Xis protein of the conjugative transposon Tn916 plays dual opposing roles in transposon excision.

The binding of Tn916 Xis protein to its specific sites at the left and right ends of the transposon was compared using gel mobility shift assays. Xis formed two complexes with different electrophoretic mobilities with both right and left transposon ends. Complex II, with a reduced mobility, formed at higher concentrations of Xis and appeared at an eightfold lower Xis concentration with a DNA fragment from the left end of the transposon rather than with a DNA fragment from the right end of the transposon, indicating that Xis has a higher affinity for the left end of the transposon. Methylation interference was used to identify two G residues that were essential for binding of Xis to the right end of Tn916. Mutations in these residues reduced binding of Xis. In an in vivo assay, these mutations increased the frequency of excision of a minitransposon from a plasmid, indicating that binding of Xis at the right end of Tn916 inhibits transposon excision. A similar mutation in the specific binding site for Xis at the left end of the transposon did not reduce the affinity of Xis for the site but did perturb binding sufficiently to alter the pattern of protection by Xis from nuclease cleavage. This mutation reduced the level of transposon excision, indicating that binding of Xis to the left end of Tn916 is required for transposon excision. Thus, Xis is required for transposon excision and, at elevated concentrations, can also regulate this process.

Specific binding of integrase to the origin of transfer (oriT) of the conjugative transposon Tn916.

Purified integrase protein (Int) of the conjugative transposon Tn916 was shown, using nuclease protection experiments, to bind specifically to a site within the origin of conjugal transfer of the transposon, oriT. A sequence similar to the ends of the transposon that are bound by the C-terminal DNA-binding domain of Int was present in the protected region. However, Int binding to oriT required both the N- and C-terminal DNA-binding domains of Int, and the pattern of nuclease protection differed from that observed when Int binds to the transposon ends and flanking DNA. Binding of Int to oriT may be part of a mechanism to prevent premature conjugal transfer of Tn916 prior to excision from the donor DNA.

Coupling sequences flanking Tn916 do not determine the affinity of binding of integrase to the transposon ends and adjacent bacterial DNA.

Coupling sequences are the 6 bp flanking the conjugative transposon Tn916 and are thought to play a role in determining the frequency of conjugative transposition. The affinity of binding of a chimeric protein, which consisted of maltose binding protein fused to the carboxy-terminal DNA binding domain of Tn916 integrase (Int), to different double-stranded oligonucleotide substrates containing coupling sequences associated with high- and low-frequency conjugative transposition was measured using a competition binding assay. The relative affinity of the chimeric protein was unaffected by the nature of the coupling sequences tested. The same results were obtained when the coupling sequences were placed in a different surrounding sequence context. It therefore appears that the effects of different coupling sequences on the frequency of conjugative transposition are not due simply to differences in Int binding.

Interactions of the integrase protein of the conjugative transposon Tn916 with its specific DNA binding sites.

The binding of two chimeric proteins, consisting of the N-terminal or C-terminal DNA binding domain of Tn916 Int fused to maltose binding protein, to specific oligonucleotide substrates was analyzed by gel mobility shift assay. The chimeric protein with the N-terminal domain formed two complexes of different electrophoretic mobilities. The faster-moving complex, whose formation displayed no cooperativity, contained two protein monomers bound to a single DNA molecule. The slower-moving complex, whose formation involved cooperative binding (Hill coefficient > 1.0), contained four protein monomers bound to a single DNA molecule. Methylation interference experiments coupled with the analysis of protein binding to mutant oligonucleotide substrates showed that formation of the faster-moving complex containing two protein monomers required the presence of two 11-bp direct repeats (called DR2) in direct orientation. Formation of the slower-moving complex required only a single DR2 repeat. Binding of the N-terminal domains in vivo could serve to position two Int monomers on the DNA near each end of the transposon and assist in bringing together the ends of the transposon so that excision can occur. The chimeric protein with the C-terminal domain of Int also formed two complexes of different electrophoretic mobilities. The major, slower-moving complex, whose formation involved cooperative binding, contained two protein molecules bound to one DNA molecule. This finding suggested that while the C-terminal domain of Int can bind DNA as a monomer, a cooperative interaction between two monomers of the C-terminal domain may help to bring the ends of the transposon together during excision.

The frequency of conjugative transposition of Tn916 is not determined by the frequency of excision.

Excision and formation of a covalently closed circular transposon molecule are required for conjugative transposition of Tn916 but are not the only factors that limit the frequency of conjugative transposition from one host to another. We found that in gram-positive bacteria, an increase in the frequency of excision and circularization of Tn916 caused by expression of integrase (Int) and excisionase (Xis) from a xylose-inducible promoter does not lead to an increase in the frequency of conjugative transposition. We also found that the concentration of Int and Xis in the recipient cell does not limit the frequency of conjugative transposition and that increased excision does not result in increased expression of transfer functions required to mobilize a plasmid containing the Tn916 origin of transfer. We conclude that in gram-positive hosts in which the Tn916 functions Int and Xis are overexpressed, the frequency of conjugative transposition is limited by the availability of transfer functions.

