Intra-chromosomal rearrangements generated by Cre-lox site-specific recombination.

Chromosomal rearrangements are useful genetic and breeding tools but are often difficult to detect and characterize. To more easily identify and define chromosome deletions and inversions, we have used the bacteriophage P1 Cre-lox site-specific recombination system to generate these events in plants. This involves three steps: (i) the introduction of two lox sites into one locus in a plant genome, including one site within a modified Ds transposon; (ii) Ac transposase-mediated transposition of the Ds-lox element to a new locus on the same chromosome; (iii) Cre-mediated site-specific recombination between the two lox sites that bracket a chromosome segment. We report the production of a deletion and three inversion events in tobacco. The utility of chromosomal segments bracketed by lox sites for targeted manipulation and cloning is discussed.     

Cre/lox位点特异重组系统在转基因植物中的应用

位点特异重组系统由重组酶和相应的重组酶识别位点组成,通过两者间的相互作用,实现外源基因精确整合与切除等一系列遗传操作.主要可分为Cre/lox系统、FLP/frt系统、R/RS系统和Gin/gix系统.目前,研究最充分应用最广泛的位点特异重组系统为Cre/lox系统.此系统为位点特异重组系统家族中的一员,由38.5kDCre重组酶和34bplox位点组成,最早被应用于动物转基因研究,包括基因敲除、基因激活、基因易位等.近年来,随着研究的深入,Cre/lox系统被逐步应用到植物研究中,并在诸多领域取得重大进展.本文总结归纳了Cre/lox系统在定点整合、定点切除以及叶绿体转化等方面的最新研究成果,旨在为利用Cre/lox系统构建环境安全和高效表达的植物遗传转化体系提供参考.     

A new approach for the identification and cloning of genes: the pBACwich system using Cre/lox site-specific recombination

With current plant transformation methods ( Agrobacterium, biolistics and protoplast fusion), insertion of DNA into the genome occurs randomly and in many instances at multiple sites. Associated position effects, copy number differences and multigene interactions can make gene expression experiments difficult to interpret and plant phenotypes less predictable. An alternative approach to random integration of large DNA fragments into plants is to utilize one of several site-specific recombination (SSR) systems, such as Cre/ lox. Cre has been shown in numerous instances to mediate lox site-specific recombination in animal and plant cells. By incorporating the Cre/ lox SSR system into a bacterial artificial chromosome (BAC) vector, a more precise evaluation of large DNA inserts for genetic complementation should be possible. Site-specific insertion of DNA into predefined sites in the genome may eliminate unwanted 'position effects' caused by the random integration of exogenously introduced DNA. In an effort to make the Cre/ lox system an effective tool for site-directed integration of large DNAs, we constructed and tested a new vector potentially capable of integrating large DNA inserts into plant and fungal genomes. In this study, we present the construction of a new BAC vector, pBACwich, for the system and the use of this vector to demonstrate SSR of large DNA inserts (up to 230 kb) into plant and fungal genomes.     

Cre-lox-based system for multiple gene deletions and selectable-marker removal in Lactobacillus plantarum

The classic strategy to achieve gene deletion variants is based on double-crossover integration of nonreplicating vectors into the genome. In addition, recombination systems such as Cre-lox have been used extensively, mainly for eukaryotic organisms. This study presents the construction of a Cre-lox-based system for multiple gene deletions in Lactobacillus plantarum that could be adapted for use on gram-positive bacteria. First, an effective mutagenesis vector (pNZ5319) was constructed that allows direct cloning of blunt-end PCR products representing homologous recombination target regions. Using this mutagenesis vector, double-crossover gene replacement mutants could be readily selected based on their antibiotic resistance phenotype. In the resulting mutants, the target gene is replaced by a lox66-P(32)-cat-lox71 cassette, where lox66 and lox71 are mutant variants of loxP and P(32)-cat is a chloramphenicol resistance cassette. The lox sites serve as recognition sites for the Cre enzyme, a protein that belongs to the integrase family of site-specific recombinases. Thus, transient Cre recombinase expression in double-crossover mutants leads to recombination of the lox66-P(32)-cat-lox71 cassette into a double-mutant loxP site, called lox72, which displays strongly reduced recognition by Cre. The effectiveness of the Cre-lox-based strategy for multiple gene deletions was demonstrated by construction of both single and double gene deletions at the melA and bsh1 loci on the chromosome of the gram-positive model organism Lactobacillus plantarum WCFS1. Furthermore, the efficiency of the Cre-lox-based system in multiple gene replacements was determined by successive mutagenesis of the genetically closely linked loci melA and lacS2 in L. plantarum WCFS1. The fact that 99.4% of the clones that were analyzed had undergone correct Cre-lox resolution emphasizes the suitability of the system described here for multiple gene replacement and deletion strategies in a single genetic background.     

