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Journal of Bacteriology, September 2002, p. 4829-4837, Vol. 184, No. 17
0021-9193/02/$04.00+0     DOI: 10.1128/JB.184.17.4829-4837.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

Development of an In Vitro Integration Assay for the Bacteroides Conjugative Transposon CTnDOT

Department of Microbiology, University of Illinois, Urbana, Illinois 61801

Received 13 March 2002/ Accepted 3 June 2002

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Integrated self-transmissible elements called conjugative transposons (CTns) are responsible for the transfer of antibiotic resistance genes in many different species of bacteria. One of the best characterized of these newly recognized elements is the Bacteroides CTn, CTnDOT. CTnDOT is thought to have a circular transfer intermediate that transfers to and integrates into the genome of the recipient cell. Previous investigations of the mechanism of CTnDOT integration have been hindered by the lack of an in vitro system for checking this model of integration and determining whether the CTnDOT integrase alone was sufficient to catalyze the integration reaction or whether host factors might be involved. We report here the development of an in vitro system in which a plasmid containing the joined ends of CTnDOT integrates into a plasmid carrying a CTnDOT target site. To develop this in vitro system, a His-tagged version of the integrase gene of CTnDOT was cloned and shown to be active in vivo. The protein produced by this construct was partially purified and then added to a reaction mixture that contained the joined ends of the circular form of CTnDOT and a plasmid carrying one of the CTnDOT target sites. Integration was demonstrated by using a fairly simple mixture of components, but integration was stimulated by a Bacteroides extract or by purified Escherichia coli integration host factor. The results of this study demonstrate both that the circular form of CTnDOT is the form that integrates into the target site and that host factors are involved in the integration process.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Bacteroides species are gram-negative anaerobes that account for about 25 to 30% of the bacterial population that normally resides in the human colon (14). Many Bacteroides strains carry large self-transmissible integrated elements that have been called conjugative transposons (CTns). In fact, a recent study has shown that over 80% of Bacteroides strains today contain at least one CTn and that the spread of resistance to tetracycline and erythromycin among Bacteroides strains has been mediated primarily by these elements (21). The best studied of the Bacteroides CTns is CTnDOT. Most of the CTns found in Bacteroides have proved to be closely related to this CTn.

Previous studies have shown that CTnDOT integrates site selectively into at least seven different target sites (attB) in the Bacteroides chromosome (3). There is a conserved 10-bp sequence (GTANNTTTGC) found at one end of CTnDOT that shares identity with a 10-bp sequence in all of the chromosomal attB sites (3). The deduced amino acid sequence of the CTnDOT integrase gene has low but significant homology (30 to 40%) to some members of the tyrosine recombinase family, of which the integrase of bacteriophage lambda is also a member. However, unlike the lambda integrase protein that makes staggered cuts 7 bp apart within the identical core sequences found in attB and attP, the CTnDOT Int protein appears to use a different mechanism. It makes staggered cuts 5 bp apart adjacent to the 10-bp conserved sequence (3). The sequences between the cleavage positions in the partner sites are not homologous. As a result, the cleavage and ligation reactions generate heteroduplex DNA regions at attL and attR. This distinct feature makes the recombination mechanism of the CTnDOT Int protein different from those of other members of the tyrosine recombinase family.

The integration of phage lambda requires integration host factor (IHF), whose role is to bend DNA in the attP site to facilitate formation of a higher-order nucleoprotein structure called the intasome. Previous studies of the integration of CTnDOT showed that the process was independent of homologous recombination (5). However, since nothing is known about possible Bacteroides host factors that might function in a manner analogous to IHF, it was not clear whether any factors other than the integrase encoded on CTnDOT were required for integration. We report here the development of an in vitro integration system that allows a plasmid carrying the CTnDOT joined ends to integrate into a second plasmid carrying one of the target sites into which CTnDOT integrates in vivo. This reaction requires the protein previously identified as the putative integrase and is stimulated by Escherichia coli IHF or by a Bacteroides extract.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Reagents and enzymes. Restriction endonucleases were obtained from New England Biolabs. Proteinase K, polyvinylalcohol (average molecular weight, 30,000 to 70,000), dimethyl sulfoxide (DMSO), spermidine, and spermine tetrahydrochloride were obtained from Sigma. Spermine tetrahydrochloride was dissolved in water to make a 100 mM solution, and the pH of the stock solution was adjusted to 6.8. Antibiotics were used at the following concentrations: ampicillin (Ap), 100 µg/ml; chloramphenicol (Cm), 20 µg/ml; rifampin (Rf), 10 µg/ml; kanamycin (Kn), 50 µg/ml.

