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Journal of Bacteriology, April 2000, p. 2043-2047, Vol. 182, No. 7
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
The Vibrio cholerae SXT element encodes resistance to
multiple antibiotics and is a conjugative, self-transmissible, and
chromosomally integrating element (a constin). Excision and
self-transfer of the SXT element require an element-encoded integrase.
We now report that the SXT element can also mobilize the plasmids
RSF1010 and CloDF13 in trans as well as chromosomal DNA in
an Hfr-like manner. SXT element-mediated mobilization of plasmids and
chromosomal DNA, unlike its self-transfer, is not dependent upon
excision of the element from the chromosome. These results raise the
possibility that the SXT element and other constins play a general role
in horizontal gene transfer among gram-negative bacteria.
The SXT element was originally found
in the chromosome of epidemic Vibrio cholerae O139 strains
that arose in late 1992 on the Indian subcontinent (6, 30).
This approximately 62-kbp element carries the genes encoding resistance
to sulfamethoxazole and trimethoprim (SXT), chloramphenicol, and low
levels of streptomycin. Despite the chromosomal location of this
element, we found that the entire element is self-transmissible and can
be transferred by conjugation to a variety of gram-negative bacteria
including V. cholerae, Escherichia coli, and
Salmonella enterica serovar Typhimurium (30). No
replicative extrachromosomal form of the SXT element has been isolated.
The transfer of the SXT element has features reminiscent of both
temperate bacteriophages and conjugative plasmids. The element encodes
a 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 mobilizable plasmids. These
mobilizable plasmids typically encode an origin of transfer
(oriT) and their own relaxase and nicking accessory proteins
for interaction with oriT but require a conjugative element to provide the mating pair formation functions for transfer
(4). Another transfer scenario is that a chromosome can
acquire an oriT by integration of a conjugative element and
thereby become mobilizable. For example, integration of the F plasmid
in E. coli results 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 Bacteroides spp. such as the
Tcr Emr DOT family can also mobilize other
genetic elements (23). Tcr Emr
DOT-like elements can mobilize plasmids in cis (by
integration into these plasmids) as well as plasmids and chromosomally
integrated elements (e.g., NBUs and Tn4555) in
trans (23). In this study, we explored whether
the SXT element is able to mobilize plasmids and chromosomal DNA.
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 system of Legionella
pneumophila, and the plasmid-encoded vir system of
Agrobacterium tumefaciens (3, 9, 25, 29). Because RSF1010 encodes resistance to sulfonamide and streptomycin, as does the
SXT element, we used an RSF1010 derivative containing a kanamycin
resistance cassette, RSF1010-Kn (29), to test whether E. coli K-12 harboring the SXT element could mobilize
RSF1010. Donor strains for these conjugation experiments were the
E. coli K-12 MG1655 derivatives CAG18439 (27) and
HW220 (CAG18439 prfC::SXT element
[14]), both transformed with RSF1010-Kn. BI533, a
spontaneous nalidixic acid-resistant mutant of MG1655, was used as a
recipient. Matings were performed as previously described
(14), and exconjugants were selected on Luria-Bertani (LB)
agar containing 50 mg of kanamycin per liter, and 40 mg of nalidixic
acid (NAL) per liter for RSF1010-Kn transfer and LB agar with 40 mg of
NAL per liter, 160 mg of sulfamethoxazole per liter, and 32 mg of
trimethoprim per liter for SXT element transfer. CAG18439 did not
mobilize RSF1010. However, when its SXTr derivative HW220
was used as a donor, Knr exconjugants were obtained with a
frequency of 10
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Mobilization of Plasmids and Chromosomal DNA
Mediated by the SXT Element, a Constin Found in Vibrio
cholerae O139
ABSTRACT
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family recombinase (Int) that is required for its excision from
the chromosome and circularization by recombination between the right
and left ends of the integrated element. Generation of this
extrachromosomal intermediate is an essential step in the successful
transfer of the SXT element; it must precede conjugative transfer to
recipient cells. Once transferred to the recipient, the SXT element
integrates site specifically into the 5' end of prfC, the
gene coding for protein chain release factor 3 (RF3). The SXT element
encodes a new N terminus for RF3 and maintains the reading frame of
prfC. Integration, like excision, requires the SXT element
int gene (14). Since the properties of the SXT element do not precisely match those of previously described
transmissible elements, we named the SXT element with an acronym for
its properties as a constin, a conjugative, self-transmissible
integrating element (14).
