Structural effect of donor DNA on the initiation of recombination for double strand break repair in human nuclear extracts.

The effect of the structure of donor DNA molecules on the initiation of recombination for double strand break repair in human nuclear extracts, was investigated here. A unique double strand break was introduced into M13 duplex derivatives by digestion with restriction enzymes. After coincubation of the cleaved DNA in human nuclear extracts, with a plasmid containing M13 sequences spanning the break, double strand break repair was estimated by the plating efficiency in JM109 (RecA1) bacteria. We first confirm that a short heterologous insert (8bp) close to the break on the recipient cleaved M13 DNA inhibits recombination with circular as well as with linear donor molecules. The results indicate that, with these substrates, recombination is initiated at the level of the break, requires uninterrupted homology on both sides of the break, and is associated with a decreasing gradient of gene conversion. When the heterologous insertion is located on the plasmid donor DNA, similar results are obtained with a circular donor DNA. In contrast, with a linear donor molecule, bearing the insert, homology requirements, in the region of the break in M13 DNA, are abolished. This last result suggests that recombination could be initiated at the extremities of the linear donor DNA.     

Directional recombination is initiated at a double strand break in human nuclear extracts.

The involvement of a double strand break in the initiation of homologous recombination was examined in human nuclear extracts. M13 duplex derivatives, containing inserts in the LacZ' region (producing white plaques), were cleaved by restriction enzymes and coincubated in the extracts with a circular plasmid containing the LacZ' region without insert, and unable to produce plaques. Repair was estimated by the ability to produce plaques after transfection into JM109 (recA1) bacteria. Recombination with the plasmid enhances the number of plaques and also the frequency of M13 producing blue plaques. Heterologous insertions in the region surrounding the break were analyzed for their effects on initiation of recombination. The extent of repair by recombination (number of plaques) was compared with the number of blue plaques among the repaired population. Initiation of recombination is inhibited when heterologous insertions are located at 7bp from the break, on the right side as well as on the left side. A low level of recombination is measurable for 27 bp of homology but the maximum efficiency of recombination occurred with homologies of 165 or 320 bp from the break to the heterologous insertion. At 320 bp, the extent of recombinational repair remained at a plateau level but the frequency of blue plaques progressively decreases. We have also analyzed the effect of different sizes of inserts. With longer inserts, a longer length of homology adjacent to the break is required for optimum recombination. However, the size of the insert does not affect the low level of recombination that occurred with a short homology (27 bp). The results indicate that the process is initiated at or near the break, requires homology on both sides of the break and is followed by an elongation from the double strand break to the distal regions of the DNA. Our data provide some support to the double-strand-break repair model established for meiotic recombination in yeast.     

Use of M13mp phages to study gene regulation, structure and function: cloning and recombinational analysis of genes of the Salmonella typhimurium histidine operon

A restriction map was determined for a phi 80 lambda dhis transducing phage DNA carrying the Salmonella typhimurium histidine operon. DNA fragments containing the promoter/regulatory region and the first two structural genes of the histidine operon (hisOGD) were identified by their ability to direct regulated synthesis of histidinol dehydrogenase (product of hisD) in a coupled in vitro protein synthesizing system. A 3.1-kb SalI-EcoRI restriction fragment containing the hisOGD region, was subcloned into phage M13mp8 and M13mp9 RF DNAs. Methods are described for shuttling mutant and wild-type bacterial DNA sequences between the M13mp::his phage and host bacterial genomes. Of novel importance is the use of the phage M13 gene II amber mutation to obtain integration of the M13mp::his phage genome into the homologous his region of the bacterial chromosome following transduction of recipients lacking an amber suppressor. This method can be used to facilitate allele replacement with genes carried on M13 transducing phages.     