Bacterial strains and plasmids and DNA manipulation. The E. coli strain used for overexpression of the CTnDOT integrase protein was BL21(DE3)/plysS (Novagen). For initial development of the in vitro system, E. coli DH5MCR (Gibco BRL) was used as the recipient. For mating experiments to confirm the activity of the tagged CTnDOT Int protein in vivo, the donor was E. coli pir⁺ strain BW19851 (11) and the recipient was E. coli pir-deficient strain EM24NR, which is the nalidixic acid- and rifampin-resistant RecA derivative of LE392 (18, 19). For overexpression of the CTnDOT Int protein, the plasmid pINT was constructed. Two primers (primer I, 5'-AATTAAGGCATATGAAGAGTACATTTTCAGTC; primer II, 5'-GTCTCGCTTCAAAGCTTCTCTTTATTAGATGG) were used to PCR amplify the int gene from chromosomal DNA of the Bacteroides thetaiotaomicron strain BT4107N3, which contains an integrated copy of CTnDOT. Primer I anneals to the 5' end of the CTnDOT int gene and contains an NdeI site (CATATG, underlined in the sequence above). The ATG in this sequence is the likely start codon of the gene. Primer II anneals to the 3' end of the int gene and includes a HindIII site (AAGCTT, underlined in the sequence above). It also includes the DNA sequence encoding the translation stop codon. The 1.3-kbp PCR product was digested with NdeI and HindIII and cloned into the expression vector pET28 (Novagen), which has the DNA sequence encoding the His₆ tag upstream of its NdeI site. DNA sequence analysis confirmed that the pINT clone has the wild-type int gene linked to the DNA sequence encoding the His₆ tag.

The plasmid pattB, which contained one of the CTnDOT integration sites in Bacteroides (attB), was constructed by cloning the attB PCR product into the PCR fragment cloning vector pGEM-T (Promega). The attB region (500 bp) was PCR amplified by using primers DLJ/U487F and DRJ/R2700R (3) and BT4001 chromosomal DNA. Another plasmid used in the in vitro integration assay, pattDOT, contained the 547-bp CTnDOT attachment site (attDOT) cloned into the ApaI and SstI sites of the pir-dependent plasmid pEPE (25) to generate pattDOT.

Two plasmids, pINT100 and pINT200, which contained the CTnDOT int gene under the control of the P_tac promoter in the pBR322-based plasmid pCKR101 (10), were constructed by cloning the CTnDOT int gene, which was amplified by using primer III (5'-TTTGAATTCGAAGGATTAAGGCATAT GAAGAGTACATTTCAG) and primer II. Primer III has an EcoRI site (GAATTC, underlined in the sequence above) at one end and also contains an E. coli ribosome-binding site (GAAGGA, boldface in the sequence above). The 1.3-kb PCR product was cloned into the EcoRI and HindIII sites of pCKR101 to form pINT100. The plasmid pINT was digested with XbaI and HindIII, and the DNA fragment containing the int gene was cloned into the XbaI and HindIII sites in pCKR101 to form pINT200. This construct placed the His₆ tag at the N terminus of the CTnDOT int gene. The int genes of both pINT100 and pINT200 were sequenced to confirm that there were no mutations in the int gene. Both pINT100 and pINT200 have the same P_tac promoter and the same ribosome-binding site. The only difference between the two plasmids is that the pINT200 has the DNA sequence from pINT that encodes the His₆ tag at the N terminus of the Int protein.

The two plasmids (pINT101 and pINT201) used in the in vivo integration assay in E. coli had the CTnDOT integration site in Bacteroides (attB) cloned into pINT100 and pINT200, respectively. To construct pINT101 and pINT201, the NcoI-PstI-digested attB region from the plasmid pattB was cloned into the NcoI and PstI sites of pMTL20 to provide flanking restriction sites for further subcloning (2). The resultant plasmid was then digested with HindIII and AatII, and the DNA fragment containing the attB region was cloned into the HindIII and AatII sites of pINT100 and pINT200 to form pINT101 and pINT201, respectively.

