Nucleotide sequence analysis of the inversion termini located within IS3 elements alpha 3 beta 3 and beta 5 alpha 5 of Escherichia coli K-12.

This paper presents the first detailed structural analysis of termini of an inversion mediated by recombination between Escherichia coli native IS elements. The complete nucleotide sequence of the inversion termini in the lactose region of Escherichia coli K-12 confirms our previous suggestion that the inversion occurred by homologous recombination between alpha 3 beta 3 and beta 5 alpha 5 IS3 elements (D. J. Savic, J. Bacteriol. 140:311-319, 1979; D. J. Savic, S. Romac, and S. D. Ehrlich, J. Bacteriol. 155:943-946, 1983). The data show a slight structural divergence of alpha 3 beta 3 and beta 5 alpha 5 elements, but they do not reveal new sequences within recombined IS3 elements that could influence the expression of nearby genes.     

Recombination of a eukaryotic DNA in bacteria

Single, 824 bp repeating units of Xenopus laevis oocyte-type 5S DNA were inserted into the recombination vectors, λrva and λrvb. When the inserts had the same orientation with respect to the λ chromosomes, Spi^-imm434 recombinants were recovered by selection on a P2, λ double lysogenic host. Because of the structure of the vectors, the crossover point in each recombinant must lie completely within the 5S DNA insert. The physical characteristics of these recombinants were determined by examination of restriction enzyme digests. By use of RecA mutant hosts and the Red^- vector, λrvc, recombination frequencies were measured separately for the bacterial and phage systems.Some of the recombination events resulted in 5S DNA inserts of altered length due to unequal crossovers within repeated sequences in the 5S DNA spacer. The occurrence of just such events in frog 5S DNA had been predicted, based on the structure of 5S DNA and evolutionary considerations.     

Elucidation of Insertion Elements Carried on Plasmids and In Vitro Construction of Shuttle Vectors from the Toxic Cyanobacterium Planktothrix

Several gene clusters that are responsible for toxin synthesis in bloom-forming cyanobacteria have been found to be associated with transposable elements (TEs). In particular, insertion sequence (IS) elements were shown to play a role in the inactivation or recombination of the genes responsible for cyanotoxin synthesis. Plasmids have been considered important vectors of IS element distribution to the host. In this study, we aimed to elucidate the IS elements propagated on the plasmids and the chromosome of the toxic cyanobacterium Planktothrix agardhii NIVA-CYA126/8 by means of high-throughput sequencing. In total, five plasmids (pPA5.5, pPA14, pPA50, pPA79, and pPA115, of 5, 6, 50, 79, and 120 kbp, respectively) were elucidated, and two plasmids (pPA5.5, pPA115) were found to propagate full IS element copies. Large stretches of shared DNA information between plasmids were constituted of TEs. Two plasmids (pPA5.5, pPA14) were used as candidates to engineer shuttle vectors (named pPA5.5SV and pPA14SV, respectively) in vitro by PCR amplification and the subsequent transposition of the Tn5 cat transposon containing the R6Kγ origin of replication of Escherichia coli. While pPA5.5SV was found to be fully segregated, pPA14SV consistently co-occurred with its wild-type plasmid even under the highest selective pressure. Interestingly, the Tn5 cat transposon became transferred by homologous recombination into another plasmid, pPA50. The availability of shuttle vectors is considered to be of relevance in investigating genome plasticity as a consequence of homologous recombination events. Combining the potential of high-throughput sequencing and in vitro production of shuttle vectors makes it simple to produce species-specific shuttle vectors for many cultivable prokaryotes.     

Recombination of DNAs in Xenopus oocytes based on short homologous overlaps.

Linear molecules of pBR322 and closely related plasmid DNAs were injected into Xenopus oocyte nuclei. Such molecules were degraded unless their ends were recombined. Non-homologous ends were joined rarely, if at all, but measurable recombination was supported by homologous sequences of less than 10 base pairs (bp). The efficiency of recombination increased as the length and degree of homology improved, in the range of about 8-20 bp. The homologous sequences had to be very close to the original molecular ends (within about 20 bp); internal homologies, even when they included better matches, were never used. These observations are best accommodated by a model of recombination which envisions exonucleolytic resection to expose homologous sequences, followed by annealing of single-stranded tails, tidying up and sealing of the new joint. Some of the recombined plasmids had novel tetracycline resistance genes; their properties give some insight into the function of the tet gene product.     

