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Previous Article | Next Article 
Journal of Bacteriology, November 2001, p. 6215-6224, Vol. 183, No. 21
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.21.6215-6224.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Identification and Characterization of
Tn4656, a Novel Class II Transposon Carrying a Set of
Toluene-Degrading Genes from TOL Plasmid pWW53
Masataka
Tsuda* and
Hiroyuki
Genka
Department of Environmental Life Science,
Graduate School of Life Sciences, Tohoku University, Katahira
2-1-1, Sendai 980-8577, Japan
Received 2 February 2001/Accepted 28 July 2001
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ABSTRACT |
It has been reported that the toluene-degrading
(xyl) genes from Pseudomonas putida
plasmid pWW53 are able to translocate to broad-host-range drug
resistance plasmid RP4, and pWW53-4 is one of the smallest RP4
derivatives (H. Keil, S. Keil, R. W. Pickup, and P. A. Williams, J. Bacteriol. 164:887-895, 1985). Our
investigation of pWW53-4 in this study demonstrated that such a
translocated region that is 39 kb long is a transposon. This mobile
element, Tn4656, was classified as a class II transposon
since its transposition occurred by a two-step process: transposase
(TnpA)-mediated formation of the cointegrate and resolvase
(TnpR)-mediated site-specific resolution of the cointegrate at the two
copies of the res site. The Tn4656 TnpA and
TnpR functions encoded in the rightmost 4-kb region were found to be
exchangeable with those specified by other Tn1721-related
class II transposons, including another toluene transposon,
Tn4653. Sequence analysis of the transposition-related genes and sites of Tn4656 also supported the hypothesis
that this transposon is closely related to the
Tn1721-related transposons. The lower transposition
frequency of Tn4656 has been suggested to be due to the
unique nucleotide sequence of one of the terminal 39-bp inverted repeats.
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INTRODUCTION |
A number of environmental
bacterial strains that can use various kinds of xenobiotic compounds as
sources of carbon and energy have been identified. Very similar
catabolic gene clusters that are presumed to have common evolutionary
origins are distributed on a variety of plasmids and chromosomes of
phylogenetically divergent bacterial species (32, 35).
Many of these catabolic gene clusters also undergo various types of
rearrangements, including deletion, duplication, and fusion with other
replicons (32, 34). In the last two decades, it has been
demonstrated that some such gene clusters are located on transposons,
explaining the rearrangements of catabolic gene clusters, as well as
the wide dissemination and rapid evolution of the common catabolic
pathways in the environment (31). Many of the catabolic
transposons belong to the class I transposons in which some, but not
all, of the catabolic genes for complete degradation of xenobiotic
compounds are flanked by two copies of insertion sequences. In
contrast, only three class II (Tn3-like) catabolic
transposons have been identified in two self-transmissible and IncP-9
broad-host-range plasmids from two strains of Pseudomonas
putida (Fig. 1)
(27-30). Two of these transposons, Tn4651 (56 kb) and Tn4653 (70 kb), carry all the xylene- and
toluene-degrading (xyl) genes from a 117-kb plasmid, pWW0,
and the latter transposon includes the former (27, 28).
The third transposon, Tn4655 (38 kb), carries all the
naphthalene-degrading (nah) genes from an 83-kb plasmid,
NAH7 (29). The terminal sequence structures of the three
transposons have the properties commonly conserved in other class II
transposons. The tnpA gene product (transposase) of
Tn4651 or Tn4653 catalyzes formation of the
cointegrate of the donor and target replicons connected by two directly
repeated copies of the transposon, one at each junction.
Tn4655 forms the cointegrate only in the presence of TnpA
from Tn1721-related transposons, such as Tn4653
and Tn1722 (10, 29, 30). The tnpR
gene product (revolvase) of Tn4655 or the tnpS
and tnpT products of Tn4651 catalyze subsequent
site-specific resolution of the cointegrate between the two copies of
the resolution (res) site. However, Tn4653 and
Tn4655 are defective because they lack the res
site and the tnpA gene, respectively (29, 30).
Our detailed analyses of transposons Tn4651,
Tn4653, and Tn4655 and studies by other groups of workers have further revealed that (i) Tn4651 is a
member of a novel subgroup of the class II transposons that includes mercury transposon Tn5041 and (ii) Tn4655 has a
novel resolution system that is not functionally exchangeable with
those of other class II transposons (Fig. 1) (12, 15, 29;
Genka and Tsuda, unpublished results).
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FIG. 1.
Structures of class II catabolic transposons and related
transposons. See references 1, 7, 12, 16, 23, and 27 to 30 for details.
