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Previous Article | Next Article 
Journal of Bacteriology, September 1999, p. 5563-5571, Vol. 181, No. 18
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
TraC of IncN Plasmid pKM101 Associates with
Membranes and Extracellular High-Molecular-Weight Structures in
Escherichia coli
Heike
Schmidt-Eisenlohr,
Natalie
Domke, and
Christian
Baron*
Lehrstuhl für Mikrobiologie der
Universität München, 80638 München, Germany
Received 5 April 1999/Accepted 4 July 1999
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ABSTRACT |
Conjugative transfer of IncN plasmid pKM101 is mediated by the
TraI-TraII region-encoded transfer machinery components. Similar to the
case for the related Agrobacterium tumefaciens T-complex transfer apparatus, this machinery is needed for assembly of pili to
initiate cell-to-cell contact preceding DNA transfer. Biochemical and
cell biological experiments presented here show extracellular localization of TraC, as suggested by extracellular complementation of
TraC-deficient bacteria by helper cells expressing a functional plasmid
transfer machinery (S. C. Winans, and G. C. Walker, J. Bacteriol. 161:402-410, 1985). Overexpression of TraC and its export
in large amounts into the periplasm of Escherichia coli allowed purification by periplasmic extraction, ammonium
sulfate precipitation, and column chromatography. Whereas TraC was
soluble in overexpressing strains, it partly associated with the
membranes in pKM101-carrying cells, possibly due to protein-protein
interactions with other components of the TraI-TraII region-encoded
transfer machinery. Membrane association of TraC was reduced in strains carrying pKM101 derivatives with transposon insertions in genes coding
for other essential components of the transfer machinery, traM, traB, traD, and
traE but not eex, coding for an entry exclusion protein not required for DNA transfer. Cross-linking identified protein-protein interactions of TraC in E. coli carrying
pKM101 but not derivatives with transposon insertions in essential
tra genes. Interactions with membrane-bound Tra proteins
may incorporate TraC into a surface structure, suggested by its removal
from the cell by shearing as part of a high-molecular-weight complex.
Heterologous expression of TraC in A. tumefaciens partly
compensated for the pilus assembly defect in strains deficient for its
homolog VirB5, which further supported its role in assembly of
conjugative pili. In addition to its association with
high-molecular-weight structures, TraC was secreted into the
extracellular milieu. Conjugation experiments showed that secreted TraC
does not compensate transfer deficiency of TraC-deficient cells,
suggesting that extracellular complementation may rely on cell-to-cell
transfer of TraC only as part of a bona fide transfer apparatus.
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INTRODUCTION |
Conjugative transfer of genetic
information plays a major role in bacterial adaptation to changing
environmental conditions, as exemplified by the rapid spread of
antibiotic resistance markers and of determinants for detoxification of
xenobiotic compounds (10, 44, 45). A better understanding of
this natural process is necessary to devise strategies for
environmental release of genetically modified microorganisms for
sustainable ecosystem management, e.g., for detoxification of
xenobiotics, biocontrol of plant pathogens, or enhanced nitrogen
fixation in symbiotic bacterium-plant associations (18, 42, 49,
50). Conjugative plasmids are frequently used as tools for such
applications, and analysis of their biology may allow construction of
improved vectors.
Studies on plasmids from different incompatibility groups (F episome,
IncF [13]; pKM101, IncN [32]; pRP1/4,
IncP [26]; pR388, IncW [38]; and the
Ti plasmid from Agrobacterium tumefaciens [27,
51]) reveal striking similarities in their transfer
mechanisms. First, DNA processing involves several enzymes forming a
relaxosome at the nicking site, with concomitant covalent attachment of
the relaxase to the transferred DNA (25). Second, a family
of proteins homologous to TraG from IncP plasmid RP4 may link the
relaxosome to the membrane-bound transfer machinery; exchange of such
linkage components between broad-host-range plasmids of different
incompatibility groups illustrates their evolutionarily conserved
function (7). Third, components of the transfer machineries
were identified, and sequence analysis suggested export as well as
membrane association (21, 26, 32, 39, 48). Sequence
comparison revealed significant similarities between components from
different plasmid transfer systems, suggesting an evolutionarily
conserved mechanism for cell-to-cell trafficking of DNA-protein
complexes (9, 27, 51, 55). Fourth, the transfer machineries
determine assembly of pili, which presumably mediate cell-to-cell
contact preceding DNA transfer and serve as binding sites for
pilus-specific bacteriophages (3, 6, 12, 14, 15, 23, 28,
55).
