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Journal of Bacteriology, August 1999, p. 4937-4948, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Excision of IS492 Requires Flanking Target Sequences
and Results in Circle Formation in Pseudoalteromonas
atlantica
Donna
Perkins-Balding,1
Guy
Duval-Valentin,2 and
Anna C.
Glasgow1,*
Department of Microbiology and Immunology,
Emory University School of Medicine, Atlanta, Georgia
30322,1 and Laboratoire de
Microbiologie et Génétique Moléculaire du CNRS, 31062 Toulouse, France2
Received 25 March 1999/Accepted 3 June 1999
 |
ABSTRACT |
The gram-negative marine bacterium Pseudoalteromonas
atlantica produces extracellular polysaccharide (EPS) that is
important in biofilm formation by this bacterium. Insertion and precise excision of IS492 at a locus essential for extracellular
polysaccharide production (eps) controls phase variation of
EPS production in P. atlantica. Examination of
IS492 transposition in P. atlantica by using a
PCR-based assay revealed a circular form of IS492 that may
be an intermediate in transposition or a terminal product of excision.
The DNA sequence of the IS492 circle junction indicates that the ends of the element are juxtaposed with a 5-bp spacer sequence. This spacer sequence corresponds to the 5-bp duplication of
the chromosomal target sequence found at all IS492
insertion sites on the P. atlantica chromosome that we
identified by using inverse PCR. IS492 circle formation
correlated with precise excision of IS492 from the P. atlantica eps target sequence when introduced into
Escherichia coli on a plasmid. Deletion analyses of the
flanking host sequences at the eps insertion site for
IS492 demonstrated that the 5-bp duplicated target sequence
is essential for precise excision of IS492 and circle
formation in E. coli. Excision of IS492 in
E. coli also depends on the level of expression of the putative transposase, MooV. A regulatory role for the circular form of
IS492 is suggested by the creation of a new strong promoter for expression of mooV by the joining of the ends of the
insertion sequence element at the circle junction.
| |
INTRODUCTION |
IS492 is a 1.2-kb
multicopy insertion sequence (IS) found in the gram-negative marine
bacterium Pseudoalteromonas atlantica (3).
Insertion and precise excision of IS492 at an essential locus for extracellular polysaccharide (EPS) synthesis (eps)
is associated with phase variation of EPS production in P. atlantica (2). The ability of P. atlantica
to switch the adhesin EPS on and off is important in the life cycle of
this biofilm-forming bacterium, which moves from solid surfaces (such
as seaweed or sand) to the open ocean and then back to a solid
substrate to initiate a new biofilm (6, 7). Southern blot
analysis performed by Bartlett et al. (2) on chromosomal DNA
from EPS phase variants of P. atlantica indicated that
excision of IS492 from the eps locus does not
result in insertion of IS492 at a new site in the chromosome. Therefore, precise excision of IS492 from
eps is not associated with replicative transposition of
IS492 or with a cut-and-paste mechanism for transposition in
which excision is directly linked to insertion at a new site. Instead,
the result of the Southern analysis suggests that precise excision
results in loss of the element or that the element moves into an
extrachromosomal form.
IS492 is a member of the IS110-IS492
family of insertion elements, a group recognized as atypical in several
aspects (for a review, see reference 19). Its
members have either extremely small or no terminal inverted repeats,
and many do not create target site duplications upon insertion. The
transposases for this family, including MooV (for mover of
IS492 in oceanic variants) from IS492, are also
unusual. These transposases have homology with each other and with the
novel site-specific DNA invertase Piv from Moraxella
lacunata and Moraxella bovis (16). Despite the homology with Piv, there is no shared catalytic amino acid motif
with the site-specific DNA recombinases of the 
Int and Hin-resolvase families (for a review, see reference 23). In addition,
it is not apparent that the DNA recombinases of the IS110-IS492 family contain the DDE motif, which
is the most common catalytic motif of the characterized
transposases-phosphoryltransferases from eukaryotes and prokaryotes
(for reviews, see references 8 and
19). These combined unique aspects suggest that the
transposases from the IS110-IS492 family of
insertion elements use a different catalytic mechanism than previously
characterized for transposases and warrant further investigation.
In the work presented here, we have focused on the excision reaction of
IS492 transposition. A circular product of IS492
excision can be detected by PCR analysis at low levels in P. atlantica and in an Escherichia coli model system. Both
excision and formation of the circular product are dependent on the
transposase MooV. Determination of the requirements for and
consequences of IS492 precise excision and circle formation
suggests that circularization of the element plays a regulatory role in
IS492 transposition. Surprisingly, these analyses also
revealed that the target sequence that is duplicated upon insertion of
IS492 is required for excision of IS492 in
E. coli.
| |
MATERIALS AND METHODS |
Bacterial strains.
P. atlantica DB27 was a gift from
D. Bartlett (2, 3). P. atlantica 19262, 43666, and 43667 (7, 36); Pseudoalteromonas espejiana
29659 (5); and Pseudoalteromonas haloplanktis
14393 (26) were obtained from the American Type Culture
Collection (ATCC). E. coli Inv
F' [F'
(
80lacZ
M15) endA1 recA1 hsdR17 supE44 thi-1
gyrA96 relA1 (lacZYA-argF)U169]
(Invitrogen), TOP10 [F
mcrA
(mrr-hsdRMS-mcrBC) 80lacZM15
lacX74 deoR recA1 araD139 (ara-leu)7697 galU galK rpsL(Strr)
endA1 nupG] (Invitrogen), DH5
[(80lacZM15) supE44 lacU169 hsdR17 recA1
endA1 gyrA96 thi-1 relA1] (obtained from C. Moran), and
HMS174(DE3) [(DE3) recA1 hsdR rifR] (Novagen) were used
as hosts for IS492-containing plasmids and MooV expression
vectors. E. coli MC1061(recA) [hsdR
araD139 (araABC-leu)7679 lacX74 galU galK
rpsL thi recA] (ATCC) and DH5 were used for circle promoter studies.
Media, reagents, and enzymes.
All E. coli strains
were grown on Luria-Bertani (LB) agar (Difco).
Pseudoalteromonas strains were cultured on Difco 2216 marine agar at 75% of the recommended concentration (4). The
following drug concentrations were used for plasmid selection and
maintenance: ampicillin at 80 or 100 µg/ml, chloramphenicol at 50 or
80 µg/ml, tetracycline at 12.5 µg/ml, and streptomycin at 25 µg/ml. When indicated,
5-bromo-4-chloro-3-indolyl-
-D-galactoside (X-Gal) (40 µl of a 40-mg/ml solution) was spread onto plates. All chemicals were purchased from Sigma Chemical Co. Restriction enzymes, T4 DNA
ligase, and Klenow DNA polymerase were purchased from New England
Biolabs. Sequenase, dideoxynucleotides, and deoxynucleotides were
purchased from Amersham, and [-32P]dATP was purchased
from Dupont NEN. Pfu DNA polymerase used in PCR was obtained
from Stratagene. Oligonucleotides were purchased from Gibco-Bethesda
Research Laboratories.
Plasmids and plasmid constructions.
The sequences of all
oligonucleotides utilized in this work are listed in Table
1. All constructs created with
PCR-amplified DNA fragments were sequenced to determine that there were
no PCR-generated mutations. Cosmids pDB200
(eps+) and pDB440
(eps::IS492) were gifts from D. Bartlett and were previously described (2). IS492
was amplified by PCR from pDB440 by using oligonucleotides 1 and 2 and
cloned into the TA cloning vector pCR2.1 (Invitrogen), resulting in
pAG949. A mooV mutant derivative of pAG949, pAG957, was
constructed by removing the 357-bp MfeI fragment of
IS492 and replacing it with an 884-bp DNA fragment
containing the chloramphenicol acetyltransferase gene (cam);
the cam fragment was PCR amplified from pACYC184 with oligonucleotides 3 and 4, encoding the MfeI sites to
facilitate cloning. Both IS492 and
IS492mooV::cam were subcloned from
pAG949 and pAG957, respectively, as BamHI-to-XhoI
fragments into the BamHI-to-XhoI region of
low-copy-number plasmid pACYC177, to generate pAG956 and pAG959.
