IHF is the limiting host factor in transposition of Pseudomonas putida transposon Tn4652 in stationary phase

Transpositional activity of mobile elements is not constant. Conditional regulation of host factors involved in transposition may severely change the activity of mobile elements. We have demonstrated previously that transposition of Tn4652 in Pseudomonas putida is a stationary phase-specific event, which requires functional sigma S (Ilves et al., 2001, J Bacteriol 183: 5445-5448). We hypothesized that integration host factor (IHF), the concentration of which is increased in starving P. putida, might contribute to the transposition of Tn4652 as well. Here, we demonstrate that transposition of Tn4652 in stationary phase P. putida is essentially limited by the amount of IHF. No transposition of Tn4652 occurs in a P. putida ihfA-defective strain. Moreover, overexpression of IHF results in significant enhancement of transposition compared with the wild-type strain. This indicates that the amount of IHF is a bottleneck in Tn4652 transposition. Gel mobility shift and DNase I footprinting studies revealed that IHF is necessary for the binding of transposase to both transposon ends. In vitro, transposase can bind to inverted repeats of transposon only after the binding of IHF. The results obtained in this study indicate that, besides sigma S, IHF is another host factor that is implicated in the elevation of transposition in stationary phase.     

Transpososome dynamics and regulation in Tn10 transposition

Tn10 is a bacterial transposon that transposes through a non-replicative mechanism. This mode of DNA transposition is widely used in bacteria and is also used by "DNA-based" transposons in eukaryotes. Tn10 has served as a paradigm for this mode of transposition and continues to provide novel insights into how steps in transposition reactions occur and how these steps are regulated. A common feature of transposition reactions is that they require the formation of a higher order protein-DNA complex called a transpososome. A major objective in the last few years has been to better understand the dynamics of transpososome assembly and progression through the course of transposition reactions. This problem is particularly interesting in the Tn10 system because two important host proteins, IHF and H-NS, have been implicated in regulating transpososome assembly and/or function. Interestingly, H-NS is an integral part of stress response pathways in bacteria, and its function is known to be sensitive to changes in environmental conditions. Consequently, H-NS may provide a means of allowing Tn10 to responed to changing environmental conditions. The current review focuses on the roles of both IHF and H-NS on Tn10 transposition.     

The tetracycline-resistance transposon Tn10 inhibits translocation of Tn10

Summary Using a set of overlapping deletion mutants in the tetracycline-resistance transposon Tn10, it has been established that certain regions of the Tn10 genome exert a powerful inhibition on translocation of an intact Tn10 element into the bacterial genome. Such inhibition is strongly temperature dependent: at 37° C translocation is inhibited by at least a factor of 100; no inhibition of translocation is detected at 30° C.     

Postexcision transposition of the transposon Tn10 in Escherichia coli K12

An experimental analysis of the fate of transposon Tn10 after excision from a proA::Tn10 site localized on the plasmid F' leads to the conclusions: 1. The precise excision is a progressive process. Its probability is estimated per time unit. 2. An excised Tn10 is always integrated into a different genetic locus. 2. An excised Tn10 is always integrated into a different genetic locus. 3. The kinetics of postexcision transposition are sometimes very slow. The excised transposon is inherited in one cell line in spite of cell multiplication. 4. The processes of excision and secondary insertion have no absolute requirement for the recA+ genotype but they are strongly enhanced in recA+ cells. 5. The kinetics of postexcision transposition are strongly dependent on the genetic site from which the transposon was excised. 6. The probability of postexcision transposition is fully determined by the probability of excision and depends on the genotype of the host and many other factors.     

Insertional transposon mutagenesis by electroporation of released Tn5 transposition complexes

DNA transposition is an important biological phenomenon that mediates genome rearrangements, inheritance of antibiotic resistance determinants, and integration of retroviral DNA. Transposition has also become a powerful tool in genetic analysis, with applications in creating insertional knockout mutations, generating gene-operon fusions to reporter functions, providing physical or genetic landmarks for the cloning of adjacent DNAs, and locating primer binding sites for DNA sequence analysis. DNA transposition studies to date usually have involved strictly in vivo approaches, in which the transposon of choice and the gene encoding the transposase responsible for catalyzing the transposition have to be introduced into the cell to be studied (microbial systems and applications are reviewed in ref. 1). However, all in vivo systems have a number of technical limitations. For instance, the transposase must be expressed in the target host, the transposon must be introduced into the host on a suicide vector, and the transposase usually is expressed in subsequent generations, resulting in potential genetic instability. A number of in vitro transposition systems (for Tn5, Tn7, Mu, Himar1, and Ty1) have been described, which bypass many limitations of in vivo systems. For this purpose, we have developed a technique for transposition that involves the formation in vitro of released Tn5 transposition complexes (TransposomesTM) followed by introduction of the complexes into the target cell of choice by electroporation. In this report, we show that this simple, robust technology can generate high-efficiency transposition in all tested bacterial species (Escherichia coli, Salmonella typhimurium, and Proteus vulgaris) We also isolated transposition events in the yeast Saccharomyces cerevisiae.     