With the exception of the F pilus, the assembly and composition of
conjugative pili remained enigmatic until recently. TraA, the major
subunit of the F pilus, shows similarity to components of several
macromolecular transfer systems, predicted to exert similar roles
(13, 16, 37). Minor pilus components, e.g., as tip-localized
adhesins in P and CS1 pili (20, 34, 36), play important
roles in adhesive pili, but so far, only indirect evidence suggests
minor components in conjugative pili (1, 13). Compositional
analyses of conjugative pili are needed to understand the molecular
basis of cell-to-cell recognition and macromolecular transfer. VirB2
was recently identified as major constituent of the T pilus from
A. tumefaciens (23), confirming earlier
predictions of VirB2 as a major pilus subunit, based on its sequence
similarity to the F pilus major subunit TraA (37).
pKM101 is a 35.4-kb incompatibility group N plasmid resulting from a
natural deletion of resistance plasmid R46 originally isolated from
Enterobacter cloacae (24). Expression of
plasmid-encoded genes mucA and mucB increases
sensitivity of plasmid-carrying strains to toxic chemicals, and pKM101
is included in Salmonella typhimurium strains used for the
Ames test (30, 31). Conjugative transfer relies on the
tra regions of pKM101, and 11 Tra proteins show significant
sequence similarity to VirB1 to VirB11, components of the
membrane-bound T-complex transfer machinery of the A. tumefaciens Ti plasmid. pKM101 derivatives carrying nonpolar
transposon insertions in traC as well as in several other
tra genes cannot undergo independent conjugative transfer.
However, helper strains expressing a functional transfer machinery can
partly compensate for the conjugative defect of insertions in
traC but not in any other tra gene (8,
52). This extracellular complementation suggested an
extracellular function of TraC, possibly as a pilus component, allowing
its intercellular transfer to deficient strains (51).
This study aims to elucidate the function of TraC in conjugative
plasmid transfer and the molecular basis of extracellular complementation. Biochemical analyses of E. coli carrying
pKM101, and transposon insertions in essential tra genes
demonstrated that membrane attachment of TraC is mediated by
protein-protein interactions with other components of the plasmid
transfer machinery. TraC was partly secreted but also colocalized with
high-molecular-weight structures, which could be isolated from
transfer-competent cells by shearing and high-speed centrifugation.
Mating experiments showed that helper strains expressing an intact DNA
transfer machinery partly compensated for the conjugative defect of
strains carrying pKM101traC-insertion derivatives.
However, external supply of large amounts of TraC did not exert
such an effect, suggesting that TraC-mediated extracellular
complementation requires its association with an intact plasmid
transfer machinery.
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MATERIALS AND METHODS |
Strains and growth conditions.
The strains used are listed
in Table 1. E. coli FM433 and
derivatives were grown in Luria-Bertani (LB) media supplemented with
streptomycin (100 µg/ml), spectinomycin (100 µg/ml), ampicillin (100 µg/ml), chloramphenicol (20 µg/ml), and kanamycin (50 µg/ml) for plasmid propagation or selection of transconjugants. A. tumefaciens carrying pTrc200 and derivatives was grown on YEB
media containing streptomycin (100 µg/ml) and spectinomycin (300 µg/ml) for plasmid propagation (2).
A. tumefaciens vir genes were induced by growth in AB
minimal medium (10 g of glucose, 4 g of morpholinoethanesulfonic
acid (MES), 2 g of NH4Cl, 0.3 g of
MgSO4 · 7H2O, 0.15 g of KCl,
0.01 g of CaCl2, and 0.0025 g of
FeSO4 · 7H2O per liter, 1 mM potassium phosphate [pH 5.5]) at 20°C by the addition of acetosyringone at a
final concentration of 200 µM. For isolation of pili, cells were
induced for 3 or 4 days at 20°C on AB medium solidified with 2% agar
and further processed as described elsewhere (23). For induction of the LacI-repressed trc promoter in pTrc200
constructs, isopropyl-
-D-thiogalactopyranoside (IPTG)
was added to a final concentration of 0.5 mM.
Quantitation of conjugative DNA transfer.
Escherichia
coli strains were grown in liquid LB at 37°C in the presence of
antibiotics for plasmid propagation to an A600 of 0.8 to 1, sedimented by centrifugation, and resuspended in an
appropriate volume of LB medium without antibiotics. Equal amounts of
donor, recipient, and helper strain (10 µl of each, corresponding to
107 cells) were mixed on a prewarmed LB agar plate and
incubated for 1 h at 37°C; the spot was washed from the plate
three times with 300 µl of LB medium. To quantitate conjugative
transfer, dilutions were plated on LB media containing appropriate
antibiotics for selection of plasmid-containing recipients.
DNA manipulations.
DNA preparation, modification, and
cloning were performed by standard procedures (29) using
enzymes purchased from MBI Fermentas and New England Biolabs. The DNA
sequence of PCR-amplified genes was confirmed by sequencing on an ABI
Prism 377 sequencer.
pTrc200 was designed as a tool for IPTG-inducible expression of genes
in a wide variety of gram-negative bacteria. The broad-host-range plasmid backbone of pPZP200 was combined with a region coding for the
LacIq repressor and the trc promoter (fusion of
trp and lac promoter) followed by a polylinker
sequence and strong transcriptional terminators from the 5S rRNA operon
of E. coli. pPZP200 derivative pBP2N was cleaved with
Ecl136II and ScaI and ligated to a 2.6-kb
ScaI/NdeI fragment from pTrc99A (Pharmacia),
which had been treated with Klenow enzyme to generate blunt ends. Genes
cloned into the NcoI site show strong IPTG-inducible
expression from the trc promoter followed by an efficient
Shine-Dalgarno sequence.