Multiple plasmids were constructed for MooV overexpression. The MooV
protein with a carboxyl-terminal His
6 tag was created
by
PCR amplifying
mooV from pDB440 with oligonucleotides 5 and
6, containing
NdeI and
XhoI restriction sites,
respectively, for
cloning into the polylinker of pET21-a (Novagen),
forming pAG921.
Derivatives of pAG921 were made in order to change
antibiotic
resistance or to obtain compatibility with other plasmids
used
in this study: (i) pAG922 was constructed by deleting the
PstI-to-
DraIII
region of pAG921, containing the
-lactamase gene (
bla), followed
by replacement with the
tetM gene from Tn
916, which was PCR amplified
from pAM120 (
12), with oligonucleotides 24 and 25, and (ii)
pAG954 was constructed by removing the
PstI-to-
BspLUII1 region
of pAG922, containing the
ColE1
ori, and replacing it with the
PstI-to-
BspHI region of pACYC177, containing the
p15a
ori. A pET21-a
derivative, pAG1300 (
32),
containing the site-specific recombinase
gene,
piv, from
M. lacunata was modified in the same fashion as
pAG921 to
create pAG955. pMalE-MooV, which expresses a translational
fusion of
malE (maltose binding protein [MBP] gene) to the 5'
end of
mooV, was created by cloning a PCR-generated fragment from
pDB440 (by using oligonucleotides 7 and 8), containing
mooV
and
the correct cloning sites, into the
XmnI-to-
HindIII region of
pMal-C2 (New
England Biolabs). The wild-type MooV (nonfusion)
protein was expressed
from pAG900, which has
mooV under control
of the
tac promoter and with its own Shine-Dalgarno sequence in
plasmid pKH197 (generously provided by K. Hughes; pKH197 is a
derivative of pKH66 [
14], having one
BamHI
site upstream from
the
tac promoter filled in and
religated); the
BamHI-to-
HindIII
region of
pKH197 containing the
hin recombinase gene was replaced
by a
fragment containing
mooV, generated by PCR with
oligonucleotides
8 and 9 and
pDB440.
Two circle junction
lacZ fusions were constructed: (i) the
multicopy plasmid pDV6 is a derivative of pCB267 (
28) with
the
BamHI-to-
XbaI region replaced by annealed
oligonucleotides 10
and 11, which span the IS
492 junction,
and (ii) the single-copy
plasmid pAG967, derived from pNN387
(
9), contains the IS
492 circle junction flanked
by 203 bp of the right-end sequence and
66 bp of the left-end sequence
of IS
492; this 274-bp sequence
was obtained as a
HindIII-to-
NotI restriction fragment from
pAG952.1
(described below) and cloned into the
HindIII-to-
NotI region of
pNN387. Plasmid
pAG952.1 is a pCR2.1 (Invitrogen) derivative containing
a 400-bp PCR
fragment insert which was amplified from
P. atlantica lysates with IS
492-complementary oligonucleotides
(oligonucleotides
12 and 13) with their 3' extendable ends in opposite
directions
(see Results). Constitutive
lacZ control plasmids
were also constructed.
The constitutive
lacUV5 promoter was
cloned into the
SmaI site
of pCB267 by using annealed
oligonucleotides 30 and 31, generating
pDV5. A constitutive
tac promoter, with all regulatory elements
deleted, was
subcloned from pNN396 (
9) as a
NotI-to-
HindIII
fragment into the
NotI-to-
HindIII region of pNN387
(
9), to
generate
pAG620.
An IS
492 target site mutant was created by first generating
a DNA fragment containing the full IS
492 sequence with the
left
end flanked by 12 bp of target
eps sequence identical
to the right-end
target sequence and the right end flanked by 76 bp of
eps right-end
target sequence. This fragment was PCR
amplified from pDB440 by
using oligonucleotides 2 and 14 and then
inserted into the unique
XhoI site of pACYC177, generating
pAG903. A series of target site
deletion plasmids were constructed by
cloning into the TA cloning
site of pCR2.1 the PCR products generated
from pAG949, using the
following primer pairs (the number of base pairs
of original target
sequence remaining on each side of IS
492
is indicated): oligonucleotides
15 and 16, pAG970 (24 bp on left and 23 bp on right); oligonucleotides
26 and 27, pAG976 (18 bp on left and 17 bp on right); oligonucleotides
17 and 18, pAG971 (10 bp on left and 10 bp on right); oligonucleotides
19 and 20, pAG972 (5 bp on left and 5 bp
on right); and oligonucleotides
21 and 8, pAG973 (1 bp on left and 0 bp
on
right).
The reporter plasmids pAG993 and pAG994 were constructed to examine
IS
492 excision in vivo. Wild-type IS
492 and an
excision-deficient
IS
492,
IS
492mooV::
lacZ, were subcloned
from pAG949 and pAG989,
respectively, as
AflII fragments
(approximately 1.2 kb each) and
cloned into the unique
AflII
site between the chloramphenicol
acetyltransferase gene and its
promoter on plasmid pAG987. The
QuikChange site-directed mutagenesis
kit (Stratagene) and oligonucleotides
34 and 35 were used to generate
pAG987, which is a pACYC184 derivative
containing a unique
AflII site, created by a single-base insertion
(A/T) at
position 232. pAG989 was constructed by inserting the
1,248-bp PCR
product resulting from amplification of pAG963 with
oligonucleotides 36 and 37 into pCR2.1. pAG963 is a derivative
of pAG956 (described above)
containing a 357-bp deletion between
distal
MfeI sites
within
mooV, which was replaced by a 453-bp
promoterless
lacZ fragment. This
lacZ fragment was
generated
as a PCR product from the amplification of pEU730
(
10) by using
oligonucleotides 38 and
39.
All PCR products created for cloning purposes were amplified by using
Pfu DNA polymerase (Stratagene). The thermal cycling
conditions were as follows: 95°C for 3 min followed by 25 cycles
of
95°C for 1 min (denaturing), the
Tm of the
oligonucleotide
with the lesser
Tm value minus
5°C for 1 min (annealing), and
72°C for 2 min (extension). The
products were digested with the
indicated restriction enzymes, or, if
ligated into pCR2.1, they
were incubated for an additional 10 min at
72°C with
Taq DNA polymerase
(Sigma). PCR products were
purified away from reaction components
with the QIAquick kit (Quiagen)
or by phenol extraction followed
by ethanol precipitation. All
ligations were done at 16°C overnight
with 400 U of T4 DNA ligase or,
for pCR2.1 cloning, with topoisomerase
from the Invitrogen kit.
Transformation of ligation mixtures into
host strains was generally
performed with competent cells prepared
by CaCl
2 treatment
(
27) or by using the One Shot (Inv
F' or
TOP10) competent
cells from Invitrogen and then plating on LB
agar containing the
appropriate
antibiotics.
Southern blotting.
Standard techniques for transfer of DNA
onto a nylon support with alkaline buffer were performed as described
by Ausubel et al. (1). Ethidium bromide staining of the
agarose gel before and after transfer of the DNA for the Southern blot
showed that approximately equal amounts of chromosomal DNA from each
strain had transferred to the blot filter. Hybridizations were
performed with Rapid-hyb buffer (Amersham) according to the
manufacturer's recommendations: the hybridization temperature was
65°C, and hybridization was followed by one low-stringency wash in
2× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate)-0.1%
(wt/vol) sodium dodecyl sulfate (SDS) for 20 min at 65°C and two
high-stringency washes in 0.5× SSC-0.1% (wt/vol) SDS for 15 min at
50°C. Following the final washes after hybridization, the blots were
visualized by using a Molecular Dynamics 445SI PhosphorImager.
