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Previous Article | Next Article 
Journal of Bacteriology, December 1998, p. 6325-6331, Vol. 180, No. 23
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Mutational Analysis of the Rhizobium etli
recA Operator
Angels
Tapias and
Jordi
Barbé*
Molecular Microbiology and Bacterial Genetics
Group, Department of Genetics and Microbiology, Universitat
Autònoma de Barcelona, Bellaterra, 08193-Barcelona, Spain
Received 12 June 1998/Accepted 24 September 1998
 |
ABSTRACT |
Based upon our earlier studies (A. Tapias, A. R. Fernández de Henestrosa, and J. Barbé, J. Bacteriol.
179:1573-1579, 1997) we hypothesized that the regulatory sequence of
the Rhizobium etli recA gene was TTGN11CAA.
However, further detailed analysis of the R. etli recA
operator described in the present work suggests that it may in fact be
GAACN7GTAC. This new conclusion is based upon PCR
mutagenesis analysis carried out in the R. etli recA operator, which indicates that the GAAC and GTAC submotifs found in the
sequence GAACN7GTAC are required for the maximal
stimulation of in vivo transcription and in vitro DNA-protein complex
formation. This DNA-protein complex is also detected when the
GAACN7GTAC wild-type sequence is modified to obtain
GAACN7GAAC, GTACN7GTAC, or
GAACN7GTTC. The wild-type promoters of the Rhizobium
meliloti and Agrobacterium tumefaciens recA genes,
which also contain the GAACN7GTAC sequence, compete with
the R. etli recA promoter for the DNA-protein complex
formation but not with mutant derivatives in any of these motifs,
indicating that the R. etli, R. meliloti, and
A. tumefaciens recA genes present the same regulatory sequence.
| |
INTRODUCTION |
The recA gene has been
isolated from a large number of bacteria (19). Its product
is a multifunctional protein which is best characterized by its role in
DNA recombination (12). RecA does, however, also play a
central role in regulating the SOS response to DNA damage. Many
proteins induced as part of this response help the cell survive, by
either directly repairing damaged DNA or allowing the cell to tolerate
DNA lesions until they can be repaired efficiently (29).
LexA protein is the common transcriptional repressor of SOS-regulated
genes, which include both recA and lexA
themselves (6). Blockage to replication or damage to DNA generates an inducing signal which, with the help of Ssb protein, results in the activation of RecA coprotease functions (13, 14,
25). In its coprotease-proficient state, RecA mediates the
efficient posttranslational cleavage and inactivation of the LexA
repressor. Inducible DNA repair systems are apparently quite common and
have been described in several bacteria (19).
The Escherichia coli LexA protein binds to a specific region
situated upstream of the SOS genes. Alignment of various SOS-regulated genes generated the consensus sequence CTG(TA)5CAG,
known as the E. coli SOS box (31). Similar
E. coli-like SOS boxes have been identified in the promoter
regions of many recA and lexA genes from
gram-negative bacteria (7, 19). Likewise, and by comparing promoter regions of several din (damage inducible) genes,
the GAACN7GTTC palindrome has been proposed as
the Bacillus subtilis SOS box (3). Recent data
indicate that, in fact, the B. subtilis SOS box is slightly
larger and has a consensus sequence of CGAACRNRYGTTYC (33). Many gram-positive bacterial species, such as
Mycobacterium tuberculosis, Mycobacterium leprae,
Streptococcus pneumoniae, and Clostridium
perfringens, among others, have a B. subtilis-like SOS
box upstream of their recA gene (4, 9, 20, 21). B. subtilis and M. tuberculosis LexA-like
proteins have been purified, and binding to their respective SOS boxes
has been previously demonstrated (18, 20, 32). Other
bacterial SOS boxes, such as that belonging to Rhizobium
etli, remain to be elucidated.
