Dependence of Frequency of Homologous Recombination on the Homology Length

The frequency of homologous recombination is believed to be a linear function of the length (N bp) of homology between DNAs. Here, the N intercept is believed to be determined by a threshold length below which some physical constraint is effective. In the mammalian gene targeting systems, however, the frequency depends more steeply than linearly on the homology length. To explain both the linear dependence and the steeper dependence, we propose a model where the branch point of a reaction intermediate is assumed to ``walk randomly' along the homologous region until it is processed. The intermediate is assumed to be destroyed if the branch point ever reaches either end of the homology. In this model, the length dependence is governed by a parameter, h, which is defined as efficiency of processing of the intermediate and reflects unlikelihood of the destruction at either end of the homology. We find that the frequency is proportional to N(3) for smaller N and is a linear function of N for larger N. Where the shift from the N(3) dependence to the linear dependence takes place is determined by the parameter h. The range of N showing the N(3) dependence becomes narrower as h becomes larger. The dependence steeper than linear dependence, which is observed not only in the mammalian gene targeting system but also in bacteriophage T4, Escherichia coli and yeast systems, agrees well with the predicted N(3) dependence. The N intercept is determined not by physical (or structural) constraints but only by the parameter h in this model.     

Homologous Recombination in ESCHERICHIA COLI: Dependence on Substrate Length and Homology

We studied the in vivo recombination between homologous DNA sequences cloned in phage lambda and a pBR322-derived plasmid by assaying for the formation of phage-plasmid cointegrates by a single (or an odd number of) reciprocal exchange. (1) Recombination proceeds by the RecBC pathway in wild-type cells and by low levels of a RecF-dependent pathway in recBC- cells. The RecE pathway appears not to generate phage-plasmid cointegrates. (2) Recombination is linearly dependent on the length of the homologous sequences. In both RecBC and RecF-dependent pathways there is a minimal length, called the minimal efficient processing segment (MEPS), below which recombination becomes inefficient. The length of MEPS is between 23-27 base pairs (bp) and between 44-90 bp for the RecBC- and RecF-dependent pathways, respectively. A model, based on overlapping MEPS, of the correlation of genetic length with physical length is presented. The bases for the different MEPS length of the two pathways are discussed in relationship to the enzymes specific to each pathway. (3) The RecBC and the RecF-dependent pathways are each very sensitive to substrate homology. In wild-type E. coli, reduction of homology from 100% to 90% decreases recombinant frequency over 40-fold. The homology dependence of the RecBC and RecF-dependent pathways are similar. This suggests that a component common to both, probably recA, is responsible for the recognition of homology.     

Homologous Recombination in Zebrafish ES Cells

Targeted insertion of a plasmid by homologous recombination was demonstrated in zebrafish ES cell cultures. Two selection strategies were used to isolate ES cell colonies that contained targeted plasmid insertions in either the no tail or myostatin I gene. One selection strategy involved the manual isolation of targeted cell colonies that were identified by the loss of fluorescent protein gene expression. A second strategy used the diphtheria toxin A-chain gene in a positive-negative selection approach. Homologous recombination was confirmed by PCR, sequence and Southern blot analysis and colonies isolated using both selection methods were expanded and maintained for multiple passages. The results demonstrate that zebrafish ES cells have potential for use in a cell-mediated gene targeting approach.     

Recombineering Homologous Recombination Constructs in Drosophila

The continued development of techniques for fast, large-scale manipulation of endogenous gene loci will broaden the use of Drosophila melanogaster as a genetic model organism for human-disease related research. Recent years have seen technical advancements like homologous recombination and recombineering. However, generating unequivocal null mutations or tagging endogenous proteins remains a substantial effort for most genes. Here, we describe and demonstrate techniques for using recombineering-based cloning methods to generate vectors that can be used to target and manipulate endogenous loci in vivo. Specifically, we have established a combination of three technologies: (1) BAC transgenesis/recombineering, (2) ends-out homologous recombination and (3) Gateway technology to provide a robust, efficient and flexible method for manipulating endogenous genomic loci. In this protocol, we provide step-by-step details about how to (1) design individual vectors, (2) how to clone large fragments of genomic DNA into the homologous recombination vector using gap repair, and (3) how to replace or tag genes of interest within these vectors using a second round of recombineering. Finally, we will also provide a protocol for how to mobilize these cassettes in vivo to generate a knockout, or a tagged gene via knock-in. These methods can easily be adopted for multiple targets in parallel and provide a means for manipulating the Drosophila genome in a timely and efficient manner.     

