Double-stranded DNA breaks and gene functions in recombination and meiosis

Meiotic prophase I is a long and complex phase. Homologous recombination is an important process that occurs between homologous chromosomes during meiotic prophase I. Formation of chiasmata, which hold homologous chromosomes together until the metaphase I to anaphase I transition, is critical for proper chromosome segregation. Recent studies have suggested that the SPO 11 proteins have conserved functions in a number of organisms in generating sites of double-stranded DNA breaks （DSBs） that are thought to be the starting points of homologous recombination. Processing of these sites of DSBs requires the function of RecA homologs, such as RAD5 1, DMC 1, and others, as suggested by mutant studies; thus the failure to repair these meiotic DSBs results in abnormal chromosomal alternations, leading to disrupted meiosis. Recent discoveries on the functions of these RecA homologs have improved the understanding of the mechanisms underlying meiotic homologous recombination.     

Analysis and location of a rice BAG clone containing telomeric DNA sequences

BAC2, a rice BAC clone containing (TTTAGGG)n homologous sequences, was analyzed by Southern hybridization and DNA sequencing of its subclones. It was disclosed that there were many tandem repeated satellite DNA sequences, called TA352, as well as simple tandem repeats consisting of TTTAGGG or its variant within the BAC2 insert. A 0. 8 kb (TTTAGGG) n-containing fragment in BAC2 was mapped in the telomere regions of at least 5 pairs of rice chromosomes by using fluorescence in situ hybridization (FISH). By RFLP analysis of low copy sequences the BAC2 clone was localized in one terminal region of chromosome 6. All the results strongly suggest that the telomeric DNA sequences of rice are TTTAGGG or its variant, and the linked satellite DNA TA352 sequences belong to telomere-associated sequences.     

应用细菌内同源重组机制快速克隆腺病毒基因组的研究

A novel procedure was used for cloning large adenovirus genome fragment by the homologous recombination in E.coli strain BJ5183. The 11.2Kb downstream fragment of the CAV-2 strain YCA18 genome was cloned by homologous recombination, the 1029bp left end and the 970bp fight end of this fragment were separately amplified by PCR. They were then cloned into plasmid pPoly2 with direction from left fragment to fight fragment, obtaining a “rescue” plasmid pT615. The pT615 was liberalized by Hind Ⅲ and PstⅠ digestion and was cotransformed with the purified CAV-2 genome which was cut by BstBI into competent E.coli strain BJ5183. Recombinant plasmids harboring the 11.2Kb downstream fragment of CAV-2 genome were obtained after bacterial intermolecular homologous recombination. The recombinant efficiency of all E.coli strains tested was 78.3%. One of the recombinant plasmids, pT618, was further identified by enzyme digestion analysis and PCR amplification. The results showed the plasmids contained the 11.2kb fragment downstream the genome of CAV-2.     

Red重组系统及在微生物基因敲除中的应用

在完成了对各种微生物基因组的测序以后,功能基因学的研究变得尤为重要。研究基因功能最直接的方法便是将待研究的基因失活。最初构建基因突变体是采用大肠杆菌的RecA系统,但是RecA重组系统操作复杂,重组效率低。最近建立了Red重组系统,该系统由3个蛋白组成：α蛋白(即λ核酸外切酶),β蛋白,Gam蛋白。应用Red系统进行基因敲除,可以直接利用线性打靶DNA,两侧同源臂长度在35~60 bp即可发生同源重组,且重组效率高。 Abstract:Since many DNA-sequencing projects of varied microorganisms have been completed,studies on their functional genomics become more important.Inactivation of an interesting gene is a direct method to characterize its function.Though the Esherichia coli RecA recombination system can be used to produce gene mutants,it needs a complex manipulation process.Furthermore,its efficiency is very low.Recently a Red recombination system was developed.This recombination system consists of three proteins:α protein（λ exonuclease）,β protein and Gam protein.In this system,the linear targeting DNA which contains a selectable marker flanked with a homologous region as short as only 35~60 bp can be directly targeted for gene knock-out with a higher efficiency.     

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.     