Excision of a conjugative transposon in vitro by the Int and Xis proteins of Tn916.

The roles of purified Int and Xis proteins of the conjugative transposon Tn 916 in excision of a deletion derivative of the closely related element Tn 1545 were investigated. At a low salt concentration (37.5 mM NaCl), Int alone was able to promote limited excision to produce a covalently closed circular form of the transposon, showing that Tn 916 Int can catalyze both DNA cleavage and strand exchange. This reaction was stimulated by Xis. At higher salt concentrations (150 mM NaCl), excision by Int alone was reduced to barely detectable levels and Xis was required for excision. The low salt, Xis-stimulated reaction was approximately 8-fold more efficient than the high salt, Xis-dependent reaction. These results reflect in vivo requirements for Int and Xis in excision.

DNA binding by the Xis protein of the conjugative transposon Tn916.

We purified the Xis protein of the conjugative transposon Tn916 and showed by nuclease protection experiments that Xis bound specifically to sites close to each end of Tn916. These specific binding sites are close to, and in the same relative orientation to, binding sites for the N-terminal domain of Tn916 integrase protein. These results suggest that Xis is involved in the formation of nucleoprotein structures at the ends of Tn916 that help to correctly align the ends so that excision can occur.

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.

Genetic analysis of the Mycobacterium smegmatis rpsL promoter.

The DNA sequence of the promoter region of the Mycobacterium smegmatis rpsL gene, which encodes the S12 ribosomal protein, was determined. Primer extension analysis and S1 nuclease protection experiments identified the 5' end of the rpsL mRNA to be 199 bp upstream of the translation initiation codon. The rpsL promoter contained sequences upstream of this start point for transcription that were similar to the canonical hexamers found at the -10 and -35 regions of promoters recognized by Esigma70, the major form of RNA polymerase in Escherichia coli. To define the promoter of the rpsL gene, DNA fragments containing progressive deletions of the upstream region of the rpsL gene were inserted into a plasmid vector containing a promoterless xylE gene. These insertions revealed that the 200 bp of DNA sequence immediately upstream from the translation initiation codon was not essential for promoter function. In addition, 5' deletions removing all but 34 bp upstream of the transcription start point retained greater than 90% promoter activity, suggesting that the -35 hexamer was not essential for promoter activity. To determine which nucleotides were critical for promoter function, oligonucleotide-directed mutagenesis and mutagenic PCR amplification were used to produce point mutations in the region upstream of the start point of transcription. Single base substitutions in the -10 hexamer, but not in the -35 hexamer, severely reduced rpsL promoter activity in vivo. Within the -10 hexamer, nucleotide substitutions causing divergence from the E. Coli sigma70 consensus reduced promoter activity. The DNA sequence immediately upstream from the - 10 hexamer contained the TGn motif described as an extended -10 region in prokaryotic promoters. Mutations in this motif, in combination with a transition at either the -38 or -37 position within the -35 hexamer, severely reduced promoter activity, indicating that in the absence of a functional -35 region, the rpsL promoter is dependent on the TGn sequence upstream from the -10 hexamer. Comparison of the nucleotide sequence of the rpsL promoter region of M. smegmatis with the homologous sequences from Mycobacterium leprae, Mycobacterium bovis, and Mycobacterium tuberculosis showed the presence in these slowly growing mycobacterial species of conserved promoter elements a similar distance upstream of the translation initiation codon of the rpsL gene, but these other mycobacterial promoters did not contain the extended -10 motif.

Tn916 target DNA sequences bind the C-terminal domain of integrase protein with different affinities that correlate with transposon insertion frequency.

The conjugative transposon Tn916 inserts with widely different frequencies into a variety of target sites with related nucleotide sequences. The binding of chimeric proteins, consisting of maltose-binding protein fused to Tn916 integrase, to three different target sequences for Tn916 was examined by DNase I protection experiments. The C-terminal DNA binding domain of the Tn916 integrase protein was shown to protect approximately 40 bp, spanning target sites in the orfA and cat genes of the plasmid pIP501 and in the cylA gene of the plasmid pAD1. Competition binding assays showed that the affinities of the three target sites for Tn916 integrase varied over a greater than 3- but less than 10-fold range and that the cat target site bound integrase at a lower affinity than did the other two target sites. A PCR-based assay for transposition in Escherichia coli was developed to assess the frequency with which a defective minitransposon inserted into each target site. In these experiments, integrase provided in trans from a plasmid was the sole transposon-encoded protein present. This assay detected transposition into the orfA and cylA target sites but not into the cat target site. Therefore, the frequency of transposon insertion into a particular target site correlated with the affinity of the target for the integrase protein. Sequences within the target fragments similar to known Tn916 insertion sites were not protected by integrase protein. Analysis ot he electrophoretic behavior of circularly permuted sets of DNA fragments showed that all three target sites contained structural features consistent with the presence of a static bend, suggesting that these structural features in addition to the primary nucleotide sequence are necessary for integrase binding and, thus, target site activity.