We have previously reported that the R. etli recA gene is
DNA damage inducible (5) and have demonstrated that the TTG
and CAA motifs found in the TTGCGAGAGTGGAACAA
(TTGN11CAA) sequence, upstream of the
R. etli recA gene, are necessary for DNA damage-mediated induction (28). Interestingly, our data indicated that the
TTG motif seemed to be less important than CAA. So, the effect of the
substitution of the TTG motif, in both formation of a DNA-protein complex in vitro and recA DNA damage mediated in vivo, was
weaker, which was a consequence of changing the CAA motif
(28). By comparison, there was only a slight decrease in
these two parameters when the TTG motif was changed. These findings
therefore led us to systematically determine the role of each
nucleotide base in the TTGN11CAA sequence, which
appears to control R. etli recA gene expression.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The CNPAF512
wild-type R. etli strain employed in this study has been
described previously (28). The wild-type strains of Rhizobium meliloti and Agrobacterium tumefaciens
were 2021 and C58, respectively (28). All plasmid
constructions and cloning experiments were performed in E. coli DH5
. R. etli, R. meliloti, and
A. tumefaciens strains were grown at 30°C in PY, LB, and
MG media (22), respectively, and E. coli cells
were cultured at 37°C in LB (17). Antibiotics were added
to the culture media at the appropriate concentration for each
bacterial species (22).
General genetic techniques.
Plasmid DNA was transformed into
competent E. coli cells as described by Silhavy et al.
(27). Bacterial matings were performed with the E. coli S17 system as reported previously (22).
Construction of recA-lacZ fusions and 
-galactosidase
assays were carried out as previously published (28).
DNA manipulations and sequencing.
Restriction enzymes, T4
DNA ligase, T4 DNA polymerase, and a DIG DNA labelling and detection
kit were purchased from Boehringer Mannheim. The conditions used for
plasmid DNA extractions, restriction endonuclease digestion, agarose
gel electrophoresis, and isolation and ligation of DNA fragments have
been described elsewhere (23). The DNA sequence of the
PCR-mutagenized fragments was determined by dideoxy sequencing
(24) on an ALF Sequencer (Pharmacia Biotech). In all cases,
the entire nucleotide sequence was determined on both DNA strands. The
presence of the desired mutation in the various recA-lacZ
fusions was determined by DNA sequencing of each fusion with a
5'-fluorescein-CGAACGGCCAGTGAATCCG-3' primer, which extends
from nucleotides +32 to +14 with respect to the translational starting
point of the E. coli lacZ gene.
DNA probes.
The R. etli recA probes employed in
retardation experiments were obtained by PCR mutagenesis using specific
upper primers which contained the desired mutation (Fig.
1). All of these fragments were labelled
with a 5'-end digoxigenin-labelled lower primer (Fig. 1). The
introduction of the desired mutation was confirmed by DNA sequence
analysis. The 5'-end digoxigenin-labelled primer used to obtain the
upper fragment (see Fig. 8) was 5'-CCGCCTTCCGATGCCGAAGC-3'. The lower primers used were 5'-GCCCGTGTTCTATATTTG-3'
for the wild-type fragment and
5'-GCCCGTGTTCTATATTCGGATATCGA-3' and
5'-GCCCGTCGGATATATTTG-3' for the mutagenized
derivatives.
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FIG. 1.
Nucleotide sequence of the 5' end of the R. etli
recA gene. P1 indicates the starting point of the upper primers
used to obtain the recA fragments employed in this work. The
transcriptional starting point (+1) is indicated in boldface type. The
two halves of the TTGN11CAA palindrome which had
been previously proposed as the control region of the R. etli
recA gene are boxed. FLP and DLLP indicate the starting points of
the lower primers used either to construct recA fusions or
to obtain fragments employed in gel retardation experiments,
respectively. The right and left submotifs of the
GAACN7GTAC sequence proposed in this work as the
regulatory element of the R. etli recA gene are overlined.
