An accumulative site‐specific gene integration system using cre recombinase‐mediated cassette exchange

The Cre‐loxP system is frequently used for site‐specific recombination in animal cells. The equilibrium and specificity of the recombination reaction can be controlled using mutated loxPs. In the present study, we designed an accumulative site‐specific gene integration system using Cre recombinase and mutated loxPs in which the Cre‐mediated cassette exchange reaction is infinitely repeatable for target gene integration into loxP target sites. To evaluate the feasibility and usefulness of this system, a series of integration reactions were repeated and confirmed in vitro using Cre recombinase protein and plasmids. Accumulative gene integration was also performed on the genome of Chinese hamster ovary (CHO) cells. The results indicated that the system was applicable for repeated gene integration of multiple genes to the target sites on both plasmids and CHO cell genomes. This gene integration system provides a novel strategy for gene amplification and for biological analyses of gene function through the genetic modification of cells and organisms. Biotechnol. Bioeng. 2010;105: 1106–1114. © 2009 Wiley Periodicals, Inc.     

Conditional gene knockout using cre recombinase

Cre recombinase has become an important instrument for achieving precise genetic manipulation in mice. Many of these desired genetic manipulations rely on Cre’s ability to direct spatially and temporally specified excision of a predesignated DNA sequence that has been flanked by directly repeated copies of the loxP recombination site. Success in achieving such conditional mutagenesis in mice depends both on the careful design of conditional alleles and on reliable detection of cre gene expression. These procedures include PCR, immunohistochemistry and the use of a recombination-proficient GFP-tagged Cre protein.     

Cre/loxP-mediated deletion system for large genome rearrangements in Corynebacterium glutamicum

Genome rearrangement is an increasingly important technique to facilitate the understanding of genome functions. A Cre/loxP-mediated deletion system for large-scale genome rearrangements in Corynebacterium glutamicum was developed. By comparative analysis of C. glutamicum R and C. glutamicum 13032 genomes, distinct 14.5-kb and 56-kb regions not essential for cell survival were identified and targeted for deletion. By homologous recombination, loxP sites were integrated at each end of the target region. Deletions between the two chromosomal loxP sites in the presence of Cre recombinase were highly efficient. Accurate deletion was observed in all 96 Cre-expressing strains tested. These deletions represent the largest genomic excisions in C. glutamicum reported to date. Despite the loss of 11 and 58 predicted ORF(s), respectively, upon the deletion of the14.5-kb and 56-kb regions, the cells still exhibited normal growth under standard laboratory conditions. Based on the precision of its deletion, the Cre/loxP system provides a new, efficient genome rearrangement technique for studying C. glutamicum.     

Mutually exclusive recombination of wild-type and mutant loxP sites in vivo facilitates transposon-mediated deletions from both ends of genomic DNA in PACs

Recombination of wild-type and mutant loxP sites mediated by wild-type Cre protein was analyzed in vivo using a sensitive phage P1 transduction assay. Contrary to some earlier reports, recombination between loxP sites was found to be highly specific: a loxP site recombined in vivo only with another of identical sequence, with no crossover recombination either between a wild-type and mutant site; or between two different mutant sites tested. Mutant loxP sites of identical sequence recombined as efficiently as wild-type. The highly specific and efficient recombination of mutant loxP sites in vivo helped in developing a procedure to progressively truncate DNA from either end of large genomic inserts in P1-derived artificial chromosomes (PACs) using transposons that carry either a wild-type or mutant loxP sequence. PAC libraries of human DNA were constructed with inserts flanked by a wild-type and one of the two mutant loxP sites, and deletions from both ends generated in clones using newly constructed wild-type and mutant loxP transposons. Analysis of the results provides new insight into the very large co-integrates formed during P1 transduction of plasmids with loxP sites: a model with tri- and possibly multimeric co-integrates comprising the PAC plasmid, phage DNA, and transposon plasmid(s) as intermediates in the cell appears best to fit the data. The ability to truncate a large piece of DNA from both ends is likely to facilitate functionally mapping gene boundaries more efficiently, and make available precisely trimmed genes in their chromosomal contexts for therapeutic applications.     

