(Received for publication, April 30, 1997, and in revised form, June 25, 1997)
From the Microbiology Unit, Department of Biochemistry, University of Oxford, South Parks Road, Oxford OX1 3QU, United Kingdom
Xer site-specific recombination functions in
maintaining circular replicons in the monomeric state in
Escherichia coli. Two recombinases of the bacteriophage integrase family, XerC and XerD, are required for recombination at the
chromosomal site, dif, and at a range of plasmid-borne
sites. Xer recombination core sites contain the 11-base pair binding
sites for each recombinase separated by a 6 to 8-base pair central
region. We report that both XerC and XerD act as site-specific type I
topoisomerases by relaxing supercoiled plasmids containing a
dif site. Relaxation by either XerC or XerD occurs in the
absence of the partner recombinase and requires only a single
recombination core site. XerC or XerD relaxation activities are
completely inhibited by the addition of the partner recombinase,
providing that the DNA recognition sequence for the inhibiting partner
is present.
Site-specific recombination systems function in a wide range of microorganisms to perform programmed DNA rearrangements (1, 2). Specialized recombinases catalyze exchanges between pairs of specific short DNA sequences which share little sequence homology. DNA cleavage, strand exchange, and rejoining of the DNA strands are catalyzed by four recombinase molecules in the absence of exogenous high energy cofactors, and proceed through a series of transient recombinase-DNA covalent complexes. This differentiates site-specific recombination from other types of genetic recombination, and relates site-specific recombinases to topoisomerases, the other class of enzymes with nicking-closing activity on DNA (3, 4). Consistent with that, most of the well studied site-specific recombinases have been shown to act as topoisomerases in vitro (5-7).
Xer site-specific recombination functions in the separation of circular
replicons prior to cell division by resolving multimeric forms produced
by homologous recombination (8). In Escherichia coli, two
recombinases, XerC and XerD, are required for recombination at the
chromosomal site, dif, and at a range of plasmid-borne sites
(9). Xer recombination core sites share a
~30-bp1 consensus DNA
sequence which contains 11-bp binding sites for each recombinase,
separated by a 6 to 8-bp central region (Fig. 1; Ref. 8). Recombinational exchanges
between pairs of plasmid sites (e.g. the cer site
of ColE1 or the psi site of pSC101) requires additional
sequences and proteins whose role is to ensure that recombination is
preferentialy intramolecular, and converts multimers to monomers
(10-12). In contrast, the chromosomal site dif consists only of a core sequence and recombination at dif occurs
intermolecularly and intramolecularly, at least when assayed in
dif containing plasmids (13-17).
XerC and XerD share 37% sequence identity and display similarities
with members of the bacteriophage integrase (
Int) family of
site-specific recombinases (9, 11, 18, 19). This family is
characterized by the conservation of two motifs which contain four
invariant residues (the RHRY tetrad), all of which have been implicated
in catalysis (21). The tyrosine (Y) serves as the attacking nucleophile
on the scissile phosphodiester bond of the DNA. This attack generates a
5
hydroxyl end and a 3
phosphotyrosyl-protein intermediate which is
released upon ligation with the recombining partner (22, 23). The three
other residues (Arg, His, and Arg) are thought to be involved in
activation of phosphodiester and phosphotyrosyl bonds during cleavage
and rejoining reactions (24, 25).
Despite the novelty of being catalyzed by two different recombinases,
the biochemical steps of Xer recombination appear to be similar to
those described for others systems of the integrase family (1, 2).
XerC and XerD bind, respectively, to the left and right halves of the
core sequence in a cooperative manner (9). Each protein specifically
cleaves one of the DNA strands at the position which separates its
binding arm from the central region (Fig. 1; Refs. 26 and 27). Strand
exchanges at plasmid sites occur in a sequential manner. XerC catalyzes
the first pair of strand exchanges to form a Holliday
junction-containing intermediate which is eventually resolved by XerD
to generate the recombination products (12).
In this paper, we report the characterization of a site-specific topoisomerase activity of both XerC and XerD. We show that XerC and XerD relax supercoiled plasmids containing the dif site in vitro. Relaxation occurs in the absence of the partner recombinase and appears not to require contact between distant recombinase-DNA complexes. Formation of a XerC-XerD-dif complex results in reciprocal inhibition of XerC and XerD relaxation activities.
