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Previous Article | Next Article 
Journal of Bacteriology, September 1999, p. 5758-5765, Vol. 181, No. 18
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Bacterial Conjugation Protein MobA Mediates
Integration of Complex DNA Structures into Plant Cells
Ana María
Bravo-Angel,1
Véronique
Gloeckler,2
Barbara
Hohn,2 and
Bruno
Tinland3,*
Friedrich Miescher Institute, CH-4002
Basel,2 and Institute for Plant
Sciences, ETH-Zentrum, CH-8092 Zurich,3
Switzerland, and Cambridge Biomedical Consultants, NL-2517 XE
The Hague, The Netherlands1
Received 11 March 1999/Accepted 15 July 1999
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ABSTRACT |
Agrobacterium tumefaciens transfers T-DNA to plant
cells, where it integrates into the genome, a property that is ensured by bacterial proteins VirD2 and VirE2. Under natural conditions, the
protein MobA mobilizes its encoding plasmid, RSF1010, between different
bacteria. A detailed analysis of MobA-mediated DNA mobilization by
Agrobacterium to plants was performed. We compared the
ability of MobA to transfer DNA and integrate it into the plant genome to that of pilot protein VirD2. MobA was found to be about 100-fold less efficient than VirD2 in conducting the DNA from the pTi plasmid to
the plant cell nucleus. However, interestingly, DNAs transferred by the
two proteins were integrated into the plant cell genome with similar
efficiencies. In contrast, most of the integrated DNA copies
transferred from a MobA-containing strain were truncated at the 5' end.
Isolation and analysis of the most conserved 5' ends revealed patterns
which resulted from the illegitimate integration of one transferred DNA
within another. These complex integration patterns indicate a specific
deficiency in MobA. The data conform to a model according to which
efficiency of T-DNA integration is determined by plant enzymes and
integrity is determined by bacterial proteins.
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INTRODUCTION |
Agrobacterium tumefaciens
evolved to perform a sophisticated version of bacterial conjugation
with a plant cell. The mobilized DNA is a segment of the bacterium's
200-kb Ti (tumor-inducing) plasmid. This DNA (T-DNA, transferred DNA)
is delimited by two 25-bp sites called the left and right borders. Upon
induction by a wounded plant cell, the T-DNA is transferred to the
plant cell nucleus and integrated into the genome. The production and transfer of the T-strand are mediated by the bacterial virulence proteins (Vir proteins; reviewed in references 15, 29, 33, 37,
41, and 46). VirD2, in conjunction with
VirD1, nicks the bottom strand and attaches itself covalently to the 5'
end of the single-stranded T-DNA. The resulting T-strand is released from the Ti plasmid and is then transferred to the plant cell.
Once the T-DNA is in the plant cell, its nuclear import is ensured by
the attached VirD2 protein, which contains the required NLSs (nuclear
localization sequences) for interaction with the import machinery
(16, 32, 43). The single-stranded DNA binding protein VirE2,
also accompanying the T-strand in the plant cell, has been shown to be
important for protecting the T-DNA from nucleolytic attack
(31) and may also facilitate its translocation through the
nuclear pore (33, 37).
Transformation experiments using an Agrobacterium strain
mutated at a particular amino acid in VirD2 revealed that the
integrated T-DNA molecules were truncated at the 5' end. This suggested
that wild-type VirD2 plays a role in conserving the 5' end of the T-DNA intact until it is delivered to the plant chromosome (42,
44). Since T-DNA integration efficiencies were not affected by
the mutation, we proposed that VirD2 was not conducting the ligation reaction. Thus, the plant machinery would carry out the steps leading
to the integration of the T-DNA into the genome.
Agrobacterium was shown to enable the transfer of
broad-host-range plasmid RSF1010 to plants (7). This
plasmid's promiscuous behavior in bacterial conjugation, which is due
to its ability to use many different transfer systems for its
mobilization (reviewed in reference 11), may explain
why RSF1010 can be transferred from Agrobacterium to plants.
Indeed, transfer of RSF1010 to plants was shown to depend on the
components of the T-DNA transfer machinery (3, 7, 12).
