(Received for publication, June 6, 1995; and in revised form, September 9, 1995)
From the
A central step in the transfer of genetic information during bacterial conjugation of the Escherichia coli F plasmid involves the formation of a protein-DNA complex, called the relaxosome, at the origin of transfer. During conjugation, the relaxosome introduces a site- and strand-specific nick from which the physical transfer of a single strand of DNA is initiated. At least two F-encoded proteins, TraIp (traI gene product) and TraYp (traY gene product), and one host-encoded protein, integration host factor, are involved in this process. In this report, we use DNase I protection and electron microscopic techniques to investigate the mechanism of relaxosome formation. Our results show that TraYp and integration host factor form a protein-DNA complex that facilitates the binding of TraIp to assemble a relaxosome capable of introducing a site- and strand-specific nick at the origin of transfer. This nick is identical to that observed during conjugation.
Bacterial conjugation, mediated by the Escherichia coli F factor, leads to the transfer of genetic material from one bacterial cell to another. Conjugation begins with the formation of a pilus bridge between a donor (F+) and recipient (F-) bacterium. In response to an as yet unidentified signal, DNA transfer is initiated from a site- and strand-specific nick within a region of F defined as the origin of transfer (oriT). From this site, a single strand of DNA is driven through the mating junction into the recipient cell in a 5` to 3` direction. DNA synthesis replaces the transferred strand in the donor and converts the transferred strand to double-stranded DNA in the recipient (for reviews, see Willetts and Wilkins(1984), Ippen-Ihler and Minkley(1986), Willetts and Skurray(1987), Wilkins and Lanka(1993), and Frost et al.(1994)).
A key step in this process is the formation of a protein complex at oriT called the relaxosome. Plasmids containing oriT can be isolated from F+ bacteria as relaxosomes, so called because treatment of these plasmid protein-DNA complexes with protein denaturants results in the release of DNA superhelicity (Wilkins and Lanka, 1993; Thompson et al., 1989). Loss of superhelicity is due to the formation of a site-specific nick located on the strand destined for transfer during conjugation. The location of this site- and strand-specific nick has been identified by sequence analysis of relaxed DNA, and it is from this site that DNA transfer is initiated (Thompson et al., 1984; Thompson et al., 1989).
Genetic studies have revealed that mutations in the F plasmid traI and traY genes affect relaxosome formation in vivo, implicating these proteins in formation of the relaxosome at oriT (Everett and Willetts(1980), Traxler and Minkley(1988), also see Traxler and Minkley(1987)). Although biochemical and genetic studies have since determined a role for the traI gene product (TraIp) in relaxosome formation (Traxler and Minkley, 1988; Matson and Morton, 1991; Reygers et al., 1991), until recently, the role of the traY gene product remained unknown (see below). Various traI mutants have been studied, and the results suggest that the protein contains two distinct functional domains (Traxler and Minkley, 1988). The amino-terminal domain appears to be required for relaxosome formation, whereas the carboxyl-terminal domain is required for steps subsequent to formation of the relaxosome. Purified TraIp (also known as DNA helicase I) has long been known to contain DNA helicase activity (Abdel-Monem et al., 1983; Lahue and Matson, 1988), and it has been shown that the carboxyl-terminal half of the protein is a DNA-dependent ATPase (Traxler and Minkley, 1988; Reygers et al., 1991). Therefore, it appears that the traI gene encodes a bifunctional protein containing an amino domain with DNA strand scission activity and a carboxyl domain with DNA helicase activity.
Under defined conditions in vitro, TraIp alone has been shown to form relaxosomes with
plasmids containing oriT (Matson and Morton, 1991; Reygers et al., 1991). Treatment of these relaxosomes with protein
denaturants such as SDS results in the conversion of supercoiled
plasmids to the relaxed open circular form via formation of a nick
within oriT. The location of this nick is identical to that
observed in plasmids isolated as relaxosomes in vivo. It is
believed that the DNA is nicked prior to the addition of protein
denaturants with the continuity of the DNA strand being maintained by a
TraIp bridge. The addition of protein denaturants disrupts the protein
bridge, exposing the nick and allowing DNA supercoils to be released.
The nature of the reaction catalyzed by the TraIp to form the site- and
strand-specific nick at oriT has been studied biochemically
(Matson and Morton, 1991; Reygers et al., 1991; Matson et
al., 1993; Sherman and Matson, 1994; Nelson et al.,
1995). It occurs by a transesterification reaction that requires
Mg, low salt conditions, and a supercoiled DNA
substrate. Following DNA relaxation, the 5` phosphate at the nick site
remains covalently associated with the TraIp, whereas the 3` hydroxyl
is free and available for extension synthesis by DNA polymerase I.