7 (Table 1).
This frequency was about 100-fold lower than the frequency of SXT
element transfer from this strain (Table 1). Only 10% of the
Knr exconjugants were also resistant to SXT. The presence
of RSF1010-Kn in the exconjugants was confirmed by plasmid isolation
(data not shown). Thus, in most cases the SXT element and RSF1010 were
transferred independently. These results indicate that RSF1010 is
mobilized in trans by the SXT element, rather than through
formation of a cointegrate between the two elements.
TABLE 1.
Plasmid mobilization by the
SXT elementa
305-1025 allele was cloned into the
allele-exchange vector pWM91 (19), resulting in pINT91.
Allelic exchange was performed in HW220 as previously described
(7), and an HW220int derivative, BI554, was
isolated. Like HW514 (14), a previously described HW220
derivative with an insertion mutation in int, BI554 did not
contain an extrachromosomal circular form of the SXT element
detectable by PCR or transfer the SXT element to a recipient. However,
BI554 could still mediate transfer of RSF1010-Kn to BI533 at nearly the
same frequency as that of the int+ strain
HW220 (Table 1). This indicates that the conjugative functions of
the SXT element are not dependent upon a functional int
gene. Therefore, excision and circularization of the SXT element are not required for expression of the SXT element-encoded
transfer functions. This result also confirms that transfer of
RSF1010 is not dependent on transfer of the SXT element.
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-bp deletion extending over the oriT region (deletion 13
[10, 29]). As expected, CAG18439 and CAG18439 carrying
RP4 could not transfer RSF1010oriT. However, to our
surprise, HW220 was still able to mobilize this plasmid with a
frequency similar to that of RSF1010-Kn (Table 1). This indicates an
alternative route of RSF1010 transfer independent of the
oriT region. Mob-independent transfer of plasmids has been
described for other conjugative elements like Tn916
(26), but the mechanism is not understood. Transfer of the
RSF1010oriT was dependent neither on cointegrate
formation between the SXT element and RSF1010oriT nor on
recombinational repair of the oriT deletion in this plasmid
by SXT element sequences. These mechanisms were excluded by our
findings that, in all exconjugants tested, RSF1010oriT
could be isolated as a plasmid and that the oriT deletion
was still present (data not shown). Furthermore, as in the previous
experiment, only about 10% of the exconjugants received both the
RSF1010oriT and the SXT element. The int
mutant BI554 was also able to mediate transfer of
RSF1010oriT, although with 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 CAG18439 and HW220 with pSU4628
(CloDF13::TnAEcoRV Apr
[4]), pSU4601 (ColE1::Kn
[4]), and pSU4620 (ColE3::Kn
[4]). Matings were performed using BI533 as a
recipient, and exconjugants were 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. As a positive control, we used a CAG18439 derivative
harboring RP4 as a donor strain and could show plasmid transfer in all
cases (data not shown). As expected, CAG18439 alone could not mediate transfer of any of these plasmids. In contrast, with HW220 as the donor
we could detect transfer of pSU4628 (CloDF13) but not of pSU4601
(ColE1) or pSU4620 (ColE3). None of 100 tested Apr
exconjugants containing pSU4628 showed resistance to SXT, indicating that cotransfer of the SXT element with pSU4628 did not occur or
occurred only at a low frequency.