Extensive in vivo and in vitro studies have demonstrated that RSF1010
encodes all of the proteins necessary for its own processing
(2). MobA, in conjunction with MobB and MobC, performs the
nicking of the plasmid specifically at the OriT (origin of transfer)
cleavage site and subsequently binds to the free 5' end of the DNA
strand to be transferred. The OriT site recognized by the MobA protein
consists of 38 bp of DNA (5); the nick itself has been
mapped within the OriT, between positions 3138 and 3139 in the
published RSF1010 sequence (35). Transfer was shown to be
linear and unidirectional (18).
It is interesting that MobA-mediated transformation of plant cells
occurs since MobA shares only a little sequence homology with VirD2
(18% identity, Fig. 1) and cannot be
suspected to have evolved any feature specific for the process in a
plant cell.
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FIG. 1.
Comparison of the amino acid sequences of the VirD2 and
MobA proteins encoded by plasmids pTiA6 and RSF1010, respectively. This
alignment reveals 18% identity and 40% similarity between the two
proteins. Motifs I, II, and III correspond to the conserved domains
characterizing members of the relaxase family to which VirD2 belongs
(27). Boldface letters indicate identical amino acids found
in all of the analyzed proteins from this family; italics symbolize
amino acids preserved in at least 50% of the cases. Y29 (underlined)
of motif I of VirD2 was shown to be involved in the phosphotyrosine
bond establishing the liaison with the T-strand (27). R129
(underlined) of motif III was replaced in a previous work with glycine
(44; see Discussion). The shaded area corresponds to
the bipartite functional nuclear localization signal from VirD2. Note
that the NLS and motifs I, II, and III are not, or poorly, conserved in
MobA.
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Among the key questions that remain unanswered in the process of
Agrobacterium-plant cell transformation is: how specific do
the interactions between proteins accompanying the T-DNA and plant cell
components have to be? To answer this question, we compared the
transfer from MobA- or VirD2-containing agrobacteria to plants, as well
as the efficiency and precision of integration into the plant DNA.
Analysis of the performance of MobA in the plant cell during
transformation was found here to be less efficient and less precise
than that of VirD2. This allowed conclusions about the activities of
VirD2 originally adapted to perform transformation of plant cells.
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MATERIALS AND METHODS |
Strains, plasmids, and media.
Strains and plasmids used are
listed in Table 1. Bacterial and plant
media were prepared as previously described (24, 34).
Binary plasmids.
pTd33 is a binary vector carrying the
marker genes uidA and nptII on its T-DNA (Fig.
2) (44). pTd33 contains an
XbaI site, located 34 bp from the border nicking site, which
can be used to analyze the integrity of the integrated DNAs at their 5'
ends. Plasmid pTd73 is a derivative of pTd33 in which the overdrive and
the right border sequence were precisely replaced with the OriT
sequence of RSF1010 (Fig. 2). For this purpose, primer pr1 (Table
2), containing the OriT sequence of
RSF1010 (Fig. 2B), was used in combination with primer pr2 to amplify a
2-kb fragment of pTd33. After sequence analysis confirming the presence
of the OriT nick site, the NotI-KpnI fragment was
used to replace the corresponding fragment in plasmid pTd33, resulting
in pTd73. The XbaI site is kept 34 nucleotides from the OriT
nicking site, inside the R-DNA. Introduction of plasmids pTd33 and
pTd73 into the Agrobacterium strains was performed by
electroporation.
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FIG. 2.
Binary plasmids pTd33 and pTd73. (A) Only the region of
pTd73 that is different from plasmid pTd33 is shown, and its sequence
is presented in panel B. pTd33 carries the right border (RB) and left
border (LB), as well as the overdrive enhancer sequence (OD). In pTd73,
primers pr1 and pr2 (see Table 2) were used to replace the right border
and the overdrive with the OriT region. The flags representing the two
borders delimit the T-DNA. P and t are the 35S promoter from CaMV and
the terminators of the nopaline synthase gene, respectively.
nptII codes for neomycin phosphotransferase (kanamycin
resistance), and uidA codes for  -glucuronidase. pBR322
ori and Ri ori correspond to the origins of replication of
Escherichia coli and Agrobacterium, respectively,
and gmR is the gene conferring resistance to gentamicin. The
underlined region of the T-DNA represents the region used as a probe
for Southern analyses. H, B, N, and X are restriction sites for
HindIII, EcoRI, BamHI,
NotI, and XbaI, respectively. (B) Sequences of
the nick regions (dark shaded box) of binary plasmids pTd33 and pTd73.