Together with the available genetic data, these results indicate that
TraIp is the enzyme that introduces the site- and strand-specific nick
within oriT prior to DNA strand transfer.
Genetic and
biochemical analysis of oriT reveals the region adjacent to
the nick site to be complex (see Fig. 8). It contains two
binding sites for integration host factor (IHF) ()(Tsai et al., 1990), one TraYp binding site (Nelson et al.,
1993), one TraMp binding site (Laurenzio et al., 1992), two
intrinsic DNA bends (Tsai et al., 1990), and several inverted
sequence repeats (Frost et al., 1994). The occurrence of IHF,
TraYp, and TraMp binding sites within oriT suggests these
proteins may play a role in DNA strand transfer. A combination of
linker-scanning and deletion mutagenesis has been employed to determine
which of these cis-acting sequence elements are involved in the DNA
strand transfer reaction (Fu et al., 1991; Nelson et
al., 1995). Based on these studies, oriT can be divided
into two regions. The first region, consisting of the IHF B and TraMp
binding sites, is required for efficient DNA transfer but not
relaxosome formation. The second region, containing the IHF A and TraYp
binding sites, is required for both relaxosome formation and DNA
transfer. These results suggest that, in addition to TraIp, IHF and
TraYp are involved in steps leading to relaxosome formation and
introduction of a site- and strand-specific nick at oriT.
TraMp is most likely required for subsequent steps during bacterial
conjugation.
Figure 8:
A schematic representation of the protein
binding sites on oriT. The binding sites for TraIp, TraYp,
IHF, and TraMp are shown schematically at the top. Base pair
coordinates (numbering system of Frost et al. (1994)) are
shown at the bottom. The binding sites for TraIp, TraYp, and
the IHF A site were determined in this study. IHF B and the TraMp
binding sites were previously determined (Tsai, et al., 1990;
Frost et al., 1994). The carats denote
sequence-directed bends; nic denotes the nick site;
denotes the DNase I hypersensitive site.
Nelson et al.(1995) have determined a biochemical role for TraYp and IHF in the formation of a relaxosome at the F plasmid oriT. They demonstrated that these proteins can stimulate the TraIp-catalyzed nicking of supercoiled DNA in vitro, relax the topological requirement for a supercoiled DNA substrate, and relieve NaCl inhibition. Although the oriT region also contains several binding sites for TraMp, the addition of purified TraMp had no detectable affect on relaxosome formation. In this report, we have investigated the mechanism by which IHF, TraYp, and TraIp coordinate with oriT DNA to form the relaxosome. The complex is formed in a stepwise manner in which IHF and TraYp assemble onto DNA prior to the TraIp. IHF and TraYp facilitate TraIp binding at oriT under conditions that preclude TraIp from binding alone. In addition, we have applied a combination of DNase I protection and electron microscopic techniques to probe the structure of the F plasmid relaxosome.
Relaxosomes for DNase I protection experiments were prepared as
described above accept that 5 µg/ml poly(dI-dC)poly(dI-dC)
was included and the substrate, pBSoriT, was digested with XbaI, treated with calf intestinal phosphatase, and 5`
end-labeled with [
-
P]ATP using T4
polynucleotide kinase according to manufacturer's specifications.
The labeled DNA was then digested with SacI to generate two
fragments 20 and 3471 bp in size (the larger fragment contains oriT), each uniquely labeled at the XbaI end prior to
incubation with TraYp, IHF, and TraIp. The protein-DNA complexes were
then exposed to DNase I (1 µg/ml) for 2 min at 25 °C. The
reactions were stopped by the addition of EDTA to 50 mM.
Products were resolved by electrophoresis through 8% acrylamide/bis
(20:1), 8 M urea denaturing polyacrylamide gels alongside DNA
sequencing markers. Sequencing markers were generated using the dideoxy
sequencing method (Sanger et al., 1977) and a primer whose 5`
end initiated at the XbaI site of the large DNA fragment and
extended toward the oriT nick site. Products were visualized
by film autoradiography.
