(Received for publication, August 4, 1994; and in revised form, October 12, 1994)
From the
T-DNA processing during agroinfection of plants is initiated by
site- and strand-specific incision at the T-DNA border sequences of the
Ti plasmid. Two proteins are required for this reaction: VirD2 (49.6
kDa), catalyzing a site-specific cleaving-joining reaction on
single-stranded DNA in vitro (Pansegrau, W., Schoumacher, F.,
Hohn, B., and Lanka, E.(1993) Proc. Natl. Acad. Sci. U. S. A. 90, 11538-11542), and VirD1 (16.1 kDa), an accessory protein
required for VirD2-mediated specific cleavage of double-stranded DNA.
Following efficient overproduction, VirD1 was isolated in active form
from inclusion bodies and purified to near homogeneity. The protein was
applied together with purified VirD2 protein for specific cleavage of
double-stranded T-DNA border sequences in vitro. The reaction
proceeds on negative superhelical DNA and requires Mg ions. Relaxed DNA is not cleaved. The 5` terminus of the broken
DNA strand is covalently associated with protein, most probably VirD2,
and the cleavage site is located at the same position that is found in vivo, indicating that the in vitro reaction mimics
the one that takes place in induced agrobacteria. Relaxation of plasmid
DNA occurs only upon addition of protein denaturants, suggesting that
the DNA in the VirD1/VirD2 complex is topologically constrained by
strong protein-DNA interactions. The characteristics of the
VirD1/VirD2-mediated cleavage reaction strongly resemble those observed
with relaxosomes of IncP plasmids involved in initiation of transfer
DNA replication during bacterial conjugation.
Agrobacterium tumefaciens is a prokaryotic plant
pathogen that transforms plant cells by a unique interkingdom DNA
transfer system. A particular DNA stretch of its 200-kb ()tumor-inducing (Ti) plasmid, the T-DNA, is transferred and
stably integrated into the plant genome (Winans, 1992; Zambryski,
1992). Expression of the transferred DNA (
20-30 kb) in the
plant cell leads to autonomous production of the plant hormones auxin
and cytokinin, resulting in tumor formation. Furthermore, the T-DNA
directs the synthesis of specific amino acid derivatives (opines) that
are exported by the transformed plant cell allowing A. tumefaciens to utilize these opines as the sole carbon and nitrogen source for
growth (Zambryski et al., 1989).
Functions required for
T-DNA transfer are encoded by the virulence (Vir) region (30 kb)
of the Ti plasmid. Expression of the DNA transfer machinery specified
by this region is stringently regulated. vir gene expression
is induced by chemical signal molecules (phenolics and sugars) released
from wounded plant cells (Winans, 1992). Recognition of these signals
by the sensor protein VirA leads to phosphorylation of VirG protein,
upon which VirG activates expression of the other vir operons (virB, virC, virD, virE, and virF) (Jin et al., 1990; Stachel and Zambryski,
1986). DNA processing involves (i) recognition and complexing of 25-bp
direct repeats flanking the T-DNA, the T-border sequences, by virD gene products (Filichkin and Gelvin, 1993; Jayaswal et
al., 1987; Yanofsky et al., 1986); (ii) single-stranded
incisions within the T-borders leading to covalent attachment of the
VirD2 protein to the 5` terminus of the T-DNA
(Dürrenberger et al., 1989; Howard et
al., 1989; Pansegrau et al., 1993a; Young and Nester,
1988); (iii) DNA transport requiring displacement of the T-DNA and its
protection by coating with the ssDNA-binding protein VirE2 (Gietl et al., 1987; Christie et al., 1988; Citovsky et
al., 1989). The resulting nucleoprotein complex, the T-complex, is
exported to the plant cell, probably through a transmembrane pore
consisting of gene products specified by the virB operon
(Kado, 1994; Kuldau et al., 1990; Lessl and Lanka, 1994;
Shirasu et al., 1990; Thompson et al., 1988; Ward et al., 1988). Inside the plant cell, targeting of the
T-complex into the nucleus is directed by nuclear localization signals
present in VirD2 (Citovsky et al., 1994; Rossi et
al., 1993; Tinland et al., 1992) and VirE2 (Citovsky et al., 1992, 1994) using the nuclear import machinery of the
plant. Insertion of the T-DNA in one of the host's chromosomes
might involve catalysis by the 5`-terminal attached VirD2 protein
(Gheysen et al., 1991; Mayerhofer et al., 1991;
Pansegrau et al., 1993a).