Homologous recombination in DNA repair and DNA damage tolerance

Homologous recombination （HR） comprises a series of interrelated pathways that function in the repair of DNA double-stranded breaks （DSBs） and interstrand crosslinks （ICLs）. In addition, recombination provides critical support for DNA replication in the recovery of stalled or broken replication forks, contributing to tolerance of DNA damage. A central core of proteins, most critically the RecA homolog Rad51, catalyzes the key reactions that typify HR： homology search and DNA strand invasion. The diverse functions of recombination are reflected in the need for context-specific factors that perform supplemental functions in conjunction with the core proteins. The inability to properly repair complex DNA damage and resolve DNA replication stress leads to genomic instability and contributes to cancer etiology. Mutations in the BRCA2 recombination gene cause predisposition to breast and ovarian cancer as well as Fanconi anemia, a cancer predisposition syndrome characterized by a defect in the repair of DNA interstrand crosslinks. The cellular functions of recombination are also germane to DNA-based treatment modalities of cancer, which target replicating cells by the direct or indirect induction of DNA lesions that are substrates for recombination pathways. This review focuses on mechanistic aspects of HR relating to DSB and ICL repair as well as replication fork support.     

T-DNA Integration Category and Mechanism in Rice Genome

T-DNA integration is a key step in the process of plant transformation, which is proven to be important for analyzing T-DNA integration mechanism. The structures of T-DNA right borders inserted into the rice (Oryza sativa L.) genome and their flanking sequences were analyzed. It was found that the integrated ends of the T-DNA right border occurred mainly on five nucleotides “TGACA” in inverse repeat (IR) sequence of 25 bp, especially on the third base “A”. However, the integrated ends would sometimes lie inward of the IR sequence, which caused the IR sequence to be lost completely. Sometimes the right integrated ends appeared on the vector sequences rightward of the T-DNA right border, which made the T-DNA, carrying vector sequences, integrated into the rice genome. These results seemingly suggest that the IR sequence of the right border plays an important role in the process of T-DNA integration into the rice genome, but is not an essential element. The appearance of vector sequences neighboring the T-DNA right border suggested that before being transferred into the plant cell from Agrobacterium, the entire T-DNA possibly began from the left border in synthesis and then read through at the right border. Several nucleotides in the T-DNA right border homologous with plant DNA and filler DNAs were frequently discovered in the integrated position of T-DNA. Some small regions in the fight border could match with the plant sequence, or form better matches, accompanied by the occurrence of filler DNA, through mutual twisting, and then the T-DNA was integrated into plant chromosome through a partially homologous recombination mechanism. The appearance of filler DNA would facilitate T-DNA integration. The fragments flanking the T-DNA fight border in transformed rice plants could derive from different parts of the inner T-DNA region; that is, disruption and recombination could occur at arbitrary positions in the entire T-DNA, in which the homologous area was comparatively easier to be disrupted. The structure of flanking sequences of T-DNA integrated in the rice chromosome presented various complexities. These complexities were probably a result of different patterns of recombination in the integrating process. Some types of possible integrating mechanism are detailed.     

A bacterial artificial chromosome transgenic mouse model for visualization of neurite growth

Class III β-tubulin(Tubb3) is a component of the microtubules in neurons and contributes to microtubule dynamics that are required for axon outgrowth and guidance during neuronal development. We here report a novel bacterial artificial chromosome(BAC) transgenic mouse line that expresses Class III β-tubulin fused to m Cherry, an improved monomeric red fluorescent protein, for the visualization of microtubules during neuronal development. A BAC containing Tubb3 gene was modified by insertion of m Cherry complementary DNA downstream of Tubb3 coding sequence via homologous recombination. m Cherry fusion protein was expressed in the nervous system and testis of the transgenic animal, and the fluorescent signal was observed in the neurons that located in the olfactory bulb, cerebral cortex, hippocampal formation, cerebellum, as well as the retina. Besides, Tubb3-m Cherry fusion protein mainly distributed in neurites and colocalized with endogenous Class III β-tubulin. The fusion protein labels Purkinje cell dendrites during cerebellar circuit formation. Therefore, this transgenic line might be a novel tool for scientific community to study neuronal development both in vitro and in vivo.     