In vivo integration assay in E. coli. The mating procedure was done as previously described (20). The E. coli donor was BW19851, which has both the RP4 transfer functions and pir gene integrated in its chromosome carrying the mobilizable attDOT vector, pattDOT. The base plasmid, pEPE (25), is pir dependent and carries a chloramphenicol resistance marker and the oriT of RP4. The pir mutant E. coli EM24NR recipient strains carried pINT101 or pINT201. The recipients were grown with and without 1 mM IPTG (isopropyl-1-thio-ß-D-galactoside) for induction of P_tac. The recipients were ampicillin resistant due to a gene carried on the plasmid and rifampin resistant due to a chromosomal mutation. Ampicillin, rifampin, and chloramphenicol were used to select transconjugants, and the transconjugants were analyzed to verify the presence of cointegrated plasmids formed by the Int-mediated site-specific recombination between attB and attDOT.

Purification of the CTnDOT Int protein. The plasmid pINT (Kn^r) was introduced into E. coli BL21(DE3)/plysS (Cm^r) by transformation. Cultures were grown at 30°C overnight and subcultured (1:100) into 400 ml of fresh Luria-Bertani broth plus the antibiotics kanamycin and chloramphenicol. When the absorbance (optical density at 600 nm) of the culture reached 0.5, expression of the Int protein was induced by the addition of IPTG to a final concentration of 1 mM. After induction at 30°C for 5 h, cells were harvested by centrifugation. The cells were then resuspended in 40 ml of lysis buffer (50 mM Na₂HPO₄ · NaH₂PO₄ [pH 8.0], 300 mM NaCl, 10 mM imidazole) with the addition of lysozyme (1 mg/ml) and the protease inhibitor phenylmethylsulfonyl fluoride (50 µg/ml). The cells were sonicated and clarified by centrifugation (14,000 x g for 30 min at 4°C). The supernatant fraction was mixed with 4 ml of nickel-nitrilotriacetic acid resin (Qiagen), incubated at 4°C for 1 h, and then applied to a column (Bio-Rad) to collect flowthrough. The resin was then washed with 40 ml of wash buffer (lysis buffer with 20 mM imidazole) and 8 ml of E50 elution buffer (lysis buffer with 50 mM imidazole). The Int protein was eluted by successive washing with 4-ml aliquots of elution buffers E100, E150, E200, and E250, which contained imidazole concentrations of 100, 150, 200, and 250 mM, respectively. Samples were electrophoresed on a sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gel to detect the Int protein. The fractions containing the highest amount of Int protein were combined and dialyzed at 4°C overnight against a buffer containing 50 mM Tris-HCl (pH 8.0), 1 mM dithiothreitol (DTT), 1 mM EDTA, 50 mM NaCl, and 40% glycerol.

In vitro integration assay. (i) Components of the reaction mixtures. The final volume of each reaction mixture was 40 µl. The reaction buffer contained 20 mM Tris-HCl (pH 7.4), 5 mM DTT, 0.1 mg of tRNA/ml, 50 mM KCl, 5% polyvinylalcohol, 50 µg of bovine serum albumin/ml, and 1% glycerol. For a typical reaction, 3 µl of pattB (approximately 0.375 µg of DNA; 0.16 pmol) and 5 µl of pattDOT (approximately 0.085 µg of DNA; 0.02 pmol) were mixed with 1 µl of CTnDOT Int protein (approximately 0.16 µg/µl; 3.2 pmol) and 1 µl of Bacteroides crude extract or diluted E. coli host factor IHF. Two different IHF samples were used for in vitro reactions. In most cases, we used IHF prepared in our laboratory according to the procedure of Nash and Robertson (16). The sample had a concentration of approximately 0.48 µg/µl and was estimated to be 90% pure, as judged by Coomassie stain analysis of SDS-PAGE gels. Another IHF sample used was the kind gift of Steve Goodman (University of Southern California, Los Angeles). It had a concentration of approximately 1 µg/µl and was greater than 95% pure. HU, another E. coli protein used in the in vitro reactions, was a kind gift of Anca Segall. It is estimated to have a concentration of 0.85 µg/µl.

Bacteroides crude extracts were made as follows. Cells from 100 ml of an overnight BT4001 culture were harvested and resuspended in 6 ml of lysis buffer (50 mM Tris-HCl [pH 7.4], 10% sucrose). Cells were broken by sonication and clarified by centrifugation at 14,000 x g for 30 min. The supernatant was concentrated to a volume of about 2 ml by using a YM-3 centrifugal filter device (Millipore; molecular weight cutoff, 3,000). In some cases, the supernatant was heated at 95°C for 10 min and then cooled to room temperature for 30 min. The sample was then centrifuged for 30 min, and the supernatant was concentrated to about 2 ml as described above.

