Mobilization of Plasmids and Chromosomal DNA Mediated by the SXT Element, a Constin Found in Vibrio cholerae O139

doi:10.1128/JB.182.7.2043-2047.2000

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Journal of Bacteriology, April 2000, p. 2043-2047, Vol. 182, No. 7
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Mobilization of Plasmids and Chromosomal DNA Mediated by the SXT Element, a Constin Found in Vibrio cholerae O139

Bianca Hochhut, Joeli Marrero, and Matthew K. Waldor^*

Division of Geographic Medicine/Infectious Diseases, New England Medical Center and Tufts University School of Medicine, Boston, Massachusetts 02111

Received 25 October 1999/Accepted 7 January 2000

	ABSTRACT

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The Vibrio cholerae SXT element encodes resistance to multiple antibiotics and is a conjugative, self-transmissible, and chromosomallyintegrating element (a constin). Excision and self-transfer ofthe SXT element require an element-encoded integrase. We now reportthat the SXT element can also mobilize the plasmids RSF1010 andCloDF13 in trans as well as chromosomal DNA in an Hfr-like manner.SXT element-mediated mobilization of plasmids and chromosomalDNA, unlike its self-transfer, is not dependent upon excisionof the element from the chromosome. These results raise the possibilitythat the SXT element and other constins play a general role inhorizontal gene transfer among gram-negativebacteria.

	TEXT

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The SXT element was originally found in the chromosome of epidemic Vibrio cholerae O139 strains that arose in late 1992 onthe Indian subcontinent (6, 30). This approximately 62-kbpelement carries the genes encoding resistance to sulfamethoxazoleand trimethoprim (SXT), chloramphenicol, and low levels of streptomycin.Despite the chromosomal location of this element, we found thatthe entire element is self-transmissible and can be transferredby conjugation to a variety of gram-negative bacteria includingV. cholerae, Escherichia coli, and Salmonella enterica serovarTyphimurium (30). No replicative extrachromosomal form of theSXT element has beenisolated.

The transfer of the SXT element has features reminiscent of both temperate bacteriophages and conjugative plasmids. The elementencodes a $lambda$ family recombinase (Int) that is required for itsexcision from the chromosome and circularization by recombinationbetween the right and left ends of the integrated element. Generationof this extrachromosomal intermediate is an essential step inthe successful transfer of the SXT element; it must precede conjugativetransfer to recipient cells. Once transferred to the recipient,the SXT element integrates site specifically into the 5' end ofprfC, the gene coding for protein chain release factor 3 (RF3).The SXT element encodes a new N terminus for RF3 and maintainsthe reading frame of prfC. Integration, like excision, requiresthe SXT element int gene (14). Since the properties of the SXTelement do not precisely match those of previously described transmissibleelements, we named the SXT element with an acronym for its propertiesas a constin, a conjugative, self-transmissible integrating element(14).

Previously described self-transmissible conjugative elements can mobilize coresiding DNA either in cis or in trans. For example,conjugative plasmids like RP4 (11) can mediate transfer of mobilizableplasmids. These mobilizable plasmids typically encode an originof transfer (oriT) and their own relaxase and nicking accessoryproteins for interaction with oriT but require a conjugative elementto provide the mating pair formation functions for transfer (4).Another transfer scenario is that a chromosome can acquire anoriT by integration of a conjugative element and thereby becomemobilizable. For example, integration of the F plasmid in E. coliresults in formation of the so-called Hfr (high frequency of recombination)strains, which can transfer their chromosomes at high frequency(12, 32). The conjugative transposons described for Bacteroidesspp. such as the Tc^r Em^r DOT family can also mobilize other genetic elements (23). Tc^r Em^r DOT-like elements can mobilize plasmids in cis (by integrationinto these plasmids) as well as plasmids and chromosomally integratedelements (e.g., NBUs and Tn4555) in trans (23). In this study,we explored whether the SXT element is able to mobilize plasmidsand chromosomalDNA.