The DNA probe for detection of IS
492 on blots containing
chromosomal DNAs from various
Pseudoalteromonas species (see
Fig.
1) was prepared by end labeling the
EcoRI fragment of
pAG949 containing
IS
492 with [
-
32P]dATP and
Klenow fragment. The DNA probe for detection of circle
junctions was
prepared by PCR, incorporating [
-
32P]dATP into newly
synthesized 405-bp circle junction fragments.
The PCR mixture (50 µl)
contained 0.1 µg of oligonucleotide 12,
0.1 µg of oligonucleotide
13, 0.1 µg of circle junction fragment
(see "PCR assay to detect
IS
492 circles" below), 50 µM each deoxynucleoside
triphosphate (dNTP) (dATP, dCTP, dTTP, and dGTP), 1×
Pfu
reaction
buffer, 0.33 µM [
-
32P]dATP, and 1 U of
Pfu polymerase (Stratagene). The thermal cycling
conditions
were as follows: 95°C for 2 min, followed by 25 cycles
of 95°C for
1 min, 60°C for 1 min, and 72°C for 2 min. The probe
was boiled for
10 min, and one-fifth of the reaction mixture was
added to 20 ml of
hybridization
buffer.
PCR assay to detect IS492 circles.
IS492 circle junctions were detected by using either of two
sets of PCR primers directed in opposing orientations (with 3' extendable ends directed outwardly): oligonucleotides 12 and 13 or
oligonucleotides 22 and 23, with 405- and 648-bp products, respectively. For initial circle detection, colony PCR was used; template DNA was prepared from single colonies by resuspending the
colony in 30 µl of Tris-EDTA (pH 8.0), boiling to lyse the cells, and
centrifuging to remove insoluble debris. The colonies were grown
overnight on solid medium, with the appropriate antibiotics and various
concentrations of isopropyl--D-thiogalactopyranoside (IPTG) as indicated, at 30°C (for P. atlantica) or 37°C
(for E. coli), followed by incubation at 4°C for 2 to
24 h. The incubation at 4°C was essential for circle detection.
Comparative PCR with wild-type IS492 and mutant strains was
done with template DNA prepared by plasmid minipreps (Qiagen) on cells
grown as described above; the DNA concentration was normalized for all
samples, first by UV spectroscopy at 260 nm and then by finding the
concentration of template which gave equal-intensity control PCR
products as determined by electrophoresis of dilutions of the products
on agarose gels, staining with ethidium bromide, image acquisition on a
fluorescence transilluminator with a digital camera, and quantitative
analysis using the image TIFF file and ImageQuant Software Package from
Molecular Dynamics. Control PCR products were generated in triplicate
by using twofold template dilutions with primers which amplify a 603-bp
region of the -lactamase resistance marker found on the
IS492-containing plasmids; 30 cycles of PCR amplification
were used, whereby the linear range of the standard curve extended from
9.3 × 104 to 9.3 × 108 pAG949
(IS492) molecules, and differences between product
intensities could be reproducibly determined. Reaction conditions for
the experimental and control products were identical: 95°C for 2 min, followed by 30 cycles of 95°C for 1 min, 60°C for 1 min, and 72°C for 2 min.
For assays in which complementation of MooV activity for circle
formation was determined by using increasing concentrations
of IPTG to
induce expression of
mooV from pAG954, it was noted
that the
colony appearance and size changed with increasing [IPTG].
Growth
curves were generated for HMS174(DE3) containing pAG954
and pAG957
in LB broth containing 0, 0.01, 0.05, or 0.1 mM IPTG
(higher
concentrations of IPTG resulted in nonviable cells) and
the appropriate
antibiotics. Overnight cultures were used to inoculate
LB broth
containing the different levels of IPTG to a final optical
density at
600 nm (OD
600) of 0.1. As the cultures were aerated
at
37°C, the OD
600 was determined every 30 min, and
dilutions
were plated to determine viable cell
counts.
PCR assay to detect repaired donor plasmid.
The repaired
donor plasmid was detected by PCR with primers complementary to known
eps sequence, oligonucleotides 28 and 29. Template DNA was
prepared and normalized as described above for the detection of
IS492 circles, using HMS174(DE3) carrying either pCR2.1,
pAG949, pAG957, or pAG957 and pAG954. Reactions were done in 1×
Pfu buffer with 50 µM dNTPs and 2.5 U of Pfu
polymerase. Cycling conditions were 95°C for 2 min, followed by 30 cycles of 95°C for 1 min, 57°C for 1 min, and 72°C for 1.5 min.
Products were detected on a 2% agarose gel (1% NuSieve, 1% SeaKem
[FMC BioProducts]).
Genetic assay for excision of IS492.
Competent
TOP10 cells were transformed with the excision reporter plasmid pAG993
(wild-type IS492) or pAG994
(IS492mooV::cam), selecting for
tetracycline resistance. These transformants were then made competent
by the CaCl2 method (27), transformed with pMal-C2 or pMalE-MooV, and then plated onto LB agar plates containing 12.5 µg of tetracycline per ml and 100 µg of ampicillin per ml. Two
primary transformant colonies were each grown to an OD600 of 0.2 to 0.4, and 10-fold serial dilutions were plated in duplicate. Acquisition of chloramphenicol resistance was scored as colonies which
were visible after overnight growth at 37°C on LB agar containing 80 µg of chloramphenicol per ml. The number of viable cells containing the excision reporter plasmid was determined by plating dilutions of
the same cultures on LB agar containing 12.5 µg of tetracycline per
ml. To physically determine if excision of the IS492 element had occurred, the plasmid DNA was prepared from
chloramphenicol-resistant cells, cut with NcoI, and examined
by agarose gel electrophoresis in comparison with the original
plasmids. The Cmr Tetr and Cms
Tetr colonies from these platings were also checked by the
PCR assay for circle junction formation.
Electrophoretic gel fractionation for detection of
IS492 circular form.
HMS174(DE3) containing pAG949 was
streaked for confluent growth on three standard (90-mm-diameter) LB
agar plates containing ampicillin at 100 µg/ml. The cells were grown
at 37°C overnight, followed by a 2-h incubation at 4°C. Plasmid DNA
was prepared from total scraped cells by using a Quiagen Plasmid Maxi
kit, and 0.25 µg of this DNA was loaded onto a 1% agarose gel. The gel was lightly stained with ethidium bromide. DNA was size
fractionated by dividing the gel into segments relative to a linear DNA
marker ladder. DNA was eluted from the agarose, phenol-chloroform
extracted, and ethanol precipitated by standard protocols described by
Sambrook, et al. (27). Two nanograms of a control artificial
IS492 circle was fractionated similarly from the same
agarose gel. The control circle was constructed with IS492
plus 150 bp of surrounding sequence which was removed from pAG949 by
EcoRI restriction digestion. The 1,352-bp EcoRI
fragment was gel purified from 1% agarose, followed by
phenol-chloroform extraction and ethanol precipitation. T4 DNA ligase
was added to DNA diluted to 0.3 µg/ml, a concentration at which
intramolecular ligation predominates. The covalently closed circular
form was then supercoiled by using DNA gyrase according to the
specifications of the manufacturer (Gibco-BRL).
DNA isolated in different fractions was used as the template in PCRs
with mixtures containing the circle junction primers,
oligonucleotides
12 and 13, 50 µM dNTPs, 1×
Pfu buffer, and 2.5
U of
Pfu polymerase. Cycling conditions were as follows: 95°C
for 2 min, followed by 30 cycles of 95°C for 1 min, 60°C for 1
min,
and 72°C for 2 min. Products were detected on a 2% agarose
gel (1%
NuSieve and 1%
SeaKem).
Identification and characterization of IS492 target
sites in P. atlantica.