(ii) Reaction conditions. The reaction mixtures were preincubated for 1 h at 4°C and then switched to 37°C incubation for up to 6 h. After the reaction, spermine precipitation (9) was used to recover the DNA. For each in vitro reaction, the total volume of the reaction mixture was brought to 500 µl by adding the appropriate amount of water, and spermine was added to a final concentration of 8 mM. After vortexing for 1 min, the solutions were left on ice for 2 h. The solutions were then centrifuged for 10 min at 12,000 rpm in an Eppendorf microcentrifuge. After the supernatant was carefully removed without disturbing the DNA pellet, 500 µl of extraction buffer (75% ethanol, 0.3 M NaAc, 0.01 M MgAc) was added to the DNA pellet. The samples were vortexed and left at 4°C overnight. After centrifugation for 10 min, the supernatant was removed and the DNA pellet was vacuum dried. The DNA was then resuspended in 40 µl of water and drop dialyzed against double-distilled water for 2 h on a nitrocellulose dialysis filter (Millipore; pore size, 0.025 µm).

Two approaches were used to detect integration events. First, DNA from the incubation mixtures was electroporated into the E. coli pir-deficient strain DH5MCR and electroporants were selected on Luria-Bertani plates supplemented with ampicillin or ampicillin and chloramphenicol. The ratio of Ap^r Cm^r colonies to Ap^r colonies was used to represent the integration frequency for the in vitro reaction. In a second approach, integration products were detected by Southern blot analysis. The dialyzed DNA mixtures were digested with EcoRI (10 U/reaction mixture) and BamHI (10 U/reaction mixture) at 37°C overnight. The DNA mixtures were then electrophoresed on a 1% agarose gel at constant voltage (35 mV) overnight. In some cases, the EcoRI-BamHI-digested DNA mixtures were extracted with phenol or incubated with proteinase K (200 µg/ml in a buffer containing 10 mM Tris-HCl [pH 7.8], 5 mM EDTA, and 0.5% SDS) at 37°C for 1 h. Southern blot analysis was done as described previously (22), and the 574-bp attDOT fragment was used as a fluorescence-labeled probe.

Mass spectrometry and DNA sequencing. To determine the molecular mass of the purified CTnDOT Int protein, the E250 elution fraction from the above purification procedure was dialyzed against double-distilled water at 4°C overnight for mass spectrometry. Matrix-assisted laser desorption ionization (MALDI) mass spectrometry was performed at the University of Illinois Protein Sciences Facility with a Voyager DE-STR MALDI mass spectrometer.

Cointegrate plasmids from the in vivo and in vitro integration assays, as well as the attL and attR PCR products amplified by using mixtures of in vitro reactions as a template, were sequenced by using the primer DRJ/R2242F for attR and DLJ/U487F (3) for attL. DNA sequencing was performed at the University of Illinois Biotechnology Genetic Engineering facility with an Applied Biosystems model 373A version 2.0.1S dye terminator automated sequencer.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
In vivo integration assay in E. coli. Since E. coli and Bacteroides species are so distant from each other genetically, it was possible that the CTnDOT integrase protein that was obtained by overproduction in E. coli was not active. Moreover, even if the wild-type protein was active, the His₆-tagged version of the protein might not be active. Accordingly, we first tested the integration efficiency of the pattDOT plasmid in a strain of E. coli that carried a plasmid containing the Bacteroides CTnDOT target site plus the untagged form of the CTnDOT int gene under control of the P_tac promoter (pINT101) (Fig. 1). The plasmid pattDOT is pir dependent, and it cannot replicate in the pir-deficient recipient used in this assay. Thus, in order for the recipient to become chloramphenicol resistant (Cm^r), the incoming pattDOT must integrate into pINT101. The frequency of the Cm^r Rf^r Ap^r transconjugants was 10^-4/recipient (Table 1). This frequency increased to 4 x 10^-3 when the recipient was grown in IPTG to increase the concentration of Int (Table 1). The data indicate that the CTnDOT Int protein expressed in E. coli was still capable of mediating the integration reaction and that the reaction frequency was dependent upon the Int concentration.