Identification of transposition proteins encoded by the bacterial transposon Tn7.

The bacterial transposon, Tn7, encodes an elaborate array of transposition genes, tnsABCDE. We report here the direct identification of the TnsA, TnsB, TnsC and TnsD polypeptides by immunoblotting. Our results demonstrate that the complexity of the protein information devoted to Tn7 transposition is considerable: the aggregate molecular size of the five Tns polypeptides is about 300 kDa. We also report the sequence of the tnsA gene and of the 5' ends of tnsB and tnsD. This analysis reveals that all five tns genes are oriented in the same direction within Tn7.     

The integration-excision system of the conjugative transposon Tn 1545 is structurally and functionally related to those of lambdoid phages

Excision of Tn1545 and related conjugative transposons of Gram-positive bacteria occurs by reciprocal site-specific recombination between non-homologous regions of the transposon-target junctions. Excisive recombination requires two transposon-encoded proteins designated Xis-Tn and Int-Tn. We have shown that, following excision, Tn1545 is a circular structure with ends separated by either of the two hexanucleotides that were present at the transposon-target junctions. Using a trans-complementation assay, we have demonstrated that Int-Tn is able to catalyse in vivo integration of a circular intermediate of Tn1545 defective for integration and excision. comparison of integration sites suggests that limited sequence homology at the vicinity of the recombining sites is required for integration of the element. These data support the hypothesis that the integration/excision systems of conjugative transposons from Gram-positive cocci and of lambdoid phages from Gram-negative bacilli have evolved from a common ancestor.     

Control of Tn5 transposition in Escherichia coli is mediated by protein from the right repeat

The right repeat in Tn5, which encodes protein absolutely required for transposition, is also capable of inhibiting Tn5 transposition. Analysis of Tn5 mutants indicates that the left repeat is defective in supplying the transposition-inhibition function because of the sequence difference between the repeats located at nucleotide 1443; that the transposition-inhibition activity is a function of the quantity of right-repeat protein synthesis; that the smaller of the right-repeat proteins, protein 2, is sufficient for supplying the transposition-inhibition function (but not for the transposase activity); and that the transposition-inhibition function can act in trans, as opposed to the transposase activity, which functions efficiently only in cis. Gene fusion experiments indicate that the transposition-inhibition activity cannot be explained by autogenous regulation of right-repeat protein synthesis. Finally, immunoprecipitation assays of right-repeat protein-lacZ fusion proteins indicate that protein 2 is synthesized in significantly greater amounts than protein 1 in whole cells. This synthetic ratio may be important with respect to the control of Tn5 transposition.     

Transposition and transposition immunity of transposon Tn3 derivatives having different ends.

Novel Tn1/3 derivatives that contained either two left- or two right-hand ends of the transposon were constructed in a small plasmid. Both transposed at reasonable frequencies to give normal transposition products, suggesting that only the 38-bp inverted repeats of Tn3 are essential for transposition. Plasmids containing transposon derivatives with only one end (either left or right) undergo transposase-dependent transposition between replicons at much lower frequencies, resulting in co-integrate molecules in which there is no substantial duplication of transposon DNA and that appear to be simple fusions of the two plasmids. Both the right and left halves of the transposon are separately able to confer transposition immunity to the plasmid, this immunity being inseparably linked to transposition proficiency and specificity.     

Conjugative transposition of Tn916: the transposon int gene is required only in the donor.

Conjugative transposition of transposon Tn916 has been shown to proceed by excision of the transposon in the donor strain and insertion of this element in the recipient. This process requires the product of the transposon int gene. We report here the surprising finding that the int gene is required only in the donor during conjugative transposition. We find that Tn916 int-1, whose int gene has been inactivated by an insertion mutation, transposes when a complementing wild-type int gene is present only in the donor during mating. When the int+ gene is present in a plasmid and is expressed from the spac promoter, conjugative transposition is very inefficient. However, when the Int+ function is supplied from a coresident distantly linked Tn916 tra-641 mutant, which is defective in a function required for conjugation, efficient conjugative transposition of Tn916 int-1 occurs. This suggests either that Int is not required for integration of Tn916 in gram-positive bacteria or that the protein is transferred from the donor to the transconjugant during the mating event. When the nonconjugative plasmid pAT145 was present in the donor, it was rarely cotransferred with Tn916. This suggests that complete fusion of mating cells is not common during conjugative transposition.     