用RACE结合cDNA文库筛选的方法获取新的锌指蛋白基因

大多数有重要功能的蛋白质都含相应的由保守氨基酸顺序组成的功能结构域。本文首先根据蛋白质功能结构域保守氨基酸序列设计简并引物,用PCR方法扩增出基因EST序列,再利用改进的快速扩增cDNA末端（RACE）方法从cDNA文库中扩增出基因非同源部位,然后以非同源序列为探针,筛选cDNA文库。利用此方法成功地从人骨髓cDNA文库中克隆到几个编码锌指蛋白并代表原有EST的新的全长cDNA。这一策略也应适用于筛选编码具有其他序列保守性功能结构域蛋白的基因。 Abstract:Most of the important functionally proteins contain the corresponding function domains that consist of conserved amino acid sequences.The study provided a method to identify novel genes that encode proteins containing important functionally domains with conserved sequences.First,primers were designed according to the sequence of the cDNA library vector and the ESTs that have been obtained by reverse PCR and degenerate primers encoding Zinc finger domain.The cDNA library DNA was used as template for PCR amplification.The amplified fragment that contains nonhomologous sequences of the cDNA was inserted into pGEM-T easy vector.The fragment was recovered and used as a probe for screening the cDNA library.Several cDNAs with full length that encode proteins with Zinc finger domain and represent the original ESTs have been successfully cloned from a human bone marrow cDNA library.This strategy can also be used in screening genes that encode proteins containing differential function domains with conserved sequences.     

A multi-step strategy for BAC recombineering of large DNA fragments

Recombineering techniques have been developed to modify bacterial artificial chromosomes (BACs) via bacterial homologous recombination systems, simplifying the molecular manipulations of large DNA constructs. However, precise modifications of a DNA fragment larger than 2-3 kb by recombineering remain a difficult task, due to technical limitations in PCR amplification and purification of large DNA fragments. Here, we describe a new recombineering strategy for the replacement of large DNA fragments using the commonly utilized phage/Red recombination host system. This approach involved the introduction of rare restriction enzyme sites and positive selection markers into the ends of a large DNA fragment, followed by its release from the donor BAC construct and integration into an acceptor BAC. We have successfully employed this method to precisely swap a number of large DNA fragments ranging from 6 to 40 kb between two BAC constructs. Our results demonstrated that this new strategy was highly effective in the manipulations of large genomic DNA fragments and therefore should advance the conventional BAC recombineering technology to the next level.     

A new method for generating point mutations in bacterial artificial chromosomes by homologous recombination in Escherichia coli

Bacterial artificial chromosomes (BACs) and P1 artificial chromosomes (PACs), which contain large fragments of genomic DNA, have been successfully used as transgenes to create mouse models of dose-dependent diseases. They are also potentially valuable as transgenes for dominant diseases given that point mutations and/or small rearrangements can be accurately introduced. Here, we describe a new method to introduce small alterations in BACs, which results in the generation of point mutations with high frequency. The method involves homologous recombination between the original BAC and a shuttle vector providing the mutation. Each recombination step is monitored using positive and negative selection markers, which are the Kanamycin-resistance gene, the sacB gene and temperature-sensitive replication, all conferred by the shuttle plasmid. We have used this method to introduce four different point mutations and the insertion of the β-galactosidase gene in a BAC, which has subsequently been used for transgenic animal production.     

Combination of overlapping bacterial artificial chromosomes by a two-step recombinogenic engineering method

Recombinogenic engineering or recombineering is a powerful new method to engineer DNA without the need for restriction enzymes or ligases. We report here a general method for using recombineering to combine overlapping bacterial artificial chromosomes (BACs) to build larger, unified BACs. In order to test the feasibility of using recombineering to combine two large DNA fragments (>20 kb), we constructed a unified BAC containing the full-length tyrosinase-related protein-1 (Tyrp-1) gene from two library-derived BACs, one containing the 5′ regulatory elements and the other containing the 3′ coding exons. This was achieved using a two-step homologous recombination method enabled by the bacteriophage λ Red proteins. In the first step, retrieval, a large DNA fragment (~22 kb) was retrieved from one of the original BACs. In the second step, recombination, the retrieved DNA fragment was inserted into the second original BAC to form the unified BAC containing all the desired Tyrp-1 sequence. To further demonstrate the general applicability of our approach, an additional DNA fragment (~20 kb) was inserted into the unified BAC downstream of the coding region. This method should prove very useful for enabling BAC manipulation in a variety of scenarios.     