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|
Rmup (5'-GTTGGAACAAAACATGTAC-3') and Atup
(5'-ATGAGAACAAATAGAGTACATACC-3') oligonucleotides were used
as upper primers to obtain the R. meliloti and A. tumefaciens recA probes, respectively. The lower primers were the
5'-end digoxigenin-labelled oligonucleotides Rmlow
(5'-CCGAACGAACGTTCGATCT-3') and Atlow
(5'-CCGAACGACCGTTCGATCT). Mutant R. meliloti and
A. tumefaciens recA probes were obtained by using Rmup*
(5'-GTTGGAACAAAACATCTACAAA-3') and Atup*
(5'-ATGAGAACAAATAGACTACATACC-3') oligonucleotides, respectively. The positions of the mutant base in these oligonucleotides are underlined. In agreement with the R. meliloti and A. tumefaciens recA gene
sequences (26, 29), the 5' ends of the Rmup and Atup primers
are 116 and 117 bases upstream of their respective translational
starting point, and the 5' ends of the Rmlow and Atlow primers are 56 bases downstream from this point.
When necessary, specific restriction sites were incorporated into the
5' ends of the oligonucleotide primers to facilitate the subcloning of
PCR fragments and the construction of lacZ fusions.
Electrophoretic mobility shift assays.
Crude cell extracts
of members of the family Rhizobiaceae were obtained by
sonication as previously reported (28). In all cases, the
total protein concentration of these crude extracts was about 15 mg/ml.
Binding mixtures were obtained by mixing the digoxigenin probe (10 ng)
and crude cell extracts (180 µg of total protein) for 30 min at
30°C. Immediately thereafter, the samples were loaded on a native 5%
polyacrylamide gel as previously described (28).
Samples were electrophoresed at 35 mA until the marker dyes had
migrated approximately two-thirds of the total gel length (so as to
avoid excessive protein-DNA dissociation). Complexes were transferred
and detected as recommended by the supplier (Boehringer Mannheim).
Densitometrical analysis of the several retardation experiments was
done by using the Molecular Analyst 1.5 (Bio-Rad) program. The reported
binding activity represents the percentage of the total DNA applied to
the gel that was bound. For every experiment, wild-type DNA was
included in the set as an internal control. Under our assay conditions
the binding activity of the wild-type probe was approximately 72% ± 7% (mean ± standard deviation) of total DNA. The wild-type
binding activity was taken as 100%, and the mutant binding activity
was expressed as a percentage of the wild-type activity. The presented
data are the averages of three independent experiments.
| |
RESULTS AND DISCUSSION |
Effects of nucleotide substitution and addition in the
TTGN11CAA sequence on electrophoretic mobility
and inducibility of the R. etli recA promoter.
In
order to further analyze the role of the TTG motif belonging to the
TTGN11GAAC sequence cited above, several gel
retardation experiments with R. etli recA promoter mutants
containing single nucleotide changes in this TTG motif were performed.
Figure 2 shows that none of these
substitutions abolished the formation of the DNA-protein complex,
although some changes in the TTG motif decreased its binding ability
(Table 1).
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FIG. 2.
Effect of single nucleotide substitutions in the TTG
motif of the TTGN11CAA palindrome upstream of
the R. etli recA gene. The migration of the wild-type (wt)
fragment either in the absence or in the presence of R. etli
crude extract (prot) is shown as a control. The mobility of the mutant
fragments is only shown in the presence of cellular extract.
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TABLE 1.
Effects of systematic single substitutions in the
TTGN11CAA sequence on the formation of retarded
complexes of the R. etli
recA promotera
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In contrast, a more-exhaustive mutational analysis of the
TTGN11CAA sequence revealed that only nucleotide
substitutions in positions 
24, 23, 22, and 21 (corresponding to
a GAAC motif) abolished or significantly decreased the recA
promoter gel mobility (Table 1). Among these changes, those involving
positions 22 and 21 appear to be the least permissive (Table 1). It
is worth noting that the C of the GAAC tetranucleotide also belongs to the CAA motif of the TTGN11CAA sequence, which
had been previously hypothesized as the binding site of the regulatory
protein. These data convincingly show that the TTG motif is not
important for binding.
Moreover, results obtained strongly implicate the GAAC sequence. This
inference is further supported by deletion and insertion analysis (Fig.
3). Thus, a three-base insertion at
position 27 did not cause any loss in protein binding (Fig. 3).
