FLP recombinase-mediated site-specific recombination in rice

The feasibility of using the FLP/ FRT site-specific recombination system in rice for genome engineering was evaluated. Transgenic rice plants expressing the FLP recombinase were crossed with plants harbouring the kanamycin resistance gene ( neomycin phosphotransferase II , nptII ) flanked by FRT sites, which also served to separate the corn ubiquitin promoter from a promoterless gusA . Hybrid progeny were tested for excision of the nptII gene and the positioning of the ubiquitin promoter proximal to gusA . While the hybrid progeny from various crosses exhibited β-glucuronidase (GUS) expression, the progeny of selfed parental rice plants did not show detectable GUS activity. Despite the variable GUS expression and incomplete recombination displayed in hybrids from some crosses, uniform GUS staining and complete recombination were observed in hybrids from other crosses. The recombined locus was shown to be stably inherited by the progeny. These data demonstrate the operation of FLP recombinase in catalysing excisional DNA recombination in rice, and confirm that the FLP/ FRT recombination system functions effectively in the cereal crop rice. Transgenic rice lines expressing active FLP recombinase generated in this study provide foundational stock material, thus facilitating the future application and development of the FLP/ FRT system in rice genetic improvement.     

Auto-excision of selectable marker genes from transgenic tobacco via a stress inducible FLP/FRT site-specific recombination system

Antibiotic resistance marker genes are powerful selection tools for use in plant transformation processes. However, once transformation is accomplished, the presence of these resistance genes is no longer necessary and can even be undesirable. We herein describe the successful excision of antibiotic resistance genes from transgenic plants via the use of an oxidative stress-inducible FLP gene. FLP encodes a recombinase that can eliminate FLP and hpt selection genes flanked by two FRT sites. During a transformation procedure in tobacco, transformants were obtained by selection on hygromycin media. Regenerants of the initial transformants were screened for selective marker excision in hydrogen peroxide supplemented media and both the FLP and hpt genes were found to have been eliminated. About 13–41% of regenerated shoots on hydrogen peroxide media were marker-free. This auto-excision system, mediated by the oxidative stress-inducible FLP/FRT system to eliminate a selectable marker gene can be very readily adopted and used to efficiently generate marker-free transgenic plants.     

Multiple pathways for Cre/lox-mediated recombination in plastids

Plastid transformation technology involves the insertion by homologous recombination and subsequent amplification of plastid transgenes to approximately 10 000 genome copies per leaf cell. Selection of transformed genomes is achieved using a selectable antibiotic resistance marker that has no subsequent role in the transformed line. We report here a feasibility study in the model plant tobacco, to test the heterologous Cre/lox recombination system for antibiotic marker gene removal from plastids. To study its efficiency, a green fluorescent protein reporter gene activation assay was utilized that allowed visual observation of marker excision after delivery of Cre to plastids. Using a combination of in vivo fluorescence activation and molecular assays, we show that transgene excision occurs completely from all plastid genomes early in plant development. Selectable marker-free transplastomic plants are obtained in the first seed generation, indicating a potential application of the Cre/lox system in plastid transformation technology. In addition to the predicted transgene excision event, two alternative pathways of Cre-mediated recombination were also observed. In one alternative pathway, the presence of Cre in plastids stimulated homologous recombination between a 117 bp transgene expression element and its cognate sequence in the plastid genome. The other alternative pathway uncovered a plastid genome 'hot spot' of recombination composed of multiple direct repeats of a 5 bp sequence motif, which recombined with lox independent of sequence homology. Both recombination pathways result in plastid genome deletions. However, the resultant plastid mutations are silent, and their study provides the first insights into tRNA accumulation and trans-splicing events in higher plant plastids.     

Genome manipulation by homologous recombination in Drosophila.

By utilising a cell's recombinational machinery, researchers in many different model organisms have been able to perform gene targeting experiments in which specific sequence alterations are introduced into virtually any endogenous gene. Not only can functional knock-outs be generated by gene targeting, interesting alleles with mutations encoding specific amino acid replacements can also be made. A practical gene targeting method has only recently become available for Drosophila. This article reviews the Drosophila gene targeting method, with emphases placed on different approaches that are being used to generate different mutations.     