Regulation of DNA Pairing in Homologous Recombination

Homologous recombination (HR) is a major mechanism for eliminating DNA double-strand breaks from chromosomes. In this process, the break termini are resected nucleolytically to form 3′ ssDNA (single-strand DNA) overhangs. A recombinase (i.e., a protein that catalyzes homologous DNA pairing and strand exchange) assembles onto the ssDNA and promotes pairing with a homologous duplex. DNA synthesis then initiates from the 3′ end of the invading strand, and the extended DNA joint is resolved via one of several pathways to restore the integrity of the injured chromosome. It is crucial that HR be carefully orchestrated because spurious events can create cytotoxic intermediates or cause genomic rearrangements and loss of gene heterozygosity, which can lead to cell death or contribute to the development of cancer. In this review, we will discuss how DNA motor proteins regulate HR via a dynamic balance of the recombination-promoting and -attenuating activities that they possess.     

植物基因同源重组研究现状

同源重组是普遍存在的生物学现象,从噬菌体、细菌到真核生物均有存在。它对生物的遗传与变异具有重大影响,一直是生物学家研究的热点。本文从染色体外同源重组、染色体内同源重组以及基因打靶三个方面综述了同源重组在植物方面的研究现状。从分子水平上较详尽的介绍了同源重组发生的机制以及同源重组在生物领域的应用、前景展望及其存在的局限性。     

植物基因同源重组研究现状

同源重组是普遍存在的生物学现象,从噬菌体、细菌到相传真核生物均有存在。它对生物的遗传与变异具有重大影响,一直是生物学家研究的热点。本文从染色体外同源重组、染色体内同源重组以及基因打靶三个方面综述了同源重组在植物方面的研究现状。从分子水平上较详尽的介绍了同源重组发生的机制以及同源重组在生物领域的应用、前景展望及其存在的局限性。     

Bloom DNA Helicase Facilitates Homologous Recombination between Diverged Homologous Sequences