Plasmids used as substrates have been described previously (9, 12, 13). Purification of wild type and mutated XerC and XerD proteins used the procedure of Colloms et al. (12). Construction of the xerCY275F, xerDY279F, and xerDR274Q mutations has been described previously (9). Construction of the xerDH244L and xerDR148K mutations will be reported elsewhere.2
General ProceduresChemicals where from Sigma, BDH, Life Technologies, Inc., and Boehringer Mannheim. E. coli topoisomerase I was purchased from New England Biolabs and was used as recommended. Chloroquine was from Sigma, SYBR-Green from Flowgen, and bovine serum albumin from New England Biolabs. DNA purification and manipulation, gel electophoresis, staining, and photography involved standard procedures (28). Agarose gels were first stained with SYBR-green and scanned in a Molecular Dynamics FluoroImager 575. Quantitative analysis was performed using ImageQuaNT software. After destaining, gels were restained with ethidium bromide and photographed.
In Vitro Relaxation ReactionStandard relaxation reactions contained 300 ng of supercoiled plasmid substrate in a final volume of 20 µl of "relaxation buffer" (50 mM Tris-HCl, pH 8.0, 50 mM KCl, 1.25 mM EDTA, 5 mM spermidine, 0.25 µg/ml bovine serum albumin, and 40% (v/v) glycerol) and 1 µl of protein in their respective dilution buffers (25 mM Tris-HCl, pH 8.0, 0.25 mM EDTA, 500 mM NaCl, 1 M urea, and 50% (v/v) glycerol for XerC; and 125 mM imidazole, 5 mM NaCl, 0.5 mM EDTA, 10 mM sodium acetate, pH 5.O, and 50% glycerol (v/v) for XerD). Final concentrations of the proteins are 1.1 µM for XerC and 0.125 µM for XerD. After 16 h of incubation at 37 °C, DNA was ethanol-precipitated and analyzed by electrophoresis on 1% agarose gels (0.5 V/cm, 16 h).
Purification of Plasmid TopoisomersPlasmid pMIN33 topoisomers were separated on a 1% agarose gel (Sea Kem GTG-agarose from Bioproducts) containing 2 µg/ml chloroquine. The gel was run for 16 h in TAE buffer containing 2 µg/ml chloroquine and stained with ethidium bromide. Bands corresponding to single topoisomers were excised from the gel on a 365-nm UV transilluminator. DNA was extracted from the gel slices by electroelution, ethanol-precipitated, and resuspended in 20 µl of water. 5 µl was used for each relaxation reaction.
The E. coli chromosomal site dif exhibits no recombination
activity in vitro on duplex recombination sites contained
within supercoiled plasmids, under conditions where the plasmid sites psi and cer recombine efficiently (12). However,
prolonged incubation of the plasmid, pMIN33, containing a single
dif site, with either purified XerC or XerD led to the
appearance of new DNA forms (Fig. 2,
lanes 5 and 6). These new forms comigrated with
relaxed topoisomers of the substrate obtained by partial treatment with
E. coli topoisomerase I (Fig. 2, lane 7). Phenol
extraction of the reactions, whether or not preceeded by treatment with
proteinase K, did not alter this pattern of bands indicating that the
novel species were not DNA-protein covalent complexes (data not shown).
We conclude that the new forms are relaxed topoisomers of the substrate
formed by XerC- and XerD-mediated catalysis. For both pMIN33 and
pSDC124, a plasmid containing two dif sites in direct
repeat, the restriction enzyme digestion patterns of the substrates
were not changed during incubation (data not shown). Therefore
relaxation is not proceeding through recombination. Relaxation depends
on the presence of the recombination site on the substrate as the
cloning vector, pUC18, is not relaxed by either XerC or XerD (Fig. 2,
lanes 2 and 3). We therefore conclude that XerC
and XerD can act as site-specific topoisomerases on
dif-containing substrates.
Both XerC and XerD relaxation activities increased with added glycerol and showed an optimal efficiency at a KCl concentration of 50 mM (data not shown). Titration of either protein in relaxation reactions showed that both are present in saturating amounts in standard reactions (see "Materials and Methods"). Even under these optimal conditions, relaxation by either XerC or XerD appears to be a slow process when compared with recombination at plasmid sites in vitro (12). Products were barely detectable after 1 h and increased up to 8 h of incubation at which time 30 to 40% of the substrate was processed (data not shown).