Functional Analysis of Coordinated Cleavage in V(D)J Recombination

V(D)J recombination in vivo requires a pair of signals with distinct spacer elements of 12 and 23 bp that separate conserved heptamer and nonamer motifs. Cleavage in vitro by the RAG1 and RAG2 proteins can occur at individual signals when the reaction buffer contains Mn²⁺, but cleavage is restricted to substrates containing two signals when Mg²⁺ is the divalent cation. By using a novel V(D)J cleavage substrate, we show that while the RAG proteins alone establish a moderate preference for a 12/23 pair versus a 12/12 pair, a much stricter dependence of cleavage on the 12/23 signal pair is produced by the inclusion of HMG1 and competitor double-stranded DNA. The competitor DNA serves to inhibit the cleavage of substrates carrying a 12/12 or 23/23 pair, as well as the cutting at individual signals in 12/23 substrates. We show that a 23/33 pair is more efficiently recombined than a 12/33 pair, suggesting that the 12/23 rule can be generalized to a requirement for spacers that differ from each other by a single helical turn. Furthermore, we suggest that a fixed spatial orientation of signals is required for cleavage. In general, the same signal variants that can be cleaved singly can function under conditions in which a signal pair is required. However, a chemically modified substrate with one noncleavable signal enables us to show that formation of a functional cleavage complex is mechanistically separable from the cleavage reaction itself and that although cleavage requires a pair of signals, cutting does not have to occur simultaneously at both. The implications of these results are discussed with respect to the mechanism of V(D)J recombination and the generation of chromosomal translocations.     

Effect of base pair mismatches on recombination via the RecBCD pathway

Summary The effect of base pair mismatches on recombination via the RecBCD pathway was studied in mutS and wild-type Escherichia coli, using substrates that contain single or multiple mismatches. Recombination between homologous DNA inserts in lambda phage and pBR322-derived plasmids forms phage-plasmid cointegrates that result from an odd number of crossovers. In the mutS host, when the sequence homology of a pair of 405 bp substrates decreased from 100% to 89%, the recombinant frequency decreased by about 9-fold, while in the wild-type host the decrease was about 240-fold. These results suggest that multiple mismatches can reduce recombinant frequencies by impeding the mechanism of recombination itself, and by provoking mismatch repair. Single mismatches in 31 bp substrates caused reductions in recombinant frequencies of 2-or 12-fold, depending on the location of the mismatch. However, unlike the reduction by multiple mismatches, the reduction of the recombinant frequencies by single mismatches was the same in both mutS and wild-type hosts. Thus a single match repair seems unable to act on single mismatches in very short homologies during recombination.     

Mammalian cell function mediating recombination of genetic elements

Recombination of segments of the SV40 genome by a variety of mechanisms is described. These include the faithful joining of linear segments that have flush termini as opposed to previously described cohesive or resected termini. Lack of involvement of viral proteins has been demonstrated for recombination of segments with homologous overlapping termini, but probably applies also to the other joining reactions. Segments of the genome that have been cleaved in such a manner as to be unable to manufacture any known viral proteins are neutral elements of genetic information, incapable of selection by replication or biological function until recombined. These recombination functions presumably are available to the host cell and any element of genetic information that can be generated in that cell.     

Genetic recombination of Xenopus laevis 5 S DNA in bacteria

The behavior in genetic recombination of Xenopus laevis 5 S DNA has been examined, with particular emphasis on the role of 15-base-pair tandem repeats in the A + T-rich spacer. Fragments of 5 S DNA were introduced into Escherichia coli cells as inserts in the recombination vectors, lambda rva and lambda rvb. Intermolecular recombinants were selected in which, because of properties of the phage vectors, the crossover event must have occurred within the 5 S DNA inserts. Inserts from individual recombinants have been characterized in detail. The effects of varying the number (n) of 15-base-pair repeats and the recombination capabilities of the phage and host have been investigated. In these crosses, unequal crossovers can occur, yielding inserts different in size from the parental inserts. When the number of 15-mers is large (n = 12 or 20), most of the unequal crossovers have occurred within the 15-mers, resulting in an altered n value, although other homologies within the 5 S DNA sequence can also support unequal events. Increasing n in the parental inserts modestly increases the overall frequency of recombination and the percentage of altered inserts. We conclude that, in a bacterial setting, the 15-base-pair repeats stimulate recombination only slightly by allowing alternative registers for heteroduplex formation. The degree of stimulation observed is less than predicted by one simple model.     