Site-specific recombination of asymmetric lox sites mediated by a heterotetrameric Cre recombinase complex

Previous reports have demonstrated that new Cre recombinase specificities can be developed for symmetrically designed lox mutants through directed evolution. The development of Cre variants that allow the recombination of true asymmetric lox mutant sites has not yet been addressed, however. In the present study, we demonstrate that a mixture of two different site-specific Cre recombinase molecules (wt Cre and a mutant Cre) catalyzes efficient recombination between two asymmetric lox sites in vitro, presumably via formation of a functionally active heterotetrameric complex. The results may broaden the application of site-specific recombination in basic and applied research, including the custom-design of recombinases for natural, asymmetric, and lox-related target sequences present in the genome. Future applications may potentially include genomic manipulations, for example, site-specific integrations, deletions or substitutions within precise regions of the genomes of mammalians and other organisms.     

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.     

Cre-lox site-specific recombination between Arabidopsis and tobacco chromosomes

To create hybrid chromosomes, we tested the Cre-lox system to mediate recombination between Arabidopsis thaliana and Nicotiana tabacum chromosomes. Protoplasts of the two plants were fused to allow site-specific recombination to join a promoter from tobacco to a hygromycin resistance coding-region from Arabidopsis. The expected recombination junction was detected in hygromycin-resistant calli. Analysis of one hybrid suspension cell line revealed the presence of markers corresponding to the north arm of Arabidopsis chromosome III, but not markers from other chromosome arms. However, these markers were not detected in regenerated plants. With a second hybrid cell line we obtained a single hygromycin-resistant progeny from approximately 18 000 self-fertilized seeds of one regenerated plant. Molecular analysis of this hybrid indicated that a small portion of the north arm of Arabidopsis chromosome V is present in the tobacco genome. However, neither the recombination junction nor Arabidopsis DNA was detected in tissue from the plant grown without selection or in the subsequent generation. Thus interspecies transfer of a chromosome arm between plant cells is possible, but maintenance of the hybrid chromosome in a plant is unlikely. The feasibility of site-specific recombination between genomes of different species offers new possibilities for engineering hybrid chromosomes that may be maintained in cell culture.     

Cre/lox系统介导的位点特异性重组技术及其应用

Ｃｒｅ／ｌｏｘ系统是源于Ｐ１噬菌体的一个ＤＮＡ重组体系,它能导致在特定的ＤＮＡ序列（ｌｏｘＰ位点）处发生定点重组。该系统以将外源基因定点整合到染色体上或将特定ＤＮＡ片段删除;这种定位重组系统在遗传操作中发挥了重要的作用。     

The assembly of large BACs by in vivo recombination

We have developed a method for recombining bacterial artificial chromosomes (BACs) and P1 artificial chromosomes (PACs) containing large genomic DNA fragments into a single vector using the Cre-lox recombination system from bacteriophage P1 in vivo. This overcomes the limitations of in vitro methods for generating large constructs based on restriction digestion, ligation, and transformation of DNA into Escherichia coli cells. We used the method to construct a human artificial chromosome vector of 404 kb encompassing long tracts of alpha satellite DNA, telomeric sequences, and the human hypoxanthine phosphoribosyltransferase gene. The specificity of Cre recombinase for loxP sites minimizes the possibility of intramolecular rearrangements, unlike previous techniques using general homologous recombination in E. coli, and makes our method compatible with the presence of large arrays of repeated sequences in cloned DNA. This methodology may also be applied to retrofitting PACs or BACs with markers and functional sequences.     

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.     

Functional expression of the cre-lox site-specific recombination system in the yeast Saccharomyces cerevisiae.

The procaryotic cre-lox site-specific recombination system of coliphage P1 was shown to function in an efficient manner in a eucaryote, the yeast Saccharomyces cerevisiae. The cre gene, which codes for a site-specific recombinase, was placed under control of the yeast GALI promoter. lox sites flanking the LEU2 gene were integrated into two different chromosomes in both orientations. Excisive recombination at the lox sites (as measured by loss of the LEU2 gene) was promoted efficiently and accurately by the Cre protein and was dependent upon induction by galactose. These results demonstrate that a procaryotic recombinase can enter a eucaryotic nucleus and, moreover, that the ability of the Cre recombinase to perform precise recombination events on the chromosomes of S. cerevisiae is unimpaired by chromatin structure.     

