In vitro transposition of transposon Tn3

Transposition of the ampicillin-resistant transposon Tn3 was reproduced in vitro using the Escherichia coli cell extract. In this cell-free system, we used plasmid DNA carrying mini-Tn3 as donor and phage lambda DNA as target and assayed for ampicillin-resistance transducing phages formed by cointegration of these DNA molecules. Ampicillin-resistance transducing phages, which were obtained by in vitro packaging of lambda DNA after the in vitro transposition reaction, were formed only in the presence of Tn3 transposase. The reaction required mini-Tn3 with the proper sequence and orientation of the terminal inverted repeats of Tn3. The reaction also required DNA synthesis but not RNA synthesis by E. coli RNA polymerase.     

DNA sequences of the integration sites and inverted repeated structure of transposon Tn3.

The nucleotide sequence of the "inverted repeat" structure of the transposon Tn3 was determined by the DNA sequencing procedure developed by Maxam and Gilbert(1). The sequence, 38 base pairs long, is as follows: 5'-GGGGTCTGACGCTCAGTGGAACGAAAACTCACGTTAAG..(Tn3) 3'-CCCCAGACTGCGAGTCACCTTGCTTTTGAGTGCAATTC.. The integration of Tn3 is associated with a directly repeated sequence of 5 nucleotides appearing at each end of Tn3. The two directly repeated sequences so far determined are not the same. Furthermore, there is no homologous structure around the integration point of Tn3.     

转座子Tn917插入位点侧翼序列的扩增

为了克隆到生防菌株的抗病基因,以一株对灰葡萄孢菌表现很高拮抗活性的蜡样芽孢杆菌B-02菌株为材料,利用转座子标签技术得到拮抗性消失的突变体,进而利用TAIL-PCR技术扩增出Tn917插入位点两侧的未知序列,利用生物信息学分析扩增序列,为进一步研究该基因片段与菌株拮抗性之间的关系奠定了基础。     

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.     

Nucleotide sequence analysis of the termini and chromosomal locus involved in site-specific integration of the streptococcal conjugative transposon Tn5252.

The 47-kb, broad-host-range, streptococcal conjugative transposon Tn5252 is capable of site-specific integration into the pneumococcal chromosome. We present the nucleotide sequence of the terminal regions of the transposon and its target site in the pneumococcal genome. No inverted repeats were found at the termini of the transposon. A 72-bp region of the target was present on either side following the insertion of Tn5252 and appeared to serve as a signal for its integration and excision. The data suggest that the left copy of the 72-bp segment was a part of the conjugative element, the crossover point of integration was nonrandom within this region, and the mechanism of insertion could resemble that of the site-specific temperate phages.     

Overproduction of the Tn3 transposition protein and its role in DNA transposition

Five single base pair mutations that increase expression of the tnpA (transposase) gene of the Tn3 transposon approximately 30-fold, but which still allow the gene to be regulated, have been isolated by using a generally applicable procedure that involves distally linked lac gene fusions. The mutations, which are all located in a region controlling initiation of translation of the tnpA gene, do not affect normal repression of tnpA by the tnpR gene product, and yield up to a 9000-fold increase in tnpA protein production when combined with a tnpR mutation and placed on a high copy number plasmid. The mutation yielding the highest expression level was separated from the fused lac gene segment by homologous recombination and was found to increase the rate of transposition without altering the nature of the transposition product; in cells defective in both the E. coli recA gene and the tnpR gene of tn3, cointegrate transposition-intermediate structures occur with the overproducing--as well as with the wild-type--tnpA gene. In the presence of a functional Tn3 tnpR gene or the related transposon delta gamma, such cointegrate structures are resolved into the final products of transposition.     