Symbols and abbreviations: solid arrowhead, terminal IR; open
arrowhead, IS1256 (21); open arrow,
IS26 (23); solid circle, res
site; solid half-circle, defective res site; A,
tnpA; R, S, and T, genes for cointegrate resolution;
nah, nah genes; xyl,
xyl genes; M and M1, meta catabolic
pathway operon; U, upper catabolic pathway operon; Hg, genes for
resistance to mercuric ion; Sm, gene for resistance to Sm; Su, gene for
resistance to sulfonamide; Tc, genes for resistance to Tc; Mcp, gene
encoding methyl-accepting chemotaxis protein. The arrow above or below
each gene or operon indicates the direction of transcription.
Tn4651 and Tn4653 are located on
pWW0, Tn4655 is located on NAH7, and
Tn4656 is located on pWW53-4. The upper pathway operons
encode the enzymes for conversion of toluene and xylenes to their
respective carboxylic acids in the case of the TOL plasmids and the
enzymes for conversion of naphthalene to salicylate in the case of
NAH7. The meta pathway operons are involved in
conversion of the final upper pathway products to catechol or its
methyl derivatives and then to central metabolites.
Tn4656 carries only one (M1) of the two
meta pathway operons of pWW53. The regulatory genes
xylS and xylR located downstream of the
xyl meta pathway operon and the regulatory gene
nahR located upstream of the nah meta
pathway operon are not shown. Previous papers have clarified (i) the
interchangeability of the TnpR functions among Tn21,
Tn1722, and Tn4653, (ii) the identity of
the amino acid sequences of the Tn4653 and
Tn1722 resolvases, (iii) the interchangeability of the
TnpA functions between Tn1722 and Tn4653,
and (iv) the cointegration of Tn4655 by the
Tn1722 or Tn4653 transposase (29,
30).
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To date, workers have described a number of TOL plasmids which carry at
least four xyl transcriptional units (the upper and meta pathway operons and the two regulatory genes,
xylR and xylS) that are strongly homologous to
those in pWW0 (4, 24, 34, 35). Many such TOL plasmids,
however, differ from pWW0 in terms of basic plasmid functions, such as
incompatibility and transmissibility, and in terms of copy number and
the relative positions of the four xyl units. For example,
pWW53 from P. putida MT53 is a nontransmissible 107-kb
plasmid that does not belong to the IncP-9 group (13). This plasmid carries a single upper pathway operon, two highly homologous but distinguishable meta pathway operons, a
single xylR gene, and three xylS-homologous genes
(xylS1, xylS2, and xylS3), and the
three operons with the same transcription direction are arranged in the
order meta operon I-xylS1-xylR-upper
operon-xylS3-meta operon II-xylS2
(2, 9, 13, 14, 20, 24). Keil et al. (13)
reported that the xyl gene clusters of pWW53 could be
inserted into a transmissible drug resistance plasmid, RP4. One of the
smallest hybrid plasmids is pWW53-4, which carries the pWW53-derived
fragment containing meta operon
I-xylS1-xylR-upper operon. However, the order of
the four xyl transcriptional units in pWW53-4 is different
from the order in Tn4651, and the remaining xyl
genes of pWW53 are not present in pWW53-4. It was expected that
elucidation of the molecular mechanism of formation of pWW53-4 should
provide some insight into the evolutionary mechanism that resulted in
the present organization of the xyl gene clusters in pWW53.
The transposability of the xyl gene cluster in pWW53-4 was
investigated in this study, and the results indicated that the
pWW53-derived xyl-containing region in pWW53-4 is a
transposon belonging to the Tn1721-related transposon group.
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and media.
The
Escherichia coli strains used were DH1 (recA1 endA1
gyrA96 thi-1 hsdR17 supE44 relA1) and HB101 (hsdS20 recA13
ara-14 proA2 lacY1 galK2 rpsL20 xyl-5 mtl-1 supE44)
(5). P. putida PaW611 is a PaW340
(Trp
Strr) derivative
carrying pWW53-4 (13). The plasmids used are listed in
Table 1. Routine cultivation of E. coli and P. putida cells was performed at 37 and
30°C, respectively. L broth (LB) was used as a liquid medium and was
solidified with 1.5% agar to obtain LB agar. When required,
antibiotics were added to the media at the following concentrations:
ampicillin, 50 µg/ml; chloramphenicol, 30 µg/ml; kanamycin, 50 µg/ml; nalidixic acid, 20 µg/ml; spectinomycin, 40 µg/ml;
streptomycin, 250 µg/ml; tetracycline, 10 µg/ml; and trimethoprim,
100 µg/ml.