Reactivation of an integrated disabled viral vector using a Cre-loxP recombination system in Arabidopsis thaliana

Summary We developed an inactivated DNA replicon of Turnip Mosaic Virus (TuMV), which was reactivated by a recombination event based on the Cre-loxP system. Viral replication was prevented by the insertion of a translation terminator sequence flanked by two loxP sites at the junction of the P1–HCPro-coding genes. In vitro recombination was tested with purified Cre, which excised the floxed sequence from the TuMV DNA, leaving a single loxP site in the reactivated viral genome, and restored the open reading frame of the replicon. Arabidopsis thaliana plants were made transgenic for the inactivated TuMV replicon. Removal of the translation terminator sequence was achieved by the controlled expression of Cre. Delivery of the Cre recombinase to the transgenic plants was obtained by three methods: agroinfiltration, PVX-based production, or transgenic chemical-inducible expression. In each case, reactivation of TuMV replication was observed.     

A genetic screen identifies novel non-compatible loxP sites

The ability of the Cre/lox system to make precise genomic modifications is a tremendous accomplishment. However, recombination between cis-linked heterospecific lox sites limits the use of Cre- mediated exchange of DNA to systems where genetic selection can be applied. To circumvent this problem we carried out a genetic screen designed to identify novel mutant spacer-containing lox sites displaying enhanced incompatibility with the canonical loxP site. One of the mutant sites recovered appears to be completely stable in HEK293 cells constitutively expressing Cre recombinase and supports recombinase-mediated cassette exchange (RMCE) in bacteria and mammalian cell culture. By preventing undesirable recombination, these novel lox sites could improve the efficiency of in vivo gene transfer.     

An inbred 129SvEv GFPCre transgenic mouse that deletes loxP-flanked genes in all tissues

A common method for generating mice with subtle genetic manipulations uses homologous recombination (HR) in embryonic stem (ES) cells to replace a wild-type gene with a slightly modified one. Generally, a drug resistance gene is inserted with the modified gene to select correctly targeted clones. Often, however, the presence of this drug resistance gene interferes with the normal locus and creates a null or hypomorphic allele. Flanking of the selectable marker by loxP sites followed by Cre-mediated deletion after drug selection can overcome this problem. The simplest method used to remove a loxP-flanked selectable marker is to breed an animal carrying a loxP-flanked drug resistance gene to an animal that expresses Cre recombinase in the germline. To date only outbred transgenic mice are available for this purpose. This can be problematic for phenotypic analysis in many organ systems, including the brain, and for the analysis of behavior. While attempting to make 129S6/SvEvTac inbred background (isogenic to our ES cells) mice that express Cre under the control of several tissue-specific promoters, we serendipitously generated a line that excises loxP-flanked drug resistance genes in all tissues, including the germline. This reagent allows deletion of loxP-flanked sequences while maintaining the mutation on an inbred background.     

A Cre/loxP-mediated self-activating gene excision system to produce marker gene free transgenic soybean plants

Marker-gene-free transgenic soybean plants were produced by isolating a developmentally regulated embryo-specific gene promoter, app1, from Arabidopsis and developing a self-activating gene excision system using the P1 bacteriophage Cre/loxP recombination system. To accomplish this, the Cre recombinase gene was placed under control of the app1 promoter and, together with a selectable marker gene (hygromycin phosphotransferase), were cloned between two loxP recombination sites. This entire sequence was then placed between a constitutive promoter and a coding region for either β-glucuronidase (Gus) or glyphosate acetyltransferase (Gat). Gene excision would remove the entire sequence between the two loxP sites and bring the coding region to the constitutive promoter for expression. Using this system marker gene excision occurred in over 30% of the stable transgenic events as indicated by the activation of the gus reporter gene or the gat gene in separate experiments. Transgenic plants with 1 or 2 copies of a functional excision-activated gat transgene and without any marker gene were obtained in T0 or T1 generation. This demonstrates the feasibility of using developmentally controlled promoters to mediate marker excision in soybean.     