Bloom syndrome caused by inactivation of the Bloom DNA helicase (Blm) is characterized by increases in the level of sister chromatid exchange, homologous recombination (HR) associated with cross-over. It is therefore believed that Blm works as an anti-recombinase. Meanwhile, in Drosophila, DmBlm is required specifically to promote the synthesis-dependent strand anneal (SDSA), a type of HR not associating with cross-over. However, conservation of Blm function in SDSA through higher eukaryotes has been a matter of debate. Here, we demonstrate the function of Blm in SDSA type HR in chicken DT40 B lymphocyte line, where Ig gene conversion diversifies the immunoglobulin V gene through intragenic HR between diverged homologous segments. This reaction is initiated by the activation-induced cytidine deaminase enzyme-mediated uracil formation at the V gene, which in turn converts into abasic site, presumably leading to a single strand gap. Ig gene conversion frequency was drastically reduced in BLM^−/− cells. In addition, BLM^−/− cells used limited donor segments harboring higher identity compared with other segments in Ig gene conversion event, suggesting that Blm can promote HR between diverged sequences. To further understand the role of Blm in HR between diverged homologous sequences, we measured the frequency of gene targeting induced by an I-SceI-endonuclease-mediated double-strand break. BLM^−/− cells showed a severer defect in the gene targeting frequency as the number of heterologous sequences increased at the double-strand break site. Conversely, the overexpression of Blm, even an ATPase-defective mutant, strongly stimulated gene targeting. In summary, Blm promotes HR between diverged sequences through a novel ATPase-independent mechanism.The RecQ helicases, a subfamily of DNA helicases, carry out the unwinding of duplex DNA in the 3′ to 5′ direction. Homologs of RecQ have been identified in a wide range of organisms, from budding yeast to humans (reviewed in Ref. 1). There are five human RecQ family proteins: Blm, Wrn, RecQ1, RecQ4, and RecQ5. The BLM, WRN, and RECQ4 genes are mutated in Bloom syndrome, Werner syndrome, and Rothmund-Thomson syndrome, respectively (1–3). A hallmark of Bloom syndrome cells is the drastic increase in the level of sister chromatid exchange (SCE),⁴ which results from homologous recombination (HR) associated with cross-over of the DNA damage caused during DNA replication (4, 5). It is therefore believed that Blm acts as an anti-recombination factor and inhibits aberrant recombination. This idea is supported by the observation that Sgs1, the yeast ortholog of Blm, facilitates the resolution of aberrant joint molecules during meiotic HR (6, 7) and following replication blockage (8).HR plays a critical role in the maintenance of genome stability by repairing DNA double-strand breaks (DSBs) and releasing replication blockages at damaged template strands (9, 10). The current model for HR-mediated DSB repair is that DSBs are processed to produce a 3′ single-stranded overhang, along which Rad51 is polymerized (11, 12). The resulting Rad51-DNA filament undergoes homology search and strand invasion into intact homologous duplex DNA, leading to the formation of the D-loop structure. DNA synthesis from the invading strand followed by dissociation from the homologous duplex DNA and subsequent re-annealing of the newly synthesized strand with the other end of the DSB completes the repair. This type of HR, referred to as synthesis-dependent strand anneal (SDSA), results in sequence transfer from the intact template sequence (donor) to the damaged DNA (recipient), and accounts for the majority of mitotic HR (11, 13). Extensive strand exchange of the D-loop, on the other hand, leads to the generation of Holliday junction (HJ) intermediates. SDSA does not cause cross-overs, whereas HR involving the Holliday junction often causes cross-overs, such as SCE and meiotic HR. An increase in the level of SCE in Bloom syndrome cells therefore supports the idea that Blm suppresses the formation of HJ as well as recombinogenic DNA lesions. This idea is supported by the biochemical evidence of the Blm-dependent resolution of Holliday junctions (14). On the other hand, in Drosophila, DmBlm is known to facilitate the repair of DSB by promoting SDSA (15, 16). However, the role of Blm in SDSA in the other higher eukaryotic cells has not been defined.BLM^−/− cells established from the chicken DT40 B lymphocyte line exhibit a marked increase in the frequency of both SCE and targeted integration (17–19), as do human Bloom syndrome cells (20, 21). In this study, using the chicken DT40 cells, we investigated the role of Blm in SDSA induced by defined DNA damage. To this end, we evaluated this type of SDSA using two phenotypic assays designed to analyze Ig gene conversion and DSB-induced gene targeting. Ig gene conversion diversifies the Ig variable (V) gene through HR during in vitro passage. This reaction is initiated by activation-induced cytidine deaminase-mediated uracil formation at the functional rearranged V-region (22–24). Uracil is converted to an abasic site, probably leading to a single-strand gap (25). This lesion in the functional rearranged VJ_λ stimulates the nonreciprocal sequence transfer of a single nucleotide to several hundred nucleotides, from an array of “pseudo-V_λ” regions (donor), located upstream from the functional rearranged VJ_λ, to the rearranged V region (recipient) (26–28) (see Fig. 1A). Because donor and recipient segments have an ∼10% sequence divergence, sequential Ig gene conversion events are able to substantially diversify Ig V segments. Ig gene conversion is raised only by SDSA without the formation of a Holliday junction. Hence, phenotypic analysis of Ig gene conversion provides a unique opportunity to selectively examine the role of Blm in activation-induced cytidine deaminase-induced SDSA. Moreover, nucleotide sequence analysis of Ig gene conversion products can evaluate the accuracy of HR. Like Ig gene conversion, DSB-induced gene targeting is mediated only by SDSA. The induction of DSBs by a rare-cutting endonuclease, I-SceI, at the endogenous locus, increases the frequency of gene targeting by 3 orders of magnitudes, and the frequency of gene targeting can be evaluated by measuring the reconstitution of a marker gene (29) (see Fig. 1B).Open in a separate windowFIGURE 1.Schematic diagram of assay systems used in this study. A, principle of the Ig gene conversion assay. The predominantly sIgM-negative DT40 clone contains a frameshift in its rearranged V-J_λ segments, which can be repaired by pseudogene-templated conversion events. The rate of Ig gene conversion can be measured in subclones by flow cytometric analysis of sIgM staining. B, phenotypic assays of Ig gene conversion and DSB-induced gene targeting. Pseudo-V genes and the targeting fragment act as donors for the rearranged V_λ segment and S2neo, respectively.We here show that the loss of Blm drastically reduces the rate of Ig gene conversion without compromising its accuracy or affecting the length of the gene conversion tracts, indicating that Blm plays a role in the promotion of SDSA. This is an unexpected result, because Blm is in fact believed to suppress general HR reactions, particularly recombination between diverged homologous sequences. To understand the function of Blm in SDSA, we analyzed the effect of heterologous sequences near a DSB site on HR-dependent DSB repair. The data demonstrate that Blm can promote SDSA when there is sequence divergence between the damaged recipient DNA and the homologous donor sequence. Thus, Blm has both positive and negative effects on HR, depending upon the type of DNA damage and the step of the HR reaction.     