Data have accumulated that
suggest a close relationship between T-DNA transfer from Agrobacterium spp. to plants and IncP plasmid-mediated
bacterial conjugation. Sequence relations have been found between four
components: the nick regions of T-borders and the IncP transfer origin
(Pansegrau and Lanka, 1991; Waters et al., 1991; Waters and
Guiney, 1993) and gene clusters of the VirD operon/relaxase operon
(Lessl and Lanka, 1994; Pansegrau and Lanka, 1991; Pansegrau et
al., 1994a, 1994b; Ziegelin et al., 1991), VirC/leader
operon (Pansegrau et al., 1994a), and VirB/Tra2 region of
pTi/IncP plasmids (Lessl et al., 1992), respectively. The gene
organization of the corresponding operons is highly conserved, and a
high degree of sequence identity between the primary structures of gene
products indicates evolutionary relationship of the DNA transfer
systems (Pansegrau et al., 1994a). Although there is little
sequence similarity detectable, the pTi virE2 gene product
seems to be functionally analogous to the TraC1 primase of IncP plasmid
RP4 concerning DNA binding properties. Both proteins have been shown to
be transported together with the DNA to recipient cells and therefore
are supposed to coat and protect the ssDNA during transfer (Gietl et al., 1987; Christie et al., 1988; Citovsky et
al., 1989, 1992, 1994; Rees and Wilkins, 1990). However, a primase
activity has not been detected in the VirE2 protein. ()
The pTi VirB region is related to three other
macromolecular transport systems, the pilus gene clusters of IncW ()and IncN plasmids (Pohlman et al., 1993) and the
Ptl operon of Bordetella pertussis mediating export of the
pertussis toxin (Weiss et al., 1993). However, the closest
relationship exists between the Ti system and IncP plasmids because
both the DNA processing and the DNA transport functions are similar in
organization and primary structure. The relationship to IncN and IncW
plasmids appears to be limited mainly to the DNA transport system.
These findings suggest that in the course of the evolution of the
different DNA transfer systems modules of different origin have been
combined and adapted to form functional conjugation machineries or, in
one case, a toxin transport system.
The mechanism of T-DNA transfer
shows striking similarity to bacterial conjugation mediated by IncP
plasmids; in both systems, a DNA single strand is transferred with the
5` end leading (Al-Doori et al., 1982; Grinter, 1981;
Zambryski, 1992). During transfer, the 5` terminus is thought to remain
covalently associated with the relaxase (VirD2/TraI)
(Dürrenberger et al., 1989; Howard et
al., 1989; Pansegrau et al., 1990b, 1993a, 1993b; Young
and Nester, 1988). Functional similarity between VirD2 and TraI has
also been detected in vitro; VirD2 and TraI catalyze
site-specific cleaving-joining reactions on single-stranded
oligonucleotides reaching an equilibrium when 35-40% of the input
DNA exists in the cleaved form (Pansegrau et al., 1993a,
1993b). The reactions are Mg ion-dependent and occur
at the same position, relative to the consensus nick region. Cleavage
results in formation of a covalent VirD2/TraI-oligonucleotide adduct in
which the protein is attached to the 5`-terminal nucleotide at the nick
site. Peptide mapping of such VirD2-oligonucleotide adducts identified
tyrosine 29 as the residue that forms a phosphodiester with the
nucleotide at the 5` end (Pansegrau et al., 1993a). A
mutational analysis of the virD2 gene had also shown that
tyrosine 29 is the only tyrosine residue within VirD2 that cannot be
replaced without loss of activity (Vogel and Das, 1992a). In agreement
with previous studies that assigned the attachment site of the IncP
relaxase TraI to tyrosine 22 (Pansegrau et al., 1993b),
tyrosine 29 of VirD2 is located within the conserved relaxase motif I
(Ilyina and Koonin, 1992; Koonin and Ilyina, 1993; Pansegrau et
al., 1994a, 1994b).