The TraC coding region was PCR amplified with Goldstar DNA polymerase
(Eurogentec) from 1 ng of pGW2137 template, using oligonucleotides C5
(5'-GGGGCCATGGCAAAATCACTTACGGCAGT-3') and C3
(5'-GAAAGTACTCAGTTAATTGAAGGTGA-3') and the
following cycle conditions: denaturation (one cycle) at 95°C for 2 min; 30 cycles at 44°C for 1 min, 72°C for 2 min, and 95°C for
30 s; strand completion (one cycle) at 44°C for 1 min and 72°C
for 5 min; and termination at 4°C. The resulting 0.7-kb fragment was
cleaved with NcoI and ScaI (underlined in
sequences above) and ligated with
NcoI/SmaI-cleaved pTrc200, resulting in plasmid pTrcTraC.
Similar conditions were used for PCR amplification of virB5
from plasmid target pGVO310; the fragment was then cleaved with AflIII and ScaI (underlined in sequence below)
and ligated with NcoI/SmaI-cleaved pTrc200,
resulting in plasmid pTrcB5. Oligonucleotides used for amplification
were B55 (5'-CCACATGTCGATCATGCAACTTGTTGC-3') and
B53 (5'-GAAAGTACTCAGGGGACGGCCC-3').
Construction of virB5 deletion strain CB1005.
Strain CB1005 carrying an in-frame deletion in the virB5
gene on the Ti plasmid of strain C58 was constructed as described by
Berger and Christie (4) as follows. Briefly, a QuickChange site-directed mutagenesis kit (Stratagene) was used with
oligonucleotides dB5-1
(5'-GATCAAAGGTGGGGAACTATGAATTTCACGATCCCGGCGC-3') and dB5-2 (5'-GCGCCGGGATCGTGAAATTCATAGTTCCCCACCTTTGATC-3') for
deletion of virB5 in plasmid pB56. A fragment carrying the
deletion was then excised from pdelB56
(BamHI/HindIII); overhanging ends were filled
in with Klenow enzyme and then ligated with ScaI-cleaved pBB50, resulting in suicide vector pBB50delB5. The deletions were then
introduced in the Ti plasmid. First, recombinant pBB50delB5 was
transformed by electroporation into strain C58. The replication origin
of pBB50 derivatives is nonfunctional in A. tumefaciens; selection of transformants for resistance to kanamycin (100 µg/ml on
LB plates) therefore identifies strains carrying cointegrates formed
via virB-homologous regions on their Ti plasmid. Second, several independent strains were grown in LB medium without antibiotics and then plated on LB agar containing 5% sucrose to select for loss of
pBB50 carrying the sacB gene (expression of levan sucrase SacB is lethal on sucrose-containing medium) via a second recombination event. Western and Southern blotting identified those strains which had
lost virB5 due to successive crossovers on either side of
the deletion in pBB50delB5.
Overexpression, purification of TraC, and generation of
antisera.
For overexpression of TraC, pTrcTraC-carrying strain
JM109 was grown in 1 liter of liquid LB medium with streptomycin (50 µg/ml) and spectinomycin (50 µg/ml) at 37°C to late log phase; expression of the trc promoter was induced by addition of
0.2 mM IPTG followed by growth for 2.5 h under the same
conditions. Cells were sedimented by centrifugation, washed in
phosphate-buffered saline (8 g NaCl, 0.2 g of KCl, 1.44 g of
Na2HPO4, and 0.24 g of
KH2PO4 per liter [pH 7.2]), and frozen at
20°C.
For periplasmic extraction, the cell sediment was suspended in
TEX buffer (50 mM Tris-HCl [pH 8.0], 3 mM EDTA, 0.1% Triton X-100),
incubated on ice for 30 min, and then subjected to centrifugation (41). The supernatant was subjected to differential ammonium sulfate precipitation; concentrations between 40 and 50% saturation precipitated the highest amounts of TraC. The pellet was resuspended in
buffer A (50 mM Tris-HCl [pH 8.0], 50 mM NaCl, 0.5 mM dithiothreitol) containing 0.1% Triton X-100, dialyzed in 5 liters of buffer A, and
applied to a Mono Q HR5/5 column (Pharmacia) in a Pharmacia FPLC
system. Whereas most proteins bound to the column under these conditions, TraC was strongly enriched in the flowthrough containing only minor impurities. Gel filtration chromatography on a Superdex 75 column (Pharmacia) in buffer A was applied as final purification followed by dialysis in buffer A containing 50% glycerol and storage at 20°C. Proteins for column calibration were ferritin (450 kDa), aldolase (158 kDa), bovine serum albumin (68 kDa), chicken albumin (45 kDa), chymotrypsinogen (25 kDa), and cytochrome c (12.5 kDa) (Roche).
TraC-specific antisera were generated by injection of 500 µg of
purified protein in rabbits following standard protocols of Eurogentec
(Seraing, Belgium). Unspecific cross-reactions of the antisera were
reduced by incubation with polyvinylidene difluoride membrane-fixed
antigen and elution of specific antibodies in 15 mM NaOH according to
standard procedures (19).
VirB2-specific antiserum was generated by injection of 500 µg of
purified inclusion bodies of phage T7 gene 10 protein fused to amino
acids 9 to 121 of VirB2 in New Zealand White rabbits for immunization
as described previously (40).
SDS-PAGE and protein analysis.