Generation of selectable marker-free transgenic tomato resistant to drought, cold and oxidative stress using the Cre/loxP DNA excision system

The aim of this research was to generate selectable marker-free transgenic tomato plants with improved tolerance to abiotic stress. An estradiol-induced site-specific DNA excision of a selectable marker gene using the Cre/loxP DNA recombination system was employed to develop transgenic tomato constitutively expressing AtIpk2β, an inositol polyphosphate 6-/3-kinase gene from Arabidopsis thaliana. Transgenic tomato plants containing a selectable marker were also produced as controls. The expression of AtIpk2β conferred improved resistance to drought, cold and oxidative stress in both sets of transgenic tomato plants. These results demonstrate the feasibility of using this Cre/loxP-based marker elimination strategy to generate marker-free transgenic crops with improved stress tolerance.     

Site-directed recombination in the genome of transgenic tobacco

Summary The plant genome responds to the bacteriophage P1-derived loxP-Cre site-specific recombination system. Recombination took place at loxP sites stably integrated in the tobacco genome, indicating that the Cre recombinase protein, expressed by a chimeric gene also stably resident in the genome, was able to enter the nucleus and to locate a specific 34 bp DNA sequence. An excisional recombination event was monitored by the acquisition of kanamycin resistance, which resulted from the loss of a polyadenylation signal sequence that interrupted a chimeric neomycin phosphotransferase 11 gene. Molecular analysis confirmed that the excision had occurred. Recombination occurred when plants with the integrated loxP construction were stably re-transformed with a chimeric cre gene and when plants with the introduced loxP construction were cross-bred with those carrying the chimeric cre gene. As assayed phenotypically, site-specific recombination could be detected in 50%–100% of the plants containing both elements of the system. Kanamycin resistance was detected at 2–3 weeks after re-transformation and in the first leaf of hybrid seedlings. This demonstration of the effectiveness of the loxP-Cre system in plants provides the basis for development of this system for such purposes as directing site-specific integration and regulation of gene expression.     

Chemical-induced autoexcision of selectable markers in elite tomato plants transformed with a gene conferring resistance to lepidopteran insects

Marker-free transgenic tomato plants harboring a synthetic Bacillus thuringiensis endotoxin gene, cryIAc, were obtained by using a chemically regulated, Cre/loxP-mediated site-specific DNA recombination system, in which the selectable marker neomycin phosphotransferase gene flanked by two directly oriented loxP sites was located between the cauliflower mosaic virus 35S promoter and a promoterless cryIAc. Upon induction by 2 μM β-estradiol, sequences encoding the selectable marker and cre sandwiched by two loxP sites were excised from the tomato genome, leading to activation of the downstream endotoxin gene cryIAc with high expression levels as shown by Northern blot and ELISA assay (250–790 ng g⁻¹ fresh wt) in T₁ generation. For transgenic line with single transgenic loci, 15% of T₁ progenies were revealed marker-free. This autoexcision strategy provides an effective approach to eliminate a selectable marker gene from transgenic tomato, thus expediting the public acceptance of genetically modified crop.     

Initiation of Genome Instability and Preneoplastic Processes through Loss of Fhit Expression

Genomic instability drives tumorigenesis, but how it is initiated in sporadic neoplasias is unknown. In early preneoplasias, alterations at chromosome fragile sites arise due to DNA replication stress. A frequent, perhaps earliest, genetic alteration in preneoplasias is deletion within the fragile FRA3B/FHIT locus, leading to loss of Fhit protein expression. Because common chromosome fragile sites are exquisitely sensitive to replication stress, it has been proposed that their clonal alterations in cancer cells are due to stress sensitivity rather than to a selective advantage imparted by loss of expression of fragile gene products. Here, we show in normal, transformed, and cancer-derived cell lines that Fhit-depletion causes replication stress-induced DNA double-strand breaks. Using DNA combing, we observed a defect in replication fork progression in Fhit-deficient cells that stemmed primarily from fork stalling and collapse. The likely mechanism for the role of Fhit in replication fork progression is through regulation of Thymidine kinase 1 expression and thymidine triphosphate pool levels; notably, restoration of nucleotide balance rescued DNA replication defects and suppressed DNA breakage in Fhit-deficient cells. Depletion of Fhit did not activate the DNA damage response nor cause cell cycle arrest, allowing continued cell proliferation and ongoing chromosomal instability. This finding was in accord with in vivo studies, as Fhit knockout mouse tissue showed no evidence of cell cycle arrest or senescence yet exhibited numerous somatic DNA copy number aberrations at replication stress-sensitive loci. Furthermore, cells established from Fhit knockout tissue showed rapid immortalization and selection of DNA deletions and amplifications, including amplification of the Mdm2 gene, suggesting that Fhit loss-induced genome instability facilitates transformation. We propose that loss of Fhit expression in precancerous lesions is the first step in the initiation of genomic instability, linking alterations at common fragile sites to the origin of genome instability.     