利用Tn5转座子介导突变提高大肠杆菌丁醇生产水平

目前,对于构建高产丁醇大肠杆菌工程菌株的工作,主要是对丁醇通路和相关途径的基因进行理性改造。为进一步提升菌株的丁醇生产能力,需要发掘基因组上可影响丁醇生产能力的基因,但这很难通过已有认识或计算机模型进行预测。本工作以一株实验室前期构建的产丁醇大肠杆菌工程菌株为研究对象,利用Tn5转座子构建了一个含有1 196个菌株的突变文库。丙酮酸是丁醇的前体,并且在发酵终产物中,副产物丙酮酸的含量与丁醇的含量呈反相关,因此,可以利用丙酮酸的含量来间接反映丁醇的含量,而丙酮酸可用二硝基苯肼显色法进行快速测定,基于此,建立了96孔板——酶标仪快速筛选方法。利用该方法成功筛选到了比对照菌株丁醇产量提高了29%、49%、56%的3个突变体菌株。利用反向PCR及测序的方法,确定了其转座子插入位置分别为:pyk A、tdk、cad C基因。这些基因可以作为进一步提高菌株丁醇产量的靶点,同时这种利用Tn5转座子筛选基因靶标的策略也为构建其他微生物细胞工厂提供了新思路。     

Specific DNA cleavage mediated by the integrase of conjugative transposon Tn916.

The conjugative transposon Tn916 encodes a protein called INT(Tn916) which, based on DNA sequence comparisons, is a member of the integrase family of site-specific recombinases. Integrase proteins such as INT(lambda), FLP, and XERC/D that promote site-specific recombination use characteristic, conserved amino acid residues to catalyze the cleavage and ligation of DNA substrates during recombination. The reaction proceeds by a two-step transesterification reaction requiring the formation of a covalent protein-DNA intermediate. Different requirements for homology between recombining DNA sites during integrase-mediated site-specific recombination and Tn916 transposition suggest that INT(Tn916) may use a reaction mechanism different from that used by other integrase recombinases. We show that purified INT(Tn916) mediates specific cleavage of duplex DNA substrates containing the Tn916 transposon ends and adjacent bacterial sequences. Staggered cleavages occur at both ends of the transposon, resulting in 5' hydroxyl protruding ends containing coupling sequences. These are sequences that are transferred with the transposon from donor to recipient during conjugative transposition. The nature of the cleavage products suggests that a covalent protein-DNA linkage occurs via a residue of INT(Tn916) and the 3'-phosphate group of the DNA. INT(Tn916) alone is capable of executing the strand cleavage step required for recombination during Tn916 transposition, and this reaction probably occurs by a mechanism similar to that of other integrase family site-specific recombinases.     

A gene and its product required for transposition of resistance transposon Tn2603.

Tn2603 is a multiple-resistance transposon encoding resistance to ampicillin, streptomycin, sulfonamide, and mercury and having a molecular size of 20 kilobase pairs, with 200-base-pair inverted repeats at both ends. The essential sites and functions of Tn2603 which are required for its transposition were determined through construction and characterization of various deletion mutants affecting the efficiency of transposition. Deletions were introduced in plasmid pMK1::Tn2603 by partial digestion with restriction endonuclease EcoRI in vitro. Analysis of deletion mutants showed that the inverted repeat segments at both ends of the trans-acting diffusible product(s) encoded in the right-hand side of the central portion were required for the transposition of Tn2603. An essential gene product was revealed as a protein having a molecular weight of 110,000 by analysis of polypeptides synthesized in Escherichia coli minicells. This protein was assumed to be the so-called transposase.     

Tn10 mediated integration of the plasmid R100.1 into the bacterial chromosome: Inverse transposition

Summary Upon integration into the bacterial chromosome the drug resistance plasmid R100.1 often loses its tetracycline resistance character. We have analyzed an Hfr strain formed by such an integration and an R-prime plasmid derived from it. We find that integration took place within the Tn10 transposon, that the two IS10 sequences were retained, but that at least 80% of the transposon segment located between them, and carrying the tetracycline resistance genes, had been lost. We suggest that integration of R100.1 was mediated by an inverse transposition using the IS10 sequences.     

Stoichiometry of metal-tetracycline/H+ antiport mediated by transposon Tn10-encoded tetracycline resistance protein in Escherichia coli.

The tetracycline resistance protein (TetA) endoded by transposon Tn10 mediates the efflux of divalent cation-tetracycline chelating complexes [Yamaguchi, A., Udagawa, T. and Sawai, T. (1990) J. Biol. Chem. 265, 4809-4813]. It was confirmed that protons were antiported with the complexes through an electrically-neutral process because the antiport consumed delta pH but not delta psi. The quantitative relationship between delta pH and delta pTC determined by a flow-dialysis method clearly indicated a 1:1 stoichiometry of the monocationic metal-tetracycline/H+ exchange.