Proteins in cell lysates were
detected after sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) in 10% acrylamide-containing gels
(22) followed by Western blotting, incubation with
TraC-specific polyclonal antisera, and detection with anti-rabbit
horseradish peroxidase-conjugated secondary antibody (Bio-Rad), using a
chemiluminescence-based detection system (NEN).
Subcellular fractionation and preparation of macromolecular
surface structures.
E. coli strains carrying pKM101 and
derivatives were grown in liquid culture in LB at 37°C to late log
phase (A600 = 0.6 to 0.8); 1 ml of culture
was plated on LB agar plates (diameter, 15 cm) and incubated at 28°C
for 18 to 24 h. Subcellular fractions (total cell lysates, soluble
proteins, and membrane fraction) were prepared in 50 mM potassium
phosphate buffer, pH 7 (buffer N), followed by separation of inner and
outer membrane by centrifugation through isopycnic sucrose gradients
essentially as described previously (2). Extracellular
macromolecular structures were removed from cells grown on LB agar
plates by shearing in buffer N and were sedimented by high-speed
centrifugation as described for the T pilus from A. tumefaciens (23). To assess the molecular weight of
TraC-containing macromolecules, pellets obtained by high-speed centrifugation were suspended in 200 µl of buffer N and applied to a
Superose 6 column (Pharmacia) for chromatography at a flow rate of 0.25 ml/min. Reference proteins for calibration of the column are indicated
in the legend to Fig. 6.
Cross-linking.
To monitor protein-protein interactions in
E. coli, cells were washed twice with buffer N and suspended
in 500 µl of the same buffer followed by addition of
bis(sulfosuccinimidyl) suberate (BS3; Pierce) to a final
concentration of 1 mM and incubation for 1 h at 28°C. A. tumefaciens cells were treated similarly in 50 mM potassium
phosphate buffer (pH 5.5), followed by addition of formaldehyde to a
final concentration of 1% and incubation for 1 h at 20°C.
Addition of 100 µl 1 M Tris-Cl (pH 6.8) to stop the reaction was
followed by centrifugation, washing, and freezing at 20°C.
Image processing.
Gels and chemoluminographs were
digitalized with a UMAX UC840 MaxVision scanner. Images were further
processed on a Power Macintosh computer using Adobe Photoshop 3 software and printed on an Epson Stylus Photo printer.
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RESULTS |
Expression and purification of soluble TraC from the periplasm
of E. coli.
The traC coding sequence was PCR
amplified and cloned behind the Shine-Dalgarno sequence of pTrc200,
resulting in strong IPTG-inducible expression from the
trc promoter in strains transformed with the resulting
vector pTrcTraC (Fig. 1).
Soluble TraC was released from cells by periplasmic extraction
using different protocols as described by Thorstenson et al.
(41), confirming its export into the periplasm predicted
by its protein sequence. Triton X-100-containing buffer (TEX) was
chosen as the most efficient method of extraction from the
periplasm, and TraC was further purified by differential ammonium
sulfate precipitation, anion-exchange chromatography, and
Superdex 75 gel filtration chromatography (Fig. 1). Elution from the
gel filtration column was compared to that of reference proteins,
showing a molecular mass of 43 kDa for purified TraC. Since protein
sequence analysis predicted a molecular mass of 26 kDa, confirmed by
its mobility in SDS-PAGE, this may indicate an abnormal shape or
purification of TraC as a dimer under nondenaturing conditions.
Purified TraC was used for immunization of rabbits to generate antisera
for further biochemical analyses of its function in plasmid transfer.
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FIG. 1.
Purification of TraC. Coomassie-stained
SDS-polyacrylamide gel showing steps leading to purification of TraC
from an overexpressing strain. Lanes: 1 to 3, pTrcTraC-carrying
strains JM109 before (lane 1) and after induction with IPTG for 45 (lane 2) and 90 min (lane 3); 4, supernatant resulting from extraction
of the periplasm with Triton X-100-containing buffer; 5, 40 to 50%
ammonium sulfate precipitation; 6, Mono Q anion-exchange
chromatography; 7, Superdex 75 gel filtration chromatography. In all
figures, positions of size standards are indicated in kilodaltons.
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Components of the pKM101 transfer machinery confer membrane
localization of TraC.
Sequence analysis predicted soluble as well
as membrane-associated Tra components, which may associate via
protein-protein interactions to form the plasmid transfer apparatus
(32). For example, sequence analysis predicted that TraM may
be a pilus component like VirB2 from A. tumefaciens. TraB
may be an ATPase like VirB4 supplying energy for plasmid transfer
or assembly of the transfer machinery. TraD, a hydrophobic protein
containing several membrane-spanning domains like VirB6, may form the
transfer pore (9). E. coli FM433 carrying
pKM101 and derivatives with transposon insertions in
traM, traB, traC, eex,
traD, or traE were grown on LB agar plates and
lysed in a French pressure cell, and subcellular fractions were
analyzed for localization of TraC. FM433/pKM101eex,
defective in entry exclusion but not in plasmid transfer
(33), was included as control for a nonpolar Tn5 insertion.
TraC was not detected in total cell lysates of
FM433/pKM101traC, and its level was strongly reduced
in FM433/pKM101traB, whereas all other strains
contained TraC in amounts similar to those in the wild type (Fig.