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 SXT element into a set of MG1655 derivatives carrying single
Tn10 (Tcr) or Tn10kan
(Knr) insertions at different sites on the chromosome
(27). The Tn10 insertions were chosen to be
upstream and downstream of the SXT element insertion site in
prfC, which is located at 99.3 min on the E. coli
K-12 chromosome (2). We found that Tn10
insertions downstream of prfC in donor strains BI722 (0 min), BI723 (5.6 min), and HW220 (7.9 min) could be donated to a
recipient if the SXT element was integrated at prfC (Fig.
1). Transfer of Tn10 was
absolutely dependent on the presence of the SXT element in the donor
strains (Fig. 1), and no transposition of Tn10 was evident in the exconjugants. Like their respective donor strains, exconjugants derived from BI722 were threonine auxotrophs, and the exconjugants derived from BI723 were proline auxotrophs. Similarly, 98% of 100 tested exconjugants derived from HW220 were LacZ (white
on plates containing 0.02%
5-bromo-4-chloro-indolyl-
-D-galactoside), indicating
cotransfer of the lacZU118 allele along with the
lacI42::Tn10 to the recipient strain.
|
(gpt-proA)62 (1)] as a recipient
and selected for Tcr
(lacI::Tn10) AB1157 (Nalr)
exconjugants. The frequency of cotransfer of the thrABC,
leuB, and proA alleles of HW220 to AB1157 was
determined (Fig. 2). These frequencies
were dependent on the distance of these markers relative to the
selected marker (lacI::Tn10). Thus,
Tcr AB1157 exconjugants were proline auxotrophs more
frequently than leucine or threonine auxotrophs, respectively (Fig. 2).
These data indicate that the transferred DNA is integrated by
homologous recombination into the recipient's chromosome. Additional
evidence that the mechanism of SXT element-mediated transfer of
chromosomal DNA is Hfr-like and dependent on homologous recombination
was the finding that transfer of Tn10 markers to
recipients was RecA dependent. When we compared the transfer frequency
of lacI::Tn10kan from HW1110
(MG1655 lacI::Tn10kan
prfC::SXT element) to either MC4100 or MC4100
recA, we found that the Tn10kan insertion in lacI could not be transferred successfully to the
recA mutant of MC4100 (Fig. 1). In contrast, RecA is not
required in the recipient for SXT element transfer (Fig. 1).
|
int derivative of HW220, was capable of donating the
lacI::Tn10 to the recipient. In fact,
the frequency of transfer of lacI::Tn10
was even higher from BI554 than from HW220 (Fig. 1), suggesting that
transfer of the SXT element DNA may interfere with transfer of
chromosomal DNA.
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 plasmids in trans and transfers chromosomal DNA in a directional fashion in cis. These findings confirm that conjugation is the mechanism of SXT element transfer. However, as a conjugative gene transfer system, the SXT element has distinct features compared with conjugative plasmids and conjugative transposons. First, compared to other known conjugation systems in gram-negative bacteria (4), the SXT element transfer system is more selective and less efficient with regard to the plasmids it can mobilize. Second, the SXT element mobilized RSF1010 in an oriT-independent manner. As we excluded cointegrate formation between RSF1010 and the SXT element, other mechanisms must account for this oriT-independent mobilization of RSF1010. One possibility is that either the SXT element or the RSF1010 MobA can recognize and nick a different RSF1010 sequence that can serve as an alternative origin of transfer. Since other conjugative transfer systems such as RP4 (10) and the icm-dot system (29) cannot mobilize an oriT-deleted RSF1010, it seems more likely that an alternative oriT is recognized by an SXT element-encoded nickase rather than by the RSF1010 MobA. It is also possible that SXT element-mediated transfer of RSF1010 proceeds via a mechanism independent of an oriT and results in the transfer of a double-stranded plasmid to recipient cells. If such a process occurs, there must be some specific interaction between the SXT element-encoded conjugative machinery and RSF1010, because we did not observe transfer of other mobilizable plasmids like pSU4601 and pSU4620. We are currently investigating which sequences of RSF1010 and the SXT element are required for this unexpected oriT-independent transfer of RSF1010.
