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Journal of Bacteriology, January 2001, p. 162-170, Vol. 183, No. 1
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.1.162-170.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Control of the Ferric Citrate Transport System of
Escherichia coli: Mutations in Region 2.1 of the FecI
Extracytoplasmic-Function Sigma Factor Suppress Mutations in the
FecR Transmembrane Regulatory Protein
Alfred
Stiefel,
Susanne
Mahren,
Martina
Ochs,
Petra T.
Schindler,
Sabine
Enz, and
Volkmar
Braun*
Mikrobiologie/Membranphysiologie,
Universität Tübingen, 72076 Tübingen, Germany
Received 26 July 2000/Accepted 13 October 2000
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ABSTRACT |
Transcription of the ferric citrate transport genes is initiated by
binding of ferric citrate to the FecA protein in the outer membrane of
Escherichia coli K-12. Bound ferric citrate does not have
to be transported but initiates a signal that is transmitted by FecA
across the outer membrane and by FecR across the cytoplasmic membrane
into the cytoplasm, where the FecI extracytoplasmic-function (ECF)
sigma factor becomes active. In this study, we isolated transcription
initiation-negative missense mutants in the cytoplasmic region of FecR
that were located at four sites, L13Q, W19R, W39R, and W50R, which are
highly conserved in FecR-like open reading frames of the
Pseudomonas aeruginosa, Pseudomonas putida,
Bordetella pertussis, Bordetella
bronchiseptica, and Caulobacter crescentus genomes.
The cytoplasmic portion of the FecR mutant proteins, FecR1-85, did not interact with wild-type FecI, in
contrast to wild-type FecR1-85, which induced
FecI-mediated fecB transport gene transcription. Two
missense mutations in region 2.1 of FecI, S15A and H20E, partially
restored induction of ferric citrate transport gene induction of the
fecR mutants by ferric citrate. Region 2.1 of
70 is thought to bind RNA polymerase core enzyme; the
residual activity of mutated FecI in the absence of FecR, however, was
not higher than that of wild-type FecI. In addition, missense mutations
in the fecI promoter region resulted in a twofold increased
transcription in fecR wild-type cells and a partial
restoration of fec transport gene transcription in the
fecR mutants. The mutations reduced binding of the
Fe2+ Fur repressor and as a consequence enhanced
fecI transcription. The data reveal properties of the FecI
ECF factor distinct from those of 70 and further support
the novel transcription initiation model in which the cytoplasmic
portion of FecR is important for FecI activity.
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INTRODUCTION |
Citrate does not serve as a carbon
source for Escherichia coli K-12 since it is not taken up by
the cells; however, Fe3+ delivered as a citrate complex is
actively transported by the FecA protein across the outer membrane
(46) and by the FecBCDE proteins (ATP binding cassette
transporter) across the cytoplasmic membrane (33, 40).
Transport studies using radiolabeled
[55Fe3+][14C]citrate revealed
uptake of iron and only minimal amounts of citrate, indicating that
only iron and not the iron complex enters the cytoplasm
(21). Yet ferric citrate induces transcription of ferric
siderophore transport genes and is the only ferric siderophore of
E. coli K-12 known to do so (46). Intracellular
ferric citrate does not serve as an inducer, and fecBCDE
mutants impaired in the transport of iron across the cytoplasmic
membrane are fully inducible (51).
The question arose as to how the inducer initiates transcription of
transport genes in the cytoplasm when only iron and not citrate enters
the cytoplasm. Mutants in the fecA, tonB,
exbB, or exbD gene (the latter two in combination
with tolQ or tolR mutations) are devoid of ferric
citrate transport across the outer membrane and are not inducible
(51). The obvious conclusion that entry of ferric citrate
into the periplasm is required for induction has been ruled out by
supplying to a fecA null mutant growth-promoting
concentrations of ferric dicitrate (molecular mass, 434 Da) that enter
the periplasm by diffusion through the porins. No induction of
fec transport genes is observed (19), and the
transport genes encoding cytoplasmic membrane transport activities have
to be constitutively overexpressed from a multicopy plasmid to provide
sufficient amounts of transport proteins.