Inverse PCR was performed with
chromosomal DNA isolated from EPS+ P. atlantica
DB27 by the protocol of Ochman et al. (24). P. atlantica chromosomal DNA (0.5 µg) was digested with either
RsaI or HaeIII (which do not have recognition
sites within the IS492 sequence). Restriction enzymes were
removed by phenol extraction followed by ethanol precipitation. The
digested DNA was diluted to 5 µg/ml, and T4 DNA ligase was added;
these conditions promote intramolecular ligation. After overnight
incubation at 16°C, the ligase was inactivated by heat. Various
dilutions of the ligated products were used as templates in PCRs with
mixtures containing primers complementary to IS492 with
their 3' ends directed outwardly (oligonucleotides 12 and 13);
therefore, these primers could be used to amplify DNA from either side
of an IS492 insertion. PCR products were generated by
Pfu (turbo) polymerase (Stratagene) under the following
thermal cycling conditions and cloned into the plasmid vector pCR2.1
(Invitrogen) for subsequent sequencing: 95°C for 2 min, followed by
30 cycles of 95°C for 1 min, 57°C for 1 min, and 72°C for 6 min.
Circle junction promoter activity assay.
For measurement of
-galactosidase activity, cultures of MC1061(recA)
carrying either pDV6, pCB267, or pDV5 and cultures of DH5 carrying
either pAG967, pNN387, or pAG620 were grown overnight at 37°C in LB
medium with the appropriate antibiotics and diluted 1:50 into fresh
medium. -Galactosidase activity was measured when cells reached
mid-exponential phase (OD600 = 0.4 to 0.6), according
to the method of Miller (21) with an SDS-chloroform lysis
modification. Lysates were centrifuged prior to measurements of
absorbance at 420 nm.
| |
RESULTS |
Prevalence of IS492 in P. atlantica and
related marine bacteria.
Bartlett et al. (2) previously
reported that P. atlantica DB27 contains several copies of
IS492. It has not been reported that IS492
appears in other isolates of P. atlantica or in other gram-negative bacteria. To determine if other P. atlantica
strains or related marine bacteria (11) also contain
IS492, Southern blot analysis (Fig.
1) was performed with chromosomal DNAs
from P. atlantica DB27 (3, 7), P. atlantica ATCC 19262 (36), P. atlantica ATCC
43666 (7) and ATCC 43667 (7),
Pseudoalteromonas (Alteromonas)
espejiana ATCC 29659 (5), and
Pseudoalteromonas (Alteromonas)
haloplanktis ATCC 14393 (26). The chromosomal DNAs were digested with BamHI alone (Fig. 1, lanes B) or
with BamHI and XmnI (Fig. 1, lanes X).
BamHI has no recognition site within the known
IS492 DNA sequence, and XmnI has a single
recognition site within IS492 at 565 bp from the left end of
the 1,202-bp element. Figure 1 shows that in addition to P. atlantica DB27, two of the ATCC P. atlantica strains
(ATCC 43666 and ATCC 43667) have IS492 insertions in the
chromosome. As expected, the BamHI fragments that hybridized
with IS492 (Fig. 1, lanes B) were cleaved by
XmnI, thus generating twice as many hybridizing bands (Fig. 1, lanes X). The differences in the hybridization profiles for the
multicopy IS492 element may reflect movement of the IS
element or restriction fragment polymorphisms. There is at least one
weakly hybridizing band in the P. espejiana DNA (Fig. 1,
lane 5X); this may indicate that a cryptic or diverged IS element,
related to IS492, is present on the chromosome of P. espejiana. No hybridization of the IS492 probe with the
DNA from P. atlantica 19262 or P. haloplanktis
was seen (Fig. 1, lanes 2 and 6). Although strain 19262 is considered
the type strain for P. atlantica, it differs from the other
P. atlantica isolates in growth rate (higher), colony
appearance (more mucoid and no phase variation), and odor, as well as
in its lack of IS492 on the chromosome.
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FIG. 1.
Southern analysis of P. atlantica and closely
related marine bacteria with 32P-labeled IS492
DNA as a probe. Chromosomal DNAs from the following strains were
digested with either BamHI alone (lanes B) or
BamHI and XmnI (lanes X) and subjected to agarose
gel electrophoresis: P. atlantica DB27 (lanes 1), P. atlantica ATCC 19262 (lanes 2), P. atlantica ATCC 43666 (lanes 3), P. atlantica ATCC 43667 (lanes 4), P. espejiana ATCC 29659 (lanes 5), and P. haloplanktis
ATCC 14393 (lanes 6). After transfer to a nylon membrane, the DNA was
probed with a 1-kb [32P]dATP-labeled IS492 DNA
fragment. The positions and sizes of the molecular size markers on the
agarose gel are indicated to the left.
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IS492 forms circles in P. atlantica and
E. coli.
Bartlett et al. (2) performed Southern
blot analysis of the chromosomes from P. atlantica DB27 that
had switched from EPS to EPS+; the results
indicated that precise excision of IS492 from the eps locus is not linked to insertion of the element at a new
site on the chromosome. A possible explanation for the unlinking of IS492 excision and insertion is that IS492 may
form a circular, extrachromosomal element as an intermediate in
transposition or as an end product of precise excision. Indeed, the
related IS element IS117, from the IS110 family,
has a circular, extrachromosomal form that is proposed to be an
intermediate in transposition (13). To assay for a circular
form of IS492 in P. atlantica DB27, PCR was used
to detect the junction of the left and right ends of IS492.
Primers that are complementary to the DNA sequences proximal to the
ends of IS492 were designed to have their 3' ends directed away from each other, such that the predicted PCR product generated with this primer set would represent amplification from a circular form
of the IS (Fig. 2A). Two independent
primer sets were used to generate PCR products. PCR amplification of
crude DNA isolated from EPS+ colonies yielded products of
the appropriate size for both primer sets, i.e., a 405-bp product for
primers 12 and 13 (Fig. 2B, lane 1) and a 648-bp product for primers 22 and 23 (data not shown), suggesting that a circular IS492
element was the template in the reaction. An additional, smaller PCR
product was present only for primers 12 and 13 (Fig. 2B, lane 1). The
related Pseudoalteromonas species P. espejiana
and P. haloplanktis, which showed no bands hybridizing to
IS492 in the Southern assay, did not yield a PCR product in
this assay (Fig. 2B, lanes 2 and 3).
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FIG. 2.
Detection of IS492 circles in vivo by PCR
analysis. (A) Diagram of IS492-containing plasmid pAG949 and
locations of primers (oligonucleotides 12 and 13) used in this PCR
analysis. Potential products of excision are drawn below the diagram.
(B) Agarose gel electrophoresis of products generated from colony PCR
with the circle junction primers (oligonucleotides 12 and 13) and total
DNA from P. atlantica DB27 (lane 1), P. espejiana
(lane 2), P. haloplanktis (lane 3), E. coli
InvF' containing pCR2.1 (lane 4), InvF' containing pAG949 (lane
5), E. coli HMS174(DE3) containing pCR2.1 (lane 6), or
HMS174(DE3) containing pAG949 (lane 7). Lanes 8 to 11 have the same
template DNAs as lanes 4 to 7, respectively, but PCR was performed with
the bla primers (see Materials and Methods), which amplify
the -lactamase gene of pAG949, as a control for template addition.
Lane M, molecular size markers in base pairs. (C) Sequences of the
eps locus prior to and after IS492 insertion and
the circle junction sequence with flanking IS492 termini.
The 5-bp target duplication-circle junction sequence is underlined, the
IS492 insertion in eps is represented by a box,
and the IS492 sequence is italicized in the circle junction
sequence.
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The PCR products obtained for
P. atlantica with each primer
set were ligated into the plasmid pCR2.1 and sequenced (see Methods
and
Materials). The primary products for both primer sets had
the
IS
492 right- and left-end sequences separated by a 5-bp
junction
sequence (Fig.