In vivo modification of a maize engineered minichromosome

Engineered minichromosomes provide efficient platforms for stacking transgenes in crop plants. Methods for modifying these chromosomes in vivo are essential for the development of customizable systems for the removal of selection genes or other sequences and for the addition of new genes. Previous studies have demonstrated that Cre, a site-specific recombinase, could be used to modify lox sites on transgenes on maize minichromosomes; however, these studies demonstrated somatic recombination only, and modified minichromosomes could not be recovered. We describe the recovery of an engineered chromosome composed of little more than a centromere plus transgene that was derived by telomere-mediated truncation. We used the fiber fluorescence in situ hybridization technique and detected a transgene on the minichromosome inserted among stretches of CentC centromere repeats, and this insertion was large enough to suggest a tandem insertion. By crossing the minichromosome to a plant expressing Cre-recombinase, the Bar selection gene was removed, leaving behind a single loxP site. This study demonstrates that engineered chromosomes can be modified in vivo using site-specific recombinases, a demonstration essential to the development of amendable chromosome platforms in plants.     

A cell-free recombination system for site-specific integration of multigenic shuttle plasmids into the herpes simplex virus type 1 genome.

This report describes a novel method for complementation studies of defective herpes simplex virus (HSV) genes. Viral test gene and nonviral reporter gene cassettes were rapidly integrated into the HSV genome in a site-specific and reversible manner by using the P1 phage-based Cre-lox recombination system. Shuttle plasmids contained a functional loxP recombination site, an expressible form of the bacterial lacZ gene, and a copy of the wild-type glycoprotein B (gB) gene or double mutant gB allele containing both a temperature-sensitive (ts) mutation and a syncytium (syn)-forming mutation. A recipient viral genome, K delta T::lox1, was constructed from the HSV type 1 (syn) gB-deficient mutant virus, K delta T, by marker transfer of the loxP recombination site into the viral thymidine kinase locus. Shuttle plasmids of up to 12.9 kb in length were recombined with high efficiency (11 to 20%) into the K delta T::lox1 genome in cell-free, Cre-mediated recombination reactions. Expression of a functional wild-type or double mutant gB polypeptide complemented the nonfunctional polypeptide expressed from the deleted, normal gB locus and allowed production of either wild-type or Syn- plaques on Vero cells. The latter recombinant virus was also ts for growth. The ability to express viral genes from plasmids which can be shuttled into and out of the HSV genome in cell-free recombination reactions makes this a powerful method for performing genetic studies of the biologic properties of viral gene products.     

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.     

Single-site manipulation of tomato chromosomes in vitro and in vivo using Cre-lox site-specific recombination

With the aim of developing new techniques for physical and functional genome analysis, we have introduced the Cre-lox site-specific recombination system into the cultivated tomato (Lycopersicon esculentum). Local transposition of a Ds(lox) transposable element from a T-DNA(lox) on the long arm of chromosome 6 was used to position pairs of lox sites on different closely linked loci. In vitro Cre-lox recombination between chromosomal lox sites and synthetic lox oligonucleotides cleaved the 750 Mb tomato genome with 34 pb specificity to release unique 65 kb and 130 kb fragments of chromosome 6. Parallel in vitro experiments on Saccharomyces cerevisiae chromosomes show the efficiency of cleavage to be 50% per chromosomal lox site at maximum. By expressing the Cre recombinase in tomato under control of a constitutive CaMV 35S promoter, efficient and specific somatic and germinal in planta inversion of the 130 kb fragment is demonstrated. The combined use of in vitro and in vivo recombination on genetically mapped lox sites will provide new possibilities for long range restriction mapping and in vivo manipulation of selected tomato genome segments.     

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.     

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.     

In vivo and in vitro characterization of site-specific recombination of actinophage R4 integrase

The site-specific integrase of actinophage R4 belongs to the serine recombinase family. During the lysogenization process, it catalyzes site-specific recombination between the phage genome and the chromosome of Streptomyces parvulus 2297. An in vivo assay using Escherichia coli cells revealed that the minimum lengths of the recombination sites attB and attP are 50-bp and 49-bp, respectively, for efficient intramolecular recombination. The in vitro assay using overproduced R4 integrases as a hexahistidine (His(6))-glutathione-S-transferase (GST)-R4 integrase fusion protein, showed that the purified protein preparation retains the site-specific recombination activity which catalyzes the site-specific recombination between attP and attB in the intermolecular reaction. It also revealed that the inverted repeat within attP is essential for efficient in vitro intermolecular recombination. In addition, a gel shift assay showed that His(6)-GST-R4 integrase bound to the 50-bp attB and 49-bp attP specifically. Moreover, based on a detailed comparison analysis of amino acid sequences of serine integrases, we found the DNA binding region that is conserved in the serine recombinase containing the large C-terminal domain. Based on the results presented on this report, attachment sites needed in vitro and in vivo for site-specific recombination by the R4 integrase have been defined more precisely. This knowledge is useful for developing new genetic manipulation tools in the future.