RSF1010 is mobilized by the SXT element. RSF1010 is a broad-host-range plasmid that can be mobilized by conjugative plasmids, the chromosomal dot-icm virulence systemof Legionella pneumophila, and the plasmid-encoded vir systemof Agrobacterium tumefaciens (3, 9, 25, 29). BecauseRSF1010 encodes resistance to sulfonamide and streptomycin, asdoes the SXT element, we used an RSF1010 derivative containinga kanamycin resistance cassette, RSF1010-Kn (29), to test whetherE. coli K-12 harboring the SXT element could mobilize RSF1010.Donor strains for these conjugation experiments were the E. coliK-12 MG1655 derivatives CAG18439 (27) and HW220 (CAG18439 prfC::SXTelement [14]), both transformed with RSF1010-Kn. BI533, a spontaneousnalidixic acid-resistant mutant of MG1655, was used as a recipient.Matings were performed as previously described (14), and exconjugantswere selected on Luria-Bertani (LB) agar containing 50 mg of kanamycinper liter, and 40 mg of nalidixic acid (NAL) per liter for RSF1010-Kntransfer and LB agar with 40 mg of NAL per liter, 160 mg of sulfamethoxazoleper liter, and 32 mg of trimethoprim per liter for SXT elementtransfer. CAG18439 did not mobilize RSF1010. However, when itsSXT^r derivative HW220 was used as a donor, Kn^r exconjugants were obtained with a frequency of 10⁷ (Table 1). This frequency was about 100-fold lower than thefrequency of SXT element transfer from this strain (Table 1).Only 10% of the Kn^r exconjugants were also resistant to SXT. The presence of RSF1010-Knin the exconjugants was confirmed by plasmid isolation (data notshown). Thus, in most cases the SXT element and RSF1010 were transferredindependently. These results indicate that RSF1010 is mobilizedin trans by the SXT element, rather than through formation ofa cointegrate between the two elements.

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TABLE 1. Plasmid mobilization by the SXT element^a

Since the int gene of the SXT element is required for excision and self-transfer of the element, we constructed a null mutationin int to test whether SXT element-mediated transfer of RSF1010requires the activity of this protein. The int bp 305 to 1025were deleted with a ClaI/NsiI digest followed by intramolecularligation, and the int $Delta$ 305-1025 allele was cloned into the allele-exchangevector pWM91 (19), resulting in pINT $Delta$ 91. Allelic exchange wasperformed in HW220 as previously described (7), and an HW220 $Delta$ intderivative, BI554, was isolated. Like HW514 (14), a previouslydescribed HW220 derivative with an insertion mutation in int,BI554 did not contain an extrachromosomal circular form of theSXT element detectable by PCR or transfer the SXT element to arecipient. However, BI554 could still mediate transfer of RSF1010-Knto BI533 at nearly the same frequency as that of the int⁺ strain HW220 (Table 1). This indicates that the conjugativefunctions of the SXT element are not dependent upon a functionalint gene. Therefore, excision and circularization of the SXT elementare not required for expression of the SXT element-encoded transferfunctions. This result also confirms that transfer of RSF1010is not dependent on transfer of the SXTelement.

To test whether the RSF1010-encoded oriT is required for its mobilization by the SXT element, we transformed CAG18439, CAG18439/RP4,HW220, and BI554 with a derivative of RSF1010-Kn carrying a 124-bpdeletion extending over the oriT region (deletion $Delta$ 13 [10, 29]).As expected, CAG18439 and CAG18439 carrying RP4 could not transferRSF1010 $Delta$ oriT. However, to our surprise, HW220 was still able tomobilize this plasmid with a frequency similar to that of RSF1010-Kn(Table 1). This indicates an alternative route of RSF1010 transferindependent of the oriT region. Mob-independent transfer of plasmidshas been described for other conjugative elements like Tn916 (26),but the mechanism is not understood. Transfer of the RSF1010 $Delta$ oriTwas dependent neither on cointegrate formation between the SXTelement and RSF1010 $Delta$ oriT nor on recombinational repair of theoriT deletion in this plasmid by SXT element sequences. Thesemechanisms were excluded by our findings that, in all exconjugantstested, RSF1010 $Delta$ oriT could be isolated as a plasmid and that theoriT deletion was still present (data not shown). Furthermore,as in the previous experiment, only about 10% of the exconjugantsreceived both the RSF1010 $Delta$ oriT and the SXT element. The int mutantBI554 was also able to mediate transfer of RSF1010 $Delta$ oriT, althoughwith a lower frequency than HW220 (Table 1).