In the IncP system, the corresponding reaction on dsDNA in addition to the TraI relaxase requires the accessory protein TraJ (Pansegrau et al., 1990a). TraJ is a specific oriT-binding protein (Ziegelin et al., 1989) proposed to form a nucleoprotein complex with negatively superhelical oriT DNA that can be recognized by TraI (Pansegrau et al., 1990a). VirD1 could play an analogous role in the Ti system since virD1 and virD2 are the only determinants essential for T-border-specific cleavage in vivo.
Any DNA sequence located between T-borders can be transferred efficiently; therefore, plant oncogenes and genes for opine catabolism may be replaced by any other gene of interest. The resulting so-called disarmed vectors are extremely helpful as widely used tools for genetic manipulation or engineering of plant cells by transformation. However, T-DNA transfer is limited in its host range, allowing efficient transformation of most dicotyledonous, but of only a few monocotyledonous, plants. Since monocots are of great economic importance, it is desirable to find efficient methods allowing their genetic transformation. A possible way could consist in generation of the T-complex in vitro and subsequent transfer into plant cells by common methods such as microinjection or particle gun transformation. Since VirD2 and VirE2 possess nuclear localization signals (Citovsky et al., 1992, 1994; Rossi et al., 1993; Tinland et al., 1992), higher transformation rates than with conventional methods are expected. A prerequisite for these experiments is the in vitro reconstitution of the initiation complex active in T-border-specific DNA cleavage.
Here we report the overproduction and purification of VirD1 protein of the A. tumefaciens plasmid pTiC58. Efficient overproduction of VirD1 in Escherichia coli required exchange of the natural ribosome binding site against that of bacteriophage T7 gene 10 and replacement of a cluster of rare Arg codons within the virD1 structural gene. The purified VirD1 protein together with VirD2 relaxase (Pansegrau et al., 1993a) was applied to cleave superhelical plasmid DNA containing T-border sequences in vitro. The in vitro cleavage reaction was shown to mimic the virD1/virD2-dependent T-border cleavage reaction observed in vivo in terms of site and strand specificity, resulting in covalent attachment of the VirD2 relaxase to the 5` terminus of the cleaved DNA strand. Implications for the mechanism of T-DNA processing and functional analogies to DNA processing during bacterial conjugation are discussed.
Figure 1:
Construction of virD1 overexpression plasmid pPS20. Upper panel,
nucleotide sequence flanking the initiation codons in pTiC58/pVir97.89
(Alt-Mörbe and Schröder, 1986)
and a sequence stretch 40 bp upstream of the stop codon. The
Shine-Dalgarno sequence (S/D) is indicated by a horizontalline; potential initiation codons are shown as blackboxes with whiteletters. MaeIII restriction enzyme recognition site is marked by a bracket above the sequence. Lowerpanel, to
construct the virD1 overexpression plasmids, the 464-bp MaeIII-SacI fragment of pVir97.89 carrying the virD1 reading frame except for the first 10 codons was
inserted in the NdeI and SacI sites of the polylinker
of the T7 promoter 10/gene 10 S/D expression
plasmid pT7-7. The 5` end of the gene was restored using synthetic
oligodeoxyribonucleotides (printed in lowercaseletters) to link the SacI cohesive end of the virD1 fragment to the NdeI-end of the vector. The
oligonucleotides carried codons from the MaeIII site to start
1 or start 2, respectively. Nucleotides of rare CGG Arg codons 40 bp
upstream of the stop codon (nucleotides 1048-1056 of Atuvird,
GenBank accession number M33673) indicated by arrows were
changed by site-directed mutagenesis. To place the manipulated virD1 gene under the control of the chemically inducible tac promoter a XbaI-SacI fragment (533 bp),
carrying the manipulated gene, together with the T7 gene 10 S/D sequence, was inserted in the multi-cloning site of pMS119HE.
