Gene replacement by homologous recombination in plants

After the elucidation of the sequence of the yeast genome a major effort was started to elucidate the biological function of all open reading frames of this organisms by targeted gene replacement via homologous recombination. The establishment of the complete sequence of the genome of Arabidopsis thaliana would principally allow a similar approach. However, over the past dozen years all attempts to establish an efficient gene targeting technique in flowering plants were in the end not successful. In contrast, in Physcomitrella patens an efficient gene targeting procedure has been set up, making the moss a valuable model system for plant molecular biologists. But also for flowering plants recently several new approaches – some of them based on the availability of the genomic sequence of Arabidopsis – were initiated that might finally result on the set up of a general applicable technique. Beside the production of hyper-recombinogenic plants either via expression or suppression of specific gene functions or via undirected mutagenesis, the application of chimeric oligonucleotides might result in major progress.     

Efficient gene targeting and removal of foreign DNA by homologous recombination in the picoeukaryote Ostreococcus

With fewer than 8000 genes and a minimalist cellular organization, the green picoalga Ostreococcus tauri is one of the simplest photosynthetic eukaryotes. Ostreococcus tauri contains many plant‐specific genes but exhibits a very low gene redundancy. The haploid genome is extremely dense with few repeated sequences and rare transposons. Thanks to the implementation of genetic transformation and vectors for inducible overexpression/knockdown this picoeukaryotic alga has emerged in recent years as a model organism for functional genomics analyses and systems biology. Here we report the development of an efficient gene targeting technique which we use to knock out the nitrate reductase and ferritin genes and to knock in a luciferase reporter in frame to the ferritin native protein. Furthermore, we show that the frequency of insertion by homologous recombination is greatly enhanced when the transgene is designed to replace an existing genomic insertion. We propose that a natural mechanism based on homologous recombination may operate to remove inserted DNA sequences from the genome.     

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.     

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     

Improving gene replacement by intracellular formation of linear homologous DNA

BACKGROUND: Gene targeting is a potential tool for gene therapy but is limited by the low rate of homologous recombination. Using highly homologous linear DNA improves gene targeting frequency but requires microinjection into nuclear cells to be effective. Because transfection of circular DNA is more efficient than transfection of linear DNA and adaptable to viral vectors, we developed a system for the intracellular release of linear fragments from circular plasmids. METHODS: Only one cutting site inside the "donor" DNA was not convenient because it led to integration of exogenous sequences into the target. So we constructed several "donor" plasmids containing the homologous sequences flanked by two I-Sce I recognition sites. Expression of I-Sce I allowed intracellular delivery of "ends-out" (replacement) vectors. We compared the efficiency of different constructions to correct a mutated gfp target. RESULTS: Co-transfection of "donor" plasmids and an I-Sce I expression vector into CHO cells enhanced the correction of an extrachromosomal mutated gfp target by at least 10 times. Maximum correction was observed with the greatest homology size and maximum effect of I-Sce I was obtained when the long hemi-sites of the duplicated I-Sce I sites were contiguous to the homologous sequence. Unexpectedly, the reverse orientation of I-Sce I sites provided little or no effect, probably due to the asymmetrical activity of the I-Sce I meganuclease. CONCLUSIONS: Releasing homologous DNA fragments with I-Sce I enhances gene replacement. This work provides the basis for the future design of viral vectors for gene replacement.     

微生物基因打靶系统的研究进展

基因打靶技术是微生物功能基因组学研究的有力工具之一,通过定向改变微生物的遗传信息可以对目的基因进行有效的功能分析。在大肠杆菌中研究较多的是转座子突变系统、RecBCD^-sbcB重组系统、RecA依赖的重组打靶系统、Chi位点刺激的重组、利用单链DNA进行的重组工程。在酵母中进行基因打靶的策略主要是转座子标记的突变、基于PCR方法的基因删除和转化相关重组。在其他微生物中主要应用转座子突变和自杀载体进行基因打靶。近年来,噬菌体重组系统的发展更使对微生物基因打靶系统的研究进入了新的阶段,主要包括Rac编码的RecET系统、Red重组系统和噬菌体退火蛋白介导的单链寡核苷酸重组系统。     

去除转基因植物标记基因的研究进展

得到转基因植物以后 ,标记基因就失去了筛选的作用。但它的存在引起公众对转基因植物的安全性以及环境效应的担心 ,所以在目的基因转入后 ,要去除标记基因。该文主要就利用共转化、转座子、同源重组、位点特异重组酶等去除标记基因的方法进行了总结 ,并对各种方法的优缺点进行了比较 ,对该技术未来的发展趋势也进行了展望。     

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.     