Cleavage occurs on the bottom strand and is indicated by the arrow. The
light shaded box contains the overdrive enhancer sequence.
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Tobacco seedling transient expression and transformation
assay.
We followed the protocol described in references
30 and 44. Briefly, 200 tobacco
seedlings were cocultivated with the Agrobacterium strain be
tested, which was diluted to an optical density of 0.6 at 600 nm. Half
of the seedlings were used to measure the transient expression and the
other half were used to measure the stable expression of the marker
genes, uidA and nptII, respectively, carried by
the T-DNA (17, 22, 25).
Analysis of the pattern of integration by PCR and by Southern
blotting.
Plant DNA was extracted as previously described
(28). A standard PCR protocol, using Ampli-Taq
polymerase (Perkin-Elmer Cetus) was applied to 0.5 to 1 mg of plant DNA
mixed with the corresponding oligonucleotides (Table 2 and Results).
Southern blot analysis was performed as previously described
(34). Radioactive probes were made by using a random priming
labeling kit (Boehringer-Mannheim, Mannheim, Germany) and
[
-32P]dATP (Amersham, Little Chalfont, United Kingdom).
Isolation and analysis of the T-DNA-plant DNA junctions by
TAIL-PCR.
Plant DNA from transformants was isolated in order to
analyze the junction region between the 5' end of the R-DNA and the adjacent plant DNA. The isolation of these border junctions was performed by thermal asymmetric interlaced PCR (TAIL-PCR) as previously described (21), except that primers RB1, RB2, and RB3 were
used as R-DNA-specific primers. The fragments were isolated, purified, and cloned into the plasmid PCR2.1 (Invitrogen). Sequencing was performed by using 
-rhodamine terminators (Applied Biosystem), which
were incorporated by using universal primers with a Gene-Amp PCR system
(Perkin-Elmer). The analysis was performed with an ABI prim 377 automated DNA sequencer.
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RESULTS |
We engineered an Agrobacterium strain containing all of
the necessary components to study MobA-mediated transformation of plants. To avoid any interference between the VirD2 and MobA proteins, we used strain ATvir
D2 (6), which carries a
complete and precise deletion of the virD2 gene. As a MobA
protein source, the RSF1010 derivative pMob (pKT231; 1) was introduced
into this Agrobacterium strain, giving ATvirD2 (pMob).
Construction of a binary plasmid for comparison of MobA- and
VirD2-mediated transformations was based on plasmid pTd33 (Table 1).
pTd73 was constructed by precisely replacing the sequence of pTd33
encompassing the right border and the overdrive with the 38 essential
nucleotides from the OriT of RSF1010 (Fig. 2 and Materials and
Methods). pTd33 and pTd73 thus differ only in their nicking sequences,
which can be recognized and processed by VirD2 and MobA, respectively.
Both plasmids carry the marker genes uidA (coding for
-glucuronidase) and nptII (conferring resistance to
kanamycin) for monitoring of transfer and transformation events, respectively.
Transfer of the DNA to plant cells could not be detected from the
resulting strain, ATvirD2(pMob/pTd33), indicating that pTd33 itself does not contain any sequence which could serve as an
alternative nicking site for the MobA endonuclease encoded by pMob.
Since pTd73 differs in sequence from pTd33 only at the OriT nick site,
any detectable transfer of pTd73 will be considered to result from a
specific nick of the vector by MobA at this sequence.
pTd73 was then introduced into ATvirD2(pMob), giving
strain ATvirD2(pMob/pTd73). For the following sections,
we define as R-DNA the molecule originating from plasmid pTd73 that is
processed and transferred by MobA.
Transfer of R-DNA to the plant cell nucleus. (i) Transfer
efficiency.