Resulting overexpression plasmids (Table 1) are: pPS20, carrying
alternative Arg codons; pPS13, carrying wild-type Arg codons; pPS22,
carrying alternative Arg codons and start 1; pPS15, carrying wild-type
Arg codons and start 1. A plasmid encoding the gene under its original
translational control was obtained inserting a 530-bp HindIII-SacI fragment from pVir97.89 in the
multicloning site of pMS119HE, resulting in pPS9. The amino acid
sequence of VirD1 is shown below the nucleotide sequence. The
underlined part was confirmed by N-terminal microsequencing.
Polypeptides resulting from initiation of translation at start 1
yielded the N-terminal sequence
M-E-E-A-M-S-Q-G-S-R.
The virD1 gene of pTiC58 including the original translational initiation site was placed under control of the LacI-regulated tac promoter in the expression vector pMS119HE. The resulting plasmid was called pPS9 (Table 1). To allow effective translational initiation in E. coli fusions of start 1 or start 2 with the S/D sequence of phage T7 gene 10 were constructed that resulted in plasmids pPS15 (start 1) and pPS13 (start 2). The rare Arg codons in these two plasmids were replaced by alternative Arg codons using site-directed mutagenesis. Resulting plasmids were named pPS22 (start 1) and pPS20 (start 2) ( Fig. 1and Table 1). Gene products specified by all the constructs were identified and quantified by immunoblotting (Fig. 2). As expected, cells carrying plasmid pPS9 with the original 5` end of virD1 expressed low amounts of a 16-kDa polypeptide (Fig. 2, lane a). In cells containing plasmid pPS13 (start 2, wild type Arg codons) the yield of this polypeptide was approximately 10 times higher (Fig. 2, lane b). Truncated forms of VirD1 were still produced but were absent in extracts of SCS1(pPS20) containing the alternative Arg codons in virD1 (Fig. 2, lanes b and d; Table 1). In cells carrying constructs with start 1 (pPS22 and pPS15) translation initiated at both, start 1 and 2; consequently two VirD1 polypeptide versions were produced. Four products were observed if the rare Arg codons were present (Fig. 2, lanes c and e; Table 1). The N termini of these four polypeptides were determined by microsequencing. The amino acid sequence of the two upper bands corresponded to peptides derived from start 1, that of the two lower bands to translational initiation at start 2. These results verify that both AUG codons are used for initiation of translation. It also suggests that truncation occurs at the C terminus of VirD1 resulting from premature termination of translation caused by the cluster of rare Arg codons. The N-terminal sequences of the product of SCS1(pPS20) (S/D T7 gene 10/start 2 and alternative Arg codons) and the lower band produced by SCS1(pPS22) (S/D T7 gene 10/start 1 and alternative Arg codons) are identical and correspond to start 2. We concluded that start 2 functions as the predominantly used translational initiation site because the size of the polypeptide specified by pPS9 and that of the smaller one specified by pPS22 are identical. In both constructs the original sequence around start 2 was preserved. In SCS1(pPS20) virD1 translation initiates at start 2 and high levels of VirD1 are produced without contaminating truncated forms; hence, this clone was used for overproduction and subsequent purification of the protein. Following chemical induction of gene expression by IPTG addition to the culture medium, approximately 8% of SDS-soluble cell protein consisted of VirD1 (Fig. 3, lane b).