Effective production of marker-free transgenic strawberry plants using inducible site-specific recombination and a bifunctional selectable marker gene

Public concerns about the issue of the environmental safety of genetically modified plants have led to a demand for technologies allowing the production of transgenic plants without selectable (antibiotic resistance) markers. We describe the development of an effective transformation system for generating such marker-free transgenic plants, without the need for repeated transformation or sexual crossing. This system combines an inducible site-specific recombinase for the precise elimination of undesired, introduced DNA sequences with a bifunctional selectable marker gene used for the initial positive selection of transgenic tissue and subsequent negative selection for fully marker-free plants. The described system can be generally applied to existing transformation protocols, and was tested in strawberry using a model vector in which site-specific recombination leads to a functional combination of a cauliflower mosaic virus 35S promoter and a GUS encoding sequence, thereby enabling the histochemical monitoring of recombination events. Fully marker-free transgenic strawberry plants were obtained following two different selection/regeneration strategies.     

Marker-free site-specific gene integration in rice based on the use of two recombination systems

Transgene integration mediated by heterologous site-specific recombination (SSR) systems into the dedicated genomic sites has been demonstrated in a few different plant species. This approach of plant transformation generates a precise site-specific integration (SSI) structure consisting of a single copy of the transgene construct. As a result, stable transgene expression correlated with promoter strength and gene copy number is observed among independent transgenic lines and faithfully transmitted through subsequent generations. Site-specific integration approaches use selectable marker genes, removal of which is necessary for the implementation of this approach as a biotechnology application. As SSR systems are also excellent tools for excising marker genes from transgene locus, a molecular strategy involving gene integration followed by marker excision, each mediated by a distinct recombination system, was earlier proposed. Experimental validation of this approach is the focus of this work. Using FLPe-FRT system for site-specific gene integration and heat-inducible Cre-lox for marker gene excision, marker-free SSI lines were developed in the first generation itself. More importantly, progeny derived from these lines inherited the marker-free locus, indicating efficient germinal transmission. Finally, as the transgene expression from SSI locus was not altered upon marker excision, this method is suitable for streamlining the production of marker-free SSI lines.     

Bacteriophage P2 integrase: another possible tool for site-specific recombination in eukaryotic cells

Aims:  To investigate if the site-specific tyrosine integrase (Int) from phage P2 has features that would make it interesting for use of gene transfer into eukaryotic cells. These include the possibility of promoting recombination with a nonphage sequence, abolishing the requirement for the bacterial DNA-binding and -bending protein integration host factor (IHF), and localization to the nucleus of eukaryotic cells.
Methods and Results:  We show that the Int protein catalyzes site-specific recombination using a human sequence in Escherichia coli and in vitro although not as efficiently as with the wild-type bacterial sequence, and that insertion of high mobility group recognition boxes in the phage attachment site substrate abolish the requirement of IHF and allows efficient recombination in vitro in a eukaryotic cell extract. Furthermore, we show by fluorescence that the Int protein contains a functional intrinsic nuclear localization signal, localizing it to the nucleus in both HeLa and 293 cells.
Conclusions:  We conclude that P2 Int may be a potential tool for site-specific integration of genes into the human chromosome.
Significance and Impact of the Study:  The study implies the possibility of using multiple prokaryotic Int proteins with different specific integration sites in human cells for future gene therapy programmes.     

Activity of the yeast FLP recombinase in Arabidopsis

The coding sequence for FLP recombinase, originally from the 2 plasmid of Saccharomyces cerevisiae, was introduced into Arabidopsis behind the cauliflower mosaic virus 35S promoter. FLP activity was monitored by the glucuronidase activity resulting from inversion of an antisense-oriented GUS reporter gene flanked by a pair of FRT target sites in inverted repeat. FLP-dependent Gus activity was observed in both transient assays and transgenic plants. The FLP system will be useful for a variety of in planta genetic manipulations.     

Cre/lox位点特异性重组系统在高等真核生物中的研究进展

来自于P1噬菌体的Cre/lox系统通过位点特异性重组可以迅速而有效地实现各种生理环境下的基因定点插入、删除、替换和倒位等操作。Cre/lox系统作为目前基因打靶技术的核心工具,已被广泛应用于拟南芥、水稻、小鼠、果蝇、斑马鱼等高等真核模式生物。文章较为全面地介绍了Cre/lox系统的基本概况及其在高等真核生物中的应用,讨论了Cre/lox系统在研究中存在的主要问题和今后的发展方向,为利用该系统在不同高等生物中进行基因操作提供有用的参考。     

Factors affecting the efficiency of introducing precise genetic changes in ES cells by homologous recombination: tag-and-exchange versus the Cre-loxp system