Strains ATvir(pTd33) and
ATvirD2(pMob/pTd73) were tested for efficiency of DNA
transfer to young tobacco seedlings (30). In this assay, the
activity of -glucuronidase transiently expressed by the
uidA gene carried on vectors pTd33 and pTd73 represents a
quantitative measure of transferred DNA molecules which arrive in the
plant cell nucleus without necessarily being integrated into the genome
(transfer efficiency). Transient expression was evaluated 3 days after
cocultivation with the respective strains by counting of the blue spots
appearing on the seedlings after histochemical staining (see Materials
and Methods). Table 3 shows that in the
absence of VirD2, MobA transferred R-DNA molecules to plants with an
efficiency between those corresponding to the dilution of strain
ATvir(pTd33) to 1/250 to 1/100. A comparably low transfer
efficiency of a virD2-containing bacterial strain ATvir(pMob/pTd73) was observed, demonstrating that DNA
transfer mediated by MobA is neither dependent on nor inhibited by the presence of VirD2 (data not shown) and confirming earlier observations (36).
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TABLE 3.
Efficiency of transfer, transformation, and integration
of Agrobacterium strains containing VirD2 or MobA
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The R-DNA molecules reach the plant cell nucleus much less efficiently
than do T-DNA molecules. Several aspects, from processing until nuclear
entry, could be impaired during this transfer process. The competition
for transfer with pMob plasmids present in the bacterium could also
contribute to the low transfer efficiency.
(ii) Requirement for VirE2 in MobA-mediated transfer.
It was
previously reported that the export of VirE2 proteins can be inhibited
by the presence of RSF1010-derived plasmids in
Agrobacterium, consequently leading to a decrease in
transfer efficiency (3, 40). We investigated whether the low
transfer efficiency mediated by MobA could be explained by a similar
blocking effect of the RSF1010-derived plasmid present in strain
ATvirD2(pMob/pTd73).
First, we analyzed the dependence of MobA-mediated transfer on VirE2.
Plasmids pMob and pTd73 were introduced into VirE2-deficient strain
ATvirE2 (Table 1) (31), resulting in strain
ATvirE2(pMob/pTd73). Transfer from this strain was not
detected, while dilutions of a wild-type strain in which transfer is
mediated by VirD2 indicated that we could have detected transfer values
at least 3 orders of magnitude lower than those measured in the
presence of VirE2. MobA-mediated transfer to plants therefore requires
VirE2 to the same extent as the VirD2-mediated transfer.
Second, we tested whether the export of VirE2 was impaired in
ATvirD2(pMob/pTd33); the concentration of VirE2 protein
delivered to the plant cell may not be sufficient to ensure proper
transfer of the R-DNA. T-DNA transfer from a VirE2-defective strain has been reported to be complementable either by another VirE2-proficient Agrobacterium present during the cocultivation period
(8, 26) or by a plant expressing the VirE2 protein
(9). Both types of complementation assays were tested here
to determine whether the VirE2 supply from transfer-proficient strain
ATvirD2(pMob/pTd73) was limiting for R-DNA transfer.
Experiments were performed by using for the cocultivation a mixture of
strain ATvirD2(pMob/pTd73) and VirE2 donor strain
ATvirD2, which lacks any transferable DNA. This gave rise
to transfer values increased by an order of magnitude (Table
4, experiments 1 and 2), confirming that
the concentration of VirE2 protein supplied by the transfer-proficient bacterium ATvirD2(pMob/pTd73) was limiting. Similarly, a
threefold increase in transfer efficiency was observed when tobacco
plants transgenic for VirE2 were used in the cocultivation experiments (Table 4, experiments 3 and 4).
(iii) Effect of the size of the transferred DNA.
We
investigated whether the larger size of the R-DNA (17 kb) than the
T-DNA of pTd33 (6 kb) was a handicap. pTd333, a derivative of pTd33
missing only the left border sequence, was constructed. The T-DNA in
this plasmid consequently consisted of 17 kb containing only one
nicking site (5a). Transfer of this plasmid from a VirD2-containing strain was found to be as efficient as that of pTd33
(data not shown). Furthermore, the transfer of T-DNA from a
pTd333-containing strain was not significantly improved by the presence
of either source of VirE2 during cocultivation (data not shown).
The low efficiency of R-DNA transfer is therefore partially due to the
transfer of limited amounts of VirE2 molecules to the plant cell in the
presence of plasmid pMob.
Integration into the plant genome. (i) Efficiency of
integration.