Effects of DNA Structure and Homology Length on Vaccinia Virus Recombination

Replicating poxviruses catalyze high-frequency recombination reactions by a process that is not well understood. Using transfected DNA substrates we show that these viruses probably use a single-strand annealing recombination mechanism. Plasmids carrying overlapping portions of a luciferase gene expression cassette and luciferase assays were first shown to provide an accurate method of assaying recombinant frequencies. We then transfected pairs of DNAs into virus-infected cells and monitored the efficiencies of linear-by-linear, linear-by-circle, and circle-by-circle recombination. These experiments showed that vaccinia virus recombination systems preferentially catalyze linear-by-linear reactions much more efficiently than circle-by-circle reactions and catalyze circle-by-circle reactions more efficiently than linear-by-circle reactions. Reactions involving linear substrates required surprisingly little sequence identity, with only 16-bp overlaps still permitting approximately 4% recombinant production. Masking the homologies by adding unrelated DNA sequences to the ends of linear substrates inhibited recombination in a manner dependent upon the number of added sequences. Circular molecules were also recombined by replicating viruses but at frequencies 15- to 50-fold lower than are linear substrates. These results are consistent with mechanisms in which exonuclease or helicase processing of DNA ends permits the forming of recombinants through annealing of complementary single strands. Our data are not consistent with a model involving strand invasion reactions, because such reactions should favor mixtures of linear and circular substrates. We also noted that many of the reaction features seen in vivo were reproduced in a simple in vitro reaction requiring only purified vaccinia virus DNA polymerase, single-strand DNA binding protein, and pairs of linear substrates. The 3'-to-5' exonuclease activity of poxviral DNA polymerases potentially catalyzes recombination in vivo.     

Position Effects in Ectopic and Allelic Mitotic Recombination in Saccharomyces Cerevisiae

We have examined the role that genomic location plays in mitotic intragenic recombination. Mutant alleles of the LEU2 gene were inserted at five locations in the yeast genome. Diploid and haploid strains containing various combinations of these inserts were used to examine both allelic recombination (between sequences at the same position on parental homologs) and ectopic recombination (between sequences at nonallelic locations). Chromosomal location had little effect on mitotic allelic recombination. The rate of recombination to LEU2 at five different loci varied less than threefold. This finding contrasts with previous observations of strong position effects in meiosis; frequencies of meiotic recombination at the same five loci differ by about a factor of forty. Mitotic recombination between dispersed copies of leu2 displayed strong position effects. Copies of leu2 located approximately 20 kb apart on the same chromosome recombined at rates 6-13-fold higher than those observed for allelic copies of leu2. leu2 sequences located on nonhomologous chromosomes or at distant loci on the same chromosome recombined at rates similar to those observed for allelic copies. We suggest that, during mitosis, parental homologs interact with each other no more frequently than do nonhomologous chromosomes.     

IS421, a new insertion sequence in Escherichia coli

The nucleotide sequence of a new insertion sequence (IS) in Escherichia coli, IS421, was determined. It is 1340 bp long and contains inverted repeats of 22 bp at its termini. It is flanked by 13 bp direct repeats apparently generated upon insertion. There are two ORFs longer than 200 bp in IS421. One can encode a polypeptide of 371 amino acids (aa) and the other, which is on the other strand, can encode a polypeptide of 102 aa. The C-terminal part of the 371 aa polypeptide shows some homology to that of transposases encoded in some other known IS elements. The copy number of IS421 in chromosomal DNA was 4 for E. coli K-12 and B, and 5 for E. coli C, as determined by the Southern hybridization of restriction fragments.     