DNA manipulation and construction of plasmids.
Established
procedures were used for preparation and manipulation of plasmid DNA,
agarose gel electrophoresis, and transformation of E. coli
cells (5).
Removal of the EcoRV fragment from pMT1209
(pMT258::Tn3) (30) gave rise to
pMT1214, which lacked the central part of the tnpA gene of
Tn3. The EcoRI-flanked 
fragment from pHP45
(8) was inserted into the EcoRI site of pBR322
(33). Subsequent excision of the fragment by
SmaI digestion led to construction of pMT266, in which the
unique EcoRI site of pBR322 was converted to
EcoRI-SmaI-EcoRI sites. pMT2890 (Fig.
2A) is a pMT258 derivative carrying
Tn4656-2890, a Tn4656 derivative in which all the
internal BamHI fragments are replaced by the
BamHI-flanked Kmr gene from pRME1
(11). Tn4656-2890 was transposed to R388 to construct pMT2916 (Table 1), and pMT2916 was then used as the donor
replicon to transpose Tn4656-2890 to pMT252. The resulting plasmid, pMT2923 (Fig. 2), was digested with KpnI, ligated,
and used to transform DH1 to select Tcr
Kmr clones. One such clone carried pMT2926
(pMT252::Tn4656-2926), in which the
Tn4656 DNA fragment between the leftmost BamHI
site and the rightmost KpnI site was replaced by the
Kmr gene. Removal of the
Kmr gene from pMT2926 by KpnI
digestion generated pMT2925 (pMT252::Tn4656-2925) (Fig. 2 and 3). Removal of some
restriction fragments from pMT2926 resulted in formation of pMT2939,
pMT2944, pMT2946, pMT2947, and pMT2948, while insertion of the
pUC4K-derived Kmr gene into some restriction
sites in pMT2525 gave rise to pMT2931, pMT2932, pMT2933, and pMT2937
(Fig. 3). pMT2827 (pMT266tet::Tn4656) (Table 1) was completely digested with HindIII, and the
plasmid portion was ligated with the HindIII-flanked
Kmr gene from pRME1. Digestion of the resulting
plasmid, pMT3019, with KpnI and subsequent self-ligation
gave rise to pMT3020, which contained only the Tn4656
fragment located downstream of the rightmost KpnI site (Fig.
4). Removal of the EcoRI
fragment containing the 5' part of tnpR from pMT3020
generated pMT3030, while removal of the two NruI fragments
containing most of the tnpA gene generated pMT3041 (Fig. 4).
Partial NruI digestion of pMT3030 and subsequent ligation
led to construction of pMT3031 and pMT3032, and removal of a unique
NcoI fragment from pMT3041 gave rise to pMT3042. Insertion of the pUC4K-derived Kmr gene into a certain
restriction site in pMT3030 or pMT3041 generated pMT3034, pMT3035,
pMT3036, pMT3043, or pMT3045 (Fig. 4).
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FIG. 2.
Structures of Tn4656 and its deletion
derivatives. Abbreviations for restriction sites: B,
BamHI; E, EcoRI; H,
HindIII; K, KpnI, S, StuI;
and Sm, SmaI. (A) Tn4656 and its large
deletion derivatives. The location of the xyl genes is
based on information from reference 13. A horizontal arrow indicates
the direction of transcription of a gene or operon, and the vertical
arrows indicate the outermost BamHI sites and the
rightmost HindIII and KpnI sites. The
res site located upstream of the tnpR
gene is not shown for the sake of simplicity. The deleted fragment
represented by a thin line was replaced by the pRME1-derived
Kmr gene. Tn4656-2926 is loaded on pMT252,
and the remaining three Tn4656 derivatives are loaded on
pMT258. For details concerning construction of the plasmids, see Table
1 and Materials and Methods. The transposition frequency is expressed
as the number of Kmr transconjugants per Tpr
transconjugant. (B) Construction of the Tn4656-2890
derivatives. Abbreviations: IRL and IRR, left and right IRs,
respectively. The derivatives are not drawn to scale. Construction of
pMT2923 from pMT2890 via pMT2916 as an intermediate is described in
Materials and Methods. The open and shaded boxes represent the
pRME1-derived fragment and the fragment deleted in the descendant
transposon, respectively. Note that only the relevant restriction sites
derived from pRME1 are shown for the sake of simplicity. The
restriction sites in parentheses are not digested by
SmaI or StuI.
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FIG. 3.