The stable expression of the nptII gene,
encoding the neomycin phosphotransferase protein, was used to select
R-DNA integration events. The number of kanamycin-resistant calli per
tested seedling was used as a measure of transformation (transformation
efficiency). Integration efficiency is defined as the ratio of the
number of kanamycin-resistant calli per seedling to the number of blue
spots per seedling (i.e., the transformation efficiency over the
transfer efficiency); it refers to the fraction of molecules integrated into the genome from the number of molecules that entered the nucleus.
The relative transfer and transformation efficiencies observed for MobA
strain ATvirD2(pMob/pTd73) were on the order of 1/250 to
1/100 of those of wild-type strain ATvir(pTd33). However, the calculated integration efficiencies of the two strains were very
similar (Table 3). This indicated that the same proportion of
transferred molecules integrated into the genome, irrespective of
whether the pilot protein was VirD2 or MobA. The integration efficiency
was independent of the dilution used in a given experiment, indicating
the linearity of the assay, as was previously reported (44).
(ii) Analysis of the right R-DNA junctions after integration.
Since one of the main features of T-DNA transformation is the precision
of insertion into the genome, analysis of the integrity of integrated
DNA molecules has proven to be very informative about the function of
the bacterial virulence proteins accompanying the T-DNA (6, 31,
44). The function of MobA in integration was therefore studied by
analyzing the pattern of the integrated R-DNA. Because OriT is the only
site on the vector which is recognized and nicked by the MobA protein
(see above), it was expected that a linear R-DNA molecule transferred
to the plant cell results from two successive cleavages of the OriT
site, in which the second nick occurs only after the initially nicked
OriT site has been restored by lagging-strand synthesis (see the
nicking site in Fig. 2B). In other words, the OriT was expected to play
the role of both the left and the right borders and the size of the
transferred DNA was expected to correspond to that of 17-kb plasmid pTd73.
The structures at the 5' end of the R-DNA after integration were
analyzed by Southern blotting by using the XbaI site,
located 34 nucleotides from the OriT nicking site inside the R-DNA, as a marker for the integrity of the 5' end. The DNA from plants that
showed a conserved 5' end was subsequently subjected to TAIL-PCR (see
Materials and Methods) for analysis of the junctions at the nucleotide
level. The DNA from plants lacking a conserved XbaI site was
tested by a classical PCR to determine the extent of the deletions.
DNA from nine independent transformants regenerated from
kanamycin-resistant calli was digested with the restriction enzyme HindIII (which cuts only once in the plasmid, 3 kb from
the right border inside the R-DNA, revealing the number of inserts per
transformant) alone or in combination with XbaI (see above
and Fig. 2). The DNA was then subjected to Southern blot analysis using
a BamHI fragment spanning the uidA open reading
frame as a probe (Fig. 2). Detection of a defined 3-kb band of the
vector upon double digestion with restriction enzymes
HindIII and XbaI was indicative of a
relatively conserved 5' end of either a T-DNA or an R-DNA after integration.
Using the TAIL-PCR technology (see Materials and Methods), we isolated
and sequenced the R-DNA-recipient DNA junctions from the transformants
which contained the most complete 5' ends of the R-DNA. This was done
by using three sets of nested primers to sequentially favor the
amplification of specific bands corresponding to the junction area.
Results of Southern blot and TAIL-PCR analyses, schematically
represented in Fig. 3A, show that
the different transformants can be grouped into
several categories.
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FIG. 3.
(A) Patterns of integrated R-DNA molecules. The dark box
represents the uidA gene, the white box represents the
nptII gene, the shaded area represents the 35S promoter from
CaMV, and the hatched area represents the phospholipase C gene (see
text). The arrows indicate the orientation of transcription in the
regions were T-DNA integration took place. H and X are restriction
sites for HindIII and XbaI. The plasmid DNA
segment is shown as a bold line. Controls C1 and C2 represent two
independent T-DNA transformants. Categories I to V are different
patterns of R-DNA transformants. They carry either one insert (category
I) or two separate inserts (categories II and III; a and b). The two
transformants in categories IV and V carry two inserts each, of which
one is a partial concatemer of plasmid pTd73 (a, b, and c, where a and
c can be interchanged). The sequenced junctions (see text) are shown
with a shaded line underneath. (B) Sequence analysis of R-DNA-plant DNA
junctions isolated by TAIL-PCR. The original sequence around OriT (dark
box; the nick site is represented by the arrowhead) of plasmid pTd73 is
shown (uppercase letters), as well as the positions of the junctions
sequenced from three transformants (boldface letters). Below, the three
sequences in lowercase correspond to the junctions between R-DNA
(boldface letters) and recipient DNA (lightface letters). The targeted
site on the recipient DNA is in parenthesis. The junctions which were
isolated but corresponded to the uncut OriT region of a concatemer of
pTd73 are not shown. The last nested primer (RB3) used during the
TAIL-PCR is indicated.