2). High-speed centrifugation
separated soluble and membrane fractions; membrane association of
TraC was detected in FM433 carrying pKM101,
pKM101eex, and pKM101traM, whereas it remained mostly soluble when other tra genes were disrupted
(Fig. 2). Thus, the pKM101-encoded plasmid transfer machinery
confers membrane association of TraC. Next, centrifugation through an isopycnic sucrose gradient was used to separate inner and outer membranes of pKM101-carrying cells. To assess the quality of the separation, measurement of NADH oxidase activity served to identify inner membrane fractions (not shown) and Coomassie dye stained porins characteristic for the outer membrane (Fig.
3A). Western blot analysis with
TraC-specific antiserum showed preferential association of TraC
with the inner membrane in pKM101-carrying cells (Fig. 3B).
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FIG. 2.
TraC associates with the membranes in strains carrying a
functional pKM101 transfer machinery. Lanes represent Western blot
analysis with TraC-specific antiserum after SDS-PAGE of subcellular
fractions from strain FM433 without plasmid () or carrying pKM101
(101) or derivatives with transposon insertions in genes encoding TraM
(M), TraB (B), TraC (C), Eex (Ex), TraD (D), or TraE (E). Arrows
indicate membrane-associated TraC.
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FIG. 3.
Sucrose gradient centrifugation shows preferential
association of TraC with the inner membrane. Membranes from strains
FM433/pKM101 and FM433 were subjected to centrifugation through
isopycnic sucrose gradients, and fractions (1 through 16) were
collected from the top of the gradient. Inner membrane-containing
fractions were identified by NADH oxidase activity detected in
fractions 1 through 5. (A) SDS-PAGE and Coomassie staining identified
porins in the outer membrane-containing fractions. (B and C) Western
blot analysis with TraC-specific antiserum after SDS-PAGE of fractions
from FM433/pKM101 (B) and FM433 (C). The arrowhead indicates porins
of the outer membrane, and the arrow indicates TraC.
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To detect protein-protein interactions of TraC, cells carrying
pKM101 or transposon-inserted derivatives were incubated in the
presence of the cross-linking agent BS3. Exposure to the
cross-linking agent resulted in covalent linkage of TraC into complexes
of higher molecular weight in cells carrying transfer-proficient
plasmids pKM101 and pKM101eex. Formation of these
complexes is strongly reduced or absent in transfer-deficient derivatives inserted in tra genes (Fig. 4B). Since
steady-state levels of TraC were not affected by tra
mutations except traB (Fig.
4A), cross-linking probably monitors
specific interactions in a functional plasmid transfer complex. In
contrast, in an overexpressing strain (FM433/pTrcTraC),
cross-linking results in multiple TraC-containing complexes differing
in molecular weight from the wild type, probably reflecting nonspecific
associations in the periplasm (Fig. 4C).
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FIG. 4.
Cross-linking identifies interactions of TraC with the
pKM101 transfer machinery. Shown are Western blot analyses with
TraC-specific antiserum after SDS-PAGE of total cell lysates of FM433
(lane ) and FM433 carrying pKM101 (lane 101) or derivatives with
transposon insertions in traM, traB,
traC, eex, traD, or traE
(lanes B, C, Ex, D, and E, respectively) (A), total cell lysates of the
same strains after cross-linking with BS3 (B), and cell
lysates and cross-linked samples of FM433 and FM433/pTrcTraC (C).
Arrows indicate higher-molecular-weight complexes formed after
cross-linking of TraC.
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Association of TraC with an extracellular macromolecular structure
depends on a functional plasmid transfer machinery.
Extracellular
complementation suggested that TraC may be a component of the
pKM101-determined conjugative pilus (51, 52). To test
this hypothesis, cells carrying pKM101 and mutant derivatives were
grown on LB agar plates, and macromolecular surface structures were
stripped from the cells by shearing through a needle (23, 35). The supernatant was subjected to high-speed centrifugation to sediment high-molecular-weight structures in the pellet, and TraC
content of the different fractions was analyzed by SDS-PAGE and Western
blotting. TraC was detected in total cell lysates and supernatants
(after shearing and high-speed centrifugation) from all strains
except negative control
FM433/pKM101traC::Tn5 (Fig.
5A). High-speed centrifugation, however,
sedimented TraC-containing macromolecules only from FM433 carrying
pKM101 and pKM101eex::Tn5 (Fig.
5A). Analyses with periplasmic protein MalE-specific and cytoplasmic protein SelA-specific antisera showed that the above procedure does not release significant amounts of periplasmic or cytoplasmic proteins from E. coli (Fig. 5B). Thus, in
strains carrying transfer-proficient pKM101 derivatives, TraC
assembles into a high-molecular-weight structure.
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FIG. 5.
TraC associates with an extracellular macromolecular
structure in FM433/pKM101. Macromolecular surface structures were
isolated from FM433 carrying pKM101 and mutant derivatives. Cells
were grown on LB agar plates and subjected to shearing, and the
resulting samples were analyzed by SDS-PAGE and Western blotting with
TraC-specific antiserum. (A) C, Total cell lysates; S1, supernatants
after shearing; S2, supernatants after high-speed centrifugation; P,
pellets after high-speed centrifugation. TraC detected in the pellet
fractions is indicated by arrows. Lanes are labeled as in Fig. 4. (B)
Analysis for content of periplasmic and cytoplasmic proteins
with MalE- and SelA-specific antisera.