Localization of transposition-related genes and sites of
Tn4656. The abbreviations for restriction sites are the
same as those described in the legend to Fig. 2 except as follows: N,
NruI; Nc, NcoI; and P,
PvuII. The following symbols and other abbreviations are
used in the Tn4656-2925 map: IRL and IRR, left and right
IRs, respectively; arrow, direction of transcription; arrowhead,
resolution site; thick vertical line, nucleotide sequence that connects
the leftmost BamHI site and the rightmost
KpnI site of Tn4656 (Fig. 2B). Plasmids
pMT2939, pMT2944, pMT2946, pMT2947, and pMT2948 are deletion
derivatives of pMT2926 (Fig. 2B), whereas pMT2931, pMT2932, pMT2933,
and pMT2937 are pMT2925 derivatives with an insert of the
Kmr gene from pUC4K. See Fig. 2B for construction of
pMT2939. The open bars and thin lines in the transposons indicate the
DNA fragments that are present and absent, respectively, and the open
and solid triangles indicate the Kmr genes from pRME1 and
pUC4K, respectively. +, transposon is able to cointegrate or
resolve;  , transposon is not able to cointegrate or resolve; NA, not
applicable. When a minitransposon was defective in either the
cointegration function or the resolution function or both,
complementation in the presence of pMT3020 (Fig. 4) was examined. The
results obtained in the absence and in the presence of pMT3020 are
shown before and after the slash, respectively.
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FIG. 4.
pMT266 derivatives carrying tnpA
and tnpR genes of Tn4656. The
abbreviations for restriction sites are the same as those described in
the legends to Fig. 2 and 3. (A) Construction of the pMT2827
derivatives. The derivatives are not drawn to scale. The thin line
indicates the pMT266 portion. The open and shaded boxes represent the
pRME1-derived fragment and the fragment deleted in the descendant
plasmid, respectively. (B) Localization of tnpA and
tnpR on pMT3020. Only the Tn4656 portion
is shown. Plasmids pMT3031, pMT3032, pMT3034, pMT3035, and pMT3036 are
derived from pMT3030, and plasmids pMT3042, pMT3043, and pMT3045 are
derived from pMT3041. The thin lines and solid triangles in the pMT3020
derivatives represent the deleted fragment and the insert of the
pUC4K-derived Kmr gene, respectively. Note that deletions
in pMT3032, pMT3041, and their derivatives extend to the unique
NruI site in the pMT266 portion. pMT3020 and its
derivatives were examined to determine their ability to complement the
defect in cointegration of Tn4656-2939 and the defects
in resolution of the Tn4656-2944- and
Tn4656-2948-mediated cointegrate (Fig. 3 and 5). For an
explanation of the plus and minus signs see the legend to Fig. 3. NT,
not tested.
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Transposition assays.
Transposition of various transposon
derivatives was investigated by performing mating-out
experiments (27). A DH1 derivative harboring a
transmissible and transposon-free plasmid, R388 (6), was
transformed with a pACYC184-based plasmid containing an appropriate transposon derivative. The resulting transformant was employed as the
donor to mate with HB101 on a membrane filter, and
Smr transconjugants which also exhibited
resistance to the marker specified by either the transposon or the
pACYC184-based plasmid were selected. Such transconjugants were
analyzed to determine their plasmid profiles. To complement the defect
of the cointegration function of a transposon derivative in the
pACYC184-based plasmid, a pBR322-based plasmid carrying a relevant
tnpA gene was introduced into the donor strain described
above. To characterize the defect in the cointegrate resolution
function, the stable cointegrate of a pACYC184-based plasmid and R388
connected by the mutant transposon was transferred to the DH1
derivative that harbored a pBR322-based plasmid having a relevant
resolvase gene. After overnight cultivation of the resulting strain in
LB, the stability of the cointegrate was investigated by physical and
genetical detection of the replicons resolved (27).
Nucleotide sequence analysis.
The DNA fragments cloned in
pUC18 and pUC19 were sequenced with an ABI 373S automated DNA sequencer
(Applied Biosystems Inc.) by using the protocols recommended by the
manufacturer. A computer analysis of the sequences was performed with
the software programs GENETYX 10 (SDC Inc., Tokyo, Japan) and BLAST 2.0 (National Institute of Genetics, Mishima, Japan).
Nucleotide sequence accession numbers.
The nucleotide
sequences of Tn4656 described in this paper have been
deposited in DDBJ/EMBL/GenBank under accession numbers AB052614 (left
end), AB052615 (right end), AB052616 (res-tnpR), and AB062597 (res-tnpR-tnpA-right end).