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The patterns of DNA extracted from kanamycin-resistant plants obtained
by VirD2-mediated transformation using strain ATvir(pTd33) were used as controls (C1 and C2). Digestion with
HindIII showed that transformants 73.4, 73.5, and 73.6 have single inserts (category I). However, upon additional digestion
with XbaI, their bands did not shift to the expected size of
3 kb, indicating that they have lost the 5' extremity of the R-DNA. In
the four transformants which contained two inserts, either both
XbaI sites were lost (73.2, 73.11, 73.13; category II) or
only one was conserved (73.1; category III). Remarkably, sequence
analysis of the junction of transformant 73.1 revealed a perfect
junction between the OriT nicking site and the recipient DNA,
suggesting that the MobA-R-DNA bond has been used in this ligation
process (IIIa; Fig. 3B). But, surprisingly, the molecular analysis of
the DNA sequence fused to the OriT nicking site corresponded to the
sequence of an nptII gene truncated at its 3' end by the
integration event, suggesting that this integration event occurred in
another molecule of R-DNA.
PCR analysis was performed on plants from categories I and II by using
a fixed primer, located 725 nucleotides from the MobA nicking site and
facing it (primer RB4), in combination with three different primers 60, 300, and 500 nucleotides from the nicking site (primers RB5, RB6, and
RB7, respectively; Table 2). The results indicated that the sizes of
the deletions were always larger than 300 nucleotides and were between
300 and 500 nucleotides in three of the six plants analyzed.
In transformant 73.25 (category IV), two of the three inserts carried a
preserved 5' end (a and b). The third insert was part of a
high-molecular-weight band only weakly hybridizing to the probe; it may
be indicative of a partial deletion of the uidA gene. The
fact that this fragment did not shift upon digestion with
XbaI indicates that the truncation occurred at the 5' end. The junction amplified by TAIL-PCR from this transformant revealed the
presence of the complete OriT sequence of plasmid pTd73 (Fig. 3, IVb).
This result indicates that plasmid pTd73 was transferred and integrated
as a concatemer in this transformant. Such an event can be explained by
a combination of rolling-circle DNA replication with lagging-strand
synthesis, displacement and export from the bacterium of the R-DNA, and
absence of a second cleavage at the restored OriT. We did not succeed
in isolating junction IVa of this transformant.
In transformant 73.28 (Fig. 3A, category V), two bands were detected by
Southern analysis while three different junctions were amplified by
TAIL-PCR (a, b, and c). Insert a carried the XbaI site and a
deletion of 15 nucleotides from the nicking site; insert b carried the
XbaI site and corresponded to a concatemer carrying a
complete OriT sequence. This fragment, identified by TAIL-PCR, was not
detectable by Southern analysis because it most probably suffered from
a severe deletion at the 3' end of the uidA gene. Insert c
lacked the XbaI site, as well as 60 nucleotides from the
nicking site. Sequence analysis of junctions 73.28a and 73.28c
suggested the integration of the R-DNA inside another R-DNA, since the
sequence fused to the right extremity of each analyzed R-DNA was found
to have a high degree of homology with a gene encoding a phospholipase
C probably of bacterial origin (homology hit with the corresponding
gene from Pseudomonas aeruginosa) and with a truncated 35S
promoter from cauliflower mosaic virus (CaMV), respectively. The
simplest interpretation of these data is that the unprocessed border
detected by the TAIL-PCR and the truncated 35S promoter belong to the
same R-DNA molecule (Fig. 3A).