Two domains in the terminal inverted-repeat sequence of transposon Tn3

Tn3 and related transposons have terminal inverted repeats (IR) of about 38 bp that are needed as sites for transposition. We made mini-Tn3 derivatives which had a wild-type IR of Tn3 at one end and either the divergent IR of the Tn3-related transposon, gamma delta or IS101, or a mutant IR of Tn3 at the other end. We then examined both in vivo transposition (cointegration between transposition donor and target molecules) of these mini-Tn3 elements and in vitro binding of Tn3-encoded transposase to their IRs. None of the elements with an IR of gamma delta or IS101 mediated cointegration efficiently. This was due to inefficient binding of transposase to these IR. Most mutant IR also interfered with cointegration, even though transposase bound to some mutant IR as efficiently as it did to wild type. This permitted the Tn3 IR sequence to be divided into two domains, named A and B, with respect to transposase binding. Domain B, at positions 13-38, was involved in transposase binding, whereas domain A, at positions 1-10, was not. The A domain may contain the sequence recognized by some other (e.g., host) factor(s) to precede the actual cointegration event.     

Identification and characterization of genes involved in excision of the Lactococcus lactis conjugative transposon Tn5276.

The 70-kb transposon Tn5276, originally detected in Lactococcus lactis NIZO R5 and carrying the genes for nisin production and sucrose fermentation, can be conjugally transferred to other L. lactis strains. Sequence analysis and complementation studies showed that the right end of Tn5276 contains two genes, designated xis and int, which are involved in excision. The 379-amino-acid int gene product shows high (up to 50%) similarity with various integrases, including that of the Tn916-related conjugative transposons. The xis gene product, like almost all known excisionase (Xis) proteins, is a small (68-residue), basic protein. Expression of both the Tn5276 int and xis genes is required for efficient excision of the ends of Tn5276 in Escherichia coli that appeared to be circularized in the excision process. Mutational analysis of the xis and int genes showed that excision efficiency is dependent on the integrity of the int gene but that an intact xis gene is also required for efficient excision.     

Nucleotide sequence of the kanamycin resistance determinant of the pneumococcal transposon Tn1545: evolutionary relationships and transcriptional analysis of aphA-3 genes

The nucleotide sequence of the kanamycin resistance determinant aphA-3 encoded by transposon Tn1545 from Streptococcus pneumoniae was determined and compared to those of plasmids pJH1 and pIP1433 from Streptococcus faecalis and Campylobacter coli, respectively. The three sequences were found to be identical and differed by two substitutions and the deletion of a codon from that of plasmid pSH2 from Staphylococcus aureus. Comparison of the 5' noncoding sequences indicated that the regions containing the aphA-3 gene in pJH1 and in Tn1545 evolved independently by deletion from a sequence similar to that found in pIP1433. In the latter plasmid, aphA-3 is transcribed from a promoter, P1, which is flanked by two 12-base pair direct repeats. The rearrangement observed in pJH1 removed one of these recombinogenic sites and altered the -10 and 3' flanking sequences of P1. The promoter thus generated. P1', allows expression of similar level of kanamycin resistance as P1. However, fusion experiments carried out with a promotorless chloramphenicol acetyltransferase gene indicated that the canonical promoter P1 is significantly less efficient than P1'. From analysis of the thermodynamic properties of these promoters, we conclude that this difference in strength reflects the melting properties of the -10 sequences. The transition from pIP1433 to pJH1 may correspond to the progression of a molecule structurally unstable to a more stable one combined with the need to maintain an efficient promoter upstream of the aphA-3 gene. The deletion event in Tn1545, which occurred between the two 12-base pair directly repeated sequences, removed P1 in its entirety.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Cloning of a lac+, bamHI fragment into transposon Tn3 and transposition of the Tn3[lac] element

By use of recombinant DNA techniques, we have inserted the lac⁺ operon into a transposon (Tn3). We constructed the recombinant in such a way that the essential step in assaying for transposition consisted of screening for bacteria with a thermostable Lac⁺ phenotype. Our results showed that transposition of the Tn3[lac⁺] element occurred and that its frequency was derepressed compared to frequencies reported by others for wild-type Tn3 transposition.     