Repair of thymine.guanine and uracil.guanine mismatched base-pairs in bacteriophage M13mp18 DNA heteroduplexes

Repair of thymine.guanine (T.G) and uracil.guanine (U.G) mismatched base-pairs in bacteriophage M13mp18 replicative form (RF) DNA was compared upon transfection into repair-proficient or repair-deficient Escherichia coli strains. Oligonucleotide-directed mutagenesis was used to prepare covalently closed circular heteroduplexes that contained the mismatched base-pair at a restriction recognition site. The heteroduplexes were unmethylated at dam (5'-GATC-3') sites to avoid methylation-directed biasing of repair. In an E. coli host containing uracil-DNA glycosylase (ung+), about 97% of the transfecting U.G-containing heteroduplexes had the U residue excised by the uracil-excision repair system. With the analogous T.G mispair, mismatch repair operated on almost all of the transfecting heteroduplexes and removed the T residue in about 75% of them when the mismatched T was on the minus strand of the RF DNA. Similar preferential excision of the minus-strand's mismatched base was observed whether the heteroduplex RF DNA molecules had only one or both strands unmethylated at dcm (5'-CC(A/T)GG-3') sites and whether the RF DNA was prepared by primer extension in vitro or by reannealing mutant and non-mutant DNA strands. Also, the extent and directionality of repair was the same at a U.G mispair in ung- host cells as at the analogous T.G mispair in ung- or ung+ cells. Only in a mismatch repair-deficient (mutH-) host was the plus strand of the transfecting M13mp18 heteroduplex DNA preferentially repaired. It is suggested that the plus strand nick made by the M13-encoded gene II protein might be employed by a mutH- host to initiate repair on that strand.     

T7 single strand DNA binding protein but not T7 helicase is required for DNA double strand break repair

An in vitro system based on Escherichia coli infected with bacteriophage T7 was used to test for involvement of host and phage recombination proteins in the repair of double strand breaks in the T7 genome. Double strand breaks were placed in a unique XhoI site located approximately 17% from the left end of the T7 genome. In one assay, repair of these breaks was followed by packaging DNA recovered from repair reactions and determining the yield of infective phage. In a second assay, the product of the reactions was visualized after electrophoresis to estimate the extent to which the double strand breaks had been closed. Earlier work demonstrated that in this system double strand break repair takes place via incorporation of a patch of DNA into a gap formed at the break site. In the present study, it was found that extracts prepared from uninfected E. coli were unable to repair broken T7 genomes in this in vitro system, thus implying that phage rather than host enzymes are the primary participants in the predominant repair mechanism. Extracts prepared from an E. coli recA mutant were as capable of double strand break repair as extracts from a wild-type host, arguing that the E. coli recombinase is not essential to the recombinational events required for double strand break repair. In T7 strand exchange during recombination is mediated by the combined action of the helicase encoded by gene 4 and the annealing function of the gene 2.5 single strand binding protein. Although a deficiency in the gene 2.5 protein blocked double strand break repair, a gene 4 deficiency had no effect. This argues that a strand transfer step is not required during recombinational repair of double strand breaks in T7 but that the ability of the gene 2.5 protein to facilitate annealing of complementary single strands of DNA is critical to repair of double strand breaks in T7.     

Homologous recombination intermediates between two duplex DNA catalysed by human cell extracts.

Using as substrates, 1: the replicative form (RF) of phage M13 mp8 in which the reading frame of the lac Z' gene was disrupted by insertion of an octonucleotide, and 2: a restriction fragment one kb long, containing the functional lac Z' gene (isolated from wild type M13 mp8), we show that nuclear extracts from human cells (3 lines tested) promote the targeted replacement of the altered sequence by the functional one. Following incubation with the extracts, the DNA's were introduced in JM 109 bacteria (rec A- and lac Z'-) which were grown in presence of a colorimetric indicator of beta-galactosidase activity. Homologous recombination gives rise to the genotypical modification: lac Z'+ instead of lac Z'- in the bacteriophage DNA. This is revealed by phenotypical expression of the lac Z' gene product in replicating bacteriophage, i.e. the formation of blue instead of white plaques. The frequency of recombination (blue/total plaques) is increased by a factor of 50-80 as a function of protein concentration and of incubation time. The maximal frequency observed is 5 X 10(-5). There is no increase over the background when extracts are boiled. Electrophoresis and electron microscopy of DNA's incubated with the extracts show the formation of recombination intermediates with single strand exchange. Restriction analysis of recombined DNA confirms that the process corresponds to targeted sequence exchange. These data allow to propose three steps for homologous recombination between two duplex DNA's: i) unpairing of the two duplexes; ii) single-strand exchange and synaptic pairing; iii) resolution of the cross-junctions. The three steps correspond to those predicted by the gene conversion model of Holliday.     