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RESULTS |
Identification of Tn4656.
After transfer of
pWW53-4 from PaW611 to E. coli, the transposability of the
xyl genes was investigated by using pMT258 as a target
replicon. Mating of DH1(pWW53-4)(pMT258) with HB101 gave rise to
Cmr transconjugants at frequencies of
approximately 5.0 × 104 transconjugant
per recipient cell. All 100 transconjugants examined carried pMT258
derivatives with an insert of Tn1, an RP4-specified transposon that is nearly identical to Tn3
(25). To reduce the undesirable transposition of
Tn1, pMT1214
(pMT258::Tn3
tnpA) was employed as
the target replicon; we expected that this plasmid with Tn3
ends would be, due to transposition immunity (10, 25), much less available for insertion of the closely related transposon. Use of pMT1214 indeed led to a 100-fold decrease in the frequency of
formation of the Cmr transconjugants. Although 95 to 98% of the transconjugants still contained the
pMT1214::Tn1 plasmids, the remaining
transconjugants contained pMT1214 derivatives carrying the insert
consisting of a 39-kb fragment. Restriction analysis indicated that the
insert carried the xyl gene clusters present in pWW53-4.
This 39-kb fragment was designated Tn4656 because of its
ability to retranspose into various sites on other replicons in
a recA-independent manner.
Various internal fragments of Tn4656 in pMT252 and pMT258
were replaced by the pRME1-derived Kmr gene, and
transposition of the resulting Tn4656 derivatives was examined by using R388 as the target replicon (Fig. 2). Deletion of the
internal fragment of Tn4656 between the leftmost
BamHI site and the rightmost KpnI site had no
effect on transposition. Approximately 80 to 90% of the
Kmr transconjugants obtained in the cross between
DH1(pMT2926)(R388) and HB101 were sensitive to tetracycline and
harbored only the R388::Tn4656-2926 plasmids.
The remaining transconjugants showed resistance to tetracycline, and
cleared lysate prepared from each transconjugant contained the
three types of plasmids (pMT2926, R388::Tn4656-2926, and the cointegrate of
the donor and target plasmids connected by two copies of the
transposon), one at each junction. Such cointegrates were structurally
unstable and efficiently resolved to the first two types of plasmids.
This suggested that Tn4656 transposition occurred via
formation of the cointegrate as the intermediate, and the results of
the experiments described below supported this suggestion.
Analysis of the DNA regions necessary for transposition.
Tn4656-2925 and Tn4656-2926 in pMT252 were
subjected to insertion and deletion mutagenesis (Fig. 3). The
transposon derivatives having mutations in the rightmost 3-kb region
(i.e., the transposon derivatives in pMT2933, pMT2937, pMT2939,
pMT2644, pMT2946, and pMT2947) could not form cointegrates with R388;
however, except for the defect of Tn4656-2933 in pMT2933,
the defects were restored in the presence of pMT3020, a pMT266-based
plasmid carrying the rightmost 4.1-kb fragment of Tn4656
(Fig. 4). Tn4656-2933, which had an insert of the
Kmr gene at the rightmost EcoRI site,
could not transpose even in the presence of pMT3020, indicating
that there was a requirement in cis of this EcoRI
site for cointegration (Fig. 3). Next, various derivatives of pMT3020
(Fig. 4) were examined to determine their ability to restore the
cointegration defect of Tn4656-2939 in pMT2939 (Fig. 3), and
a trans-acting cointegration (i.e., TnpA) activity
was found in the rightmost 3.0-kb EcoRI fragment in pMT3030.
The cointegrates formed by the minitransposons in pMT2932,
pMT2939, pMT2944, pMT2947, and pMT2948 were stable, and these
Tn4656 derivatives had defects in the region between the
KpnI site and the middle EcoRI site (Fig. 3). All
of these stable cointegrates except that formed by
Tn4656-2939 in pMT2929 resolved to the final transposition
products in the presence of pMT3020 and its deletion derivative,
pMT3041 (Fig. 3 to 5). This indicated
that the 1.4-kb KpnI-NruI fragment in pMT3041
encodes a trans-acting resolution (i.e., TnpR) activity. The
pMT3041 derivative lacking the 0.32-kb NcoI fragment
(pMT3042) and the derivatives carrying an insert of a
Kmr fragment at the PvuII and
EcoRI sites (pMT3043 and pMT3045, respectively) did not have
the TnpR activity (Fig. 4 and 5). The ability of pMT3041 to resolve the
Tn4656-2944- and Tn4656-2948-mediated
cointegrates and its inability to resolve the
Tn4656-2939-mediated cointegrate also indicated that the
cis-acting (res) site required for cointegrate resolution was located in the 0.52-kb KpnI-NcoI
fragment (Fig. 3 and 4B).