XerC and XerD Catalytic Residues Are Required for Relaxation ActivityMutants in three residues of the RHRY tetrad of XerD
(R148K, R247Q, and Y279F) and of the catalytic tyrosine of XerC
(Y275F), are defective in the cleavage step of catalysis (9, 12, 26, 27).3 These mutants were also
defective in relaxation (Fig. 3),
suggesting that cleavage during relaxation and recombination involve
the same residues and mechanism.
XerDH244L is mutated for the conserved histidine of the RHRY tetrad of XerD. Like its counterpart in the Flp recombinase (25), XerDH244L cleaves Holliday junction-containing DNA substrates efficiently, but religates the cleaved DNA strands poorly, resulting in the accumulation of protein-DNA covalent complexes.4 This failure to religate DNA leads to the accumulation of a nicked form of the substrate to which XerDH244L is covalently bound. No new DNA species or increase in the intensity of the open circle band was detectable in relaxation reactions with XerDH244L, even after release of possible protein-DNA covalent complexes by treatment of the reaction with proteinase K (Fig. 3 and data not shown). XerDH244L is therefore defective in cleavage in relaxation reactions but not in recombination reactions, that require exchange of strands with a partner duplex within a complex containing two bound XerC molecules and two bound XerD molecules. The reasons for this difference may reside in the structure of the nucleoprotein recombination complex and/or in the conformation of the DNA substrate, since XerD resolves Holliday junction-containing DNA molecules during recombination whereas the substrates used in relaxation are unbranched. Catalysis by XerD on linear and X-shaped DNA substrates may therefore involve different catalytic residues within a given recombinase protomer.
XerC and XerD Are Type I TopoisomerasesTopoisomerases have
been classified into type I or type II topoisomerases on the basis of
whether they change the linking number of the DNA substrate in steps of
one (type I), or two (type II) (3, 4). To investigate whether XerC and
XerD are type I or II topoisomerases, relaxation reactions were
performed using a purified single topoisomer of pMIN33 as substrate
(Fig. 4). XerC- and XerD-mediated
relaxation of this substrate yielded the same band pattern as the
substrate containing a mixture of topisomers (Fig. 4B).
Since this behavior is expected only from a type I enzyme, XerC and
XerD are site-specific type I topoisomerases.
For XerD- and XerC-mediated relaxation, proccessed DNA molecules appear to be almost completely relaxed whereas the majority of the substrate has not been proccessed (Fig. 2). Absence of extensive relaxation of the species running as fully supercoiled DNA has been confirmed by two-dimensional gel electrophoresis (data not shown). In addition, the relative distribution of the relaxed topoisomers bands did not vary with varying reaction efficiency, for example, during time courses, protein titrations, or glycerol ranges (data not shown). This suggests that relaxation by XerC and XerD occurs in one of two ways. First, only one supercoil could be relaxed per cleavage event, the recombinase remaining bound to the site after religation and being strongly prone to continue relaxing the same DNA molecule. Second, the cleaved DNA strand could be free to rotate about the intact one a large number of times before religation, leading to a large number of supercoils relaxation per cleavage event. This second mechanism seems the most plausible because it correlates better with what XerC and XerD topoisomerase activities may reflect, i.e. aberrant behavior of enzymes displaced from their normal catalytic environment (see below). Furthermore, if relaxation was processive, changes in the reaction conditions such as salt concentration might modify the behavior of the recombinases by changing their dissociation rate from the DNA thus favoring their turnover between different DNA molecules. No change in the relative quantities of the topoisomers were observed when the KCl concentration was varied between 25 and 200 mM in the reactions (data not shown). This would argue against the processive relaxation hypothesis.
Topoisomer Activity Does Not Appear to Require Synapsis between Distant SitesThe relaxation activities of XerC and XerD show
that either recombinase can catalyze strand cleavage and rejoining in
the absence of its partner. However, catalysis may require interactions between protomers of the same recombinase bound to two distant sites.
This question was investigated by performing a series of relaxation
reactions at different recombinase/DNA-substrate ratios. If any
interaction between distant sites was require for catalysis, the
efficiency of the reaction should decrease as a second order function
with respect to the substrate concentration under saturating protein
conditions. Reaction efficiency should not vary with substrate concentration if interactions between sites are not required. Substates
carrying one or two dif sites were also compared, reasoning that the effect of substrate dilution on relaxation efficiency should
be far less dramatic for a plasmid containing two sites in the
eventuality of a dependence on synapsis. For both types of substrates,
no significant variation in XerD relaxation efficiency over a 5-fold
dilution of the substrate was observed (Fig.