To summarize, these analyzes revealed that in 1 out of 15 integration
events (monitored within nine plants), the nucleotide presumably
attached to MobA was conserved. In three cases, the deletion is less
than 60 nucleotides long, and in at least four cases (and in, at the
most, seven cases, if we consider that in plants 73.1, 73.2, and 73.11 the longest insert would hinder the analysis of the shorter one by
PCR), it extended to between 300 and 500 nucleotides from the nick
site. In the remaining cases (seven or four cases [see above]), the
deletion extended to more than 500 nucleotides. Using the right side of
the R-DNA, we could only rescue three junctions, all corresponding to
recombination events between two molecules of R-DNA: one event could
have been MobA mediated, whereas the two others were probably MobA
independent since they led to truncations of the right end of the
transferred molecules.
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DISCUSSION |
There are interesting parallels between
Agrobacterium-mediated transformation of plants and conjugal
transfer of DNA between bacteria (20, 38, 39, 45). To
analyze whether VirD2 evolved special functions allowing it to mediate
integration of the T-DNA into the plant genome, we compared
VirD2-mediated and MobA-mediated plant transformations.
Transfer of R-DNAs.
In our study, almost similar binary
plasmids, differing only by 38 nucleotides at the nick site for the
respective endonuclease, were used to compare the transfer efficiencies
of MobA and VirD2. To avoid any competition, we measured the transfer
of an OriT-containing plasmid mediated by MobA in a VirD2-free
Agrobacterium strain and VirD2-mediated T-DNA transfer in a
MobA-free Agrobacterium strain. MobA-dependent R-DNA
transfer occurred with a much lower efficiency than VirD2-dependent
T-DNA transfer (less than 1/100). This low transfer efficiency could
reflect the impairment of any step, from processing in the bacteria to
entry into the plant cell nucleus. Earlier reports on MobA-mediated
transformation indicate that products from the RSF1010 plasmid could
interfere with the export of the VirE2 protein from
Agrobacterium (3, 40). Since our aim was to study
the integration process and since VirE2 protein plays a crucial role in
preserving the T-DNA's integrity (31), we first
investigated whether products from the RSF1010 derivative pMob could
similarly inhibit the export of VirE2. Indeed an additional source of
VirE2 protein was able to increase up to 10-fold the transfer of
uidA-containing R-DNA strands from a strain already
expressing VirE2, indicating that VirE2 export was limiting the
transformation mediated by MobA. This competition between RSF1010
products and VirE2 suggests a high-affinity recognition of elements of
the DNA export machinery by the MobA components and may be an important
feature of broad-host-range plasmids since it would allow them to
parasitize other DNA transfer systems efficiently.
Although the complementation by extracellular VirE2 allowed a
significant (10-fold) increase in transfer efficiency, the transfer efficiency mediated by MobA under these conditions remained 1 order of
magnitude lower than that mediated by VirD2. We did not attempt to
identify other steps that could be affected during transfer of R-DNAs,
but the lack of classical NLSs on MobA, necessary for efficient nuclear
entry, probably contributes to the observed phenotype. However, the
activity of a nonconsensus NLS cannot be excluded (Fig. 1). The
presence of the plasmid pMob in the bacterium may also contribute to
the low transfer efficiency measured for pT73, but it is not expected
that transfer of pMob to plant cells would influence the integration
efficiency, since this depends on the transfer and transformation
efficiencies, which were measured with marker genes located only on pTd73.
Apart from nuclear targeting, it is possible that MobA-mediated T-DNA
transfer is handicapped by the lack specific interactions with certain
plant proteins involved in as yet unknown mechanisms (e.g.,
cyclophilins; 10).
Integration.
The efficiency of integration of R-DNA molecules
was very similar to that measured for T-DNA, indicating that the R-DNA
complex has integrative capacities similar to those of the T-DNA
complex. However, analysis of the 5'-end integration patterns of R-DNAs revealed drastic differences between the two systems: while the 5' end
of the T-DNA is usually preserved up to the nucleotide attached to
VirD2 (6, 13, 23, 31, 44), the 5' ends of the integrated
R-DNAs are deleted in the majority of the cases. This result suggests
that MobA, unlike VirD2, is not "conceived" to release the attached
nucleotide in order to favor a precise ligation between the R-DNA and
the plant DNA.