Conjugative transposition.

Conjugative transposons are important determinants of antibiotic resistance, especially in gram-positive bacteria. They are remarkably promiscuous and can conjugate between bacteria belonging to different species and genera. Transposon-promoted conjugation may be similar to F plasmid-promoted conjugation, as it appears that only one strand of the transposon DNA is transferred from donor to recipient. The recent determination of the entire nucleotide sequence of Tn916 allowed us to make specific predictions about the possible function of different open reading frames and the position of a (hypothetical) origin of transfer. The mechanism of recombination during conjugative transposition differs from that of other transposons, as shown by the absence of a duplication of the target sequence upon integration. The current model for recombination postulates that staggered double-stranded cleavages occur at each end of the transposon. One DNA strand is cut six bases from the end of the transposon, and the other strand is cut immediately adjacent to the end. The ends of the excised transposon are then ligated to form a circular intermediate with a six-base heteroduplex. Staggered cleavages of the circular intermediate and the target DNA allow the transposon to insert into the target, where it is flanked by heteroduplex regions that are resolved by replication. All hosts examined contain preferential target sites: these are not specific sequences but apparently consist of bent DNA. The site-specific recombinases encoded by conjugative transposons belong to the integrase family. Like phage lambda integrase, the integrase of Tn916 has two DNA-binding domains that recognize different sequences, one within the ends of the element and one that includes target DNA. The affinity of Tn916 integrase for target sites correlates with the frequency of integration into a particular site. The similarity between conjugative transposons and phage lambda is striking and suggests that both use the same mechanism of recombination. In lambda, however, recombining sites must be homologous. Homology may be necessary because of branch migration, which is thought to occur during recombination. In conjugative transposition, the recombining sites are nearly always different, and therefore branch migration probably does not occur. This review presents a speculative model for the alignment of the ends of Tn916 during excision that was adapted from one recently proposed for lambda.

Cloning and sequence analysis of the rpsL and rpsG genes of Mycobacterium smegmatis and characterization of mutations causing resistance to streptomycin.

The Mycobacterium smegmatis rpsL and rpsG genes, encoding the ribosomal proteins S12 and S7, were cloned, and their DNA sequence was determined. The third nucleotide of the S12 termination codon overlapped the first nucleotide of the S7 translation initiation codon. A collection of 28 spontaneous streptomycin-resistant mutants of M. smegmatis were isolated. All had single-base-pair substitutions in the rpsL gene which were changed to a streptomycin-sensitive phenotype by complementation with a low-copy-number plasmid carrying the wild-type M. smegmatis rpsL gene. A total of eight different mutations were found in two specific regions of the rpsL gene. Fifty-seven percent (16 of 28) altered the Lys codon at position 43. Forty-six percent of the mutations (13 of 28) were due to a transition changing an AAG Lys codon to an AGG Arg codon, with eight changes at codon 43 and five at codon 88.

Conjugative transposition: Tn916 integrase contains two independent DNA binding domains that recognize different DNA sequences.

Transposition of the conjugative transposon Tn916 requires the activity of a protein, called Int, which is related to members of the integrase family of site-specific recombinases. This family includes phage lambda integrase as well as the Cre, FLP and XerC/XerD recombinases. Different proteins, consisting of fragments of Tn916 Int protein fused to the C-terminal end of maltose binding protein (MBP) were purified from Escherichia coli. DNase I protection experiments showed that MBP-INT proteins containing the C-terminal end of Int bound to the ends of the transposon and adjacent plasmid DNA. MBP-INT proteins containing the N-terminal end of Int bound to sequences within the transposon close to each end. Competition binding experiments showed that the sites recognized by the C- and N-terminal regions of Int did not compete with each other for binding to MBP-INT. We suggest that Tn916 and related conjugative transposons are unique among members of the integrase family of site-specific recombination systems because the presence of two DNA binding domains in the Int protein might allow Int to bridge recombining sites, and this bridging seems to be the sole mechanism ensuring that only correctly aligned molecules undergo recombination.

Replication origin mutations affecting binding of pSC101 plasmid-encoded Rep initiator protein.