View larger version (30K): [in this window] [in a new window]   FIG. 1. In vivo integration assay in E. coli. Two different mating experiments were done to confirm that the His6-tagged CTnDOT Int protein expressed in E. coli had all of the functions necessary to perform site-specific recombination in vivo. In the first mating, the plasmid pattDOT (Cmr, pir dependent, containing CTnDOT attachment site attDOT) was mobilized from the donor E. coli pir+ strain BW19851 into the recipient E. coli pir-deficient strain EM24NR carrying the plasmid pINT101 (Apr). The pINT101 plasmid contains the wild-type int gene (under the control of Ptac promoter) from CTnDOT and one of its chromosomal target sites (attB). The Cmr Rfr Apr transconjugants (rifampin resistance from the recipient strain EM24NR) were derived from the cointegrate plasmid due to site-specific recombination between the attDOT and attB sites. The reaction was mediated by the wild-type Int protein expressed from pINT101 in the recipient. The second mating had the same donor and a recipient that carried pINT201. pINT201 has the same attB site and expresses the His6-tagged Int protein. The Cmr Rfr Apr transconjugants were obtained at a similar frequency (10-4/recipient; see Results).

Overexpression and purification of CTnDOT Int protein. Since the His₆-tagged Int protein was clearly active in E. coli, this protein was overproduced in E. coli and purified by passage over a nickel-nitrilotriacetic acid column described in Materials and Methods for use in the in vitro assay. The majority of the Int protein was found in the fractions with imidazole concentrations of 150, 200, and 250 mM (E150, E200, and E250 fractions) (Fig. 2). The molecular mass of the protein appeared to be about 47 kDa on an SDS-PAGE gel, which is less than its real molecular mass (50 kDa) as determined by MALDI mass spectrometry (data not shown). After dialysis, all three fractions (E150, E200, and E250) showed integrase activity in the in vitro integration assay. The three fractions were combined.

View larger version (103K): [in this window] [in a new window]   FIG. 2. SDS-PAGE to monitor the purification of the His6-tagged CTnDOT Int protein. Lane 1 contains crude extract of the parental strain BL21(DE3)/pLysS with the plasmid pINT. Lane 2 contains crude extract of the parental strain BL21(DE3)/pLysS with the pET28 vector. Both strains were induced with IPTG at a concentration of 1 mM for 5 h. A clear strong band at about 47 kDa is seen in lane 1 but is absent from lane 2. After serial washing steps, the protein was eluted by aliquots of buffer containing 100 (E100), 150 (E150), 200 (E200), or 250 (E250) mM imidazole in the elution buffer. The E100, E150, E200, and E250 fractions are in lanes 3 to 6, respectively. Lane 7 contains E250 elution fraction after it was dialyzed (see Materials and Methods). The majority of the CTnDOT Int protein was present in the E150, E200, and E250 fractions at a position corresponding to a molecular mass of about 47 kDa. It migrated faster than its real molecular mass (50 kDa, including the His6 tag) as determined by MALDI mass spectrometry. Lane 8 contains protein molecular mass standard markers (Benchmark; Gibco).

Coupling sequences for the in vitro integration assay. When the conjugative transposon CTnDOT excises itself from the Bacteroides chromosome, the Int protein presumably makes staggered cuts 5 bp adjacent to the left and right ends. The 5-base overhang from one end is then joined to the overhang of the other end to form a circular intermediate that has 5 bp of heteroduplex DNA in the middle of the two ends. The 5-bp DNA heteroduplexes, called coupling sequences, are resolved after excision. After conjugal transfer of the CTnDOT into a recipient, the single-stranded DNA recircularizes and replicates into a double-stranded circular intermediate carrying the resolved coupling sequences from the donor chromosome. In the following integration step, staggered cuts are made again on the coupling sequences in the circular intermediate as well as the potential coupling sequences adjacent to a target site in the recipient chromosome. After integration, two DNA heteroduplex regions are formed (Fig. 3) at the left (attL) and right (attR) junctions. The DNA heteroduplexes are believed to be resolved later by either DNA replication or DNA mismatch repair systems. As a result, the original coupling sequences from the donor chromosome are located in either attL or attR in the recipient chromosome, with an equal chance that one sequence of the other is present (Fig. 3).

View larger version (38K): [in this window] [in a new window]   FIG. 3. Coupling sequences for the in vitro integration assay. The donor DNA pattDOT contains the CTnDOT joined ends (left and right end joined together) with the coupling sequence TTAGT in the middle. The target DNA pattB contains one of the CTnDOT target sites in Bacteroides (attB) and the potential coupling sequence GCAAT. The 10-bp conserved sequence (GTANNTTTGC) between attDOT and attB is indicated in the boxed regions. During site-specific recombination mediated by the CTnDOT Int protein, 5-base staggered cuts were made at the borders of the coupling sequences (four DNA nick sites indicated by arrows), and DNA heteroduplex regions (indicated by circles) were formed in the attR and attL regions as a result of strand exchange and ligation. When the reaction mixtures were used as a template for PCR to amplify the attR or attL region, DNA heteroduplexes were resolved in PCRs. Sequencing data of the PCR products show that two different coupling sequences (GCAAT and TTAGT) were seen in the attR and attL regions.