5). For XerC, a slight decrease of
activity with substrate dilution was noted (Fig. 5). However, this
dependence is not a second order dependence and is equally detectable
on substrates containing one dif site (pMIN33) or two
dif sites either in direct or in inverted orientation
(pSDC124 and pGB105, respectively, Fig. 5). The observed decrease in
XerC activity is therefore unlikely to reflect a requirement for an
interaction between distant sites. This is supported by the observation
that cleavage by XerC on linear substrates shows a linear decrease with
respect to protein concentration, as would be predicted if no synapsis
is required (27). Therefore, XerD and XerC relaxation activities are
not likely to require synapsis between distant recombination sites.
XerC and XerD Inhibit the Relaxation Activity of the Partner Recombinase
Plasmid relaxation by either XerC or XerD is observed
when only one of the two recombinases is present in the reaction.
Addition of the partner recombinase results in a total inhibition of
either XerC or XerD topisomerase activity (Fig.
6). This reciprocal inhibition does not
require the catalytic activity of the inhibiting partner since the
catalytically inactive mutants XerCY275F and XerDY279F inhibit the wild
type XerD and XerC, respectively (Fig. 6, lanes 5 and
6). A series of relaxation reactions on plasmids containing only the left half (XerC-binding site, pGB206) or the right half (XerD-binding site, pGB205) of the dif site (9) was
performed to assess whether inhibition is dependent on binding to the
core sequence. pGB205 is relaxed by XerC but not by XerD and vice versa for pGB206 (Fig. 6, lanes 8, 9, 12, and 13).
Thus, relaxation does not require the presence of the binding site for
the absent recombinase and a given recombinase can only mediate
relaxation when it interacts with its own binding site; if there is any
weak interaction with the partner recombinase-binding site it does not
lead to relaxation. Reciprocal inhibition no longer occurs on pGB205
and pGB206 (Fig. 6, lanes 10 and 14), showing
that it only occurs within a complex where both recombinases are bound to the core sequence (note the partial inhibition of XerD relaxation activity by XerC in lane 14 when compare with lane
13 which is consistent with the weak binding of XerC to the
mutated dif site present in pGB205 in presence of XerD, Ref.
9). This strongly suggests that reciprocal inhibition proceeds through
XerC-XerD interactions across the core sequence. No inhibition of
XerD-mediated relaxation upon binding of two XerD protomers to a
mutated dif site in which the XerC-binding site has been
changed to an XerD-binding site was observed (data not shown). This
confirms that specific XerC-XerD interactions are required for
inhibition.
During a complete recombination reaction, site-specific recombinases catalyze two pairs of DNA strand exchanges between two recombination sites (1, 2). In this process, recombinases catalyze both the cleavage and the rejoining steps, using covalent protein-DNA complexes as intermediates, a property shared by topoisomerases. Consistent with this, most of the well studied recombinases have been shown to act as topoisomerases in vitro by relaxing supercoiled DNA without recombining it (5-7). In this report, we characterize the topoisomerase activities of E. coli XerC and XerD and indicate how recombinase-recombinase interactions may be important in controlling the topoisomerase activity of site-specific recombinases.
Relaxation of supercoiled plasmids by either XerC or XerD occurs
in vitro providing that the plasmid substrate contains their respective DNA recognition sequence. It occurs in the absence of the
recombinase partner and is unlikely to require any contact between
distant recombinase-bound sites. This supports a simple "swivel"
type mechanism in which a single recombinase protomer bound to its DNA
recognition sequence cleaves one of the two DNA strands which is then
free to rotate about the intact one before being resealed. The pattern
of topoisomers formed upon relaxation by either XerC or XerD suggests
that relaxation occurs in a process in which a single cleavage event
can lead to loss of a large number of supercoils before rejoining. This
view is supported by the observation that a wide range of reaction
conditions, which would be expected to influence recombinase binding,
did not change the pattern of relaxation. The swivel mechanism has been
proposed to account for relaxation by eucaryotic type I-3
topoisomerases, that also use a 3
-phosphotyrosine DNA-protein covalent
complex as a reaction intermediate (4, 22, 23).
