomeric sequence, a process similar to that described in S. cerevisiae. To investigate the stability of alphoid DNA in fission yeast, bacterial artificial chromosomes (BACs) containing 130 and 173 kb of alphoid DNA were retrofitted with the Sch. pombe ars1 element and ura4+ marker using Cre-lox recombination. These alphoid BACs were found to be highly unstable in Sch. pombe deleting down to less than 40 kb, whilst control BACs of 96 and 202 kb, containing non-repetitive DNA, were unrearranged. Alphoid DNA has been shown to be sufficient for human centromere function, and this marked instability excludes Sch. pombe as a useful cloning host for mammalian artificial chromosomes. In addition, regions containing repetitive DNA from mammalian genomes may not be truly represented in libraries constructed in Sch. pombe.

The integrase family of recombinase: organization and function of the active site

The integrase family of site-specific recombinases (also called the tyrosine recombinases) mediate a wide range of biological outcomes by the sequential exchange of two pairs of DNA strands at defined phosphodiester positions. The reaction produces a recombinant arrangement of the DNA sequences flanking the cross-over region. The crystal structures of four integrase family members have revealed very similar three-dimensional protein folds that belie the large diversity in amino acid sequences among them. The active sites are similar in organization to those seen in structures of eukaryotic type IB topoisomerases, and conservation of catalytic mechanism is expected. The crystal structures, combined with previous biochemical knowledge, allow the refinement of models for recombination and the assignment of catalytic function to the active site residues. However, each system has its own peculiarities, and the exact sequence of events that allows the reaction to proceed from the first exchange reaction to the second is still unclear for at least some family members.

Wild-type Flp recombinase cleaves DNA in trans

Site-specific recombinases of the Integrase family utilize a common chemical mechanism to break DNA strands during recombination. A conserved Arg-His-Arg triad activates the scissile phosphodiester bond, and an active-site tyrosine provides the nucleophile to effect DNA cleavage. Is the tyrosine residue for the cleavage event derived from the same recombinase monomer which provides the RHR triad (DNA cleavage in cis), or are the triad and tyrosine derived from two separate monomers (cleavage in trans)? Do all members of the family follow the same cleavage rule, cis or trans? Solution studies and available structural data have provided conflicting answers. Experimental results with the Flp recombinase which strongly support trans cleavage have been derived either by pairing two catalytic mutants of Flp or by pairing wild-type Flp and a catalytic mutant. The inclusion of the mutant has raised new concerns, especially because of the apparent contradictions in their cleavage modes posed by other Int family members. Here we test the cleavage mode of Flp using an experimental design which excludes the use of the mutant protein, and show that the outcome is still only trans DNA cleavage.

Structure and mechanism in site-specific recombination

Three-dimensional structural information on the integrase family of site-specific recombinases has only recently become available, with the crystal structures of catalytic domains, full-length proteins and protein-DNA complexes of this family reported over the past two years. These results have led to a model for the overall architecture and active site stereochemistry of the recombination pathway that addresses a number of interesting mechanistic issues.

The same two monomers within a MuA tetramer provide the DDE domains for the strand cleavage and strand transfer steps of transposition

The chemistry of Mu transposition is executed within a tetrameric form of the Mu transposase (MuA protein). A triad of DDE (Asp, Asp35Glu motif) residues in the central domain of MuA (DDE domain) is essential for both the strand cleavage and strand transfer steps of transposition. Previous studies had suggested that complete Mu transposition requires all four subunits in the MuA tetramer to carry an active DDE domain. Using a mixture of MuA proteins with either wild-type or altered att-DNA binding specificities, we have now designed specific arrangements of MuA subunits carrying the DDE domain. From analysis of the abilities of oriented tetramers to carry out DNA cleavage and strand transfer from supercoiled DNA, a new picture of the disposition of DNA and protein partners during transposition has emerged. For DNA cleavage, two subunits of MuA located at attL1 and attR1 (sites that undergo cleavage) provide DDE residues in trans. The same two subunits contribute DDE residues for strand transfer, also in trans. Thus, only two active DDE+ monomers within the tetramer carry out complete Mu transposition. We also show that when the attR1-R2 arrangement used on supercoiled substrates is tested for cleavage on linear substrates, alternative chemically competent DNA-protein associations are produced, wherein the functional DDE subunits are positioned at R2 rather than at R1.

Selection of novel, specific single-stranded DNA sequences by Flp, a duplex-specific DNA binding protein

Flp is a member of the integrase family of site-specific recombinases. Flp is known to be a double-stranded (ds)DNA binding protein that binds sequence specifically to the 13 bp binding elements in the FRT site (Flprecognitiontarget). We subjected a random pool of oligonucleotides to the in vitro binding site selection method and have unexpectedly recovered a series of single-stranded oligonucleotides to which Flp binds with high affinity. These single-stranded oligonucleotides differ in sequence from the duplex FRT site. The minimal length of the oligonucleotides which is active is 29 nt. This single strand-specific DNA binding activity is located in the same C-terminal 32 kDa domain of Flp in which the site-specific dsDNA binding activity resides. Competition studies suggest that the apparent affinity of Flp for single-stranded oligonucleotide is somewhat less than for a complete duplex FRT site but greater than for a single duplex 13 bp binding element. We have also shown that Cre, another member of the integrase family of site-specific recombinases, also exhibits single-stranded DNA binding similar to that of Flp.