Plasmid pBSoriT contains the cis-acting F plasmid oriT sequence cloned into the pBS phagemid (Matson and Morton, 1991). Active relaxosomes can be formed by incubating purified proteins involved in relaxosome formation with supercoiled pBSoriT DNA (see accompanying paper). These protein-DNA complexes are detected by exposing the complexes to protein denaturants and following the conversion of the plasmid from a supercoiled to a relaxed form by agarose gel electrophoresis. The criteria which were applied to discriminate true relaxosome formation from nonspecific relaxation events were as follows: 1) the reaction must be dependent on the cis-acting oriT element and 2) the relaxed plasmid must contain a site- and strand-specific nick identical to that observed in DNAs isolated as relaxosomes in vivo. Using this assay it has been shown that, under defined conditions, TraIp alone can form a relaxosome at oriT (Matson and Morton, 1991; Reygers et al., 1991). Nelson et al.(1995) have furthered these studies by demonstrating that IHF and TraYp can act in conjunction with TraIp to form relaxosomes under conditions in which TraIp alone fails to form relaxosomes.
Figure 1: Relaxosome formation depends upon the order of addition of TraYp, IHF, and TraIp. Relaxosomes were formed by the addition of IHF (18 nM), TraYp (157 nM), and TraIp (37.5 nM) to a reaction buffer containing supercoiled pBSoriT DNA (6.7 nM) in the order indicated below the bar graph. Samples were incubated for 5 min at 23 °C after addition 1, for 5 min at 23 °C after addition 2, and for 15 min at 37 °C after addition 3. Reactions were terminated with EDTA, SDS, and proteinase K as described under ``Experimental Procedures'' and applied to a 0.8% agarose gel. The relative amount of nicked product formed upon exposure of relaxosomes to SDS and proteinase K is expressed as the percentage of total DNA, which migrated as a relaxed species when electrophoresed through agarose (see ``Experimental Procedures'').
To investigate this question further, assembly of the relaxosome was examined using DNase I protection methodologies. pBSoriT DNA was linearized and uniquely labeled at the 5` end of the XbaI restriction site located 155 bp upstream of the oriT nick site. This DNA was incubated with varying amounts of IHF, TraYp, or TraIp alone and exposed to DNase I, and the products of this reaction were examined on an 8% denaturing polyacrylamide gel alongside DNA sequencing markers. Consistent with previously published reports, IHF and TraYp bind DNA independently and protect the DNA between positions 168 and 194 and positions 205 and 240, respectively (numbering system of Frost et al., 1994), from DNase I in a protein concentration-dependent manner (data not shown). In contrast, TraIp alone did not provide any protection from DNase I cleavage at any concentration tested up to a 20-fold molar excess of TraIp over DNA (Fig. 2). It appears that the TraIp alone is unable to bind linear double-stranded DNA in a stable manner at these concentrations and thus is unable to form a relaxasome on a linear DNA substrate under these conditions.
Figure 2:
TraIp alone does not bind to linear
pBSoriT. Uniquely end-labeled P-labeled DNA (6.7
nM), prepared as described under ``Experimental
Procedures,'' was incubated at 37 °C for 15 min with
increasing amounts of TraIp: lane 1, 10 nM; lane
2, 20 nM; lane 3, 40 nM; lane
4, 100 nM; lane 5, no TraIp. DNase I was then
added to the reaction as described under ``Experimental
Procedures,'' and the products were resolved on an 8% denaturing
polyacrylamide gel alongside DNA sequencing markers (G, A, T, C). The
nick site (nic) is indicated by the arrow to the left of the autoradiograph. Numbers to the right represent the distance in nucleotides from the BglII site
located within oriT (see Frost et
al.(1994)).
The addition of TraYp (Fig. 3) or IHF (Fig. 4) to the DNase I protection experiments containing TraIp did not produce any additional protection other than that expected for IHF or TraYp alone. However, the addition of all three proteins in the following order, IHF, TraYp, and then TraIp revealed a region of DNase I protection that included the IHF and TraYp binding sites plus an additional region of protection that extended across the nick site to position 135 (Fig. 5, also see Fig. 8). In addition, a site of DNase I hypersensitivity appears near the distal end of the IHF binding site at position 192 only when all three proteins are included in these experiments. These results indicate that neither IHF nor TraYp alone can facilitate the binding of TraIp, but together these two proteins act to promote the formation of a relaxosome that includes TraIp. These data are consistent with the observation that all three proteins are involved in the introduction of a site- and strand-specific nick at oriT (see Fig. 1and Nelson et al.(1995)).