Experimental evidence has shown that XerC and XerD cleave the phosphodiester bonds adjacent to their respective binding sites and do so independently of the catalytic activity of the partner recombinase (Fig. 1) (12, 26, 27). This eliminates models in which either recombinase would be implicated in cleavage of the phosphodiester bond activated by its partner. The fact that relaxation occurs in the absence of the partner recombinase is consistent with that. The observation that relaxation is unlikely to require contact between recombinase-DNA complexes also indicates that single protomers of either XerC or XerD do not need to interact with a second molecule of the same recombinase to catalyze cleavage and rejoining, at least in a reaction which leads to relaxation. Whether XerC and XerD are catalytically autonomous in all stages of a complete recombination reaction remains to be clarified.
Relaxation is inefficient when compared with the relatively fast rate
of strand exchange observed for in vitro recombination reactions (12, 26). Under most experimental conditions, strand exchange
mediated by XerC or XerD require the partner recombinase be present (9,
11, 26), although on linear nicked "suicide" substrates a low level
of XerD-independent XerC-mediated cleavage was observed (27). This
suggest that catalysis during a recombination reaction requires binding
of both recombinase for the activation of each of their catalytic
activities (a phenomenon referred to as "cross-core stimulation" in
the case of integrase; Ref. 30). The relaxation activities we
observe are probably residual low activities that may not have any
biological significance. However, these activities provide a powerful
tool for study the catalytic functions of the recombinases and
recombinases interactions when bound on DNA.
An interesting observation is that XerD relaxes cer containing plasmids, albeit less efficiently than dif containing substrates (data not shown). This was unexpected since cleavage or strand exchange by XerD on cer containing substrates has never been detected in vitro using different recombination assays (12, 26). Consistent with that, XerD catalytic activity is not required for recombination at cer in vivo (12). Recent experiments point out that XerD-mediated strand exchange on dif containing Holliday junctions depends on the spatial configuration of the four DNA strands forming the junction (20). It is proposed that cer containing Holliday junctions adopt an unappropriate configuration for XerD catalysis to occur. XerD-mediated catalysis on unbranched substrates in the absence of XerC could been released from this topological constrain.
The reciprocal inhibition of XerC and XerD relaxation activities by the partner recombinase requires the presence of the DNA recognition sequence for the inhibiting partner and is therefore mediated by XerC-XerD interaction through the core sequence of dif. This highlights the importance of cooperative interactions between recombinases in the control of their catalytic activities. Inhibition of relaxation could occur at the level of cleavage, cleavage not being allowed until a synaptic complex competent for recombination is correctly assembled. Assembly of the synaptic complex would then couple cleavage to strand exchange. Alternatively, XerC-XerD interactions could prevent rotation of the cleaved strand about the intact one, or could stimulate the rejoining step which would then always occurs without providing an opportunity for rotation.
How are XerC and XerD relaxation activities and reciprocal inhibition
related to the topoisomerase activities displayed by others systems of
the integrase family? Two other members of the family have been
shown to relax supercoiled plasmids in vitro using a type I
topoisomerase activity:
integrase itself and the Cre recombinase of
bacteriophage P1. In both cases relaxation is by far less efficient
than strand exchange and the pattern of topoisomers obtained after
relaxation resembles those obtained with XerC and XerD (5, 7).
Moreover, to the best of our knowledge, Cre-mediated relaxation was
only observed on a substrate containing a mutated recombination site in
which 1 bp had been removed from the central region (7). This reduces
the spacing between the two Cre recognition sequences and might modify
or impair the interaction between the two Cre protomers resulting in
reciprocal inhibition release. Relaxation by
integrase occurs with
the same efficiency on substrates with or without a recombination site
(5). This has been proposed to occur upon recognition of "pseudo
half-recombination sites" present on the substrates (31). The fact
that relaxation is not improved by the presence of a bona fide
recombination site on the substrate suggest that binding of two
integrase protomers to the recombination site results in reciprocal
inhibition in this system too. Taken together, these data suggest that
the relaxation mechanism of XerC and XerD, and the way in which it is
controlled, is similar to that of other members of the family. Perhaps
significantly, the only well studied recombinase of the family for
which no relaxation activity has been described so far is Flp, for
which, all of the evidence suggests, needs two protomers to form a
single active site capable of cleavage and rejoining (29).
We thank Andrew Spiers, Rachel Baker, and Sean Colloms for supplying the purified proteins used in this study. Many thanks to Finbarr Hayes and Garry Blakely for critical reading of the manuscript.