Nevertheless, either insertion or deletion of 1 nucleotide at position
18 (downstream from the GAAC submotif) is sufficient to suppress
recA promoter retardation (Fig. 3). In addition,
substitutions at position 24, 23, 22, or 21 also eliminate
recA inducibility and produce a dramatic increase in the
basal level of expression of the gene (Fig.
4).
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FIG. 3.
Effect of changing the spacing between the palindromic
submotifs found in TTGN11CAA (lanes 1 to 4) and
the imperfect repeat present in GAACN7GTAC
(lanes 5 to 8) upon the formation of retarded complexes of the
R. etli recA promoter. Mutational analysis of the
TTGN11CAA sequence was carried out by insertion
of three bases (CCC) in its central region (position 27), whereas the
GAACN7GTAC sequence was mutagenized by either
the addition or deletion of one base in its central region (position
18). The mobility of the wild-type (lanes 1 and 2) and the
mutagenized (lanes 3 to 8) fragments in the presence (lanes 2, 4, 6, and 8) or in the absence (lanes 1, 3, 5, and 7) of R. etli
crude cell extract is shown. Fragments containing either the insertion
or the deletion of 1 nucleotide (lanes 5 to 8) are slightly smaller
than both the wild-type fragment (lanes 1 and 2) and the one carrying
the insertion of 3 nucleotides (lanes 3 and 4) because of the presence
of a SmaI restriction site in the 5' end of the primers used
to obtain these two fragments (see Materials and Methods).
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FIG. 4.
Effects of mutations in the GAAC and GTAC submotifs of
the GAACN7GTAC sequence upon the transcription
of the R. etli recA gene, as measured by -galactosidase
activity in recA-lacZ fusions. -Galactosidase activities
of all fusions were measured in the absence of mitomycin C (open bars
with black dots) or 180 min after its addition at 1.6 µg/ml (solid
bars with white dots). The activities (in units) are the mean data from
three independent assays. Values were reproducible to within an error
of ±10%.
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Identification of R. etli recA regulatory
sequence.
The data presented above raised the possibility that at
least one regulatory element of the recA gene is located
downstream from the GAAC motif. Inspection of the surrounding region
revealed the presence of a GTAC sequence (positions 13 to 10 in
Fig. 1) seven bases downstream from the GAAC tetranucleotide described above (Table 1 and Fig. 4). These two sequences (GAAC and GTAC) are
potentially variants of a symmetrical GAACN7GTTC
palindrome. To test this hypothesis, the role of the GTAC submotif was
further characterized (Fig. 5). Our
findings indicate that replacing G and C with any base eliminates
recA promoter mobility. Moreover, promoter mobility is lost
whether T and A are replaced by either G or C (Fig. 5). The retardation
band is also detected when the T and A of this GATC motif are changed
to A and T, respectively (Fig. 5). These results suggest that the
recA promoter can also be shifted when the second submotif
is either GAAC or GTTC, although GTTC appeared to bind less well.
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FIG. 5.
Effects of systematic variation on the submotif GTAC
found in the GAACN7GTAC sequence upon the
electrophoretic mobility of the R. etli recA promoter. The
symbols + and refer to the presence or absence of R. etli crude protein extract, respectively.
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Substitution within the GTAC submotif resulted in a loss of
recA promoter inducibility in vivo, although the basal level
in this case was practically the same as that exhibited by the wild type (Fig. 4). This reduction in derepressed level may be attributed to
the fact that the GTAC tetranucleotide overlaps the predicted 10
region of the recA promoter (28). Hence, an
increase in expression due to the absence of negative regulation would
be neutralized by a decrease in the efficiency of transcription. Similar behavior has been described in other inducible genes
(2). However, the inducibility of the recA gene
is lost and the basal level is increased to values obtained in DNA
damage-induced wild-type cells only when the G-to-C change is
introduced into the GTAC motif (Fig. 4). This fact clearly demonstrates
that the inducibility of the R. etli recA gene is dependent
upon the GTAC motif.
All together, these findings prompted us to create all the possible
variants of this sequence in which the two internal bases were A or T
and the combination had either a direct or inverted repeat of the two
half sites. The recA promoter fragment containing either
GTTCN7GTTC, GTTCN7GAAC or
GATCN7GATC did not bind any protein (see Fig. 7). In
contrast, however, converting the sequence to GAACN7GTTC
and GTACN7GTAC reduced the extent of gel retardation (Fig.