The attL and attR PCR products were also cloned into the vector pGEM-T, and over 10 individual clones were sequenced. The coupling sequences (TTAGT) from the donor DNA pattDOT could be found in both attL and attR clones at a similar frequency. This further confirmed that the coupling sequence from donor DNA could be relocated in either the attL or attR regions after integration. All these results strongly suggest that during the in vitro integration assay, the CTnDOT Int protein makes staggered cuts to generate and relocate coupling sequences as it does in vivo.

E. coli IHF can substitute for Bacteroides host factor(s) to stimulate the integration frequency. The E. coli host factors IHF and HU are known to be able to promote recombination in other systems, and they are also heat stable. Thus, purified IHF or HU was added into the in vitro integration assay to replace the Bacteroides crude extract. In most cases, an IHF preparation that was about 90% pure and prepared in our laboratory was used (see Materials and Methods). Another IHF sample used (over 95% pure) was the gift of Steve Goodman. Both IHF samples significantly stimulated the reaction (to 10^-3 to 10^-2; Table 2, reaction mixture 3). The IHF did not alter the negative results seen in the control samples in reaction mixtures 4 to 6 of Table 2. Since the two IHF preparations gave essentially identical results, these experiments suggest that IHF is the protein in the preparations that stimulates the in vitro reaction. However, we could not unequivocally rule out the possibility that a low level of host protein contaminant present in both IHF samples is required for the reaction.

With IHF present in the reactions, we were able to detect an integration product by Southern blot analysis with fluorescence-labeled 574-bp attDOT DNA as a probe (Fig. 4, lanes 1 to 5). The reaction mixture was digested with EcoRI and BamHI and then run on an agarose gel. This enzyme combination cuts the plasmid pattDOT to produce a 1.8-kb DNA fragment containing attDOT. If site-specific recombination occurs and pattDOT is integrated into the plasmid pattB (3.5 kb) to form a cointegrate plasmid, an extra band (5.3 kb) is produced. When high concentrations of IHF (>0.25 µg/reaction mixture) were used, the integration reaction was less efficient, as shown in Fig. 4, lane 1. Excess IHF also inhibits site-specific recombination in the lambda in vitro system (23). When the IHF concentration was too low (<0.008 µg/reaction mixture), no significant integration product was observed by Southern blotting (Fig. 4, lanes 6 and 7).

View larger version (62K): [in this window] [in a new window]   FIG. 4. E. coli host factor IHF can stimulate the in vitro integration reactions. Different concentrations of IHF (lane 1, 0.25 µg; lane 2, 0.125 µg; lane 3, 0.063 µg; lane 4, 0.032 µg; lane 5, 0.016 µg; lane 6, 0.008 µg; lane 7, 0.004 µg) were used in each reaction mixture. The products from the reaction mixtures were digested by EcoRI and BamHI. The 1.8-kb DNA substrate is the digested DNA fragment containing attDOT from the plasmid pattDOT. The 5.3-kb integration product (lanes 1 to 5) is the digested DNA fragment containing attDOT from the final reaction product cointegrate plasmid. The integration product is not seen when the concentration of IHF is too low (<0.008 µg/reaction mixture; lanes 6 and 7). Lane 8, molecular size markers.

The frequency of the in vitro integration assay is also dependent on the quantity of Int and the molar ratio of Int to IHF. When IHF was maintained at a constant level while the CTnDOT Int concentration was varied in the in vitro reactions, the integration frequency increased as the Int concentration increased (data not shown). This suggests that integration is dependent on the quantity of Int protein added to the reaction mixture. We also determined the effect of different molar ratios of Int to IHF. The results are shown in Fig. 5. When the Int-to-IHF molar ratio was between 1:1.8 (lane 3) and 2.2:1 (lane 4), the integration frequency rose to the level of 10^-2 in the electroporation assay, the highest frequency observed so far. When the Int to IHF ratio was over 35.6:1 (lane 6) or below 1:28 (lane 1), the integration frequency went down to a barely detectable level of <10^-6 in both cases.