2C). The 5-bp junction sequence, 5'-CTTGT-3',
matches
the 5-bp sequence of
eps that is duplicated upon
IS
492 insertion
into the
eps target site (Fig.
2C). The sequence for the secondary
product from primers 12 and 13 revealed that this product resulted
from annealing of primer 12 to a
partially homologous sequence
within the
eps locus.
To determine if formation of this IS
492 excision product
requires any host factors or conditions specifically provided by
P. atlantica, we used the same PCR assay as used for
P. atlantica to detect IS
492 circle junction
formation in
E. coli. Plasmids
pAG949 and pAG956, containing
the 1.2-kbp IS
492 element and 134
bp of surrounding
eps target sequence (59- and 76-bp flanking
sequences from
the left and right ends, respectively) within a
ColE1
ori
plasmid and a p15a
ori plasmid, respectively, were
introduced
into
E. coli Inv
F' and HMS174(DE3). The circle
junction PCR product
was detected in the transformant colonies (Fig.
2B, lanes 5 and
7). The DNA sequences of the PCR products derived from
the
E. coli strains containing pAG949 and pAG956 contained
the same circle
junction sequence as had been identified for
IS
492 in
P. atlantica (Fig.
2C).
Although the circle junction PCR products support the hypothesis that
IS
492 forms a circle upon excision in
P. atlantica and
E. coli, confirmation of an
extrachromosomal, circular form of
IS
492 was needed because
the same PCR products could be generated
from tandem copies of
IS
492 in the chromosome (or on a plasmid)
and not from a
circular form. To address this possibility, we
assayed for the presence
of a circular form of IS
492 in purified
extrachromosomal DNA
isolated from an
E. coli strain containing
the 5.2-kb
IS
492-carrying plasmid pAG949. Extrachromosomal circular
DNA, purified from total cellular DNA by using the anion-exchange
resin, was fractionated by molecular size by agarose gel
electrophoresis
(Fig.
3). PCR analysis of
the fractionated DNA indicated that
fractions containing DNA migrating
between 1,500 and 3,000 bp
(linear DNA standards) yielded the circle
junction PCR product
(Fig.
3). As a control, a 1.35-kb DNA fragment
from pAG949, containing
the 1.2-kb IS element and flanking sequence
from the plasmid,
was ligated to give an open circular form. This
control circle
migrated a similar distance relative to the DNA markers
as the
IS
492 circle. The PCR product for the control circle
is slightly
larger than the circle junction for IS
492
circular form, since
it has an additional 150 bp of adjacent plasmid
DNA (Fig.
3).
The apparent molecular size for the circular form of
IS
492 in
this fractionation was slightly higher than the
molecular size
of the linear form of IS
492 (1,200 bp),
suggesting that it is
an open circle. These results confirm that the
circle junction
PCR product does indeed correlate with a circular form
of IS
492 and not tandem copies of the element.
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FIG. 3.
Demonstration of circular product from IS492
excision by electrophoretic fractionation of circular DNA from E. coli containing IS492. The illustration shows the 1%
agarose gel used to fractionate the open circular IS492
control DNA (OC) and the Qiagen plasmid (circular) DNA preparations (Q1
and Q2) from E. coli containing pAG949, which
carries wild-type IS492. Slices were cut from the gel based
on comigration with the DNA molecular size standards (1-kb ladder;
Promega). DNAs electroeluted from these slices were used as template
DNAs for PCR analysis to detect the IS492 circle junction.
The PCR products from the wide-range molecular size gel slices (Q1 and
OC, >3, 3 to 0.5, and <0.5 kb) and from the narrow-range molecular
size slices (Q2, 3 to 1.5, 1.5 to 1, 1 to 0.75, and 0.75 to 0.5 kb)
were separated on a 2% agarose gel. The white arrows indicate the
primary circle junction PCR product for each group of fractions.
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It is important to note that detection of IS
492 circles in
P. atlantica and in
E. coli required incubation
of the cells at
4°C for at least 2 h before isolation of the DNA
(data not shown).
These results suggest that, unlike the circular form
of IS
117 (
13), the IS
492 circle is not
persistent, and perhaps the lower
temperature permits isolation of a
transient intermediate in
transposition.
Circle formation is transposase dependent.
The predicted
transposase for IS492 transposition is encoded by the only
long open reading frame of the element (957 bp), designated
mooV. To determine if IS492 circle formation is
dependent on expression of mooV, we replaced 357 bp of the
mooV sequence with an 884-bp DNA fragment containing the
chloramphenicol acetyltransferase (cam) gene. This
mooV::cam derivative of
IS492 was introduced into E. coli on a
ColE1-ori plasmid, and transformants were assayed for circle
formation by using the colony PCR assay for the circle junction (see
Materials and Methods). The IS492
mooV::cam construct gave no circle
junction product (Fig. 4, lane 3),
indicating no circle formation, whereas the wild-type IS492
construct generated circles that served as a template for producing the
circle junction PCR fragment (Fig. 4, lane 2). Several control measures
were performed to confirm the negative result for the
IS492mooV::cam construct, including determining the template concentration in the reaction mixture and Southern blotting to increase the sensitivity for detection
of the PCR product (see Materials and Methods) (data not shown).
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FIG. 4.
Effect of MooV-His6 and Piv-His6
on IS492 circle formation. IS492 circle formation
was examined in E. coli HMS174(DE3) by the PCR assay
diagrammed in Fig. 1. The circle junction PCR products after agarose
gel electrophoresis are shown. MooV-His6 and
Piv-His6 (presence or absence is indicated by + or  ,
respectively) were provided in trans from pAG954 and pAG955,
respectively, to the
IS492mooV::cam-carrying plasmid,
pAG957 (). The levels of MooV-His6 and
Piv-His6 were varied by using different concentrations of
IPTG for induction. The following plasmids in HMS174(DE3) were included
as controls: pCR2.1 ( for IS492), pAG949 (+ for
IS492), and pAG903 (T, IS492 target site mutant
[see Materials and Methods]). Lane M, Promega 1-kb markers.
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Complementation analysis was performed to examine whether the
mooV deletion had affected expression of
mooV
only or the function
of a
cis-acting site as well. In strain
HMS174(DE3), MooV-His
6 was supplied in
trans to
IS
492mooV::
cam from a compatible
plasmid,
pAG954, which has
mooV translationally fused to six
histidine
codons at its 3' end and expressed from the T7 promoter. In
this
strain the T7 polymerase gene is expressed from the
lacUV5 promoter
on the
DE3 prophage. Western blot
analysis showed that IPTG-induced
expression of
mooV-his6 produced a 35.7-kDa protein,
consistent
with the predicted amino acid sequence of the
MooV-His
6 fusion
protein (data not shown). Supplying
MooV-His
6 in
trans resulted
in a detectable
IS
492mooV::
cam circle junction PCR
product (Fig.
4, lane 6); therefore, the deletion affected only
expression of
MooV and not the function of a
cis-acting
site.
To determine how the formation of circle product corresponds to the
level of MooV, we quantitated the response of
IS
492mooV::
cam to various
concentrations of MooV-His
6 by using increasing levels
of
IPTG to induce expression of
mooV-his6. After
induction, the
DNA was isolated and its concentration was normalized,
as described
in Materials and Methods; this was followed by PCR
analysis for
the circle junction. Circle formation did vary with
different
levels of MooV (Fig.
4, lanes 5 to 7). A low level of circle
formation
is detected when no IPTG is added; this is likely due to
leaky
expression of T7 polymerase from the
lacUV5 promoter
in the absence
of IPTG. Optimal circle formation was obtained at
approximately
0.01 mM IPTG, and no circle formation could be detected
at or
above 0.1 mM IPTG. The lack of circle formation when
mooV-his6 expression was induced at 0.1 mM IPTG
(or higher) could be explained
either by repression of IS
492
excision at high concentrations
of MooV or by a decrease in cell
viability with higher levels
of MooV-His
6. The latter
explanation is supported by growth rate
and cell viability assays,
which showed that induction of
mooV-his6 expression at 0.1 or 0.5 mM IPTG results in decreased growth rate
or
cell inviability, respectively (data not
shown).