6). It is worth noting that the
GAACN7GAAC sequence bound nearly as well as the wild type.
The reason why band retardation is found with the
GAACN7GAAC sequence but not with the GTTCN7GTTC sequence, despite the fact that the former would have
GTTCN7GTTC on the bottom strand, is so far unknown.
However, and such as happens in the B. subtilis SOS box
(33), some internal bases of the direct repeat are perhaps
involved in DNA-protein binding. Interestingly, the
GAACN7GTTC sequence presents the same two palindromic submotifs as the B. subtilis SOS box (3),
although in the latter case there are only 4 nucleotides between these
two submotifs. Our results indicate, nevertheless, that addition or
deletion of just 1 nucleotide between the two submotifs abolishes the
DNA gel mobility shift (Fig. 3). To our knowledge, the B. subtilis SOS box has been mutagenized in vitro at several internal
and surrounding positions. Some of these changes eliminated LexA
binding, whereas others reduced binding (32, 33). Whether
the spacing between the two half sites can be altered is, however,
still unknown.
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FIG. 6.
Mobility shift of the R. etli recA promoter
carrying direct or inverted repeat variants of the paired half sites of
the GAACN7GTAC motif. The resultant combinations
of 5' and 3' submotifs obtained after PCR mutagenesis are indicated
above each lane. The symbols + and refer to the presence
or absence of R. etli crude protein extract, respectively.
The mean binding activity of each fragment in three independent
experiments is also shown.
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The R. etli recA operator contains two potential
repressor binding sites.
The mutational experiments described
above demonstrate that several derivatives of the
GAACN7GTAC sequence are specifically recognized by the
protein which regulates the R. etli recA gene. One of these
derivatives coincides with the AAACN7GAAC sequence, which
is centered at 85 bp in the R. etli recA promoter.
Therefore, the protein-binding ability surrounding this upstream region
was analyzed. Figure 7 indicates that a
DNA-protein complex, presenting a binding activity of 8%, is indeed
formed when this fragment is used. This complex is specific and
apparently results from the binding of the same protein which
recognizes the GAACN7GTAC sequence found in the downstream
sequence, as binding disappears when a DNA fragment containing this
sequence is used as a competitor, but not when GAACN10GTAC
is used (Fig. 7). Furthermore, replacement of either the AAAC or GAAC
submotif of the AAACN7GAAC motif with a TCCG
tetranucleotide eliminates DNA-protein complex formation (Fig. 7). The
in vivo functional significance of this second binding site is unknown.
Although binding occurs at this sequence, DNA damage-mediated induction
still occurs from recA promoter fragments lacking the
AAACN7GAAC sequence (Fig. 4). Our data suggests that the protein controlling recA gene expression (which in all
likelihood is a homolog of the LexA-like proteins) is able to bind to
GAACN7GTAC and some variants found in the
R. etli chromosome.
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FIG. 7.
(A) Diagram showing the upstream region of the
GAACN7GTAC sequence present in the R. etli
recA promoter. The starting points of the upper (pC and pD) and
lower (pA and pB) primers used to obtain the recA up and recA down
fragments are indicated. Note that this figure is not drawn to scale.
wt, wild type. (B) Electrophoretic mobilities of the recA down, recA
up, recA upmut1, and recA upmut2 fragments in the absence (lanes 1, 3, 7, and 9) or in the presence (lanes 2, 4, 8, and 10) of R. etli crude extract. The effect of the addition of either a 10-fold
excess of the unlabelled wild-type recA down fragment (lane 5) or
100-fold excess of the unlabelled recA down (N10) mutant fragment (lane
6) on the migration of the wild-type recA up fragment is also shown.
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The GAACN7GTAC motif is present and
functional in R. meliloti and A. tumefaciens
recA genes.