The SXT element can mobilize CloDF13. To investigate whether the SXT element can also mediate the transfer of other mobilizable plasmids, we transformed CAG18439and HW220 with pSU4628 (CloDF13::TnA $Delta$ EcoRV Ap^r [4]), pSU4601 (ColE1::Kn [4]), and pSU4620 (ColE3::Kn [4]).Matings were performed using BI533 as a recipient, and exconjugantswere selected on LB agar with NAL and ampicillin (100 mg/liter)and LB plates with NAL and kanamycin, respectively (Table 1).In each experiment, SXT element transfer was also monitored. Asa positive control, we used a CAG18439 derivative harboring RP4as a donor strain and could show plasmid transfer in all cases(data not shown). As expected, CAG18439 alone could not mediatetransfer of any of these plasmids. In contrast, with HW220 asthe donor we could detect transfer of pSU4628 (CloDF13) but notof pSU4601 (ColE1) or pSU4620 (ColE3). None of 100 tested Ap^r exconjugants containing pSU4628 showed resistance to SXT, indicatingthat cotransfer of the SXT element with pSU4628 did not occuror occurred only at a lowfrequency.

As was the case for SXT element-mediated transfer of RSF1010, transfer of pSU4628 was independent of the SXT element-encodedint. The int mutant BI554 donated pSU4628 to recipient cells atapproximately the same frequency as did the int⁺ HW220 (Table 1). Interestingly, both pSU4628 and pSU4620 influencedthe SXT element transfer frequency (Table 1). With pSU4628, therewas a 10-fold reduction in the transfer frequency of the SXT element.This could at least partly account for our inability to detectcotransfer of the SXT element with pSU4628. pSU4620 (ColE3), eventhough it was not mobilized by the SXT element, also interferedwith the SXT element transfer, as no SXT^r exconjugants could be isolated in these matings. Inhibition ofF transfer by a copy number mutant of CloDF13 has been attributedto a reduction of the level of TraD (31). A similar mechanismmight account for the reduced frequency of SXT element transferin the presence of either pSU4628 or pSU4620. A study by Cabezónet al. (4) showed that it is primarily the TraD (in F)-TraG(in RP4) protein family that mediates the coupling between therespective conjugation systems and the mobilizable plasmids. CloDF13encodes its own TraG homologue, but pSU4601 and pSU4620 do not.This difference could account for the efficient mobilization ofCloDF13 by the SXT element and the failure to mobilize pSU4601orpSU4620.

The SXT element can mobilize chromosomal DNA in an Hfr-like manner. We tested whether the SXT element can, in addition, mobilize chromosomal DNA in cis. To accomplish this, we moved the SXTelement into a set of MG1655 derivatives carrying single Tn10(Tc^r) or Tn10kan (Kn^r) insertions at different sites on the chromosome (27). TheTn10 insertions were chosen to be upstream and downstream of theSXT element insertion site in prfC, which is located at 99.3 minon the E. coli K-12 chromosome (2). We found that Tn10 insertionsdownstream of prfC in donor strains BI722 (0 min), BI723 (5.6min), and HW220 (7.9 min) could be donated to a recipient if theSXT element was integrated at prfC (Fig. 1). Transfer of Tn10was absolutely dependent on the presence of the SXT element inthe donor strains (Fig. 1), and no transposition of Tn10 was evidentin the exconjugants. Like their respective donor strains, exconjugantsderived from BI722 were threonine auxotrophs, and the exconjugantsderived from BI723 were proline auxotrophs. Similarly, 98% of100 tested exconjugants derived from HW220 were LacZ (white on plates containing 0.02% 5-bromo-4-chloro-indolyl- $beta$ -D-galactoside),indicating cotransfer of the lacZU118 allele along with the lacI42::Tn10to the recipient strain.

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FIG. 1. Mobilization of chromosomal DNA by the SXT element. The transfer frequency was calculated by dividing the number of exconjugant cells by the number of donor cells. All donor strains are derivatives of E. coli K-12 MG1655. Locations of the Tn10 insertions in the donor strains were determined by Singer et al. (27) and Nichols et al. (20). ND, not done.