Variable Recombination Efficiency in Responder Transgenes Activated by Cre Recombinase in the Vasculature

Cre recombinase has become a ubiquitous tool in transgenic strategies for regulation of transgene expression in a tissue-specific manner. We report analysis of two SM22αCre lines and their ability to mediate genomic recombination in five independent Cre-responsive transgenic lines. One of the SM22αCre lines developed was a tet-on system based on the reverse tetracycline transactivator. Our goal was to use this strategy to inhibit the Notch signaling pathway specifically in smooth muscle cells. Our responder transgenes contained a constitutively expressed marker gene (chloramphenicol acetyltransferase, CAT), flanked by loxP sites in direct orientation, upstream of Notch-related transgenes. We developed two dominant negative Notch transgenic responder lines activated by Cre-mediated DNA recombination. The first is the extracellular domain of human Jagged1, and the second is the extracellular domain of the human Notch2 receptor. Despite high expression of the marker gene in all responder lines, we found that Cre-mediated genomic recombination between these five lines was highly variable, ranging from 46 to 93% of individuals using an SM22αCre activating strain, or 8–58% of individuals using an inducible SM22αrtTACre. In all cases examined, detection of recombination by PCR correlated with expression of the transgene as determined by Western blot analysis. Our studies reflect the variability in recombination success based on the responder strain, presumably due to inaccessibility of the locus of integration of the responder allele.     

A loss of function screen identifies nine new radiation susceptibility genes

Genomic instability is considered a hallmark of carcinogenesis, and dysfunction of DNA repair and cell cycle regulation in response to DNA damage caused by ionizing radiation are thought to be important factors in the early stages of genomic instability. We performed cell-based functional screening using an RNA interference library targeting 200 genes in human cells. We identified three known and nine new radiation susceptibility genes, eight of which are linked directly or potentially with cell cycle progression. Cell cycle analysis on four of the genes not previously linked to cell cycle progression demonstrated that one, ZDHHC8, was associated with the G₂/M checkpoint in response to DNA damage. Further study of the 12 radiation susceptibility genes identified in this screen may help to elucidate the molecular mechanisms of cell cycle progression, DNA repair, cell death, cell growth and genomic instability, and to develop new radiation sensitizing agents for radiotherapy.     

A novel reporter rat strain that expresses LacZ upon Cre‐mediated recombination

The recent widespread application of Cre/loxP technology has resulted in a new generation of conditional animal models that can better recapitulate many salient features of human disease. These models benefit from the ability to monitor the expression and functionality of Cre protein. We have generated a conditional (Cre/loxP dependent) LacZ reporter rat (termed the LacZ541 rat) to monitor Cre in transgenic rats. When LacZ541 rats were bred with another transgenic rat line expressing Cre recombinase under the control of the CAG promoter, LacZ/Cre double transgenic embryos displayed ubiquitous expression of LacZ, and when LacZ541 rats were bred with transgenic rats expressing Cre/loxP‐dependent oncogenic H‐ or K‐ras, LacZ was expressed in the lesions resulting from the activation of the oncogene. The LacZ541 rat enables evaluation of the performance of Cre‐expressing systems which are based upon transgenic rats or somatic gene transfer vectors and provides efficient and simple lineage marking. genesis 51:268–274. © 2013 Wiley Periodicals, Inc.     