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The molecular weight of TraC-containing structures was next
characterized by gel filtration chromatography. High-molecular-weight structures were isolated from strains FM433 and FM433/pKM101 as described above; pellets obtained after ultracentrifugation were suspended in buffer N and subjected to gel filtration on a Superose 6 column followed by SDS-PAGE. Western blot analysis revealed that TraC
elutes in two fractions, indicating its association in complexes of
different molecular weights (Fig. 6).
Comparison with the elution volume of reference proteins demonstrates a
molecular mass larger than 440 kDa (ferritin) for the TraC-containing
complex detected in fraction 6. TraC detected in fraction 11, however, elutes from the Superose 6 column like TraC purified by TEX extraction from the periplasm (not shown).
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FIG. 6.
Analysis of TraC-containing high-molecular-weight
structures by gel filtration chromatography. Surface structures
isolated from FM433/pKM101 (A) and FM433 (B) were subjected to gel
filtration on a Superose 6 column. Shown is analysis of column
fractions by SDS-PAGE followed by Western blotting with specific
antiserum; the arrow indicates TraC in a high-molecular-weight complex.
Molecular masses of reference proteins for calibration of the gel
filtration column: F, ferritin (440 kDa); B, bovine serum albumin (68 kDa); C, cytochrome c (12 kDa).
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To further substantiate its role in pilus assembly, TraC was expressed
in A. tumefaciens strain CB1005, which carries a deletion of
the gene coding for its homolog VirB5 on the Ti plasmid and does not
assemble VirB2-containing T pili on its surface (23). Strain
CB1005 carrying VirB5- or TraC-expressing plasmids was grown on agar
medium either in the presence of IPTG to induce plasmid-coded genes or
in the presence of IPTG and acetosyringone to induce expression of
plasmid-coded genes and vir genes, respectively. Surface
structures were isolated as described previously (23) and
monitored by SDS-PAGE followed by Western blotting with VirB2- and
TraC-specific antisera. Extracellular pilus assembly of VirB2 was
observed in vir-induced strain CB1005 expressing VirB5 or TraC, albeit at strongly reduced levels in the latter case (Fig. 7A), but the strain did not elicit tumors
after wounding and infection of Kalanchoë
diagremontiana (not shown). However, this finding raised the
possibility of a specific interaction of TraC with VirB components
leading to partial restoration of pilus formation. To test this
possibility, formaldehyde was added to strain CB1005 expressing TraC
alone or in the presence of Vir proteins to analyze its interactions
with VirB components. Exposure to chemical cross-linking agent resulted
in covalent association of TraC with higher-molecular-weight complexes,
but a complex of 32 kDa is observed only in vir-induced cells, suggesting that TraC may interact with possibly one (or few)
components of the VirB transmembrane machinery (Fig. 7B), thereby
mediating assembly of VirB2 into the T pilus.
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FIG. 7.
Extracellular pilus assembly of VirB2 in A. tumefaciens and cross-linking of cell-associated proteins suggest
interaction of TraC with VirB components. (A) Pili were isolated from
wild-type C58, virB5 deletion mutant CB1005 (CB5) carrying
cloning vector pTrc200 (200), and CB1005 expressing VirB5 (B5) and
TraC alone (+IPTG) or in the presence of Vir proteins (+AS
[acetosyringone], +IPTG), and analyzed with VirB2- and TraC-specific
antisera. Arrows indicate VirB2 content of extracellular
high-molecular-weight structures. TraC is secreted in large amounts of
pTrcTraC-carrying cells, partly associates with the pellets
obtained after high-speed centrifugation of surface structures, and is
also detected with VirB2-specific antiserum (arrowheads). (B) Cells of
strain CB1005 carrying pTrcTraC were grown on AB agar plates
without inducer, in the presence of IPTG or IPTG and acetosyringone
(AS), followed by cross-linking with 1% formaldehyde (FA) and analysis
of TraC content with specific antiserum.
|
|
TraC is a secreted protein in E. coli and A. tumefaciens.
TraC-overexpressing liquid cultures accumulate TraC
in the supernatant (Fig. 8A), but this
may be caused by periplasmic leakage in strains expressing TraC
at nonphysiological levels. We next analyzed TraC secretion in
liquid-grown FM433 carrying pKM101 or its mutant derivatives. TraC
was detected in concentrated culture supernatants of all strains, and
the ratio of cell-bound to secreted protein was approximately equal
(Fig. 8B). As a control for periplasmic leakage, we monitored
localization of MalE, which was detected exclusively in cell lysates
(Fig. 8C). Thus, TraC is partly secreted from E. coli
independent of a functional plasmid transfer machinery. Gel filtration
chromatography determined a molecular mass of 43 kDa for
periplasmic and secreted TraC (not shown), implying that secretion of TraC in liquid-grown cells does not lead to its
incorporation into a high-molecular-weight structure.
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|
FIG. 8.