Red重组系统用于大肠杆菌基因修饰的研究进展

Red重组作为一种新的重组系统已经被广泛用于大肠杆菌的基因敲除、基因替换。与传统的Rec重组相比,Red重组具有同源臂短,重组效率高等优点。本文分别详细介绍了Red重组系统中Exo、Beta、Gam三种蛋白质的功能,Red重组系统运用在大肠杆菌基因敲除中的三种质粒及其功能,同时概括了Red重组的技术要点及技术难点,分析了文献报道的阿拉伯糖诱导浓度和诱导时间、转化后的复苏温度及时间、引物同源臂长度对于重组率的影响,总结出了Red重组的最佳条件。     

Bacteriophage lambda cloning vehicles for studies of genetic recombination

A pair of bacteriophage lambda cloning vehicles has been constructed for use in studies of genetic recombination. These phages, lambda rva and lambda rvb, have the following properties: (1) Each vector has a single HindIII site in the immunity region, at which segments of DNA can be inserted. (2) These HindIII sites are flanked by selectable markers with the following phenotypes: Spi+/- (Fec+/-) to the left, and imm lambda or imm434 to the right. (3) There is essentially no sequence homology between the two phages in this region, so recombination of the markers at reasonable frequency depends on the presence of homologous inserts at the HindIII sites. As a consequence, recovered recombinants must have resulted from a crossover event within the insert DNA. Restriction enzyme maps of the vectors have been determined. Variants of the original vectors have been isolated which permit separate examination of the viral (Red) and bacterial (Rec) generalized recombination mechanisms, and which provide a standard interval to which frequencies of recombination in cloned DNAs can be compared.     

Recombination between Chromosomal Is200 Elements Supports Frequent Duplication Formation in Salmonella Typhimurium

Spontaneous tandem chromosomal duplications are common in populations of Escherichia coli and Salmonella typhimurium. They range in frequency for a given locus from 10(-2) to 10(-4) and probably form by RecA-dependent unequal sister strand exchanges between repetitive sequences in direct order. Certain duplications have been observed previously to confer a growth advantage under specific selective conditions. Tandem chromosomal duplications are unstable and are lost at high frequencies, representing a readily reversible source of genomic variation. Six copies of a small mobile genetic element IS200 are evenly distributed around the chromosome of S. typhimurium strain LT2. A survey of 120 independent chromosomal duplications (20 for each of six loci) revealed that recombination between IS200 elements accounted for the majority of the duplications isolated for three of the loci tested. Duplications of the his operon were almost exclusively due to recombination between repeated IS200 elements. These data add further support to the idea that mobile genetic elements provide sequence repeats that play an important role in recombinational chromosome rearrangements, which may contribute to adaptation of bacteria to stressful conditions.     

Recombination and chimeragenesis by in vitro heteroduplex formation and in vivo repair.

We describe a simple method for creating libraries of chimeric DNA sequences derived from homologous parental sequences. A heteroduplex formed in vitro is used to transform bacterial cells where repair of regions of non-identity in the heteroduplex creates a library of new, recombined sequences composed of elements from each parent. Heteroduplex recombination provides a convenient addition to existing DNA recombination methods ('DNA shuffling') and should be particularly useful for recombining large genes or entire operons. This method can be used to create libraries of chimeric polynucleotides and proteins for directed evolution to improve their properties or to study structure-function relationships. We also describe a simple test system for evaluating the performance of DNA recombination methods in which recombination of genes encoding truncated green fluorescent protein (GFP) reconstructs the full-length gene and restores its characteristic fluorescence. Comprising seven truncated GFP constructs, this system can be used to evaluate the efficiency of recombination between mismatches separated by as few as 24 bp and as many as 463 bp. The optimized heteroduplex recombination protocol is quite efficient, generating nearly 30% fluorescent colonies for recombination between two genes containing stop codons 463 bp apart (compared to a theoretical limit of 50%).     

Specificity of insertion of IS91, an insertion sequence present in α-haemolysin plasmids of Escherichia coli

We have determined the DNA sequences of eight different insertions of IS91 in a specifically engineered recipient plasmid of known DNA sequence (pSU300). The sequences at the termini of IS91 are 5'-CGAGTAGG...CCTATCGAT. IS91 inserts specifically 5' to either one of the tetranucleotides 5'-GAAC or 5'-CAAG, and always in the same relative orientation with respect to the sequence of the target. Except in one special case, no duplications of the recipient DNA were produced at the site of insertion.     