To investigate the role of binding sites for Rep initiation protein in the replication of pSC101, a series of plasmids was constructed which carried different combinations of mutations in three binding sites within the minimal origin of replication. Mutation of all three sites reduced the affinity of purified Rep protein for the origin by 100-fold, as measured by a competition binding assay. Mutations in individual binding sites prevented binding of Rep protein to the mutant site but not to adjacent wild-type sites. Transformation efficiency, copy number, and stability over 150 generations were measured for each of the mutant plasmids. Unlike other similar plasmids related to pSC101, the Rep binding sites were found not to be equivalent. A mutation in the site RS1, proximal to repeated sequences which serve as DnaB helicase entry sites in oriC, had a severe effect on replication activity. A similar mutation in the distal site RS3 caused a reduction in copy number, but the mutant plasmid was stably maintained despite a broadened distribution of copy number within the population. A mutation in the middle RS2 site had no significant effect on pSC101 replication.

Control of cyclic chromosome replication in Escherichia coli.

The biochemical basis for cyclic initiation of bacterial chromosome replication is reviewed to define the processes involved and to focus on the putative oscillator mechanism which generates the replication clock. The properties required for a functional oscillator are defined, and their implications are discussed. We show that positive control models, but not negative ones, can explain cyclic initiation. In particular, the widely accepted idea that DnaA protein controls the timing of initiation is examined in detail. Our analysis indicates that DnaA protein is not involved in the oscillator mechanism. We conclude that the generations of a single leading to cyclic initiation is separate from the initiation process itself and propose a heuristic model to focus attention on possible oscillator mechanisms.

A copy-number mutant of plasmid pSC101.

Copy-number mutants of plasmid pSC101 were isolated by u.v. mutagenesis and selection for elevated expression of ampicillin resistance. Three independent mutations were identical and mapped in codon 93 of the initiation protein RepA. The mutated plasmids were maintained at a level four to five times higher than that of the wild type. For one of them, it was determined that: (i) the mRNA of the autoregulated repA gene, cloned onto a pUC19 plasmid under the control of its own promoter, was expressed at a level 1.7 times higher than that of the wild type; (ii) the RepA protein, under the same conditions, was expressed at a similarly higher level; (iii) the affinity of the mutated protein for three repeated sequences in the origin region of the plasmid was, on average, 3.4 times higher than that of the wild-type protein. We postulate that the copy-number effect is due to a combination of these two effects, i.e. higher protein concentration and increased affinity of the protein for the repeated sequences.

Transcription events in the origin of replication of plasmid pSC101.

Insertion mutations were isolated in the origin fragment of the plasmid pSC101 after random cleavage with DNase I. The replication properties of the resulting plasmids confirmed previous findings and extended the characterization of the essential regions. Using these plasmids, we analyzed by various methods the transcription events in the pSC101 origin. In addition to the mRNA of repA, a gene coding for the self-regulated RepA protein which is essential for replication of the plasmid, we characterized a transcript, which we called RNA Y, that runs in the opposite direction and that starts in the middle of the second repeated sequence in the origin region. Like the self-regulated repA mRNA, RNA Y is weakly expressed. It does not code for a complete protein within the origin fragment but may do so in the wild-type plasmid. We also found indications for one or, possibly, two small RNA species, called RNA X, which run in the same direction as RepA and which are partially complementary to RNA Y. We postulate that RNA Y and, possibly, RNA X are implicated in the initiation of replication of pSC101.

Replication of pSC101: effects of mutations in the E. coli DNA binding protein IHF.

We have shown that the plasmid pSC101 is unable to be maintained in strains of E. coli carrying deletions in the genes himA and hip which specify the pleitropic heterodimeric DNA binding protein, IHF. We show that this effect is not due to a modulation of the expression of the pSC101 RepA protein, required for replication of the plasmid. Inspection of the DNA sequence of the essential replication region of pSC101 reveals the presence of a site, located between the DnaA binding-site and that of RepA, which shows extensive homology with the consensus IHF binding site. The proximity of the sites suggests that these three proteins, IHF, DnaA, and RepA may interact in generating a specific DNA structure required for initiation of pSC101 replication.

Initiation of chromosome replication in Escherichia coli after induction of dnaA gene expression from a lac promoter.

Escherichia coli HB282 carries a dnaA46(Ts) allele on the chromosome, a wild-type dnaA allele under the control of the lacUV5 promoter on the multicopy plasmid pBC32, and an overproducing lac repressor allele on an F' factor. When the plasmid dnaA gene is repressed, the strain is thermosensitive. After a temporary deficiency in active dnaA protein at nonpermissive temperature, the addition of isopropyl-beta-D-thiogalactopyranoside to the culture was found to produce a burst of initiations within 5 to 10 min at 30% of the origins in 90% of the cells. Initiations then continued at a rate slightly faster than the mass-doubling time such that after 2 h the origin-to-mass ratio of the control culture was restored.