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FIG. 5.
Resolution of stable cointegrates. Plasmid
pMT2978, a cointegrate formed by R388 and pMT2944 (=
pMT252::Tn4656-2944), was
transferred to DH1(pMT3041) and DH1(pMT3042). After overnight
cultivation of the resulting strains in LB, the plasmids in the cleared
lysate prepared from each strain were analyzed by electrophoresis in a
0.6% agarose gel. The figure is a negative of a photograph of the
ethidium bromide-stained gel. Lane 1, lysate from
DH1(pMT2978)(pMT3041); lane 2, lysate from
DH1(pMT2978)(pMT3042). R388::Tn,
R388::Tn4656-2944; Chr., chromosomal DNA.
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Complementation of transposition functions by other
transposons.
The genetic analysis described above clearly
indicated that Tn4656 belongs to the class II transposons.
We next investigated the exchangeability of the cointegration and
resolution functions of Tn4656 with those of other class II
transposons, including Tn3, Tn21,
Tn1722, Tn4651, Tn4653, and
Tn4655 (1, 7, 16, 29, 30). The
Tn4656-specified resolution function could be efficiently
exchanged with the resolution functions of Tn21,
Tn1722, and Tn4653 but could not be exchanged at
all with the resolution functions of Tn3, Tn4651,
and Tn4655 (data not shown). The Tn4656-specified TnpA function could not be exchanged with the TnpA function of Tn3, Tn21, or Tn4651 (data not shown).
The wild-type tnpA gene of Tn4656 could
complement the tnpA defects of Tn4653,
Tn1722, and Tn4655, while the tnpA
defect of Tn4656 was complemented by the wild-type
tnpA genes of Tn4653 and Tn1722 (Table
2). It was noteworthy that the wild-type
tnpA genes of Tn4656, Tn4653, and Tn1722 complemented the tnpA mutations of
Tn4653, Tn1722, and Tn4655 at
frequencies more than 10-fold higher than the frequencies at which they
complemented the tnpA mutation of Tn4656.
Sequence analysis of Tn4656.
Analysis of the
insertion sites of Tn4656 in pMT252 and pMT258 showed that
insertion led to a 5-bp duplication of the target sequences (data not
shown). The left and right terminal sequences of Tn4656 form
39-bp inverted repeats (IRs) with 12-bp mismatches and exhibit high
levels of homology with the terminal sequences of the
Tn1721-related transposons Tn4653,
Tn1404, Tn501, Tn1722, Tn1720, and Tn4655 (Fig.
6) (1, 7, 10, 23, 29, 30). The sequence homology of the left extremity of Tn4656 with
the left extremities of the Tn1721-related transposons was
limited to the external 38-bp IR regions. In contrast, the rightmost
4,094-bp region of Tn4656 (AB062597) exhibited extensive
sequence homology with the rightmost regions of the
Tn1721-related transposons, and the 3,573-bp sequence of the
right extremity of Tn4656 (the downstream region starting
from base position 522 in Fig. 7)
exhibited a very high level of homology (91%) with the sequences of
the tnpR-tnpA-right IR regions of Tn501 and
Tn1722 (1, 7). The right region of this
sequence was occupied by a large open reading frame (ORF) that encoded
a 988-amino-acid protein, and this ORF started with the canonical ATG
codon and terminated in the right IR. The amino acid sequence of the
predicted protein also exhibited 96% identity with the amino acid
sequences of the Tn501 and Tn1722 TnpA proteins
and 72% identity with the amino acid sequences of the TnpA proteins of
the Tn21-related transposons Tn21 and
Tn5036 (16, 37). A comparison of these sequence
data and successful genetic complementation of the tnpA
genes between Tn4656 and Tn1722 (see above)
supported the hypothesis that the large ORF of Tn4656 is the
tnpA gene.
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FIG. 6.
Comparison of the ends of Tn4656-related
transposons. The left (L) and right (R) ends of each transposon are
defined as the ends distal and proximal, respectively, to the
tnpA gene (Fig. 1). The Tn4656 sequences
determined in this study are the leftmost 498-bp fragment (AB052614)
and the rightmost 4,094-bp fragment (AB062597). The outermost 60 nucleotides of Tn4656 are shown together with the
nucleotides of other related transposons (1, 7, 23, 29,
30). The nucleotides in the IRs are indicated by uppercase
letters. Differences in the sequences of pairs of IRs in
Tn4656 are indicated by asterisks, whereas sequence
identities for pairs of IRs in each of the other transposons are
indicated by dashes in the right IR. The arrows indicate the 3' part of
the tnpA gene, and the EcoRI site is
indicated by lines.
|
|
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FIG. 7.