Similarities and differences among 105 members of the Int family of site-specific recombinases

Alignments of 105 site-specific recombinases belonging to the Int family of proteins identified extended areas of similarity and three types of structural differences. In addition to the previously recognized conservation of the tetrad R-H-R-Y, located in boxes I and II, several newly identified sequence patches include charged amino acids that are highly conserved and a specific pattern of buried residues contributing to the overall protein fold. With some notable exceptions, unconserved regions correspond to loops in the crystal structures of the catalytic domains of lambda Int (Int c170) and HP1 Int (HPC) and of the recombinases XerD and Cre. Two structured regions also harbor some pronounced differences. The first comprises beta-sheets 4 and 5, alpha-helix D and the adjacent loop connecting it to alpha-helix E: two Ints of phages infecting thermophilic bacteria are missing this region altogether; the crystal structures of HPC, XerD and Cre reveal a lack of beta-sheets 4 and 5; Cre displays two additional beta-sheets following alpha-helix D; five recombinases carry large insertions. The second involves the catalytic tyrosine and is seen in a comparison of the four crystal structures. The yeast recombinases can theoretically be fitted to the Int fold, but the overall differences, involving changes in spacing as well as in motif structure, are more substantial than seen in most other proteins. The phenotypes of mutations compiled from several proteins are correlated with the available structural information and structure-function relationships are discussed. In addition, a few prokaryotic and eukaryotic enzymes with partial homology with the Int family of recombinases may be distantly related, either through divergent or convergent evolution. These include a restriction enzyme and a subgroup of eukaryotic RNA helicases (D-E-A-D proteins).

Mechanism of active site exclusion in a site-specific recombinase: role of the DNA substrate in conferring half-of-the-sites activity

The Flp site-specific recombinase assembles its active site by recruiting the catalytic tyrosine (Tyr-343) from one Flp monomer into the pro-active site containing a triad of Arg-191, His-305, and Arg-308 from a second monomer. In principle, two active sites may be assembled from a Flp dimer by simultaneous, reciprocal contribution of the shared amino acids by its constituent monomers. In practice, only one of the two active sites is assembled at a time, as would be consistent with a recombination mechanism involving two steps of single-strand exchanges. By using substrates containing strand-specific base bulges, we demonstrate that the relative disposition of their DNA arms can account for this active site exclusion. We also show that the exclusion mechanism operates only at the level of positioning Tyr-343 with respect to the pro-active site, and not at the level of orienting the labile phosphodiester bond within the DNA chain. It is not negative cooperativity of substrate binding but, rather, the substrate-induced negative cooperativity in protein orientation that accomplishes half-of-the-sites activity in the Flp system.

Site-specific recombination: synapsis and strand exchange revealed

Recently determined crystal structures of several members of the lambda integrase family of site-specific recominases have provided insights into the cis versus trans action of active site constituents, and hte processes of synapsis and strand exchange.

The integrase family of tyrosine recombinases: evolution of a conserved active site domain

The integrases are a diverse family of tyrosine recombinases which rearrange DNA duplexes by means of conservative site-specific recombination reactions. Members of this family, of which the well-studied lambda Int protein is the prototype, were previously found to share four strongly conserved residues, including an active site tyrosine directly involved in transesterification. However, few additional sequence similarities were found in the original group of 27 proteins. We have now identified a total of 81 members of the integrase family deposited in the databases. Alignment and comparisons of these sequences combined with an evolutionary analysis aided in identifying broader sequence similarities and clarifying the possible functions of these conserved residues. This analysis showed that members of the family aggregate into subfamilies which are consistent with their biological roles; these subfamilies have significant levels of sequence similarity beyond the four residues previously identified. It was also possible to map the location of conserved residues onto the available crystal structures; most of the conserved residues cluster in the predicted active site cleft. In addition, these results offer clues into an apparent discrepancy between the mechanisms of different subfamilies of integrases.

Flexibility in DNA recombination: structure of the lambda integrase catalytic core

Lambda integrase is archetypic of site-specific recombinases that catalyze intermolecular DNA rearrangements without energetic input. DNA cleavage, strand exchange, and religation steps are linked by a covalent phosphotyrosine intermediate in which Tyr342 is attached to the 3'-phosphate of the DNA cut site. The 1.9 angstrom crystal structure of the integrase catalytic domain reveals a protein fold that is conserved in organisms ranging from archaebacteria to yeast and that suggests a model for interaction with target DNA. The attacking Tyr342 nucleophile is located on a flexible loop about 20 angstroms from a basic groove that contains all the other catalytically essential residues. This bipartite active site can account for several apparently paradoxical features of integrase family recombinases, including the capacity for both cis and trans cleavage of DNA.