Figure 3:
TraIp does not bind to linear pBSoriT DNA
in the presence of TraYp. Uniquely end-labeled
[P]DNA (6.7 nM), prepared as described
under ``Experimental Procedures'' was incubated with varying
amounts of TraYp at 23 °C for 5 min followed by the addition of
varying amounts of TraIp and incubation at 37 °C for 15 min (lanes 2-5). Protein-DNA complexes were then exposed to
DNase I, and the products were resolved on an 8% denaturing
polyacrylamide gel alongside DNA sequencing markers (C, T, A, G). The
amount of TraYp and TraIp in each reaction corresponding to lanes
2-5 is indicated as follows: lane 2, 2 and 0.1
µM; lane 3; 0.52 and 0.04 µM; lane 4, 0.26 and 0.02 µM; lane 5, 0.13
and 0.01 µM. The locations of the TraYp DNase I protection
site (TraYp) and the nick site (nic) are indicated to
the left of the autoradiograph. Numbers to
the right represent the distance in nucleotides from the BglII site located within oriT (see Frost et
al.(1994)).
Figure 4:
TraIp does not bind to linear pBSoriT DNA
in the presence of IHF. Uniquely end-labeled
[P]DNA (6.7 nM), prepared as described
under ``Experimental Procedures,'' was incubated at 23 °C
with varying amounts of IHF followed by the addition of varying amounts
of TraIp and incubation at 37 °C for 15 min (lanes
6-9). Protein-DNA complexes were then exposed to DNase I,
and the products were resolved on an 8% polyacrylamide denaturing gel
alongside DNA sequencing markers (C, T, A, G). The amount of IHF and
TraIp in each reaction corresponding to lanes 2-5 is
indicated below: lane 2, 320 and 100 nM; lane
3, 160 and 40 nM; lane 4, 80 and 20 nM; lane 5, 40 and 10 nM. The locations of the IHF-DNase
I protection site (IHF) and the nick site (nic) are
indicated to the right of the autoradiograph. Numbers to the left represent the distance in
nucleotides from the BglII site located within oriT (see Frost et al. (1994)).
Figure 5:
TraIp binds linear pBSoriT DNA in the
presence of IHF and TraYp. Uniquely end-labeled
[P]DNA (6.7 nM), prepared as described
under ``Experimental Procedures,'' was incubated at 23 °C
for 5 min with varying amounts of IHF, followed by the addition of
varying amounts of TraYp and an additional 5-min incubation. Next,
varying amounts of TraIp were added and incubation continued at 37
°C for 15 min (lanes 2-5). Protein-DNA complexes
were then exposed to DNase I, and the products were resolved on a 8%
polyacrylamide denaturing gel alongside DNA sequencing markers (C, T,
A, G). The amount of IHF, TraYp, and TraIp in each reaction,
corresponding to lanes 2-5 is indicated as follows: lane 2, 320 nM, 2 µM, and 100
nM; lane 7; 160 nM, 0.52 µM,
and 40 nM; lane 8, 80 nM, 0.26
µM, and 20 nM; lane 9, 40 nM,
0.13 µM, and 10 nM. The locations of the IHF (IHF), TraYp (TraYp), and TraIp (TraIp)
DNase I protection sites and the nick site (nic) are indicated
to the left of the autoradiograph. The asterisk to
the left of the autoradiograph shows the position of a DNase I
hypersensitive site seen in lanes 2-5. Numbers to the right represent the distance in nucleotides from
the BglII site located within oriT (see Frost et
al.(1994)).
Another characteristic of protein complexes that wrap DNA is a shortening of the curvilinear length of the DNA. The curvilinear length can be directly measured from electron micrographs of DNA containing a relaxosome and compared with protein-free DNA. To further examine this question, we prepared relaxosomes containing IHF, TraYp, and TraIp for examination in the electron microscope. Fig. 6A shows electron micrographs of a 1622-bp SspI/AflIII restriction fragment of pBSoriT in which the nick site is centrally located. 36 such molecules were measured, and the distance of the protein complex was determined from one end and plotted as a percentage of the total distance (Fig. 6B). 34 protein complexes out of those examined were located at or within 10% of the nick site.
Figure 6: Visualization of the relaxosome complex by electron microscopy. A, a 1622-base pair SspI/AflIII restriction fragment containing the oriT nick site located in the center of the molecule was incubated with IHF (320 nM), TraYp (2 µM), and TraIp (100 nM). The protein-DNA complexes were then fixed with formaldehyde/glutaraldehyde and prepared for electron microscopy as described under ``Experimental Procedures.'' The arrows indicate the location of relaxosome complexes. B, the distance from one end of the DNA to each relaxosomes was measured, and that distance was plotted as a percentage of the total DNA length versus the number of molecules at each position.