Secretion of TraC in E. coli and A. tumefaciens. Cells were grown in liquid medium to late logarithmic
growth phase and sedimented by centrifugation followed by
trichloroacetic acid precipitation of secreted proteins. Cell-bound and
secreted proteins (fivefold concentrated) were subjected to SDS-PAGE
and Western blotting with TraC-specific (A, B, and D), MalE-specific
(C), and VirB5-specific (E) antisera. (A) E. coli FM433
(lanes ) and FM433/pTrcTraC (lanes +); (B and C) FM433 (lanes
) and FM433 carrying pKM101 (lanes 101) and derivatives
pKM101traM, pKM101traB,
pKM101traC, pKM101eex,
pKM101traD, and pKM101traE
(remaining lanes, left to right); (D and E) A. tumefaciens wild-type C58 and virB5 deletion
strain CB1005 (CB5) carrying pTrc200, pTrcB5, and pTrcTraC
grown in the presence of IPTG in vir gene-inducing
(+AS [acetosyringone]) or noninducing (AS) conditions. SN,
supernatant.
|
|
Secretion of TraC was analyzed in A. tumefaciens and
compared to that of its homolog VirB5. Wild-type strain C58,
virB5 deletion strain CB1005, and CB1005 transformed with
TraC- and VirB5-expressing plasmids pTrcTraC and pTrcB5 were
grown in liquid AB medium in virulence gene-inducing or
noninducing conditions. Cells were sedimented followed by analysis
of cell-bound proteins and supernatants for VirB5 and TraC. As in
E. coli, TraC was detected in cells and supernatants of
TraC-expressing agrobacteria in the presence and in the absence of
virulence gene induction (Fig. 8D). In contrast, VirB5 was detected
exclusively in cells (Fig. 8E).
A functional plasmid transfer machinery is necessary for
extracellular complementation of TraC defects.
TraC undergoes
partial secretion, suggesting that extracellular complementation may
rely on external supply of soluble TraC from the helper strain,
allowing assembly of the conjugative pilus of a
TraC-deficient recipient. Mating experiments were performed to directly
assess this possibility. Donor and recipient (and sometimes a third
helper strain) from liquid-grown cultures were mixed and incubated on
LB agar without antibiotics for 1 h and washed from the
plates, and different dilutions were plated on LB agar containing
antibiotics for selection of transconjugants (Table
2). Conjugative transfer of pKM101
from donor FM433 to recipient WL400 was 109-fold more
efficient than that of pKM101traC. Extracellular
complementation by helper cells (pGW2137) carrying the TraI-TraII
region encoding plasmid transfer but not DNA processing functions from
pKM101 inserted in pACYC184 (52), resulted in 400-fold
more efficient conjugative transfer of pKM101traC. In
contrast, cells carrying pKM101traM or
pKM101traD could not exert helper function, showing that
an intact plasmid transfer machinery is required for extracellular complementation.
These results argue against a role of secreted TraC in extracellular
complementation, as insertions in traM and traD
affect plasmid transfer and presumably pilus assembly but not
steady-state levels and secretion of TraC (see above). Further
experiments were performed to supply large amounts of external TraC to
stimulate pKM101traC transfer (Table 2). First, when
donor FM433/pKM101traC and recipient WL400 were mixed
with TraC-overproducing (and secreting) helper strain FM433/ pTrcTraC
on a plate, there was no effect on conjugative transfer of
pKM101traC. Second, pTrcTraC was introduced into
WL400 to analyze whether overexpression of TraC in the recipient promotes conjugative transfer. TraC overexpression failed to increase conjugative transfer in this experiment as well. Third, purified TraC
(0.1, 1, and 10 ng [equivalent to 500 to 50,000 molecules per donor
cell]) or TraC-containing high-molecular-weight structures isolated by
shearing and ultracentrifugation were added to FM433 pKM101traC and recipient WL400 on a plate, but changes
in the efficiency of conjugative transfer were not observed (not shown).
| |
DISCUSSION |
Cells expressing the pKM101 transfer machinery partly
compensate for conjugative defects of cells carrying transposon
insertions in the traC gene, a phenomenon termed
extracellular complementation (52). It was suggested
that TraC may localize at the cell exterior, e.g., as a pilus
component, allowing transfer to the deficient strain and incorporation
into its plasmid transfer machinery (51). Here, the basis of
this complementation was analyzed in detail.
By analogy to the T-complex transfer machinery from A. tumefaciens, the TraI-TraII region-coded products from
pKM101 were predicted to form a membrane-associated plasmid
trafficking complex. Indeed, here we show that these predictions hold
true. Whereas expression of TraC in the absence of other TraI-TraII
region gene products resulted in a soluble periplasmic protein,
it associated with the membranes in pKM101- and
pKM101eex-carrying bacteria, suggesting protein-protein
interactions with membrane-bound components of functional transfer
machineries. Membrane association was also detected in strains carrying
transfer-deficient pKM101traM. TraM may not be required
for membrane attachment of TraC but exert other functions in plasmid
transfer, e.g., as a pilus component (32). Membrane
association of TraC was not observed in cells carrying pKM101 with
transposon insertions located in traB, traD, and
traE, implying involvement of their gene products in
assembly or stabilization of the plasmid transfer complex.