The herpes simplex virus type 1 alkaline nuclease and single-stranded DNA binding protein mediate strand exchange in vitro

The replication of herpes simplex virus type 1 (HSV-1) DNA is associated with a high degree of homologous recombination. While cellular enzymes may take part in mediating this recombination, we present evidence for an HSV-1-encoded recombinase activity. HSV-1 alkaline nuclease, encoded by the UL12 gene, is a 5'-->3' exonuclease that shares homology with Redalpha, commonly known as lambda exonuclease, an exonuclease required for homologous recombination by bacteriophage lambda. The HSV-1 single-stranded DNA binding protein ICP8 is an essential protein for HSV DNA replication and possesses single-stranded DNA annealing activities like the Redbeta synaptase component of the phage lambda recombinase. Here we show that UL12 and ICP8 work together to effect strand exchange much like the Red system of lambda. Purified UL12 protein and ICP8 mediated the complete exchange between a 7.25-kb M13mp18 linear double-stranded DNA molecule and circular single-stranded M13 DNA, forming a gapped circle and a displaced strand as final products. The optimal conditions for strand exchange were 1 mM MgCl(2), 40 mM NaCl, and pH 7.5. Stoichiometric amounts of ICP8 were required, and strand exchange did not depend on the nature of the double-stranded end. Nuclease-defective UL12 could not support this reaction. These data suggest that diverse DNA viruses appear to utilize an evolutionarily conserved recombination mechanism.     

53BP1-mediated DNA double strand break repair: insert bad pun here

53BP1 is an established player in the cellular response to DNA damage and is a canonical component of ionizing-radiation induced foci--that cadre of proteins which assemble at DNA double strand breaks following radiation exposure and which are readily visualized by immunofluorescence microscopy. While its roles in p53 regulation and cell cycle checkpoint activation have been studied for some time, the impact of 53BP1 on DNA double strand break rejoining has only come to light in the past few years. Convincing evidence now exists for 53BP1 significantly affecting the outcome of DNA double strand break repair in several contexts, many of which hint to an important role in modulating chromatin structure surrounding the break site. Here, we highlight the known and emerging roles of 53BP1 in DNA double strand break repair, including the repair of lesions induced within heterochromatin, following telomere uncapping, in long-range V(D)J recombination, during immunoglobulin class switch recombination and its much debated role in regulating resection during homologous recombination.     

The rapid generation of oligonucleotide-directed mutations at high frequency using phosphorothioate-modified DNA.

M13 RF IV DNA may be prepared in vitro to contain phosphorothioate-modified internucleotidic linkages in the (-)strand only. Certain restriction enzymes react with this modified DNA to hydrolyze the (+)strand exclusively when a phosphorothioate linkage occurs at the normal cleavage point in the (-)strand. The reaction of Pvu I with M13mp2 RF IV DNA containing dCMPS residues in the (-)strand is of this type, and is exploited to allow subsequent digestion with exonuclease III of a portion of the (+)strand opposite different mutagenic mismatched oligonucleotide primers. Two methods are described by which this approach has been used to produce mutations in M13mp2 phage DNA with high efficiency as a result of simple and rapid in vitro manipulations. Plaques containing mutant phage in a genetically-pure form are obtained at a frequency of 40-66%, allowing their characterisation directly by sequence analysis without prior screening and plaque purification. The wide applicability of this approach is discussed.     