To examine the
curvilinear lengths of relaxosomes, a smaller 684-bp HaeII
restriction fragment of pBSoriT was assembled into relaxosomes and
prepared for electron microscopy. The lengths of 33 DNA molecules with
protein complexes at the expected location was compared with the
lengths of 37 protein-free DNA molecules (Fig. 7). Wrapping or
looping of 100 bp of DNA (the relaxosome covers approximately 110 bp)
would result in a linear foreshortening of the DNA by approximately
0.025 µm. The measured length of 3 relaxosomes was 0.025 µm
shorter than the mean. However, the mean length of all measured
relaxosomes compared with free DNA molecules was identical. Although we
cannot rule out the possibility that these three relaxosomes represent
wrapped complexes, the majority of relaxosomes do not appear to be
complexed in such a way as to result in a significant foreshortening of
the DNA.
Figure 7: Absence of linear foreshortening of DNA within the relaxosome complex. A 684-bp HaeII restriction fragment containing the F plasmid oriT was assembled into relaxosomes and prepared for electron microscopy as described in Fig. 6. The curvilinear lengths of 33 DNA molecules containing a relaxosome were measured from electron micrographs using a Summagraphics digitizing board, and the data were represented as a histogram (upper panel). The curvilinear lengths of 37 protein-free DNA molecules were measured from electron micrographs using a summagraphics digitizing board, and the data were represented as a histogram (lower panel).
In conclusion, we have demonstrated that the relaxosome at the F plasmid origin of transfer is formed in a stepwise manner. IHF and TraYp assemble onto DNA prior to TraIp, and this complex facilitates TraIp binding at oriT under conditions that preclude TraIp from binding alone (Fig. 8). In addition, information about the superstructure of the relaxosome can be gleaned from DNase I protection experiments and electron microscopy. These results suggest that the DNA is not wrapped significantly around the surface or within the relaxosome complex as might be expected from the highly bent nature of oriT DNA and the presence of IHF and TraYp within the relaxosome, both of which are known to bend DNA. The presence of a DNase I hypersensitive site present only when all three proteins are bound to DNA, which is located at the distal end of the IHF binding site, suggests that the DNA at this site is exposed at the surface of the relaxosome and distorted to expose the minor groove to DNase I cleavage.
One model, consistent with the data presented in
this paper, that can be advanced to explain the ability of TraYp and
IHF to facilitate the formation of the F plasmid relaxosome invokes a
DNA structural change induced by the binding of these proteins. An
alteration in DNA structure could allow TraIp to interact with oriT DNA, which is normally refractory to TraIp binding. In support of
this model, the ability of TraIp to nick-supercoiled DNA in the absence
of other proteins suggests that superhelical energy can mimic the
affect of TraYp and IHF to favor TraIp binding at the nick site. It is
important to note that negatively supercoiled or underwound DNA can
promote the formation of non-B form DNA such as Z-DNA, cruciforms, and
triplex structures depending on the primary sequence of the DNA
(Palecek, 1991). Negative supercoiling can also drive transient melting
of duplex DNA, especially within A-T-rich regions. The oriT region of F contains several inverted repeats, which could form
cruciforms when exposed to either superhelical stress or localized
stress induced by TraYp and IHF binding. These same factors could also
induce transient DNA melting within the highly A-T-rich DNA region
found just 5` of the nick site. In fact, recent evidence indicates that
TraIp alone can efficiently cleave single-stranded oligonucleotides and
heat-denatured DNA containing the oriT nick site (Sherman and
Matson, 1994). ()These observations suggest that TraIp can
either recognize single-stranded DNA as a substrate or that
single-stranded DNA can adopt a conformation for the nicking reaction,
which can also be formed by supercoiled DNA or DNA bound by TraYp and
IHF.
The in vitro formation of a relaxosome at the F plasmid origin of transfer provides a substrate for examining the next step in DNA transfer; the conversion of DNA within the relaxosome from the supercoiled to relaxed form in response to a cellular mating signal. Extracts from mating bacteria or purified prospective mating signals can be added to relaxosomes in vitro, and the conversion of supercoiled relaxosomes to relaxed complexes can be easily assayed. Continued work along these lines will surely lead to the in vitro reconstitution and a more complete understanding of each event, which occurs during DNA strand transfer directed by the F plasmid.