Assisted large fragment insertion by Red/ET-recombination (ALFIRE)--an alternative and enhanced method for large fragment recombineering

Functional genomics require manipulation and modification of large fragments of the genome. Such manipulation has only recently become more efficient due to the discovery of different techniques based on homologous recombination. However, certain limitations of these strategies still exist since insertion of homology arms (HAs) is often based on amplification of DNA sequences with PCR. Large quantities of PCR products longer than 4-5 kb can be difficult to obtain and the risk of mutations or mismatches increases with the size of the template that is being amplified. This can be overcome by adding HAs by conventional cloning techniques, but with large fragments such as entire genes the procedure becomes time-consuming and tedious. Second, homologous recombination techniques often require addition of antibiotic selection genes, which may not be desired in the final construct. Here, we report a method to overcome the size and selection marker limitations by a two- or three-step procedure. The method can insert any fragment into small or large episomes, without the need of an antibiotic selection gene. We have humanized the mouse luteinizing hormone receptor gene (Lhcgr) by inserting a approximately 55 kb fragment from a BAC clone containing the human Lhcgr gene into a 170 kb BAC clone comprising the entire mouse orthologue. The methodology is based on the rationale to introduce a counter-selection cassette flanked by unique restriction sites and HAs for the insert, into the vector that is modified. Upon enzymatic digestion, in vitro or in Escherichia coli, double-strand breaks are generated leading to recombination between the vector and the insert. The procedure described here is thus an additional powerful tool for manipulating large and complex genomic fragments.     

Engineering large fragment insertions into the chromosome of Escherichia coli

An effective DNA replacement system has been established for engineering large fragment insertions into the chromosome of Escherichia coli. The DNA replacement plasmid, pHybrid I, was first constructed based on the bacterial artificial chromosome (BAC) vector. Two fragments of the E. coli genome, 5.5 and 6.5 kb in length, were introduced into the vector for homologous recombination. In addition to the chloramphenicol gene, a second gene neo was introduced for double marker screening for recombinant clones. By shot-gun cloning and homologous recombination techniques, using our new recombinant vector (pHybrid I), a 20-kb fragment from Lactococcus lactis genomic DNA has been successfully integrated into the chromosome of the E. coli strain J93-140. Plating tests and PCR amplification indicated that the integration remained stable after many generations in cell culture. This system will be especially useful for the chromosome engineering of large heterologous fragment insertions, which is necessary for pathway engineering.     

Assembly of long DNA sequences using a new synthetic Escherichia coli-yeast shuttle vector

Synthetic biology is a newly developed field of research focused on designing and rebuilding novel biomolecular components, circuits, and networks. Synthetic biology can also help understand biological principles and engineer complex artificial metabolic systems. DNA manipulation on a large genome-wide scale is an inevitable challenge, but a necessary tool for synthetic biology. To improve the methods used for the synthesis of long DNA fragments, here we constructed a novel shuttle vector named p GF(plasmid Genome Fast) for DNA assembly in vivo. The BAC plasmid p CC1 BAC, which can accommodate large DNA molecules, was chosen as the backbone. The sequence of the yeast artificial chromosome(YAC) regulatory element CEN6-ARS4 was synthesized and inserted into the plasmid to enable it to replicate in yeast. The selection sequence HIS3, obtained by polymerase chain reaction(PCR) from the plasmid p BS313, was inserted for screening. This new synthetic shuttle vector can mediate the transformation-associated recombination(TAR) assembly of large DNA fragments in yeast, and the assembled products can be transformed into Escherichia coli for further amplification. We also conducted in vivo DNA assembly using p GF and yeast homologous recombination and constructed a 31-kb long DNA sequence from the cyanophage PP genome. Our findings show that this novel shuttle vector would be a useful tool for efficient genome-scale DNA reconstruction.     