Unidirectional Cre-mediated genetic inversion in mice using the mutant loxP pair lox66/lox71

The Cre/loxP recombination system is a commonly used tool to alter the mouse genome in a conditional manner by deletion or inversion of loxP-flanked DNA segments. While Cre-mediated deletion is essentially unidirectional, inversion is reversible and therefore does not allow the stable alteration of gene function in cells that constitutively express Cre. Site-directed mutagenesis yielded a pair of asymmetric loxP sites (lox66 and lox71) that display a favorable forward reaction equilibrium. Here, we demonstrate that lox66/lox71 mediates efficient and predominantly unidirectional inversion of a switch substrate targeted to the mouse genome in combination with either inducible or cell type-specific cre-transgenes in vivo.     

Generalized bacterial genome editing using mobile group II introns and Cre‐lox

Efficient bacterial genetic engineering approaches with broad‐host applicability are rare. We combine two systems, mobile group II introns (‘targetrons’) and Cre/lox, which function efficiently in many different organisms, into a versatile platform we call GETR (Genome Editing via Targetrons and Recombinases). The introns deliver lox sites to specific genomic loci, enabling genomic manipulations. Efficiency is enhanced by adding flexibility to the RNA hairpins formed by the lox sites. We use the system for insertions, deletions, inversions, and one‐step cut‐and‐paste operations. We demonstrate insertion of a 12‐kb polyketide synthase operon into the lacZ gene of Escherichia coli, multiple simultaneous and sequential deletions of up to 120 kb in E. coli and Staphylococcus aureus, inversions of up to 1.2 Mb in E. coli and Bacillus subtilis, and one‐step cut‐and‐pastes for translocating 120 kb of genomic sequence to a site 1.5 Mb away. We also demonstrate the simultaneous delivery of lox sites into multiple loci in the Shewanella oneidensis genome. No selectable markers need to be placed in the genome, and the efficiency of Cre‐mediated manipulations typically approaches 100%.     

The DNA damage effector Chk1 kinase regulates Cdc14B nucleolar shuttling during cell cycle progression

Chk1 is a critical effector of DNA damage checkpoints necessary for the maintenance of chromosome integrity during cell cycle progression. Here we report, that Chk1 co-localized with the nucleolar marker, fibrillarin in response to radiation-induced DNA damage in human cells. Interestingly, in vitro studies using GST pull down assays identified the dual-specificity serine/threonine nucleolar phosphatase Cdc14B as a Chk1 substrate. Furthermore, Chk1, but not a kinase-dead Chk1 control, was shown to phosphorylate Cdc14B using an in vitro kinase assay. Co-immunoprecipitation experiments using exogenous Cdc14B transfected into human cells confirmed the interaction of Cdc14B and Chk1 during cell cycle. In addition, reduction of Chk1 levels via siRNA or UCN-01 treatment demonstrated that Chk1 activation following DNA damage was required for Cdc14B export from the nucleolus. these studies have revealed a novel interplay between Chk1 kinase and Cdc14B phosphatase involving radiation-induced nucleolar shuttling to facilitate error-free cell cycle progression and prevent genomic instability.Key words: Chk1, nucleoli, DNA damage, Cdc14B, genomic instabiliy, cell cycle     

A new site-specific recombinase-mediated system for targeted multiple genomic deletions employing chimeric loxP and mrpS sites

A newly designed site-specific recombination system is presented which allows multiple targeted markerless deletions. The most frequently used tool for removing selection markers or to introduce genes by recombination-mediated cassette exchange is the Cre/loxP system. Many mutant loxP sites have been created for this purpose. However, this study presents a chimeric mutant loxP site denoted mroxP-site. The mroxP site consists of one Cre (loxP/2) and one MrpA (mrpS/2) binding site separated by a palindromic 6-bp spacer sequence. Two mroxP-sites can be recombined by Cre recombinase in head-to-tail as well as in head-to-head orientation. In the head-to-head orientation and the loxP half-sites inside, Cre removes the loxP half-sites during site-specific recombination, creating a new site, mrmrP. The new site is essentially a mrpS site with a palindromic spacer and cannot be used by Cre for recombination anymore. It does, however, present a substrate for the recombinase MrpA. This new system has been successfully applied introducing multiple targeted gene deletions into the Escherichia coli genome. Similar to Cre/loxP and FLP/FRT, this system may be adapted for genetic engineering of other pro- and eukaryotes.