寡聚核苷酸诱导突变法改造φ×174噬菌体A基因蛋白的DNA识别序列

 为了进一步研究φX174噬菌体A基因蛋白的复制功能与其所识别的30核苷酸保守序列的关系,我们采用寡聚核苷酸诱导的定点突变法成功地改造了这30核苷酸保守序列。将此保守序列重组到M_(13)mp9噬菌体后,以其单链为模板,在14或16寡聚核苷酸的诱导下,合成共价闭环DNA。经转化到E.coli JM103菌株,用点印迹(Dot blot)杂交法筛选,得到两种重组突变株。一种突变株其30核苷酸保守序列正链的第22碱基由A改为G。另一突变株为其第10碱基A改为C,第11碱基T改为A。突变效率约为5％。制备了此突变株单链及双链DNA,分别做了双脱氧末端终止法及Maxam和Gilbert法序列分析鉴定。     

Coping with DNA double strand breaks

The repair of DNA double strand breaks (dsb) is important for maintaining the physical and genetic integrity of the genome. Moreover, in humans it is associated with the prevention of diseases such as immune deficiencies and cancer. This review briefly explores the fundamental strategies for repairing dsb, examines how cells maximize the fidelity of dsb repair in the cell cycle and discusses the requirements for dsb repair in the context of chromatin.     

M13 vectors for selective cloning of sequences specifying initiation of DNA synthesis on single-stranded templates

M13 cloning vectors have been developed for the selection of DNA sequences capable of directing initiation of DNA synthesis on single-stranded templates. These vectors are derived from viable M13 mutants containing large deletions in the region of the complementary strand origin. The deletion mutants are defective in the conversion of viral single strands to the duplex replicative form (SS leads to RF) both in vivo and in vitro, give a reduced phage yield and form turbid plaques. A receptor site for foreign single strand initiation determinants has been introduced into the mutants by the insertion of EcoRI linker sequences at the deletion sites. Specific cloned sequences from bacteriophage G4 RF and from Co1E1 DNA restore a clear plaque type and normal phage growth. Selection of clear-plaque isolates obtained by transfection with RF from one of these vectors, M13 delta E101, carrying inserted Co1E1 HaeIII fragments resulted in the selective cloning of one specific fragment, the HaeIII-E fragment. Insertion of either the H or L strand of the HaeIII-E fragment into the M13 delta E101 viral strand gives a clear plaque phenotype, indicating the presence of initiation determinants on both the H- and L-strands of the Co1E1 HaeIII-E fragment. These cloning vectors provide a new means for the functional dissection of replication origins and for the identification of DNA sequences that determine the enzymatic mechanism of discontinuous synthesis along the length of the bacterial chromosome. The ability to assess initiation capability on the basis of plaque morphology also provides a means for rapid genetic analysis of initiation determinants.     

Repair of double-stranded DNA breaks by homologous DNA fragments during transfer of DNA into mouse L cells.

To test the validity of various models for recombination between extrachromosomal DNAs in mammalian cells, we measured recombination between a plasmid containing a herpesvirus thymidine kinase (tk) gene with an internal BamHI linker insertion mutation (ptkB8) and a tk gene deleted at both ends (tk delta 3' delta 5'). The two DNAs shared 885 base pairs of perfect tk homology except for the interruption at the linker insertion site. Recombination events that restored the mutated insertion site to wild type were monitored by the generation of hypoxanthine-aminopterine-thymidine-resistant colonies after cotransformation of Ltk- cells with the two DNAs. We found that cleavage of the ptkB8 DNA at the linker insertion site was essential for gene restoration. If the tk delta 3' delta 5' DNA was ligated into mp10 vector DNA, then recombination with the cleaved ptkB8 DNA was inefficient. In contrast, if it was excised from that vector by cleavage at flanking restriction sites, then recombination was stimulated about 150-fold. Using restriction site polymorphisms, we showed that most of the recombination events leading to restoration of the tk gene with the excised tk delta 3' delta 5' fragment involved three double-strand duplexes: two ptkB8 DNAs and one tk delta 3' delta 5' fragment. These results are much more readily explained by the single-strand annealing model of recombination than by the double-strand break repair model, and they suggest that the deficiency of the latter pathway for extrachromosomal mammalian recombination may be due, at least in part, to the obligate tripartite nature of the reaction. Finally, we measured the effect of DNA homology on the efficiency of the ptkB8-tk delta 3' delta 5' reaction. Our results showed a near-linear relationship between the efficiency of recombination and the amount of homology flanking either side of the linker insertion site. Moreover, we could detect thymidine kinase-positive transformants with as little as 10 base pairs of homology.     