Reconstitution of Marek's disease virus serotype 1 (MDV-1) from DNA cloned as a bacterial artificial chromosome and characterization of a glycoprotein B-negative MDV-1 mutant

The complete genome of Marek's disease virus serotype 1 (MDV-1) strain 584Ap80C was cloned in Escherichia coli as a bacterial artificial chromosome (BAC). BAC vector sequences were introduced into the U(S)2 locus of the MDV-1 genome by homologous recombination. Viral DNA containing the BAC vector was used to transform Escherichia coli strain DH10B, and several colonies harboring the complete MDV-1 genome as an F plasmid (MDV-1 BACs) were identified. DNA from various MDV-1 BACs was transfected into chicken embryo fibroblasts, and from 3 days after transfection, infectious MDV-1 was obtained. Growth of MDV-1 recovered from BACs was indistinguishable from that of the parental virus, as assessed by plaque formation and determination of growth curves. In one of the MDV-1 BAC clones, sequences encoding glycoprotein B (gB) were deleted by one-step mutagenesis using a linear DNA fragment amplified by PCR. Mutant MDV-1 recovered after transfection of BAC DNA that harbored a 2.0-kbp deletion of the 2.6-kbp gB gene were able to grow and induce MDV-1-specific plaques only on cells providing MDV-1 gB in trans. The gB-negative virus reported here represents the first MDV-1 mutant with a deletion of an essential gene and demonstrates the power and usefulness of BACs to analyze genes and gene products in slowly growing and strictly cell-associated herpesviruses.     

利用Red重组系统快速构建基因打靶载体

基因敲除小鼠模型是在哺乳动物体内研究基因功能最可靠的方法之一。利用常规的分子克隆的方法构建基因打靶载体往往工作周期长,对于难度特别大的基因有时甚至无法完成打靶载体的构建。通过合理应用Red重组系统和低拷贝中间载体,利用50bp的同源重组序列直接从BAC载体中克隆了长片段的小鼠基因组序列;将得到的基因组序列再次通过重组和改造,构建了Gpr56等基因的完全敲除并带有报告基因的打靶载体,实现了打靶载体的快速构建。     

Cre-LoxP系统在炭疽芽胞杆菌基因敲除中的应用及eag基因的敲除

将Cre-LoxP系统应用于Bacillus anthracis中并成功敲除eag基因．以B.anthracis基因组为模板扩增得到上下游同源臂,联合两端带有LoxP位点的壮观霉素抗性基因片段构建好同源重组载体,转化B．anthracis AP422,通过一系列筛选得到带有抗性标记的重组菌．然后,通过转入Cre重组酶表达质粒,去除抗性标记,得到eag基因缺失的重组菌,并在DNA水平、RNA水平和蛋白质水平进行了系统的鉴定．最终建立了Cre-LoxP系统在B．anthracis中的应用方法,并成功敲除eag基因.     

Ultra-Low Background DNA Cloning System

Yeast-based in vivo cloning is useful for cloning DNA fragments into plasmid vectors and is based on the ability of yeast to recombine the DNA fragments by homologous recombination. Although this method is efficient, it produces some by-products. We have developed an “ultra-low background DNA cloning system” on the basis of yeast-based in vivo cloning, by almost completely eliminating the generation of by-products and applying the method to commonly used Escherichia coli vectors, particularly those lacking yeast replication origins and carrying an ampicillin resistance gene (Amp^r). First, we constructed a conversion cassette containing the DNA sequences in the following order: an Amp^r 5′ UTR (untranslated region) and coding region, an autonomous replication sequence and a centromere sequence from yeast, a TRP1 yeast selectable marker, and an Amp^r 3′ UTR. This cassette allowed conversion of the Amp^r-containing vector into the yeast/E. coli shuttle vector through use of the Amp^r sequence by homologous recombination. Furthermore, simultaneous transformation of the desired DNA fragment into yeast allowed cloning of this DNA fragment into the same vector. We rescued the plasmid vectors from all yeast transformants, and by-products containing the E. coli replication origin disappeared. Next, the rescued vectors were transformed into E. coli and the by-products containing the yeast replication origin disappeared. Thus, our method used yeast- and E. coli-specific “origins of replication” to eliminate the generation of by-products. Finally, we successfully cloned the DNA fragment into the vector with almost 100% efficiency.