View larger version (26K): [in this window] [in a new window]   FIG. 5. The effect of the molar ratio of Int to IHF on the in vitro integration frequency. The integration frequency was determined as the percentage of Apr Cmr colonies relative to Apr colonies. Different molar ratios of Int to IHF were used in the standard reactions. Lane 1, 0.02 µg of Int (0.4 pmol) and 0.25 µg of IHF (11.5 pmol); lane 2, 0.04 µg of Int (0.8 pmol) and 0.125 µg of IHF (5.75 pmol); lane 3, 0.08 µg of Int (1.6 pmol) and 0.063 µg of IHF (2.88 pmol); lane 4, 0.16 µg of Int (3.2 pmol) and 0.032 µg of IHF (1.44 pmol); lane 5, 0.32 µg of Int (6.4 pmol) and 0.016 µg of IHF (0.072 pmol); lane 6, 0.64 µg of Int (12.8 pmol) and 0.008 µg of IHF (0.36 pmol). The molar ratios of Int to IHF in lanes 1 to 6 were therefore 1:28, 1:7, 1:1.8, 2.2:1, 8.9:1, and 35.6:1, respectively.

View larger version (57K): [in this window] [in a new window]   FIG. 6. Time course of the in vitro integration assay. Lane 1 contains HindIII DNA standards. Lane 2 contains a reaction mixture lacking Int after 6 h of incubation at 37°C. Lane 3 contains a reaction mixture lacking IHF after 6 h of incubation at 37°C. Lanes 4 to 9 contain reaction mixtures with incubation times at 37°C of 1, 2, 4, 6, and 8 h and overnight, respectively. The 5.3-kb integration product was seen clearly after incubation for 1 h (lane 4), and its intensity peaked after incubation for 6 h (lane 7). With the increase in incubation time, there were some other bands that accumulated at the bottom of the gel. Notice that these weak bands are not present in the two controls (lanes 2 and 3).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Previously, we tried to understand why the wild-type Bacteroides conjugative transposon CTnDOT tagged with an antibiotic gene that is expressed in E. coli did not integrate into the E. coli chromosome (B. J. Paszkiet, unpublished data). We constructed several mini-elements that contained the attDOT site and the CTnDOT int gene. All of them integrated into the E. coli chromosome at a low frequency (10^-7 to 10^-6 transconjugants per recipient), indicating that the expression of CTnDOT protein in E. coli from its native promoter is poor.

In this work, we constructed an in vivo integration assay in E. coli by using plasmids with the CTnDOT int gene behind the E. coli P_tac promoter. Without inducing Int expression, the integration frequency was still 10^-5 to 10^-4 transconjugants per recipient. With the induction of Int expression by 1 mM IPTG, however, the integration frequency increased to up to 10^-3 to 10^-2 transconjugants per recipient. This result suggests that expression of Int protein is one of the important limitations that determine the integration frequency of the mini-element (or even the wild-type element) in E. coli.

Another possibility for the low integration frequency of the mini-elements or the whole CTnDOT element in E. coli is that the host factors from E. coli cannot work as well as Bacteroides host factor(s) to stimulate integration events. From the in vivo and in vitro integration assays described here, it is clear that the E. coli host factor IHF can at least partially complement the function of the Bacteroides host factor(s). Preliminary results from gel shift assays (A. Gupta, unpublished data) also show that purified CTnDOT Int protein can shift radiolabeled attDOT DNA only if E. coli IHF protein is included. This suggests that E. coli IHF is able to facilitate the binding of CTnDOT Int to its putative binding sites in attDOT to form a stable protein-DNA complex that might be important for integration. Inspection of the attDOT sequence did not reveal any obvious candidates for an IHF binding site. Genomic sequences for the B. thetaiotaomicron 5482A (ATCC 29148) strain used in this study and for Bacteroides fragilis 638, which has been used in studies of Bacteroides CTns and other integrated mobilizable elements, are becoming available. Currently there appear to be several Bacteroides sequences related to ihfA and ihfB, although there is significant amino acid sequence divergence. This observation might indicate that IHF proteins made by diverse host bacteria can function interchangeably in site-specific recombination.

Another E. coli host factor, HU, is a nonspecific DNA-binding protein that has been shown to be able to replace IHF in the assembly of a functional attL intasome for lambda recombination (7). HU was also tested in this study in the in vitro system, and only low levels of integration products were detected. Thus, HU may not be as evolutionarily universal as IHF in its ability to function. Based on the preliminary genome sequences of B. thetaiotaomicron 5482, we have already identified two putative IHF subunit homologues and two HU subunit homologues. We are in the process of isolating these genes and purifying these proteins to use in the in vitro integration system.