In contrast to Tn10 insertions downstream of prfC, the two Tn10 insertions upstream of prfC in donor strains BI646 (90.3 min)and BI647 (98.25 min) could not be transferred by the SXT element.The lack of detectable transfer from insertions upstream of prfCsuggests that imprecise excision of the SXT element, as seen withspecialized transducing phages or an F' plasmid, does not constitutethe mechanism of transfer of chromosomal DNA by this element.Instead, it appears that the SXT element mobilizes chromosomalDNA in a directional manner, similar to Hfr mobilization of chromosomalDNA. To investigate this further, we carried out conjugation experimentsusing HW220 as a donor and a Nal^r derivative of AB1157 [E. coli K-12; thr-1, leuB6 $Delta$ (gpt-proA)62(1)] as a recipient and selected for Tc^r (lacI::Tn10) AB1157 (Nal^r) exconjugants. The frequency of cotransfer of the thrABC, leuB,and proA alleles of HW220 to AB1157 was determined (Fig. 2). Thesefrequencies were dependent on the distance of these markers relativeto the selected marker (lacI::Tn10). Thus, Tc^r AB1157 exconjugants were proline auxotrophs more frequently thanleucine or threonine auxotrophs, respectively (Fig. 2). Thesedata indicate that the transferred DNA is integrated by homologousrecombination into the recipient's chromosome. Additional evidencethat the mechanism of SXT element-mediated transfer of chromosomalDNA is Hfr-like and dependent on homologous recombination wasthe finding that transfer of Tn10 markers to recipients was RecAdependent. When we compared the transfer frequency of lacI::Tn10kanfrom HW1110 (MG1655 lacI::Tn10kan prfC::SXT element) to eitherMC4100 or MC4100 recA, we found that the Tn10kan insertion inlacI could not be transferred successfully to the recA mutantof MC4100 (Fig. 1). In contrast, RecA is not required in the recipientfor SXT element transfer (Fig. 1).

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FIG. 2. Frequency of cotransfer of unselected markers. The relative organization and map locations of the genes prfC (SXT element integration site), thrABC, leuB, proA, and lacI on the E. coli K-12 chromosome are depicted. Matings were performed with HW220 (lacI::Tn10 prfC::SXT element) as donor and AB1157 Nal^r as recipient cells. Exconjugants (which had obtained Tn10) were selected as Nal^r Tc^r CFU and subsequently scored for the presence of functional thrABC, leuB, and proA alleles. The frequency of cotransfer of thrABC, leuB, and proA along with lacI::Tn10 is given as a percentage (bottom line).

Chromosomal DNA transfer mediated by the SXT element, like transfer of plasmids by this element, appears to be independentof transfer of the element itself. Only a fraction of the Tn10-containingexconjugants derived from BI722, BI723, and HW220 were also SXT^r (41, 36, and 14%, respectively). Also, BI554, the $Delta$ int derivativeof HW220, was capable of donating the lacI::Tn10 to the recipient.In fact, the frequency of transfer of lacI::Tn10 was even higherfrom BI554 than from HW220 (Fig. 1), suggesting that transferof the SXT element DNA may interfere with transfer of chromosomalDNA.

Conclusions. In this study, we found that the gene transfer capacity of the SXT element goes beyond its self-transfer. In E. coli K-12,we showed that the SXT element also mobilizes certain plasmidsin trans and transfers chromosomal DNA in a directional fashionin cis. These findings confirm that conjugation is the mechanismof SXT element transfer. However, as a conjugative gene transfersystem, the SXT element has distinct features compared with conjugativeplasmids and conjugative transposons. First, compared to otherknown conjugation systems in gram-negative bacteria (4), theSXT element transfer system is more selective and less efficientwith regard to the plasmids it can mobilize. Second, the SXT elementmobilized RSF1010 in an oriT-independent manner. As we excludedcointegrate formation between RSF1010 and the SXT element, othermechanisms must account for this oriT-independent mobilizationof RSF1010. One possibility is that either the SXT element orthe RSF1010 MobA can recognize and nick a different RSF1010 sequencethat can serve as an alternative origin of transfer. Since otherconjugative transfer systems such as RP4 (10) and the icm-dotsystem (29) cannot mobilize an oriT-deleted RSF1010, it seemsmore likely that an alternative oriT is recognized by an SXT element-encodednickase rather than by the RSF1010 MobA. It is also possible thatSXT element-mediated transfer of RSF1010 proceeds via a mechanismindependent of an oriT and results in the transfer of a double-strandedplasmid to recipient cells. If such a process occurs, there mustbe some specific interaction between the SXT element-encoded conjugativemachinery and RSF1010, because we did not observe transfer ofother mobilizable plasmids like pSU4601 and pSU4620. We are currentlyinvestigating which sequences of RSF1010 and the SXT element arerequired for this unexpected oriT-independent transfer ofRSF1010.