Figure 2:
Solid phase immunoassay of overproduced
VirD1 proteins. Extracts of SCS1 cells induced for 4 h by addition of 1
mM IPTG to the culture carrying various plasmids were loaded
on a 17.5% polyacrylamide gel containing 0.1% SDS. Following
electrophoresis proteins were transferred to a nitrocellulose membrane
by electroblotting and detected as described under
``Experimental Procedures.'' Lanea, pPS9 (300 A units of cells); lane b, pPS13 (75 A
); lane c,
pPS15 (25 A
); lane d, pPS20 (51 A
); lane e, pPS22 (17 A
); lane f, pMS119HE (75 A
); lane g, molecular mass standards
bovine serum albumin (BSA, 68 kDa) and lysozyme (LYS,
14.3 kDa) labeled with fluorescein
isothiocyanate.
Figure 3: Purification of VirD1 protein. Samples were electrophoresed on a 17.5% polyacrylamide gel containing 0.1% SDS. The gel was stained with Serva Blue R. Lane a, SCS1(pPS20), no IPTG was added; lane b, SCS1(pPS20), cells were induced for 4 h with 1 mM IPTG; lanes c-e, fractions I-III (35, 14, and 9 µg of protein, respectively); lane f, molecular mass standards: bovine serum albumin (BSA, 68 kDa), ovalbumin (OVA, 46 kDa), chymotrypsinogen A (CHYA, 25.7 kDa), lysozyme (LYS, 14.3 kDa), and aprotinin (APR, 6.5 kDa).
Figure 4:
Specific cleavage of T-border plasmids
catalyzed by VirD1 and VirD2. A, various plasmids were
incubated with VirD proteins under conditions described under
``Experimental Procedures'' and electrophoresed in a
0.7% agarose gel (89 mM Tris borate, pH 8.0, 2 mM EDTA) at 1.5 V/cm. Lanes a-e, pPS100 (right border,
0.7 µg of DNA); a, proteins omitted; b, 500 ng of
VirD1; c, 60 ng of VirD2; d, 500 ng of VirD1 and 60
ng of VirD2, MgCl omitted; e, 500 ng of VirD1 and
60 ng of VirD2; lanes f and g: pPS101 (right and left
border, 0.7 µg of DNA); f, proteins omitted; g,
500 ng of VirD1 and 60 ng of VirD2; lanes h and i:
pBR329 (0.7 µg of DNA); h, proteins omitted; i,
500 ng of VirD1 and 60 ng of VirD2. B, schematic diagram of
design of T-border plasmids. Synthetic oligonucleotides symbolized by boxes were inserted in resistance genes of plasmid pBR329
(shown as arrows). Base pair coordinates of restriction sites
in pBR329(4151) are BamHI (606), SalI (882), PstI (2755), and AatII (3432) (Covarrubias and
Bolivar, 1982). The corresponding size of the substrates is given in
base pairs.
Previously, a nonspecific DNA relaxation activity was reported for VirD1 containing extracts (Ghai and Das, 1989). Under our conditions and also using the conditions described by Ghai and Das(1989), this activity was never observed with purified VirD1 protein that is active in T-border cleavage (Fig. 4, lane b). E. coli and calf thymus topoisomerase I served as positive controls; upon incubation with the topoisomerases, all of our DNA substrates gave a spectrum of topoisomers independent of whether vector DNA or T-border DNA was used (data not shown). Under our conditions, superhelicity of the DNA was an essential prerequisite for specific T-border cleavage by VirD1/VirD2, and form III and form IV DNA did not act as a substrate (data not shown). This finding is analogous to that of the cleavage reaction at RP4 oriT catalyzed by TraI and TraJ protein, which also required superhelical DNA substrates (Pansegrau et al., 1990a). While the nick regions of RP4 oriT and pTi T-borders share close sequence similarity (Pansegrau and Lanka, 1991; Waters et al., 1991) and VirD2 cleaves RP4 nick region oligonucleotides (Pansegrau et al., 1993a). VirD1 and VirD2 together failed to cleave oriT form I plasmid DNA (data not shown). TraJ instead of VirD1 in the reaction mixture did not stimulate cleavage of RP4 oriT DNA by VirD2 (data not shown). These results indicate the higher degree of specificity of the dsDNA cleavage reaction as compared to ssDNA cleavage and suggest that VirD1 contributes to the stringency of T-border recognition on dsDNA substrates.