Recombination-dependent DNA replication stimulated by double-strand breaks in bacteriophage T4.

We analyzed the mechanism of recombination-dependent DNA replication in bacteriophage T4-infected Escherichia coli using plasmids that have sequence homology to the infecting phage chromosome. Consistent with prior studies, a pBR322 plasmid, initially resident in the infected host cell, does not replicate following infection by T4. However, the resident plasmid can be induced to replicate when an integrated copy of pBR322 vector is present in the phage chromosome. As expected for recombination-dependent DNA replication, the induced replication of pBR322 required the phage-encoded UvsY protein. Therefore, recombination-dependent plasmid replication requires homology between the plasmid and phage genomes but does not depend on the presence of any particular T4 DNA sequence on the test plasmid. We next asked whether T4 recombination-dependent DNA replication can be triggered by a double-strand break (dsb). For these experiments, we generated a novel phage strain that cleaves its own genome within the nonessential frd gene by means of the I-TevI endonuclease (encoded within the intron of the wild-type td gene). The dsb within the phage chromosome substantially increased the replication of plasmids that carry T4 inserts homologous to the region of the dsb (the plasmids are not themselves cleaved by the endonuclease). The dsb stimulated replication when the plasmid was homologous to either or both sides of the break but did not stimulate the replication of plasmids with homology to distant regions of the phage chromosome. As expected for recombination-dependent replication, plasmid replication triggered by dsbs was dependent on T4-encoded recombination proteins. These results confirm two important predictions of the model for T4-encoded recombination-dependent DNA replication proposed by Gisela Mosig (p. 120-130, in C. K. Mathews, E. M. Kutter, G. Mosig, and P. B. Berget (ed.), Bacteriophage T4, 1983). In addition, replication stimulated by dsbs provides a site-specific version of the process, which should be very useful for mechanistic studies.     

Lack of interference of DNA single-strand breaks with the measurement of double-strand breaks in mammalian cells using the neutral filter elution assay.

In this study, the effect of DNA single strand breaks (ssb) on the neutral (pH 9.6) filter elution of DNA from Chinese hamster ovary (CHO K1) cells containing DNA double strand breaks (dsb) was investigated. Protein associated ssb were induced by the inhibition of DNA topoisomerase I with camptothecin (cpt). Protein associated dsb were introduced by treating cells with the DNA topoisomerase II poison; etoposide (VP-16). Protein associated ssb and dsb were converted to ssb and dsb by proteinase K present in the lysis solution. In some experiments dsb were generated by the restriction endonuclease Pvu II. It was found that elution of DNA in the presence and absence of ssb was similar under neutral conditions. This finding is consistent with the view that the fast component of the bi-phasic repair kinetics observed in irradiated mammalian cells with the neutral filter elution technique is not attributable to the interference of ssb with the measurement of dsb, and thus suggests that the two components of repair observed with the neutral filter elution elution technique may represent two different types of dsb or modes of repair of dsb.     

A short primer for sequencing DNA cloned in the single-stranded phage vector M13mp2.