These data are reminiscent of the properties of T-DNA integration
mediated by a mutant form of VirD2, VirD2R129G (created by replacement
of arginine 129 with glycine; 44); in both cases, the efficiency of integration is unaltered compared to the respective wild-type situation while the pattern of integration indicates deletions at the 5' end. The independence of efficiency and precision of integration was used to suggest that the 3' end of the T-DNA was
affecting the first synapsis with the plant DNA (44).
However, there is a clear difference between the integration mediated
by this VirD2R129G mutant protein and that mediated by MobA. The junction isolated with the mutant protein never showed integration within another T-DNA molecule; the patterns of integration were clear
and easy to analyze and could be mostly interpreted as single integration events. When R-DNA integration was analyzed, in the majority of the cases, at least two right-end junctions were identified per transformed plant. Furthermore, in the three cases in which it was
possible to rescue and analyze these junctions, they showed integration
events occurring inside another R-DNA molecule, indicating complicated
recombination events.
It is difficult to interpret how, despite a low efficiency of
transformation, the majority of the plants recovered after
MobA-mediated transformation contain two distinct inserts and a complex
pattern of integration. This phenomenon has never been observed under similar experimental conditions for VirD2- or VirD2R129G-mediated transformation, either in the presence or in the absence of VirE2 (6, 31, 44). Therefore, a specific defect of MobA in
ligating the R-DNA to the recipient DNA would probably not be
sufficient to explain the observed pattern of integration. Rather, this
indicates that certain plant cells are far more competent than others
for transformation by R-DNAs. Our hypothesis is that this competence is
determined by the disruption of the nuclear envelope that accompanies mitosis. Under these conditions, several R-DNAs present in the cytoplasm can reach the genomic DNA simultaneously. The particular recombinogenic activity associated with the status of the dividing cells would then contribute to integration patterns. Our results therefore suggest that the presence of NLSs on VirD2 is also a determining factor in the pattern of integration of the T-DNA, a
hypothesis which is being tested in our laboratory.
This hypothesis meets two other lines of evidence: firstly, the
complexity of the T-DNA integration has already been reported to be
very much dependent on the type of plant tissue used for transformation, suggesting variation from cell to cell in recombination behavior (14; but it has not been demonstrated that
a higher complexity can be correlated to cell division). Secondly,
complex types of integration patterns are encountered when trangenic
plants are obtained by using direct gene transfer technologies (see
reference 19 and references therein); in these
cases, the transfected DNA is not associated with any nuclear
localization signal and its access to the nuclear genome probably
depends upon mitosis and disruption of the nuclear envelope.
The complexity of the R-DNA integration events observed does not allow
extensive speculation about the mechanism taking place (e.g., whether
there is extrachromosomal recombination and whether the recombination
substrates are present in single- or double-stranded form). However, it
remains interesting that in 1 integration event (among 15 analyzed),
the nucleotide proposed to be attached to MobA is found correctly
ligated to the "recipient" DNA. Although rare, this event indicates
that MobA has the potential to release the phosphotyrosine bond
involved in the linkage with the transferred DNA. Specifically for the
ligation reaction, the two proteins VirD2 and MobA may indeed vary in
the ability to expose the linkage bond.
Our detailed analysis of MobA's "flaws" when substituting for
VirD2 reinforces the qualities already attributed to VirD2. These
properties have enabled Agrobacterium to ensure precise and
efficient transformation of plants, making it a widely used instrument
in the generation of transgenic plants. This and a plant tissue
carrying a high generation capacity combined with a good generation
susceptibility to transformation are the most important requirements
for the successful generation of transgenic plants. However, quality
control of integration events at the cellular level will probably
represent one of the next challenges in transgenesis.
| |
ACKNOWLEDGMENTS |
We thank P. Crouzet and J. Fütterer for stimulating
discussions and advice and A. Zimienowicz and M. Hanin for critically reading the manuscript. F. Jasper and H. H. Steinbiss kindly
provided the transgenic plants expressing VirE2, and M. Bagdasarian
provided the plasmid pKT231.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute for
Plant Sciences, ETH-Zentrum, Universitätstrasse 2, CH-8092
Zurich, Switzerland. Phone: (41) 1 632 59 87. Fax: (41) 1 632 10 44. E-mail: bruno.tinland{at}ipw.biol.ethz.ch.
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Journal of Bacteriology, September 1999, p. 5758-5765, Vol. 181, No. 18
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Abstract
Introduction