Comparison of res-containing regions of
Tn4656-related transposons. Sequence data were obtained
in this study (AB062597) and from references 1, 7, 16, 23, and 30. The
numbers on the right are the base positions; the upstream
KpnI site (Fig. 3) was defined as position 1. The dots
represent nucleotides identical to nucleotides of
Tn4656, whereas the dashes represent gaps that result in
maximum matching. Three putative resolvase-binding sites are enclosed
in boxes, and the putative crossover point based on the data for
Tn1722 (22) is indicated by a vertical
arrow. Note that Tn1404 and Tn4653 are
defective in cointegrate resolution because of a lack of crossover
points (23, 30). The predicted start of the Tn4656
tnpR gene is indicated by a horizontal arrow, and the predicted
promoter and ribosome-binding (SD) sequences for the
tnpR gene are overlined. The ATG codon of
Tn4656 mentioned in the text and the NcoI
site are underlined.
|
|
In the 4,094-bp sequence there were also two overlapping ORFs; these
two ORFs started at nucleotide positions 477 (ATG) and 531 (TTG), and
both terminated at the stop codon 6 bp upstream of the tnpA
gene. The TTG start codon, but not the ATG codon, was preceded
by a typical Shine-Dalgarno sequence (Fig. 7). It is very likely, but
has not been proven, that the latter ORF, which gives rise to a protein
with 186 amino acids, encodes the resolvase. The deduced amino acid
sequence of the predicted resolvase exhibits extensive homology with
the deduced amino acid sequences of the resolvases of the
Tn1721-related transposons (Tn501,
Tn1722, and Tn4653; 93 to 95% identity)
(1, 7, 30) and the Tn21-related transposons
(Tn21, Tn5036, and Tn5059; 81 to 83%
identity) (16, 18, 37). At the DNA level, the Tn4656
tnpR gene is 87% identical to the tnpR genes of the
former three transposons and 73 to 77% identical to the
tnpR genes of the latter three transposons. The 5' upstream
regions of the tnpR genes of all of these related transposons except Tn4653 carry the res sites,
and each res site is made up of the three resolvase-binding
domains (sites I, II, and III) that contain the crossover point for
cointegrate resolution and 35 and 10 sequences of the
tnpR promoter, respectively (Fig. 7) (1, 7, 16,
22). Nucleotide sequences that are 128 bp long and are highly
homologous to these three domains with appropriate spacers are located
in the region approximately 70 bp upstream of the tnpR start
codon of Tn4656. Although no additional biochemical
experiments were carried out with respect to the Tn4656 res
site, it is very probable based on the exchangeability of the
resolution functions between Tn4656 and Tn1722
(see above) that the 128-bp sequence of Tn4656 has
functional domains and a crossover point identical to those determined
experimentally for the Tn1722 res site (22).
The 330-bp sequence upstream of site I of Tn4656
exhibited no similarity to nucleotide sequences in the databases.
| |
DISCUSSION |
In this paper we describe a fourth class II catabolic transposon,
Tn4656, residing in pWW53-4. Successful identification of this transposon depended on using transposition immunity, by which undesirable transposition of another pWW53-4-specified transposon, Tn1, was greatly suppressed. Structural and functional
analyses of Tn4656 clearly demonstrated that this transposon
is a member of the Tn1721-related transposon group (Fig. 1).
However, the transposition frequency of Tn4656 was lower
(<10-fold) than those of Tn1722 and Tn4653
(27, 28, 30). The lower frequency of transposition
of Tn4656 is attributed to the sequences of its IRs and not
to the sequence of the transposase because the Tn4656 transposase catalyzed cointegration of the tnpA mutants of
Tn4653, Tn1722, and Tn4655 at
frequencies that were more than 10-fold higher than the frequency of
cointegration of the tnpA mutant of Tn4656 (Table
2). Although the nucleotides at positions 12 to 38 in the right IR of
Tn4656 are essentially identical to those conserved in the
IRs of other Tn1721-related transposons (Fig. 6) (1,
7, 10, 23, 29, 30), the conserved nucleotides are different at
eight positions in the left IR of Tn4656. Except for the
left IR of Tn4656, at least a five-base A stretch from position 22 to position 26 is conserved in the
Tn1721-related transposons, and the heptanucleotide ACGNTAAG
at positions 31 to 38 is conserved in the IRs of the class II
transposons (10, 25). Mutational analyses of the 38-bp IRs
of Tn3 and Tn1000 have indeed indicated that the
base pair changes in the heptanucleotide lead to more-than-100-fold
reductions in the cointegration frequencies (17, 19).