影响动物细胞同源重组发生与基因打靶效率的分子机制

真核细胞的基因打靶是基因结构与功能研究的一种非常有价值的技术,也是可应用于基因治疗的具有潜力的工具。有2个限制因素束缚真核细胞基因打靶的发展,即同源重组(HR)率非常低而随机整合率非常高。通过特定基因的过表达或表达干涉,使一些参与DNA重组的蛋白表达水平瞬间改变,可能会增加HR率,降低随机整合率。本文列举了一些与HR相关的候选基因,详细介绍了其中的Rad52上位簇基因,还讨论了打靶载体的设计与修饰、DNA转染方法的有效性等。     

同源重组分子基础的教学讨论

本文从教学出发,着重以广泛流行的Meselson-Radding模型讨论了同源重组和基因转换的分子基础,以助于学生在学习中的理解与掌握。 Abstract:In order to assist students with understanding homologous recombination and gene conversion,the molecule basis of homologous recombination and gene conversion was discussed in this paper.     

Multiple Pathways for Homologous Recombination in Saccharomyces Cerevisiae

The genes in the RAD52 epistasis group of Saccharomyces cerevisiae are necessary for most mitotic and meiotic recombination events. Using an intrachromosomal inverted-repeat assay, we previously demonstrated that mitotic recombination of this substrate is dependent upon the RAD52 gene. In the present study the requirement for other genes in this epistasis group for recombination of inverted repeats has been analyzed, and double and triple mutant strains were examined for their epistatic relationships. The majority of recombination events are mediated by a RAD51-dependent pathway, where the RAD54, RAD55 and RAD57 genes function downstream of RAD51. Cells mutated in RAD55 or RAD57 as well as double mutants are cold-sensitive for inverted-repeat recombination, whereas a rad51 rad55 rad57 triple mutant is not. The RAD1 gene is not required for inverted-repeat recombination but is able to process spontaneous DNA lesions to produce recombinant products in the absence of RAD51. Furthermore, there is still considerably more recombination in rad1 rad51 mutants than in rad52 mutants, indicating the presence of another, as yet unidentified, recombination pathway.     

Detection of Homologous Recombination Events in Bacterial Genomes

We study the detection of mutations, sequencing errors, and homologous recombination events (HREs) in a set of closely related microbial genomes. We base the model on single nucleotide polymorphisms (SNPs) and break the genomes into blocks to handle the rearrangement problem. Then we apply a dynamic programming algorithm to model whether changes within each block are likely a result of mutations, sequencing errors, or HREs. Results from simulation experiments show that we can detect 31%–61% of HREs and the precision of our detection is about 48%–90% depending on the rates of mutation and missing data. The HREfinder software for predicting HREs in a set of whole genomes is available as open source (http://sourceforge.net/projects/hrefinder/).     

Homologous Recombination Involving a Large Heterology in Escherichia Coli

Recombination between two different deletion alleles of a gene (neo) for neomycin and kanamycin resistance was studied in an Escherichia coli sbcA- recB-C- strain. The two homologous regions were in an inverted orientation on the same plasmid molecule. Kanamycin-resistant plasmids were selected and analyzed. The rate of recombination to form kanamycin-resistant plasmids was decreased by mutations in the recE, recF and recJ genes, but was not decreased by a mutation in the recA gene. It was found that these plasmids often possessed one wild-type kanamycin-resistant allele (neo+) while the other neo allele was still in its original (deletion) form. Among kanamycin-resistant plasmids with one wild-type and one parental allele it was often found that the region between the inverted repeats had been flipped (turned around) with respect to sites outside the inverted repeats. These results were interpreted as follows. Gene conversion, analogous to gene conversion in eukaryotic meiosis, is responsible for a unidirectional transfer of information from one neo deletion allele to the other. The flipping of the region between the inverted repeats is interpreted as analogous to the crossing over associated with gene conversion in eukaryotic meiosis. In contrast with a rec+ strain, these products cannot be explained by two rounds of reciprocal crossing over involving a dimeric form as an intermediate. In the accompanying paper we present evidence that gene conversion by double-strand gap repair takes place in the same E. coli strain.     