Figure 5: Analysis of cleavage products. A, pPS100 form II DNA specifically cleaved by VirD1/VirD2 in vitro was isolated from 0.7% agarose gels. 1.5 µg of DNA were linearized with either XmnI or AatII, denatured in 0.1 M NaOH and electrophoresed for 6 h (3.5 V/cm) on a alkaline 0.7% agarose gel (McDonnell et al., 1977). Lane M contains a 1-kb ladder (Life Technologies, Inc.). B, the physical structure of pPS100 and the corresponding cleavage products including the position of the cleavage site (nic) are drawn schematically.
Figure 6: Nucleotide sequencing of the 5` terminus of specifically cleaved T-border plasmid DNA. I, pPS100 form II DNA (0.5 µg) specifically cleaved by VirD1/VirD2 was used as substrate for primer extension. Reactions were initiated at a 24-mer primer [d(GTGCGGCGACGATAGTCATGCCCC)] hybridizing 77 bp downstream from the nic site. II, as a control template pPS100 form I DNA (2 µg) was used for sequencing reactions.
A key event in the initiation of DNA processing for T-DNA transfer resulting in the production of T-complexes is the site- and strand-specific cleavage at the Ti plasmid border sequences. Based on genetic studies, it was demonstrated that this reaction is mediated by products of the Ti plasmid's VirD operon. In particular, the virD1 and virD2 gene products have been shown to be the only Ti-encoded polypeptides required for T-border cleavage (De Vos and Zambryski, 1989; Filichkin and Gelvin, 1993; Jayaswal et al., 1987; Porter et al., 1987; Stachel et al., 1987; Yanofsky et al., 1986). In a previous study, it was also shown that VirD2 alone exerts a site-specific DNA cleaving-joining reaction on single-stranded DNA, indicating that this protein bears the catalytic activity required for DNA scission (Pansegrau et al., 1993a). In vitro experiments employing VirD2 in the presence of dsDNA, either relaxed or supercoiled, failed to detect any border-specific cleavage, suggesting that an essential accessory component for dsDNA cleavage is missing (Pansegrau et al., 1993a). Others reported that even the combination of the purified proteins VirD1 and VirD2 was inactive in specific cleavage of dsDNA (Jasper et al., 1994).
In the present study we demonstrate
that the proteins VirD1 and VirD2 together are sufficient to catalyze
the T-border-specific cleavage on dsDNA in vitro. The reaction
takes place on negative superhelical DNA in the presence of
Mg ions. dsDNA cleavage results in covalent
attachment of a protein (most likely VirD2) to the DNA 5` terminus as
it has been shown for T-DNA single strands that were isolated from
bacterial cells (Dürrenberger et al.,
1989; Howard et al., 1989; Young and Nester, 1988). The
position of the cleaved phosphodiester bond is the same that is found in vivo (Dürrenberger et al.,
1989), indicating that the in vitro reaction described here is
mimicking that occurring in agrobacteria.
What could the role of VirD1 in the dsDNA cleavage reaction be? Obviously, VirD2 recognizes specific nucleotide sequences in ssDNA; therefore, the VirD2 target surface in dsDNA probably is buried. Binding of VirD1 to the T-border could locally distort the DNA double helix structure, exposing the T-border nick region as a single strand for cleavage by VirD2. Negative supercoiling of the DNA, which is an essential requirement for the reaction to occur, could lower the energy required for local strand separation. Alternatively, VirD1 could assemble in a complex with VirD2 in the absence of DNA, resulting in an altered recognition specificity, directed against dsDNA.
Thus far, there is no clear evidence to decide between the two hypotheses. Complex formation of VirD1 with linear double-stranded DNA under our conditions was not detectable by the fragment retardation assay (not shown). However, negative supercoiling of the DNA might also be a prerequisite for binding of VirD1. On the other hand, detection of complex formation between VirD1 and VirD2 by chemical cross-linking in the absence of DNA and analysis of the products by gel electrophoresis did not yield specific VirD1-VirD2 protein-protein complexes (not shown).