We also performed the complementation assay for circle formation with
an MBP-MooV fusion protein and the wild-type MooV protein
supplied in
trans from compatible plasmids (see Materials and
Methods).
Both MBP-MooV and wild-type MooV supported circle formation
by
IS
492mooV::
cam (data not shown).
Since the site-specific recombinase
Piv from
M. lacunata has
significant homology with the transposases
of the
IS
110-IS
492 family elements, we determined the
ability
of Piv-His
6, MBP-Piv, and wild-type Piv
(
32) to complement for
IS
492 excision. The
complementation assays were performed as with
MooV; however, Piv did
not mediate detectable circle formation
at any level of expression
tested (Fig.
4, lanes 8 to 10). Western
blot analysis confirmed that
Piv-His
6, MBP-Piv, and wild-type
Piv were expressed in
these assays (data not
shown).
Precise excision of IS492 and repair of the donor
molecule.
In P. atlantica, excision of IS492
from the eps locus restores expression of eps,
indicating that either there is precise exchange of DNA strands in the
excision process or the eps target sequence is frequently
repaired upon excision of IS492. If circle formation by
IS492 corresponds to precise excision from eps,
then the repaired donor DNA molecule should be detectable. In the
assays for circle formation by IS492 in E. coli,
the donor molecules are multicopy plasmids carrying the
IS492 element within the eps target sequence.
Examination of plasmid DNA carrying wild-type IS492 (pAG949)
by electrophoresis on an agarose gel revealed an additional,
faster-migrating DNA species. The slower-migrating plasmid DNA was
electroeluted from the agarose gel and transformed into naive E. coli cells at a DNA concentration at which the likelihood of
cotransformation was negligible. Plasmid preparations from these
transformants again yielded the additional faster-migrating DNA on
agarose gels (Fig. 5A). PCR amplification
was performed on this plasmid preparation by using primers to the
eps target sequence; DNA sequencing of this PCR product
(Fig. 5B, lane 4) revealed that the sequence matches the eps
locus with no IS492 insertion. This result indicates that
the faster-migrating species was the donor molecule after precise
excision of IS492. The eps target sequence PCR
product was not amplified from the same E. coli strain
containing the plasmid with
IS492mooV::cam within the
eps sequence or from the E. coli strain
containing the parent plasmid pCR2.1 (Fig. 5B, lanes 3 and 5, respectively). Repair of the donor molecule can be detected for
IS492mooV::cam when MooV-His6 is supplied in trans and its
expression is induced by IPTG (Fig. 4B, lanes 1 and 2). Thus, precise
excision was detected only under conditions that also gave
IS492 circles. These results indicate that excision of
IS492 and repair of the donor correlate with circle
formation. However, every excision event that results in circle
formation may not also give a repaired donor molecule; the results
given in Fig. 4, lane 5, show that circle formation can be detected for
IS492::cam at very low levels of
mooV-his6 expression (in the absence of IPTG),
but the repaired eps target sequence is not detected by PCR
(Fig. 5B, lane 2) until induction of mooV-his6
expression at 0.01 mM IPTG.
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FIG. 5.
Detection of the repaired donor DNA after
IS492 excision. (A) Plasmid preparation of pAG949 after
agarose gel electrophoresis. The following forms of the plasmid are
indicated to the right of the gel: open circular (O.C.), supercoiled
(S.C.), and the repaired pAG949 after excision of IS492
(repaired donor). The DNA molecular size marker (lane M) is the Promega
/H3 markers, with sizes indicated to the left. (B) PCR assay for the
repaired donor DNA, using primers complementary to eps
(lanes 1 to 5), and controls for addition of template to the reaction
mixtures, using primers complementary to bla (lanes 6 to
10). Strains tested for the repaired donor DNA were HMS174(DE3)
containing pCR2.1 (no IS492) (lanes 5 and 6), pAG949
(wild-type IS492) (lanes 4 and 7), pAG957
(IS492mooV::cam) (lanes 3 and 8),
pAG957 and pAG954 (IS492mooV::cam
plus mooV-his6) (lanes 2 and 9), and pAG957 and
pAG954 (inducing conditions [0.01 mM IPTG]) (lanes 1 and 10). The
molecular size marker (lane M) is the New England Biolabs 100-bp marker
with sizes (in base pairs) indicated to the left.
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To further examine excision of IS
492 from the
eps
sequence, we used reporter plasmids in which IS
492 or
IS
492mooV::
lacZ (with
23-bp
flanking
eps sequences on the left and right ends of the
element) is inserted between the chloramphenicol acetyltransferase
gene
(
cam) and its promoter (
pcam) on the
plasmid pACYC184 (pAG993
or pAG994, respectively). Transformants with
pAG993 gave a mixed
population of plasmids containing the
IS
492 insertion or the target
eps sequence from
which IS
492 had been precisely excised (data
not shown);
therefore, all transformant colonies exhibited chloramphenicol
resistance (Cm
r) (Table
2).
Insertion of IS
492mooV::
lacZ
(pAG994) downstream
of
pcam resulted in
termination of transcription before the
cam gene and
chloramphenicol sensitivity (Cm
s) in the absence of MooV
(Table
2). When MooV was provided in
trans as an MBP-MooV
fusion protein from pMalE-MooV, the frequency
of excision, as
determined by the number of Cm
r colonies versus the total
number of Tet
r colonies that contain the excision reporter
plasmid, was approximately
10
5 for
IS
492mooV::
lacZ (Table
2). Excisant
plasmids were sequenced
for both the wild-type excision substrate and
the IS
492mooV::
lacZ substrate and
were found to have undergone precise excision of
the IS element, thus
restoring the
eps sequence. The 23-bp
eps sequences flanking the left and right ends of the IS element contain
the 5-bp duplication; therefore, after excision, the
eps
sequence
is the total 46-bp flanking sequences minus one copy of the
5-bp
duplication. This 41-bp
eps sequence did not affect
cam expression,
as evidenced by the value of 1 for the ratio
of Cm
r to Tet
r colonies for one of the
excisants (pAG992.2) that was derived
from pAG993 (Table
2). Colony PCR
assays for circle junctions
were performed on colonies for all strains
used in the excision
assays. Again, circle formation correlated with
excision of IS
492;
however, unlike the results of the PCR
assays for excision compared
to circle formation under noninducing
conditions (Fig.
5B, lane
2, and Fig.
4, lane 5), the genetic assay
indicated that both
excision and circle formation occurred at the low
level of MooV
expression in the absence of IPTG (Table
2). This result
probably
reflects the fact that different levels of
MooV-His
6 or MBP-MooV
are expressed in the absence of IPTG
due to the different expression
systems (see Materials and Methods).
IS492 excision requires flanking eps
sequences.
The ability of IS492 to be excised precisely
and restore the donor sequence is a very unusual feature for a
transposable element (8, 19). Another unusual aspect of
IS492 is that it does not have inverted-repeat DNA sequences
at the ends of the element; for most IS elements, the short terminal
inverted-repeat DNA sequences are required for transposase recognition
and cleavage of the DNA at the ends of the element (for a review, see
reference 19). These features of IS492
suggest that the sequence flanking the IS element at its insertion
sites may play an essential role in transposase binding and in the
excision reaction. For example, the 5-bp sequence that is duplicated
upon insertion of IS492 may function very much like the
attL and attR sequences in excisive site-specific
recombination for bacteriophage (for a review, see reference
15). To determine if flanking DNA sequences affected circle formation of IS492, a deletion analysis of the
eps target sequence was performed. Our original plasmid
constructs containing the wild-type IS492 (pAG949 and
pAG956) carried 58 and 76 bp of eps target sequence flanking
the left and right ends of the inserted element, respectively. This
eps target sequence was reduced systematically on either
side of IS492 in a series of plasmids (see Materials and
Methods), resulting in IS492 flanked by 24 and 23 bp, 18 and 17 bp, 10 and 10 bp, 5 and 5 bp, or 1 and 0 bp of eps target
sequence (Fig. 6A). PCR amplification to
detect the circle junction, using DNA from E. coli carrying
each of these derivative plasmids as a template, indicated that having
between 5 and 10 bp of the flanking eps target sequence is
essential for detection of the circle junction fragment and, therefore,
IS492 excision (Fig. 6B).