We found that the SXT element int is not required for mobilization of plasmids or chromosomal DNA. Thus, similar to integratedconjugative plasmids such as F (8), but unlike other obligateintegrated elements such as Tn916 (5), the expression of SXTelement transfer functions is not dependent on its excision. ForTn916, the most thoroughly studied conjugative transposon of gram-positivebacteria, excision is required for expression of the transposon-encodedtransfer functions (5). However, the transfer frequency ofTn916 is not determined by its frequency of excision, indicatingthat other factors in addition to excision regulate transfer ofthis conjugative transposon (18). The coupling of excision andtransfer could explain why transfer of chromosomal DNA has notbeen reported for Tn916. It will be interesting to see whetherother constins, such as CTnscr94 from enterobacteria (13), Tn5276from Lactococcus lactis (21), the clc element from Pseudomonasputida (22), the Mesorhizobium loti symbiosis island (28),and the Tc^r elements (24), will also be found to be capable of transferof chromosomal DNA in a manner similar to the SXTelement.

Transfer of linked chromosomal DNA by the SXT element may be an important mechanism of cross-species gene transfer. Presumably,any DNA sequence within about 500 kbp of the 3' end of prfC couldbe mobilized by the SXT element. In the era of sequenced microbialgenomes, this large stretch of DNA can be examined in a numberof bacterial species to identify genes that could have been mobilizedby the SXT element. For example, we wondered whether the wfb genecluster, which is thought to be horizontally transmitted in V.cholerae populations (16), is closely linked to the V. choleraeprfC. This turned out not to be the case, as the wfb region mapsabout 460 kbp 5' of prfC. Therefore, it seems unlikely that theSXT element played a role in the mobilization of the O139 wfbcluster from some donor strain into an El Tor V. cholerae O1 strainto give rise to V. cholerae O139. However, the V. cholerae pathogenicityisland, which encodes TCP pili, maps only about 200 kbp 3' ofprfC. Although the entire V. cholerae pathogenicity island hasrecently been reported to be self-transmissible as a bacteriophage(17), the SXT element could provide an alternative pathway formobilization of this virulence gene cluster. Similarly, the S.enterica serovar Typhimurium pathogenicity island encoding SigE,a factor required for invasion of host cells, is located at about25 min (15). We were able to transfer a marked version of sigEat a very low frequency, in an SXT element-dependent fashion betweenS. enterica serovar Typhimurium strains (our unpublished results).This raises the possibility that the SXT element or perhaps similarconstins may play a role in the mobilization of pathogenicityislands (whose mechanism of mobility is generally not understood)as well as other chromosomally encoded virulence genes. Finally,the SXT element may be a useful tool for mobilization of linkedchromosomal genes in bacterial species like V. cholerae wherethere are currently no Hfr-like elements available. The expandedpotential of bacteria harboring the SXT element to engage in horizontalgene transfer may be an explanation for the widespread disseminationof the SXT element and similar elements in bacterialpopulations.

	ACKNOWLEDGMENTS

We are grateful to J. P. Vogel, F. de la Cruz, V. L. Miller, and C. A. Lee for kindly providing us with plasmids and strains.We appreciate the helpful suggestions of A. Wright. We also thankA. Kane, B. Davis, M. Malamy, D. RayChaudhuri, A. Camilli, andH. Kimsey for critical reading of themanuscript.

This work was supported by the Deutsche Forschungsgemeinschaft (B.H.), NIH grant AI42347 (M.K.W.), a PEW Scholar Award (M.K.W.),and P30DK-34928 (for the NEMC GRASP Center). J.M. was supportedby the NIH Short-Term Training Program for minority students (2T35 HL07785-06).

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Geographic Medicine/Infectious Diseases, New England Medical Center andTufts University School of Medicine, NEMC 041, 750 WashingtonSt., Boston, MA 02111. Phone: (617) 636-7618. Fax: (617) 636-5292.E-mail: mwaldor{at}lifespan.org.

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