The introduction of genetic modifications in specific genes by homologous recombination provides a powerful tool for elucidation of structure-function relationships of proteins of biological interest. Presently, there are several alternative methods of homologous recombination that permit the introduction of small genetic modifications in specific loci. Two of the most widely used methods are the tag-and-exchange, based on the use of positive--negative selection markers, and the Cre-loxP system, based on the use of a site-specific recombinase. The efficiency of detection of targeting events at different loci using the two systems was compared. Additionally, we analysed how the distance between two gene markers placed within the region of homology of a targeting vector affects the rate at which both markers are introduced into the locus during the homologous recombination event. Our results indicate that the method based on the use of positive--negative selection markers was les s efficient than the Cre-loxP based system, irrespective of locus or type of positive--negative selection. It was also determined that as the distance between the selectable marker and the genetic modification being introduced increases, there is a progressive reduction in the efficiency of detecting events with the desired genetic modification     

Cre/lox位点特异性重组系统在高等真核生物中的研究进展

来自于P1噬菌体的Cre/lox系统通过位点特异性重组可以迅速而有效地实现各种生理环境下的基因定点插入、删除、替换和倒位等操作。Cre/lox系统作为目前基因打靶技术的核心工具, 已被广泛应用于拟南芥、水稻、小鼠、果蝇、斑马鱼等高等真核模式生物。文章较为全面地介绍了Cre/lox系统的基本概况及其在高等真核生物中的应用, 讨论了Cre/lox系统在研究中存在的主要问题和今后的发展方向, 为利用该系统在不同高等生物中进行基因操作提供有用的参考。     

A high-throughput system for genome-wide measurement of genetic recombination in Arabidopsis thaliana based on transgenic markers

A high-throughput system for the measurement of recombination frequencies in the genetic model plant, Arabidopsis thaliana, is described. It is based on 21 mono-transgenic isogenic lines harboring antibiotic resistance genes on all five chromosomes. Recombination between pairs of gene insertions in repulsion phase that confer resistance against kanamycin (kan) and hygromycin (hyg) is determined by a phenotypic assay of progeny (DART: Double Antibiotic Resistance Technique). DART allows testing for the influence of numerous environmental and genetic factors, including candidate genes, on recombination frequencies in specific genomic regions as well as the entire genome. Its usefulness is demonstrated by investigating the effects of UV treatment, different temperature and phosphorus supply regimes, and sex on recombination frequencies for all five chromosomes of A. thaliana. Electronic Publication     

位点特异性重组系统及其在植物转基因研究中的应用

随着植物转基因研究的不断深入,对基因重组系统提出了新的要求。位点特异性重组系统具有高效、精确等的优点,在植物基因工程领域的应用越来越广泛。对常用的三类位点特异性重组系统的作用机制、优缺点及其应用进展进行了全面的综述,期望为植物转基因研究提供技术参考。对于目前研究较为热点的基因编辑技术CRISPR-Cas系统作了简要概述。     

Synapsis in phage Bxb1 integration: selection mechanism for the correct pair of recombination sites

Recombination by site-specific recombinases is a highly concerted process that requires synapsis of the correct pair of DNA substrates. Phage-encoded serine-integrases are unusual among the serine-recombinase family, which includes transposon resolvases and DNA invertases, in that they utilize two simple but different DNA substrates (attB and attP) and do not require accessory sites, additional proteins, or DNA supercoiling. Synapsis must therefore be directed solely by integrase-DNA interactions. We show here that the Bxb1 serine-integrase binds as a dimer to its two DNA substrates (attB, attP) and recombinant products (attL, attR) with similar affinities. However, synapsis occurs only between attP and attB, and not between any of the other nine possible site combinations. The Bxb1 integrase domain structure, the unusual DNA-binding properties of the integrase, and the characterization of a mutant protein with altered site-discrimination, are consistent with synaptic selectivity being derived from DNA sequence-induced changes in the conformations of integrase-DNA complexes.     

Tracing the recombination and colonization history of hybrid species in space and time

Hybrid speciation has long fascinated evolutionary biologists and laymen alike, presumably because it challenges our classical view of evolution as a ‘one‐way street’ leading to strictly tree‐like patterns of ancestry and descent. Homoploid hybrid speciation (HHS) has been a particularly interesting puzzle, as it appears to occur extremely rapidly, perhaps within less than 50 generations ( McCarthy et al. 1995 ; Buerkle et al. 2000 ). Nevertheless, HHS may sometimes involve extended or repeated periods of recombination and gene exchange between populations subject to strong divergent natural selection ( Buerkle & Rieseberg 2008 ). Thus, HHS provides a highly interesting setting for understanding the drivers and tempo of adaptive divergence and speciation in the face of gene flow ( Arnold 2006 ; Rieseberg & Willis 2007 ; Nolte & Tautz 2009). In the present issue of Molecular Ecology, Wang et al. (2011) explore a particularly challenging issue connected to HHS: they attempt to trace the colonization and recombination history of an ancient (several MYA) hybrid species, from admixture and recombination in the ancestral hybrid zone to subsequent range shifts triggered by tectonic events (uplift of the Tibetan plateau) and climatic shifts (Pleistocene ice ages). This work is important because it addresses key issues related to the origin of the standing genetic variation available for adaptive responses (e.g. to climate change) and speciation in temperate species, which are topics of great current interest ( Rieseberg et al. 2003 ; Barrett & Schluter 2008 ; de Carvalho et al. 2010 ).     