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FIG. 6.
Target site requirements for IS492 excision.
(A) Schematic diagram showing the extent of eps target
sequence on either side of IS492 (left flanking sequence,
open box; right flanking sequence, hatched box). The number at either
end of IS492 indicates the number of nucleotides of
eps sequence. Whether a circle junction PCR product could be
detected is indicated as + or . (B) Agarose gel electrophoresis
of circle junction (CJ primers) PCR products and bla
(bla primers) control products generated from plasmids
carrying IS492 sequence with the flanking sequences shown in
panel A. Lane M, Promega 1-kb marker, with the sizes of some of the
markers (in base pairs) shown to the left.
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The 5-bp
eps target sequence (5'-CTTGT-3') is normally in
direct repeats at the ends of the element. To determine whether
excision of IS
492 required that this sequence be in direct
repeats
at the ends of the element, we replaced the
eps
sequence at the
left end of the element with 12 bp of flanking sequence
from the
right end, but in an inverted orientation. The resulting
plasmid,
pAG903, carried the IS
492 element with the flanking
5 bp in an
inverted repeat, i.e., 5'-ACAAG/IS
492/CTTGT-3'
(Fig.
6A). This
IS
492 mutant is not excised to form circles,
as demonstrated by
PCR analysis (Fig.
4, lane 4). A minor,
approximately 1,600-bp
PCR product is detected instead when primers
which normally generate
the 405-bp product in our standard assay and
used. Upon sequencing,
it appears that this product might be the result
of an aberrant
one-ended excision event within pAG903 (data not
shown).
Other insertion sites for IS492 in P. atlantica DB27.
When multiple circle junction PCR products
were sequenced for the circular form of IS492 in P. atlantica, all of the junctions had the identical 5-bp sequence
that is duplicated at the eps locus upon insertion of
IS492. That same 5-bp sequence is critical in excision of
the IS element in E. coli, based on our deletion analysis
described above. Therefore, it was of interest to determine whether
this 5-bp sequence is found at the other insertion sites for
IS492 on the chromosome of P. atlantica. We used
the inverse PCR method described by Ochman et al. (24) for
amplifying flanking DNA to determine the sequences of other
IS492 target sites in P. atlantica DB27.
Digestion of total cellular DNA with RsaI or HaeIII, which have no recognition sequences within the
IS492 element, results in linear restriction fragments from
the chromosomal DNA containing the full IS element with some of its
flanking sequence from both the left and right ends at each of the
IS492 insertion sites. Dilution and ligation of the linear
fragments result in open circles that are then used as templates in
PCRs with the primer set (primers 12 and 13) used in the circle
junction assays (Fig. 2A). Thus, the PCR products contained the ends of
IS492 separated by the flanking DNA sequence from either end
of the element up to the nearest RsaI or HaeIII
site, where ligation occurred. The different-sized PCR products
generated from the ligated dilutions of the RsaI- and
HaeIII-restricted chromosomal DNA (Fig.
7A) should each represent a different
insertion site for IS492 on the chromosome of P. atlantica; as expected, the 405-bp circle junction fragment is
also seen from each amplification with the inverse PCR primers.
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FIG. 7.
Identification of other target sites in P. atlantica DB27. (A) Agarose gel electrophoresis of PCR products
generated from inverse PCR (described in Materials and Methods) of
diluted and ligated P. atlantica DB27 chromosomal DNA
following digestion with either RsaI (lanes 1 to 3) or
HaeIII (lanes 4 to 6). Either 0.25 µg (lanes 1 and 4),
0.025 µg (lanes 2 and 5), or 0.0005 µg (lanes 3 and 6) of P. atlantica chromosomal DNA was used as a template in inverse PCRs.
Lane M, Promega 1-kb marker. The inverse image of the UV-illuminated
ethidium bromide-stained gel is shown. (B) Alignment of target site
sequences. The duplicated target sequence is indicated with a box.
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The PCR products shown in lanes 3 and 5 of Fig.
7A were cloned in
pCR2.1 and sequenced, as described in Materials and Methods.
The DNA
sequences for different IS
492 target sites are shown in
Fig.
7B. All of these target sites have the same 5-bp duplication
as seen
for the
eps target site (5'-CTTGT-3'); therefore, any
of
these copies of IS
492 could be the source of the circular
form
of IS
492 detected in
P. atlantica.
Consistent with this result,
we found that the IS
492 circle
junction could be detected in EPS
+ cells which lack the
eps::IS
492 insertion (data not shown).
Comparison
of the flanking sequence beyond the 5-bp duplication for the
eps and four other insertion sites indicates that there is
limited
sequence conservation at the left and right ends of the
inserted
elements (Fig.
7B). Comparison searches of the databases with
the insertion site sequences (by using the Wisconsin Package,
version
9.1 [Genetics Computer Group]) indicate that one of the
other
insertion sites (pDB12) appears to be within an IS
10-like
transposase gene. No significant homology or similarity to other
genes
in prokaryotes or eukaryotes could be found for the other
insertion
sites.
Assembly of a strong promoter by circle junction formation.
A
possible advantage for an insertion element to have a circular
intermediate has been proposed based on studies of IS911 transposition (33, 34). For IS911, it has been
shown that inverse repeat left- and right-end joining results in the
formation of a strong promoter which can drive transposase expression
during a brief time when the presence of the transposase is essential for continued survival. We examined whether IS492, too,
might possess such a regulatory mechanism for transposase expression. The 5-bp circle junction flanked by 26 bp of the left end and 18 bp of
the right end of IS492 was inserted into a multicopy vector
used for promoter identification in front of a promoterless lacZ (pDV6) (Fig. 8A).
Positive transformants were dark blue on LB agar plates containing
X-Gal, thus indicating that the circle junction of IS492
does form a promoter driving -galactosidase expression.
-Galactosidase assays were performed with these cells as well as a
reference strain containing the same plasmid but with a
lacUV5 constitutive promoter driving -galactosidase
expression (pDV5). -Galactosidase levels were 6.7-fold higher for
the IS492 circle junction promoter, with 2,000 Miller units
of activity versus 300 Miller units for the lacUV5 control
promoter (pDV6 versus pDV5 in Fig. 8B). The circle junction promoter
was also cloned in single copy on pNN387 (9) to estimate its
strength. A larger fragment containing the circle junction was cloned,
with 66 bp of the left end and 202 bp of the right end of
IS492, in front of a promoterless lacZY; this
plasmid construction was designated pAG967 (Fig. 8A). Positive
transformants were dark blue on LB agar containing X-Gal, suggesting
the circle junction represents a strong promoter. -Galactosidase
assays were performed with these cells, and the activity levels were
compared to those in control cells containing the same plasmid with a
constitutive tac promoter driving lacZ
expression; this control tac promoter, conII, has
all regulatory elements deleted (9). The IS492
circle junction promoter demonstrated 4.3-fold higher -galactosidase activity than the constitutive tac promoter, with 1,700 versus 400 Miller units (Fig. 8B).
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|
FIG. 8.
Promoter activity associated with the IS492
circle junction sequence. (A) The potential promoter sequence created
when IS492 ends are joined at the circle junction is
indicated by boxes. Relevant regions of plasmids pDV6 and pAG967, used
to evaluate circle junction promoter activity, are schematically shown.