Thermosensitive vector derived from RP1 plasmid for detection of transposable elements

The involvement of the transposable DNA element of E. coli K12 chromosome in integrative recombination of RP1 plasmid was studied. Using temperature sensitive for replication plasmid RP1ts12--the derivative of RP1 which contains mutated transposon Tnl, it was shown that integration of RP1 into host chromosome and Hfr formation may occur according to a mechanism mediated by chromosome IS-elements. Plasmids that are desintegrated from the chromosome of these Hfrs contain discrete DNA segments (IS-elements) and possess elevated frequency of integration into chromosome of rec+ cells. The latter was used for selection of RP1ts12 recombinants carrying chromosome IS. For identification of IS involved in RP1 integration the number of independent RP1ts 12 recombinants was subjected to restriction and heteroduplex analysis. By analysing recombinants integrated into bacterial chromosome with frequency 5 X 10(-3), a new IS-element of E. coli K12 designated IS111 was discovered. IS111-element is about 1500bp of length, contains Smal, Pst1 and BamH1 restriction endonuclease sites and was found in the same position on the plasmid RP1 in two different orientations. IS-elements that have been revealed in a number of other RP1ts12 recombinants were preliminary identified as IS1-like elements. One recombinants plasmid was found to have an IS5-like elements. The activity of IS-elements inserted into RP1ts12 in recA-dependent integrative recombination was estimated. From the data of absolute and relative RP1ts12 integration frequencies mediated by IS111, IS1- and IS5-like elements a conclusion was made about the absence of E. coli K12 chromosome IS-elements in RP1 plasmid. The Hfr-formation and chromosomal gene transfer by recombinant plasmids RP1ts12: IS111 were studied. The possibility to use insertion RP1ts12 derivatives for the estimation of copies number, mapping and definition of orientation of IS-elements in bacterial chromosome and the possibilities for detection of transposable DNA elements using RP1ts12 in a wide range of gram-negative bacteria are discussed.     

The IS1111 family members IS4321 and IS5075 have subterminal inverted repeats and target the terminal inverted repeats of Tn21 family transposons

IS5075 and IS4321 are closely related (93.1% identical) members of the IS1111 family that target a specific position in the 38-bp terminal inverted repeats of Tn21 family transposons and that are inserted in only one orientation. They are 1,327 bp long and have identical ends consisting of short inverted repeats of 12 bp with an additional 7 bp (TAATGAG) or 6 bp (AATGAG) to the left of the left inverted repeats and 3 bp (AGA) or 4 bp (AGAT) to the right of the right inverted repeat. Circular forms of IS5075 and IS4321 in which the inverted repeats are separated by abutting terminal sequences (AGATAATGAG) were detected. A similar circular product was found for the related ISPa11. Transposition of IS4321 into the 38-bp target site was detected, but a flanking duplication was not generated. The precisely reconstituted target site was also identified. Over 50 members of the IS1111 family were identified. They encode related transposases, have related inverted repeats, and include related bases that lie outside these inverted repeats. In some, the flanking bases number 5 or 6 on the left and 4 or 3 on the right. Specific target sites were found for several of these insertion sequence (IS) elements. IS1111 family members therefore differ from the majority of IS elements, which are characterized by terminal inverted repeats and a target site duplication, and from members of the related IS110 family, which do not have obvious inverted repeats near their termini.     

Red重组技术研究进展

主要从Red系统组成元件、作用机理、重组策略以及先进性和发展前景四个方面综述了利用Red 重组系统敲除或替换细菌染色体目的基因的方法。首先简要介绍了传统的细菌染色体重组技术,指出了其中的缺陷。然后提出了Red重组技术的定义：利用噬菌体Red系统介导来实现外源线性DNA片断与细菌染色体的靶基因进行同源重组的方法,外源线性DNA通常是PCR产物、寡核苷酸片断等,在它们的两翼各含有与染色体靶基因两翼同源的序列40~60bp。这种Red重组技术省去了体外DNA酶切和连接等步骤,使细菌染色体靶基因的敲除与替换操作相对简单,逐渐成为基因功能探索以及新菌株构建的有力手段。