DNA topology and geometry in Flp and Cre recombination

The Flp recombinase of yeast and the Cre recombinase of bacteriophage P1 both belong to the lambda-integrase (Int) family of site-specific recombinases. These recombination systems recognize recombination-target sequences that consist of two 13bp inverted repeats flanking a 6 or 8bp spacer sequence. Recombination reactions involve particular geometric and topological relationships between DNA target sites at synapsis, which we investigate using nicked-circular DNA molecules. Examination of the tertiary structure of synaptic complexes formed on nicked plasmid DNAs by atomic-force microscopy, in conjunction with detailed topological analysis using the mathematics of tangles, shows that only a limited number of recombination-site topologies are consistent with the global structures of plasmids bearing directly and inversely repeated sites. The tangle solutions imply that there is significant distortion of the Holliday-junction intermediate relative to the planar structure of the four-way DNA junction present in the Flp and Cre co-crystal structures. Based on simulations of nucleoprotein structures that connect the two-dimensional tangle solutions with three-dimensional models of the complexes, we propose a recombination mechanism in which the synaptic intermediate is characterized by a non-planar, possibly near-tetrahedral, Holliday-junction intermediate. Only modest conformational changes within this structure are needed to form the symmetric, planar DNA junction, which may be characteristic of shorter-lived intermediates along the recombination pathway.     

Control of directionality in L5 integrase-mediated site-specific recombination

Mycobacteriophage L5 is a temperate phage that forms lysogens in Mycobacterium smegmatis. These lysogens carry an integrated L5 prophage inserted at a specific chromosomal location and undergo subsequent excision during induction of lytic growth. Both the integrative and excisive site-specific recombination events are catalyzed by the phage-encoded tyrosine integrase (Int-L5) and require the host-encoded protein, mIHF. The directionality of these recombination events is determined by a second phage-encoded protein, Excise, the product of gene 36 (Xis-L5); integration occurs efficiently in the absence of Xis-L5 while excision is dependent upon it. We show here that Xis-L5 binds to attR DNA, introduces a DNA bend, and facilitates the formation of an intasome-R complex. This complex, which requires mIHF, Xis-L5 and Int-L5, readily recombines with a second intasome formed by Int-L5, mIHF and attL DNA (intasome-L) to generate the attP and attB products of excision. Xis-L5 also strongly inhibits Int-L5-mediated integrative recombination but does not prevent either the protein-DNA interactions that form the attP intasome (intasome-P) or the capture of attB, but acts later in the reaction presumably by preventing the formation of a recombinagenic synaptic intermediate. The mechanism of action of Xis-L5 appears to be purely architectural, influencing the assembly of protein-DNA structures solely through its DNA-binding and DNA-bending properties.     

Polycomb-group histone methyltransferase CLF is required for proper somatic recombination in Arabidopsis

Homologous recombination(HR) is a key process during meiosis in reproductive cells and the DNA damage repair process in somatic cells. Although chromatin structure is Researchthought to be crucial for HR, only a small number of chromatin modifiers have been studied in HR regulation so far. Here, we investigated the function of CURLY LEAF(CLF), a Polycomb-group(PcG) gene responsible for histone3 lysine 27 trimethylation(H3K27me3), in somatic and meiotic HR in Arabidopsis thaliana. Although fluorescent protein reporter assays in pollen and seeds showed that the frequency of meiotic cross-over in the loss-of-function mutant clf-29 was not significantly different from that in wild type, there was a lower frequency of HR in clf-29 than in wild type under normal conditions and under bleomycin treatment. The DNA damage levels were comparable between clf-29 and wild type, even though several DNA damage repair genes(e.g. ATM, BRCA2 a, RAD50, RAD51, RAD54,and PARP2) were expressed at lower levels in clf-29. Under bleomycin treatment, the expression levels of DNA repair genes were similar in clf-29 and wild type, thus CLF may also regulate HR via other mechanisms. These findings expand the current knowledge of PcG function and contribute to general interests of epigenetic regulation in genome stability regulation.