In this paper we describe the synthesis and cloning of a short segment of DNA complementary to the region immediately adjacent to the EcoRI insertion site in the single-stranded bacteriophage vector M13mp2. This segment is useful as a "universal" primer for DNA sequencing by the dideoxynucleotide chain termination method; the template can be any DNA species cloned in M13mp2 or its derivatives. The primer has been cloned into the tetracycline resistance gene of plasmid pBR322 as one strand of a 26 bp EcoRI/BamHI fragment. This fragment may be readily prepared from an EcoRI + BamHI restriction digest of the parent plasmid (designated pSP14) by a simple size fractionation.     

The Greek Goddess,Artemis, reveals the secrets of her cleavage

A recent paper in Cell by Ma et al. [Cell 8 (2002) 781] showed that the protein Artemis cleaves a hairpin intermediate during V(D)J recombination. Peter O'Neill and Penny Jeggo discuss this finding in the light of evidence that Artemis also functions to repair radiation damage [Cell 105 (2001) 177]. The findings suggest that Artemis may function in double strand break repair by "tidying up" double strand ends with associated base damage. The development of genetic diversity during immune development, therefore, seems to exploit damage response mechanisms that function to maintain genetic stability in other cell lineages.     

A new pair of M13 vectors for selecting either DNA strand of double-digest restriction fragments

The strategy of shotgun cloning with M13 is based on obtaining random fragments used for the rapid accumulation of sequence data. A strategy, however, is sometimes needed for obtaining subcloned sequences preferentially out of a mixture of fragments. Shotgun sequencing experiments have shown that not all DNA fragments are obtained with the same frequency and that the redundant information increases during the last third of a sequencing project. In addition, experiments have shown that particular fragments are obtained more frequently in one orientation, allowing the use of only one of the two DNA strands as a template for M13 shotgun sequencing. Two new M13 vectors, M13mp8 and M13mp9, have been constructed that permit the cloning of the same restriction fragment in both possible orientations. Consequently, each of the two strands becomes a (+) strand in a pair of vectors. The fragments to be cloned are cleaved with two restriction enzymes to produce a fragment with two different ends. The insertion of such a fragment into the vector can occur only in one orientation. Since M13mp8 and M13mp9 have their array of cloning sites in an antiparallel order, either orientation for inserting a double-digest fragment can be selected by the choice of the vector.     

Complementary-addressed elimination of E1a sequence of simian adenovirus oncogene SA7 from circular single-stranded DNA of recombinant phage M13

The G fragment of the simian adenovirus SA7 oncogene corresponding to E1a region was cloned into M13mp8 and M13mp9 phages. Single-stranded DNAs of the recombinant phages thus obtained (mp8G and mp9G) partially digested with DNAse II were used to synthesize polyalkylating derivatives capable of specific hybridisation and subsequent alkylation of complementary G sequences of corresponding phage DNAs. After incubation of complementary alkylated DNA in the presence of lysine, the preselected region (G fragment) was specifically eliminated without damaging vector sequences. The method of complementary-addressed cleavage proved to be useful for precise analysis of reactions of polyalkylating derivatives within complementary complexes.     

Menage á trois: Double strand break repair,V(D)J recombination and DNA-PK

All organisms possess mechanisms to repair double strand breaks (dsbs) generated in their DNA by damaging agents. Site-specific dsbs are also introduced during V(D)J recombination. Four complementation groups of radiosensitive rodent mutants are defective in the repair of dsbs, and are unable to carry out V(D)J recombination effectively. The immune defect in Severe Combined Immunodeficient (scid) mice also results from an inability to undergo effective V(D)J recombination, and scid cell lines display a repair defect and belong to one of these complementation groups. These findings indicate a mechanistic overlap between the processes of DNA repair and V(D)J recombination. Recently, two of the genes defined by these complementation groups have been identified and shown to encode components of DNA-dependent protein kinase (DNA-PK). We review here the three fields which have become linked by these findings, and discuss the involvement of DNA-PK in dsb rejoining and in V(D)J recombination.