Arrows and numbers (base pairs) are used to indicate the region of
IS492 included on either side of the circle junction on
these plasmids. The circle junction sequence is underlined. (B)
Promoter activity measured as -galactosidase activity (Miller units)
in plasmids having constitutive control promoters (lacUV5
[pDV5] or conII [pAG620]) or the circle junction and
surrounding IS492 sequence (pDV6 or pAG967). Besides having
different amounts of surrounding IS492 sequence, pDV6 and
pAG967 have different copy numbers (multiple and single copy,
respectively). The relative -galactosidase activities for these
promoter constructions remained constant in multiple experiments.
|
|
| |
DISCUSSION |
IS492 is a member of an atypical family of insertion
elements that do not have inverted repeats at their ends and whose
transposition is mediated by an apparently novel group of DNA
recombinases (16). Transposition of IS492
controls phase variation of EPS production in the marine bacterium
P. atlantica. The frequency of switching from
EPS to EPS+ and, apparently, the frequency of
IS492 precise excision from a locus that is essential for
EPS production (eps) varies more than 104-fold
depending on the growth conditions (2). These unique features of the IS element and its transposase, along with the control
of IS492 excision frequency by environmental conditions, suggest that there are likely to be many interesting features to the
regulation of IS492 transposition. In this study we have begun to address the mechanism for IS492 transposition.
In PCR-based assays we detected a circular form of IS492 in
P. atlantica DB27. The same circular form of
IS492 was also detected in E. coli when we
introduced wild-type IS492 on multi- or single-copy plasmids
by transformation. DNA sequencing of the junction of the ends of the
element in the circular form showed that a 5-bp sequence linked the
ends of IS492. This 5-bp sequence corresponds to the
eps sequence that is duplicated at the insertion site for IS492. In previous Southern analyses of IS492
transposition (2), only the eps-associated copy
of the element appeared to have been excised. This suggested to us that
perhaps the 5-bp eps sequence defined the circular form as
being generated only from the copy of IS492 in the
eps site. We identified the other insertion sites of
IS492 on the P. atlantica chromosome by inverse
PCR (24) and found that all of the target sites had this
same 5-bp sequence; therefore, any of these copies of the element could
be the source for the IS492 circle.
The conservation of this 5-bp sequence at all of the target sites for
IS492 suggests an interesting possibility for the mechanism of transposition of IS492. Perhaps the transposases for
IS492 and the related IS110 family of insertion
elements utilize a recombination reaction more like the site-specific
recombinases such as the integrases of the -Int family. In this
scenario, the 5-bp target sequence would function similarly to the core
sequences of the attB/attP and attR/attL sites,
where DNA cleavage and precise strand exchange occur in bacteriophage
integration and excision, respectively (for a review, see reference
15). The homology of these transposases with the
site-specific invertase of M. lacunata lends some support to
this hypothesis. If the 5-bp sequence does function in this manner,
then it would be essential for the excision process. A stepwise
deletion analysis of the flanking DNA sequence showed that, indeed,
between 5 and 10 bp of the flanking sequence is required for excision
and circle formation. Inverting the orientation of 12 bp of the
flanking sequence at one end of the element also affected circle
formation; no circles could be detected, but instead of a site-specific
inversion of the element, an apparent one-ended transposition event was
detected by PCR. We are currently undertaking a more detailed analysis
of the essential sequences at the ends of IS492 and in the
flanking DNA to address their role in the excisive recombination reaction.
While some transposable elements, such Tn7, Tn10,
and bacteriophage Mu, show various extents of target site selectivity
for insertion, a critical role for flanking host DNA sequences in transposition is exceptional. Mu transposase shows a conditional effect
of flanking host sequences on cleavage at the donor site in vitro
(35), and the transposases of conjugative transposons, which
share the catalytic amino acid motif of the -Int site-specific recombinases, exhibit dependence on flanking host sequences for frequency of transposition (14a). The requirement for the
5-bp duplicated target sequence for excision of IS492 is
truly an unusual feature for an IS element. Another unusual aspect of
IS492 excision is that it appears to frequently result in
restoration of the target DNA sequence. In both P. atlantica
(2, 3) and E. coli (Fig. 5), the donor DNA is
repaired after excision of IS492. This ability to excise
precisely is not necessarily linked to circle formation. The related IS
element IS117 from Streptomyces coelicolor has
been shown to form a minicircle which may be an intermediate in
transposition; however, precise excision of IS117 is never
seen (18). In fact, it has been suggested that all IS117 transposition events are replicative in S. coelicolor and Streptomyces lividans (31).
Thus, although our results show that circle formation and precise
excision require the same trans-acting factor, MooV, and at
least some of the same cis-acting DNA sequences in the
flanking host DNA, the questions of whether precise excision and circle
formation by IS492 are directly linked and of what role
circle formation plays in the transposition reaction still remain.
Formation of circular products in transposition is not unique to the
IS110-IS117 family of insertion elements; circles
have been detected in a number of other systems, including
IS3 (29), IS2 (17),
IS150 (19), IS10 (22),
IS1 (19, 30), IS91 (20),
and IS911 (19, 25). IS911 circles have
been shown to actively integrate in vivo and in vitro, supporting their
possible role as transposition intermediates (33, 34).
Strong evidence supporting a functional role of the IS911
circle in transposition comes from regulation studies of the
IS911 transposase. The assembly of IS911 inverse
repeat right and left ends as a circle junction creates a strong
promoter which is stronger than the indigenous promoter driving
transposase transcription; thus, it has been suggested that in a
postexcision situation where a transposon circle has been formed, the
upregulation of transposase transcription may increase the likelihood
of integration occurring (33).
IS492, like IS911, forms a strong promoter from
the left and right ends when joined by the 5-bp host target sequence at
the circle junction (Fig. 8). The high level of transcription from this
newly assembled promoter upon excision of IS492 could either positively or negatively regulate reinsertion of the element. The new
promoter is appropriately positioned to initiate increased expression
of mooV. In E. coli, the amount of circle
formation by a mooV derivative of IS492 was
dependent on the level of mooV expression from a plasmid in
trans (Fig. 4). In general, for most transposable elements,
there are multiple levels of regulation to keep transposition
frequencies low (for a review, see reference 8). The
decrease in circle formation at high levels of MooV (Fig. 4) may
reflect autoregulation of transposase expression, as is seen for
IS1 and Tn7 (8, 30), although the
decrease in cell viability upon induction of MooV complicates this
analysis. Alternatively, a negative effect of the high level of
transcription from the promoter overlapping the ends of the element may
be that RNA polymerase then prevents binding of MooV to the ends. An
assay for insertion of IS492 is needed to address the role
of the IS492 circle and the circle junction promoter. We
have not observed insertion of IS492 into the eps
sequence or a new locus in E. coli (data not shown), which
suggests that regulatory or accessory recombination factors that are
involved in transposition of IS492 in P. atlantica are absent in E. coli. We are pursuing the
characterization of the mechanism for IS492 transposition
and its regulation genetically in P. atlantica and E. coli and biochemically in an in vitro recombination system.
| |
ACKNOWLEDGMENTS |
This work was supported by Public Health Service grant GM
49794-05 from the National Institutes of Health and Presidential Young
Investigator award MCB-9396003 from the National Science Foundation to
A.C.G.
We thank Russell Karls, Mick Chandler, Gordon Churchward, and June
Scott for helpful discussions and critical review of the manuscript. We
appreciate the contribution of Wendy Mahler to the construction of pAG956.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, Rollins Research Center, Room 3105, 1510 Clifton Rd., Atlanta, GA 30322. Phone: (404) 727-3734. Fax: (404) 727-3659. E-mail: acglasg{at}bimcore.emory.edu.
| |
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Journal of Bacteriology, August 1999, p. 4937-4948, Vol. 181, No. 16
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Abstract
Introduction