Increased efficiency of homologous recombination in ES cells by cleavage at both ends of homology in the targeting vector

Transgenic Research -     

Chloroplast lysates support directed mutagenesis via modified DNA and chimeric RNA/DNA oligonucleotides

Chimeric RNA/DNA and modified DNA oligonucleotides have been shown to direct gene-conversion events in vitro through a process involving proteins from several DNA-repair pathways. Recent experiments have extended the utility of these molecules to plants, and we previously demonstrated that plant cell-free extracts are competent to support oligonucleotide-directed genetic repair. Using this system, we are studying Arabidopsis DNA-repair mutants and the role of plant proteins in the DNA-repair process. Here we describe a method for investigating mechanisms of plastid DNA-repair pathways. Using a genetic readout system in bacteria and chimeric or modified DNA oligonucleotides designed to direct the conversion of mutations in antibiotic resistance genes, we have developed an assay for genetic repair of mutations in a spinach chloroplast lysate system. We report genetic repair of point and frameshift mutations directed by both types of modified oligonucleotides. This system enables the mechanistic study of plastid gene repair and facilitates the direct comparison between plant nuclear and organelle DNA-repair pathways.     

Homologous recombination: a basis for targeted genome optimization in crop species such as maize

In an attempt to understand the feasibility of future targeted genome optimization in agronomic crops, we tested the efficiency of homologous recombination-mediated sequence insertion upon induction of a targeted DNA double-strand break at the desired integration site in maize. By the development of an efficient tissue culture protocol, and with the use of an I- Sce I gene optimized for expression in maize, large numbers of precisely engineered maize events were produced in which DNA integration occurred very accurately. In a subset of events examined in detail, no additional deletions and/or insertions of short filler DNA at the integration site were observed. In 30%–40% of the recovered events, no traces of random insertions were observed. This was true for DNA delivery by both Agrobacterium and particle bombardment. These data suggest that targeted double-strand break-induced homologous recombination is a superior method to generate specific desired changes in the maize genome, and suggest targeted genome optimization of agronomic crops to be feasible.     

Efficient FLP recombination in mouse ES cells and oocytes

Summary: We report an improved vector, pCAGGS‐FLPe, for transient expression of the enhanced FLP recombinase in mouse ES cells and oocytes. In standard transfection experiments, about 6% of total ES colonies showed FLP recombination, albeit with mosaicism within each colony. After microinjection of pCAGGS‐FLPe into oocytes, about one‐third of heterozygotic mice born showed complete FLP recombination. Thus pCAGGS‐FLPe presents two practical options for removal of FRT cassettes in mice. genesis 31:6–10, 2001. © 2001 Wiley‐Liss, Inc.     

Homologous recombination and gene targeting

Gene therapy and the production of mutated cell lines or model animals both require the development of efficient, controlled gene-targeting strategies. Classical approaches are based on the ability of cells to use homologous recombination to integrate exogenous DNA into their own genome. The low frequency of homologous recombination in mammalian cells leads to inefficient targeting. Here, we review the limiting steps of classical approaches and the new strategies developed to improve the efficiency of homologous recombination in gene-targeting experiments.     

Precise excision of plastid DNA by the large serine recombinase Bxb1

Marker genes are essential for the selection and identification of rarely occurring transformation events generated in biotechnology. This includes plastid transformation, which requires that multiple copies of the modified chloroplast genome be present to obtain genetically stable transplastomic plants. However, the marker gene becomes dispensable when homoplastomic plants are obtained. Here, we demonstrate the precise excision of attP‐ and attB‐flanked DNA from the plastid genome mediated by the large serine recombinase Bxb1. We transformed the tobacco plastid genome with the pTCH‐PB vector containing a stuffer fragment of DNA flanked by directly oriented nonhomologous attP and attB recombinase recognition sites. In the absence of the Bxb1 recombinase, the transformed plastid genomes were stable and heritable. Nuclear‐transformed transgenic tobacco plants expressing a plastid‐targeted Bxb1 recombinase were crossed with transplastomic pTCH‐PB plants, and the T₁ hybrids exhibited efficient excision of the target sequence. The Bxb1–att system should prove to be a useful tool for site‐specifically manipulating the plastid genome and generating marker‐free transplastomic plants.     