We found that the SXT element int is not required for mobilization of plasmids or chromosomal DNA. Thus, similar to integrated conjugative plasmids such as F (8), but unlike other obligate integrated elements such as Tn916 (5), the expression of SXT element transfer functions is not dependent on its excision. For Tn916, the most thoroughly studied conjugative transposon of gram-positive bacteria, excision is required for expression of the transposon-encoded transfer functions (5). However, the transfer frequency of Tn916 is not determined by its frequency of excision, indicating that other factors in addition to excision regulate transfer of this conjugative transposon (18). The coupling of excision and transfer could explain why transfer of chromosomal DNA has not been reported for Tn916. It will be interesting to see whether other constins, such as CTnscr94 from enterobacteria (13), Tn5276 from Lactococcus lactis (21), the clc element from Pseudomonas putida (22), the Mesorhizobium loti symbiosis island (28), and the Tcr elements (24), will also be found to be capable of transfer of chromosomal DNA in a manner similar to the SXT element. 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 could be mobilized by the SXT element. In the era of sequenced microbial genomes, this large stretch of DNA can be examined in a number of bacterial species to identify genes that could have been mobilized by the SXT element. For example, we wondered whether the wfb gene cluster, which is thought to be horizontally transmitted in V. cholerae populations (16), is closely linked to the V. cholerae prfC. This turned out not to be the case, as the wfb region maps about 460 kbp 5' of prfC. Therefore, it seems unlikely that the SXT element played a role in the mobilization of the O139 wfb cluster from some donor strain into an El Tor V. cholerae O1 strain to give rise to V. cholerae O139. However, the V. cholerae pathogenicity island, which encodes TCP pili, maps only about 200 kbp 3' of prfC. Although the entire V. cholerae pathogenicity island has recently been reported to be self-transmissible as a bacteriophage (17), the SXT element could provide an alternative pathway for mobilization 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 about 25 min (15). We were able to transfer a marked version of sigE at a very low frequency, in an SXT element-dependent fashion between S. enterica serovar Typhimurium strains (our unpublished results). This raises the possibility that the SXT element or perhaps similar constins may play a role in the mobilization of pathogenicity islands (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 linked chromosomal genes in bacterial species like V. cholerae where there are currently no Hfr-like elements available. The expanded potential of bacteria harboring the SXT element to engage in horizontal gene transfer may be an explanation for the widespread dissemination of the SXT element and similar elements in bacterial populations.| |
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 thank A. Kane, B. Davis, M. Malamy, D. RayChaudhuri, A. Camilli, and H. Kimsey for critical reading of the manuscript.
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 supported by the NIH Short-Term Training Program for minority students (2 T35 HL07785-06).
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FOOTNOTES |
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* Corresponding author. Mailing address: Division of Geographic Medicine/Infectious Diseases, New England Medical Center and Tufts University School of Medicine, NEMC 041, 750 Washington St., Boston, MA 02111. Phone: (617) 636-7618. Fax: (617) 636-5292. E-mail: mwaldor{at}lifespan.org.
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Iwanaga, M., Toma, C., Miyazato, T., Insisiengmay, S., Nakasone, N., Ehara, M.
(2004). Antibiotic Resistance Conferred by a Class I Integron and SXT Constin in Vibrio cholerae O1 Strains Isolated in Laos. Antimicrob. Agents Chemother.
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Prentice, M. B., James, K. D., Parkhill, J., Baker, S. G., Stevens, K., Simmonds, M. N., Mungall, K. L., Churcher, C., Oyston, P. C. F., Titball, R. W., Wren, B. W., Wain, J., Pickard, D., Hien, T. T., Farrar, J. J., Dougan, G.
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