Homologous Recombination between Autonomously Replicating Plasmids in Mammalian Cells

The ability of autonomously replicating plasmids to recombine in mammalian cells was investigated. Two deletion plasmids of the eukaryotic-prokaryotic shuttle vector pSV2neo were cotransfected into transformed monkey COS cells. Examination of the low molecular weight DNA isolated after 48 hr of incubation revealed that recombination between the plasmids had occurred. The DNA was also used to transform recA- E. coli. Yield of neoR colonies signified homologous recombination. Examination of the plasmid DNA from these colonies confirmed this view. Double-strand breaks in one or both of the input plasmids at the sites of deletion resulted in an enhancement of recombination frequency. The recombination process yielded monomeric and dimeric molecules. Examination of these molecules revealed that reciprocal recombination as well as gene conversion events were involved in the generation of plasmids bearing an intact neo gene. The COS cell system we describe is analogous to study of bacteriophage recombination and yeast random-spore analysis.     

The Frequency of Homologous Recombination in Human ALT Cells

Instead of telomerase, some immortal cells use the alternative lengthening of telomeres pathway (ALT) to maintain their telomeres. There is good evidence that homologous recombination contributes to the ALT mechanism. Using an inducible GFP reporter system to measure the frequency of homologous recombination, we asked whether or not ALT cells exhibited a general change of the recombination machinery. Our results show that the frequency of homologous recombination for non-telomeric sequences in ALT cells is identical to that in telomerase positive cells, irrespective of whether the reporter was present at an intra-chromosomal location or next to a telomeric sequence. We conclude that the underlying recombination defect in ALT cells is restricted to telomeric sequences.     

Homologous Recombination between Episomal Plasmids and Chromosomes in Yeast

We have observed genetic recombination between ura3( -) mutations (among them extensive deletions) carried on "episomal" (i.e., 2micro DNA-containing) plasmids and other ura3( -) alleles present at the normal chromosomal URA3 locus. The recombination frequency found was comparable to the level observed for classical mitotic recombination but was relatively insensitive to sunlamp radiation, which strongly stimulates mitotic recombination. Three equally frequent classes could be distinguished among the recombinants. Two of these are the apparent result of gene conversions (or double crossovers) which leave the URA3(+) allele on the chromosome (class I) or on the plasmid (class II). The third class is apparently due to a single crossover that results in the integration of the plasmid into a chromosome. Plasmid-chromosome recombination can be useful in fine structure genetic mapping, since recombination between a chromosomal point mutation and a plasmid-borne deletion mutation only 25 base pairs distant was easily detected.     

黑暗链霉菌DNA同源重组系统的构建

以黑暗链霉菌Tt-49基因组为模板,利用PCR方法,扩增安普霉素生物合成关键基因aprF-G的上、下游序列,作为同源交换臂,并将红霉素抗性基因筛选标记及其启动子插入两交换臂之间,以温敏型质粒pKC1139为基础,构建用于阻断黑暗链霉菌Tt-49安普霉素生物合成的重组质粒pFD8.该质粒通过E.coil ET12567/pUZ8002去甲基化修饰后,经接舍转移进入黑暗链霉菌Tt-49,利用红霉素抗性筛选得到3株阳性转化子,分别命名为Tt-49 AG1、Tt-49 AG2和Tt-49 AG3.通过PCR鉴定,证明pFD8已插入黑暗链霉菌Tt-49基因组的目标位点.以亲株作对照,对3株工程菌进行红霉素抗性能力考察,发现3株工程菌的抗红霉素能力均高迭1 000 μg/mL以上.     

RecX Facilitates Homologous Recombination by Modulating RecA Activities

The Bacillus subtilis recH342 strain, which decreases interspecies recombination without significantly affecting the frequency of transformation with homogamic DNA, carried a point mutation in the putative recX (yfhG) gene, and the mutation was renamed as recX342. We show that RecX (264 residues long), which shares partial identity with the Proteobacterial RecX (<180 residues), is a genuine recombination protein, and its primary function is to modulate the SOS response and to facilitate RecA-mediated recombinational repair and genetic recombination. RecX-YFP formed discrete foci on the nucleoid, which were coincident in time with RecF, in response to DNA damage, and on the poles and/or the nucleoid upon stochastic induction of programmed natural competence. When DNA was damaged, the RecX foci co-localized with RecA threads that persisted for a longer time in the recX context. The absence of RecX severely impaired natural transformation both with plasmid and chromosomal DNA. We show that RecX suppresses the negative effect exerted by RecA during plasmid transformation, prevents RecA mis-sensing of single-stranded DNA tracts, and modulates DNA strand exchange. RecX, by modulating the “length or packing” of a RecA filament, facilitates the initiation of recombination and increases recombination across species.