The results obtained in our previous studies
suggest that R. etli, R. meliloti, and A. tumefaciens possess a common LexA-like repressor, since their
recA genes are DNA damage inducible when introduced into any
of these three bacterial species (22). As a consequence, we
have hypothesized that the promoter of the recA gene of
these microorganisms should contain the same regulatory sequence.
Indeed, Fig. 8A reveals that the
GAACN7GTAC motif is found upstream of the
R. meliloti and A. tumefaciens recA genes. To
test for the presence of specific binding to these sites, each recA gene fragment was incubated with a crude cell lysate
made from the same strain. A stable DNA-protein complex was observed with fragments containing either the R. meliloti or A. tumefaciens recA genes when they were incubated with their
respective crude cell lysates (Fig. 8B). In contrast, mutagenesis of
these GAACN7GTAC motifs abolished the
DNA-protein complex formation in both recA promoters (Fig.
8B). We were interested in determining whether these complexes were due
to the binding of a protein homologous to that which gave rise to the
band retardation in the R. etli extract and have analyzed
the effect of the crude cell extracts on the mobility of R. meliloti and A. tumefaciens recA promoters. Figure 8C
indicates that the mobility of the wild-type R. meliloti and
A. tumefaciens recA promoters is shifted in the presence of the R. etli extract. Moreover, the retarded bands disappear
when a wild-type R. etli recA promoter is used as a
competitor but not when an unlabelled R. etli recA promoter
carrying an insertion of three bases between the GAAC and GTAC motifs
is used (Fig. 8C). Furthermore, mutant forms of the R. meliloti and A. tumefaciens GAACN7GTAC
sequence did not show any change in electrophoretic mobility in
the presence of the R. etli extract (Fig. 8C). Together, these data indicate that the recA genes of R. etli, R. meliloti, and A. tumefaciens
possess the same damage-inducible regulatory sequence. Isolation and
characterization of other DNA damage-inducible genes of these organisms
is, however, required to determine whether the
GAACN7GTAC sequence is the SOS box of the
Rhizobiaceae family or whether it is only involved in the
regulation of their recA genes.
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FIG. 8.
(A) Sequence of the upstream region of the R. etli, R. meliloti, and A. tumefaciens recA
genes in which the GAACN7GTAC motif (which is
underlined) is present. The sequences of mutant derivatives of both
R. meliloti and A. tumefaciens recA genes
obtained after PCR mutagenesis (labelled with an asterisk) are also
shown. The mutational change introduced is overlined. As a landmark,
the +1 position of the R. etli recA gene is indicated. (B)
Gel mobility of both wild-type and mutant derivatives of the R. etli, R. meliloti, and A. tumefaciens recA
promoters in the absence () or in the presence (+) of their
respective crude cell extracts. (C) Electrophoretic mobility of both
the wild-type and mutant derivative forms of R. meliloti and
A. tumefaciens recA promoters in the presence of R. etli crude cell extract. The effect of the addition of either the
wild type (wt) or a mutant form (N10) of the R. etli
recA promoter on the gel mobility of the recA promoters
of R. meliloti and A. tumefaciens is also shown.
Strain abbreviations used in panels B and C are defined in panel A.
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ACKNOWLEDGMENTS |
This work was funded by grants PB94-0687 and PB97-0194 of the
Dirección General de Investigación Científica
y Técnica of Spain (DGICYT) and partially supported by the
Comissionat per Universitats i Recerca de la Generalitat de Catalunya.
Angels Tapias was a recipient of a predoctoral fellowship from the
Ministerio de Educación y Ciencia. We gratefully acknowledge the
help of the Direcció General d'Universitats de la Generalitat de
Catalunya for different grants for the purchase of equipment.
We are deeply indebted to Roger Woodgate for his comments on the
manuscript and general helpful suggestions. We are grateful to Maria
Aguilar for editorial assistance.
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FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Genetics and Microbiology, Faculty of Sciences, Universitat
Autònoma de Barcelona, Bellaterra, 08193-Barcelona, Spain. Phone:
34-93-5811837. Fax: 34-93-5812387. E-mail:
jbarbe{at}cc.uab.es.
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Journal of Bacteriology, December 1998, p. 6325-6331, Vol. 180, No. 23
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