Small serine recombination systems ParA‐MRS and CinH‐RS2 perform precise excision of plastid DNA

Selectable marker genes (SMGs) are necessary for selection of transgenic plants. However, once stable transformants have been identified, the marker gene is no longer needed. In this study, we demonstrate the use of the small serine recombination systems, ParA‐MRS and CinH‐RS2, to precisely excise a marker gene from the plastid genome of tobacco. Transplastomic plants transformed with the pTCH‐MRS and pTCH‐RS2 vectors, containing the visual reporter gene DsRed flanked by directly oriented MRS and RS2 recognition sites, respectively, were crossed with nuclear‐genome transformed tobacco plants expressing plastid‐targeted ParA and CinH recombinases, respectively. One hundred per cent of both types of F₁ hybrids exhibited excision of the DsRed marker gene. PCR and Southern blot analyses of DNA from F₂ plants showed that approximately 30% (CinH‐RS2) or 40% (ParA‐MRS) had lost the recombinase genes by segregation. The postexcision transformed plastid genomes were stable and the excision events heritable. The ParA‐MRS and CinH‐RS2 recombination systems will be useful tools for site‐specific manipulation of the plastid genome and for generating marker‐free plants, an essential step for reuse of SMG and for addressing concerns about the presence of antibiotic resistance genes in transgenic plants.     

Precision genome editing in plants via gene targeting and piggyBac‐mediated marker excision

Precise genome engineering via homologous recombination (HR)‐mediated gene targeting (GT) has become an essential tool in molecular breeding as well as in basic plant science. As HR‐mediated GT is an extremely rare event, positive–negative selection has been used extensively in flowering plants to isolate cells in which GT has occurred. In order to utilize GT as a methodology for precision mutagenesis, the positive selectable marker gene should be completely eliminated from the GT locus. Here, we introduce targeted point mutations conferring resistance to herbicide into the rice acetolactate synthase (ALS) gene via GT with subsequent marker excision by piggyBac transposition. Almost all regenerated plants expressing piggyBac transposase contained exclusively targeted point mutations without concomitant re‐integration of the transposon, resulting in these progeny showing a herbicide bispyribac sodium (BS)‐tolerant phenotype. This approach was also applied successfully to the editing of a microRNA targeting site in the rice cleistogamy 1 gene. Therefore, our approach provides a general strategy for the targeted modification of endogenous genes in plants.     

High fidelity extrachromosomal recombination and gene targeting in plants

The precision of extrachromosomal homologous recombination and gene targeting in plant cells was investigated. Recombination was directed to introns of selectable marker genes where potential changes could persist without affecting the function and therefore the selectability of the genes. Approximately 9 kb of crossover regions was rescued and sequenced. Changes were detected at a frequency below one point mutation per 1000 bp, indicating that extrachromosomal recombination and gene targeting both appear to occur with high fidelity.     

Elevated levels of intrachromosomal homologous recombination in Arabidopsis overexpressing the MIM gene

The Arabidopsis MIM gene encodes a protein belonging to the SMC family (structure maintenance of chromosomes) which is required for intrachromosomal homologous recombination (ICR). Both ICR and MIM gene expression are enhanced by DNA-damaging treatments, suggesting that MIM is a factor limiting DNA repair by homologous recombination (HR) under genotoxic stress. We tested this hypothesis by measuring the levels of recombination in the mim mutant under genotoxic stress, using methyl methanesulfonate. Although the mutant clearly showed diminished basal and induced levels of ICR, enhancement of ICR by DNA-damaging treatments was similar to that observed in the wild type. This suggests that the MIM gene product is required for DNA repair by HR, but is not critical for HR induction. To determine whether enhanced availability of MIM would increase basal HR levels in Arabidopsis, we examined ICR frequencies in transgenic Arabidopsis strains overexpressing the MIM gene after ectopic insertion of additional MIM copies. Two independent lines showed a twofold increase in ICR frequency relative to the wild type. Thus MIM is required for efficient ICR in plants, and its manipulation can be used to change homologous recombination frequencies. Since MIM is one of the components responsible for chromatin dynamics, our results suggest that the chromatin environment determines the frequency of homologous recombination.     

Nuclear and chloroplast transformation inChlamydomonas reinhardtii: strategies for genetic manipulation and gene expression

Transformation of the nuclear, chloroplast, and mitochondrial genomes can now be accomplished inChlamydomonas reinhardtii. Many biosynthetic pathways are carried out in the chloroplast, and efforts to manipulate these pathways will require that gene products be directed to this compartment. Chloroplast proteins are encoded in either the chloroplast or nuclear genome. In the latter case they are synthesized in the cytoplasm and imported post-translationally into the chloroplast. Thus, strategies for expressing foreign genes or overexpressing endogenous genes whose products reside in the chloroplast could involve either genome. This paper reviews the present status of transformation methodology for the nuclear and chloroplast genomes inChlamydomonas. Considerations for expressing gene products in the chloroplast are discussed. Experimental evidence for homologous recombination during transformation of the nuclear genome is presented.