Taking these facts into consideration, we suggest that either or both
of the trinucleotides TTT (positions 24 to 26) and TAC (positions 33 to
35) in the left IR of Tn4656 are probably responsible for
the relatively lower cointegration frequency of Tn4656,
although no further experiments were carried out in this study.
Catabolic transposons Tn4653 and Tn4655 belong to
the Tn1721-related transposon group (Fig. 1). It has been
proposed that these transposons became established after various kinds
of unknown genetic rearrangements, even rearrangements in the
transposition-related genes themselves (27-31).
Tn4653 has a defect in its res site and contains
another class II catabolic transposon, Tn4651, that is clearly distinct from the Tn1721-related transposons. It is
thought that Tn4655 lost the res-tnpR-tnpA region
of the Tn1721-related transposons and acquired the region
encoding a new site-specific resolution system before establishment of
the present structure. Therefore, Tn4653 and
Tn4655 might be less suitable for investigating the putative
molecular mechanisms of incorporation of the catabolic genes in the
common ancestral transposon. Tn4656, in contrast, has the
simple organization of the transposition-related genes, and use of this
transposon might help clarify the diversification of the
non-transposition-related genes in the Tn1721-related transposons.
Detailed characterization of the pWW53-specified xyl genes
has been initiated by the pioneering work of Williams' group through translocation of the xyl genes of this plasmid to coresident
plasmid RP4 in order to obtain RP4 derivatives carrying at least a set of xyl genes for complete degradation of toluene and xylenes
(13). We are very interested in such RP4 derivatives for
the following two reasons. The first is that the physical map of
pWW53-4 reported by Keil et al. (13) appears, in our
hands, not to cover the 4-kb DNA segment of Tn4656 that
includes the res-tnpR-tnpA-IR fragment
(our unpublished data). More detailed comparisons of physical maps of
pWW53, pWW53-4, and Tn4656 should reveal the location of the
4-kb segment in the original host strain carrying pWW53 and should
provide some clues for understanding the formation of Tn4656
from pWW53. The second reason is that the pWW53-derived insert in
pWW53-4 has been reported to be the smallest fragment among the
fragments translocated into RP4. We are also trying to detect various
transposable regions of pWW53 by using a transposon-free and
broad-host-range plasmid as a target replicon.
At a position downstream of xylS2, pWW53 carries a gene
encoding a putative site-specific resolvase that exhibits high levels of homology with the enzymes specified by several plasmids and the
class II transposons (3). The pWW53 resolvase (PWW53RES) gene is, however, clearly distinguishable from the Tn4656
tnpR gene in terms of the nucleotide sequence. These facts mean
that PWW53RES is not involved in Tn4656 transposition at
all. However, it would be interesting to know whether PWW53RES plays
some role in formation of Tn4656 from pWW53, although the
function of PWW53RES remains to be investigated.
For a long time the xyl operon organization of pWW53,
meta operon I-upper operon-meta operon II, has
been considered to be exceptional and unique. However, Sentchilo et al.
(23) have recently reported that such an organization is
not unusual, at least in the Pseudomonas TOL plasmids from
Belarus. In spite of relatively minor structural diversity (i.e.,
insertion and deletion of small DNA fragments) in the xyl
operons, these TOL plasmids have much more diversity, especially in the
regions located outside the catabolic operons. The diversity includes
differences in size, self-transmissibility, and incompatibility of the
plasmids. Our identification of Tn4656 in pWW53 may also
explain (as one possible mechanism) the structural diversity of the
Belarus TOL plasmids.
| |
ACKNOWLEDGMENTS |
We are grateful to P. A. Williams, who kindly provided
pWW53-4. We also thank M. Sota for determining nucleotide sequences.
This work was supported by a Grant-in-Aid for Scientific Research from
the Ministry of Education, Science, Sports, and Culture, Japan.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Environmental Life Science, Graduate School of Life Sciences, Tohoku University, Katahira 2-1-1, Sendai 980-8577, Japan. Phone:
81-22-217-5699. Fax: 81-22-217-5699. E-mail:
mtsuda{at}ige.tohoku.ac.jp.
| |
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Journal of Bacteriology, November 2001, p. 6215-6224, Vol. 183, No. 21
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.21.6215-6224.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