Components such as DMSO, spermidine, and Mg²⁺ were able to stimulate the frequency of many in vitro recombination systems. DMSO is believed to be able to decrease the requirements for the formation of the stable protein-DNA complexes for Mu (6, 13) and IS911 (24) in vitro systems. Spermidine was able to stimulate lambda (15), Tn5 (8), and Tn10 (1) in vitro reactions. In the presence of Mg²⁺, MuA protein binds to Mu end sequences and the reaction efficiently undergoes the subsequent DNA cleavage and strand exchange steps (12). However, the CTnDOT in vitro reaction does not require DMSO, spermidine, or Mg²⁺.

CTnDOT Int protein belongs to the tyrosine recombinase family and has three out of the four conserved Arg-His-Arg-Tyr residues of this family (3). Lambda integrase is also a member of this family, and a variety of experiments have shown that DNA cleavage, strand exchange, and religation reactions during lambda integration are coordinated. After lambda Int binds to donor and target DNA, the conserved residue Tyr-342 serves as a nucleophile to attack the phosphodiester bond at the junction of the core-type site and the overlap region. Int forms a covalent phosphotyrosyl bond with the 3' end of the DNA at the cleavage site, and this is believed to conserve the energy required for the strand exchange step (17). A similar nucleophilic attack occurs and forms another phosphotyrosyl bond in the partner site. The reaction proceeds when the free 5'-OH groups at the cleavage sites in the top strands attack the phosphotyrosyl linkage in the partner site to ligate the DNA and form a Holliday junction. Another round of strand exchange and religation occurs for the bottom strands to complete the lambda integration reaction. The detailed mechanism of the CTnDOT integration reaction is not known. However, the fact that the CTnDOT Int has a conserved Tyr residue together with the finding that no external energy source, such as ATP, is required for the in vitro reactions suggests that CTnDOT Int has a similar mechanism for DNA cleavage and the subsequent strand exchange step. In other words, it is possible that the CTnDOT Int might be able to use the conserved Tyr to form the phosphotyrosyl bond and conserve the energy required for the strand exchange step. The correct attL and attR junctions could be amplified by PCR after the reaction mixtures from in vitro reactions were used as templates. This suggests that all three steps, DNA cleavage, strand exchange, and ligation, occur in the in vitro reactions. In the future, it will be informative to identify different intermediates from the above three steps, because the study of these intermediates will provide insights into understanding the molecular basis of CTnDOT recombination.

Coupling sequences are a unique feature of CTnDOT recombination. This is true of the gram-positive CTn, Tn916, as well as CTnDOT. From the in vitro work described here, it is clear that the formation of coupling sequences does not require any proteins from CTnDOT other than Int. The Int protein presumably recognizes a 10-bp conserved sequence (GTANNTTTGC) in both attDOT and attB and makes 5-bp staggered cuts adjacent to the conserved sequences. This is reminiscent of some restriction endonucleases that can recognize certain DNA sequences but cut DNA outside of the recognition sites. However, unlike restriction endonucleases, the CTnDOT Int belongs to a recombinase family that can perform DNA cleavage, strand exchange, and religation by a single protein. The presence of coupling sequences makes the CTnDOT recombination distinct from the lambda recombination system. After the CTnDOT integration is finished in vivo, the coupling sequences are believed to be resolved by DNA replication or DNA mismatch repair systems. During the in vitro reactions, the coupling sequences are not resolved and heteroduplex DNA sequences are still present in both the attL and attR junctions. This suggests that the mechanism of CTn integration is novel despite its evident evolutionary relationship to the lambda family recombinases. The availability of the in vitro integration system should facilitate future work on the reaction mechanism.

Based on the in vivo mini-excision system we developed (4), we are trying to determine which gene products are important for excision in order to construct an in vitro excision system. So far, it appears that here, too, the CTnDOT element will be unique. The Xis equivalent for CTnDOT, in contrast to the Xis of Tn916, which resembles the lambda Xis in many ways, is a much larger protein that has topoisomerase activity (Y. Sutanto, submitted for publication). This is a property that has not been previously reported for excisionases of phage or other CTns.

	ACKNOWLEDGMENTS

 
We thank Steve Goodman for providing purified IHF and Anca Segall for purified HU. We thank Kimberly Taylor for assistance in the cloning and protein purification. We also thank George Chaconas for valuable suggestions.

This collaborative study was supported by grants AI22383 (to A. A. Salyers) and GM28717 (to J. F. Gardner) from the National Institutes of Health.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Microbiology, 601 S. Goodwin Ave., University of Illinois, Urbana, IL 61801. Phone: (217) 333-7287. Fax: (217) 244-6697. E-mail: jeffgard{at}uiuc.edu.

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