Interestingly, steady-state levels of TraC were strongly reduced in
pKM101traB-carrying cells, similar to effects of
deletions in some virB genes on the stability of the
T-complex transfer machinery (4), but transcriptional polarity due to transposon insertion in the upstream gene may also
account for this phenomenon.
The different Tra proteins probably exert specialized functions in
assembly and/or stabilization of the membrane-bound plasmid transfer
complex and conjugative pilus. Cross-linking directed TraC to
high-molecular-weight complexes in E. coli carrying
transfer-proficient but not tra-defective plasmids. The lack
of cross-linking in strains carrying transposon-inserted pKM101
derivatives, probably reflecting misassembly or destabilization of the
plasmid transfer machinery, correlates well with their deficiency in
conjugative transfer. Cross-linking of TraC may therefore constitute a
biochemical assay for assembly of a functional plasmid transfer
complex, which will be useful for further analyses of Tra protein function(s).
Compositional analysis of the virulence pilus from A. tumefaciens recently identified VirB2 as its major constituent
(23). A similar approach was pursued here to isolate
components of extracellular macromolecular structures in E. coli carrying pKM101 or its transfer-deficient derivatives.
TraC proved to be a component of a high-molecular-weight structure,
which could be isolated from the cells by shearing, and transposon
insertion in any of the tra genes abolished its assembly.
Gel filtration chromatography confirmed the solubility of a
high-molecular-weight TraC-containing complex whose molecular weight
was larger than that of the reference protein ferritin (440 kDa). In
addition, TraC eluted from the gel filtration column at a position
corresponding to that of TraC purified from the periplasm. This may
be due to disassembly of the high-molecular-weight complex or
contamination of the pellet fraction applied to the column with soluble
TraC from the supernatant. To further assess a function of TraC in
pilus biogenesis, expression was performed in an A. tumefaciens strain defective for its homolog VirB5, which does not
form pili (23). Heterologous expression of TraC partly restored external assembly of VirB2 into the T pilus, and cross-linking suggested that TraC may interact with Vir proteins, thereby
substituting VirB5 in T pilus assembly. Thus, TraC is partly functional
in a well-defined heterologous system, indicating a role in pilus assembly. Further analyses of the composition of TraC-containing high-molecular-weight structures are necessary to assess whether TraC
is a component of the pKM101-determined pilus. Alternatively, TraC
could be part of a surface-exposed pilus assembly complex which
mediates extracellular polymerization of VirB2-homologous protein TraM
to form the conjugative pilus.
In spite of the obvious similarities between the A. tumefaciens- and pKM101-coded transfer systems, the mechanisms
of pilus assembly may differ. Whereas its homolog VirB5 from
A. tumefaciens is a cell-bound protein, TraC was partly
secreted independently of the presence of other components of the
pKM101 transfer machinery. Possibly, assembly of the conjugative
pilus involves a secreted intermediate of TraC. The assembly mechanism
may therefore resemble that of adhesive curli involving secretion of
CsgA (curlin) subunits and their extracellular assembly into a pilus
mediated by outer membrane-localized nucleator protein CsgB
(5). Curli assembly in csgA-mutant strains can be
complemented intercellularly by CsgA-secreting helper strains
(17), and a similar mechanism may explain extracellular
complementation. We directly addressed the possibility of pilus
assembly mediated by an external pool of TraC in conjugation
experiments with TraC-secreting and overproducing helper and recipient
strains or by external addition of large amounts of purified TraC.
However, conjugative transfer of pKM101traC was never
rescued, indicating that the above model for TraC-mediated pilus
assembly is probably not correct. Only helpers expressing an intact
plasmid transfer machinery can serve as donors in extracellular complementation. Extracellular complementation may therefore bear similarity to transfer of pilus phenotype in Myxococcus
xanthus where social gliding defects of tgl mutants are
compensated, presumably by cell-to-cell transfer of type IV pilus
components or a pilus assembly protein (46, 47). Similarly,
cell-to-cell contact may allow transfer of fragments of the pKM101
pilus from helper to pKM101traC-carrying cells, thereby
partly restoring their ability for plasmid transfer. Future studies
will address the role of TraC and other Tra proteins either as
structural components of the pKM101-coded pilus or as pilus
assembly factors to unravel the mechanism of cell-cell recognition
during bacterial conjugation.
| |
ACKNOWLEDGMENTS |
We thank Peter Christie and Stephen C. Winans for gifts of
strains, phages, and plasmids, Michael Ehrmann for donation of MalE-specific antiserum, and August Böck for support,
discussions, and donation of SelA-specific antiserum. We are indebted
to Bernhard Neuhierl for advice during protein purification and P. C. Zambryski for helpful comments on the manuscript.
This study was supported by grant BA 1416/2-1 from the Deutsche
Forschungsgemeinschaft to C.B.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Lehrstuhl
für Mikrobiologie der Universität München,
Maria-Ward-Str. 1a, 80638 München, Germany. Phone:
49-89-2180-6138. Fax: 49-89-2180-6122. E-mail: cbaron{at}lrz.uni-muenchen.de.
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Aly, K. A., Krall, L., Lottspeich, F., Baron, C.
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Abstract
Introduction