Recently, a topoisomerase activity of type I was described for VirD1-containing extracts (Ghai and Das, 1989). This activity was attributed to VirD1 and proposed to be required for relaxing the DNA in order to prepare it for cleavage by VirD2 (Ghai and Das, 1989). In our hands, the purified VirD1 protein never showed any topoisomerase activity. Assuming that the denaturation/renaturation procedures that were applied in our VirD1 purification protocol restored the protein's activities only partially (indeed, the VirD1 preparation is fully active as an accessory component in dsDNA border cleavage), any hypothetical topoisomerase I activity of VirD1 would be anti-productive for T-complex formation since the cleavage reaction requires negative superhelical DNA. It is therefore extremely unlikely that the topoisomerase activity observed by Ghai and Das(1989) originates from VirD1. It is rather VirD2 that possesses a topoisomerase I-like activity (Pansegrau et al., 1993a). The reaction that is catalyzed by VirD2 on ssDNA is a cleaving-joining reaction that reaches an equilibrium when approximately 35-40% of the substrate exist in the cleaved form (Pansegrau et al., 1993a). The observation that only 35-40% of the input form I plasmid DNA can be converted to form II by the combination VirD1/VirD2, even when the proteins are added in great molar excess, parallels this result and suggests that the reaction on dsDNA is an equilibrium reaction too. However, spontaneous relaxation of supercoiled plasmid DNA containing T-borders in the presence of VirD1 and VirD2 has not been observed, indicating that the cleaved plasmid DNA species might be topologically constrained by strong protein-DNA interactions. Indeed, this has been shown for the analogous TraJ/TraI system encoded by the conjugative plasmid RP4 (videinfra). Application of a TraI mutant that is impaired in the interaction with the oriT nick region (TraI S74A) resulted in spontaneous release of plasmid topoisomers demonstrating continuous cleaving-joining (Pansegrau et al., 1994b). As in the VirD1/VirD2 system, cleaved reaction products could be captured only upon addition of protein-denaturing agents like SDS or proteases.
The reactions described for VirD1/VirD2 strongly resemble
those catalyzed by relaxosomes of the IncP plasmid RP4. The RP4
relaxase (TraI) is analogous to VirD2, specifically recognizing
single-stranded substrates containing the nick region of the IncP
transfer origin (oriT) (Pansegrau et al.,
1993b). The corresponding reaction with dsDNA requires the accessory
protein TraJ that binds specifically to a target sequence adjacent to
the nick region (Pansegrau et al., 1990a; Ziegelin et
al., 1989). Formation of the TraJ
oriT nucleoprotein
complex is the first step in a cascade that culminates in the formation
of stable relaxosomes (Pansegrau et al., 1990a). It is
tempting to speculate that TraJ and VirD1 are functional analogs,
although there is only little similarity in their amino acid sequences
(Llosa et al., 1994; Pansegrau et al., 1994a). The
low degree of amino acid sequence similarity might also reflect
different recognition specificities, concerning the target DNA as well
as the respective relaxases with which the proteins interact.
The operons encoding the components required for initiation of transfer DNA replication in the Ti and for relaxosome formation in the IncP system are organized in a strikingly similar manner, and the amino acid sequences of several gene products are similar too, indicating that both systems have evolved from a common ancestor (Pansegrau et al., 1994a; Ziegelin et al., 1991). Formation of stable relaxosomes at T-border sequences has not yet been observed (not shown). However, this is conceivable since relaxosome assembly in the IncP systems requires a third polypeptide component: the chaperone-like TraH protein, which is required for stabilization of the nucleoprotein complex assembled at oriT (Pansegrau et al., 1990a). A possible candidate for a TraH-analogue in the Ti system is the product of the virD3 gene that is, like TraH, non-essential for DNA transfer (Kado and Lin, 1993; Vogel and Das, 1992b). The virD3 gene is located downstream of virD2 at a position that corresponds to that of traH in the IncP system (Pansegrau et al., 1994a).