Effects of deletions in transposon Tn7 on its frequency of transposition.

Deletions in transposon Tn7 either abolished transposition or reduced transposition frequency. Except for a deletion in the right-hand terminus, these deletions could be complemented in trans. A 2.1-kilobase fragment of Tn7 encodes a diffusible gene product which stimulates transposition above the wild-type frequency. No cointegrate formation was detected.     

Tn3 transposition immunity is conferred by the transposase-binding domain in the terminal inverted-repeat sequence of Tn3

A series of mutant terminal inverted repeats (IRs), having 2 bp substitutions at various sites within the 38-bp IR sequence of the ampicillin-resistance transposon Tn3, were tested for transposition immunity to Tn3. Mutations within region 1-10 in the IR did not affect transposition immunity, while mutations within region 13-38 inactivated the immunity function. These two regions corresponded to domain A which was not bound specifically by Tn3 transposase and to domain B which was bound by the transposase, respectively. This indicates that specific binding of transposase to domain B within the IR sequence is responsible for transposition immunity.     

Tn7 transposition in vitro proceeds through an excised transposon intermediate generated by staggered breaks in DNA.

We have developed a cell-free system in which the bacterial transposon Tn7 inserts at high frequency into its preferred target site in the Escherichia coli chromosome, attTn7; Tn7 transposition in vitro requires ATP and Tn7-encoded proteins. Tn7 transposes via a cut and paste mechanism in which the element is excised from the donor DNA by staggered double-strand breaks and then inserted into attTn7 by the joining of 3' transposon ends to 5' target ends. Neither recombination intermediates nor products are observed in the absence of any protein component or DNA substrate. Thus, we suggest that Tn7 transposition occurs in a nucleoprotein complex containing several proteins and the substrate DNAs and that recognition of attTn7 within this complex provokes strand cleavages at the Tn7 ends.     

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.     

Functional analysis of the two domains in the terminal inverted repeat sequence required for transposition of Tn3.

Bacterial transposon Tn3 has a 38-bp terminal inverted repeat (IR) sequence. The IR sequence has been divided into two domains, A and B, of which domain B is bound by transposase, and domain A is not Here, we defined the two domains more precisely by constructing three IR mutants with a 2-bp substitution at relevant sites within the IR sequence, followed by examination of the binding of transposase to the fragments containing these IR mutants: domain A was located at bp 1-11, whereas domain B was at bp 12-38. To see if the two domains in the IR are functionally distinct, we constructed mini-Tn3 derivatives flanked by two IRs with various 2-bp substitutions within domain A or B, and analyzed their ability to mediate cointegration. The mini-Tn3 derivatives flanked by IR(A+ B+) and IR(A- B+) [or IR(A+ B-)] and those flanked by IR(A-B+) and IR(A+ B-) mediate cointegration more efficiently than the mini-Tn3 derivatives flanked by two IR(A- B+)s or by two IR(A+ B-)s. These results and others presented here indicate that the two domains of IR are functionally distinct in promoting cointegration.     

Insertion sites and the terminal nucleotide sequences of the Tn4 transposon.

The nucleotide sequences at the ends of the Tn4 transposon (mercury spectinomycin and sulfonamide resistance) have been determined. They are inverted repeated sequences of 38 nucleotides with three mismatched base pairs. These sequences are strongly homologous with the terminal sequences of Tn501 (mercury resistance) but less so with those of Tn3 (ampicillin resistance). The Tn4 transposon generates pentanucleotide members (Tn3, Tn1000, Tn501, Tn551, IS2) with the exception of Tn1721 and bacteriophage Mu. Among the three Tn4 insertion sites examined here, two of them occurred near a nonanucleotide sequence in perfect homology with part of the terminal inverted-repeat sequence of Tn4 and the third insertion occurred near a sequence of partial homology to one end of Tn4. All three insertions were in the same orientation such that IRb is proximal to its homologous sequence on the recipient DNA.     

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.