A direct involvement of FecA in induction has been shown with
fecA missense mutants that induce fec
transcription constitutively in the absence of ferric citrate
(19) but do not transport ferric citrate. In contrast to
other E. coli ferric siderophore receptors, the mature FecA
protein contains an N-terminal extension. When a portion of the extra
peptide (residues 14 to 68) is removed by genetic means, induction is
abolished, but FecA fully retains transport activity. An overexpressed
N-terminal FecA1-67 fragment inhibits induction but not
transport (22). This proves that the N terminus of mature
FecA specifically participates in signal transduction but is
dispensable for transport.
The N-proximal portion of mature FecA is located in the periplasm
(22) and most likely interacts with the FecR regulatory protein; residues 101 to 317 of FecR were localized to the periplasm, residues 86 to 100 were localized to the cytoplasmic membrane, and
residues 1 to 85 were localized to the cytoplasm (31, 47). The transmembrane topology of FecR suggests that it transmits the
signal, elicited by binding of ferric citrate to FecA, across the
cytoplasmic membrane into the cytoplasm. FecR does not directly act on
the promoter upstream of the fecA gene that regulates
transcription of fecA and of the fecBCDE genes
downstream of fecA (2). Rather, FecR is
required for the activity of the FecI sigma factor, which belongs to
extracytoplasmic-function (ECF) sigma factors (28). No
other ECF regulatory system has been studied with respect to the entire
sequence of events, chemical entity of the signal, signal recognition,
signal transmission, and signal response, to the same extent as the
ferric citrate regulation system. Purified FecI mediates specific
binding of the RNA polymerase core enzyme to the promoter region
upstream of fecA, as revealed by DNA mobility band shift
experiments, and promotes fecA transcription in vitro (2). fecA and fecBCDE mRNA formation
is dependent on FecI under iron-limiting conditions in the presence of
ferric citrate, as shown by Northern hybridization studies
(12).
Interaction between the FecA, FecR, and FecI regulatory proteins has
been demonstrated using two methods. In in vitro binding assays, FecA
retained by FecR His tagged at the N terminus (His10-FecR) and bound to a Ni-nitrilotriacetic acid agarose column is coeluted with
His10-FecR; FecI retained by FecR His tagged at the C
terminus (FecR-His6) bound to the column and is coeluted
with FecR-His6 from the column. An N-terminally truncated,
induction-negative but transport-active FecA protein does not bind to
His10-FecR. In an in vivo assay, the FecA-, FecR-, and
FecI-interacting regions have been determined using the bacterial
two-hybrid Lex-based system. FecA1-79 interacts with
FecR101-317, and FecR1-85 interacts with
FecI1-173 (13).
The regulatory fecIR genes and the fecABCDE
transport genes form separate transcripts (12).
Transcription of fecIR is repressed by iron and the Fur
protein but is unaffected by ferric citrate, while fecABCDE
transcription is regulated by iron and Fur and by ferric citrate via
FecI and FecR (3, 12). FecI and FecR regulate
fec transport genes transcription, but they display no autoregulation (32). The iron transport genes are
regulated by the internal iron concentration and by external ferric
citrate. This is a very economical way of using ferric citrate as an
iron source. When iron is not needed or when ferric citrate is not present, the transport system is almost totally shut off by cytoplasmic iron. When the iron concentration in the cytoplasm falls below a
certain limit, the fecIR genes are transcribed. To turn on
the ferric citrate transport system, the carrier has to be in the culture medium. In addition to regulatory functions, the FecA, FecR,
and FecI proteins also have vectorial activities in that they transmit
information through three cell compartments. Binding of ferric citrate
to FecA induces a signal that is transferred from the cell surface into
the periplasm and across the cytoplasmic membrane into the cytoplasm.
It is thought that the information flux involves coupled conformational
changes of FecA and FecR.
In this paper, we report further investigation of the unusual mechanism
of transcription initiation mediated by FecA, FecI, and FecR.
Induction-inactive missense mutants in the cytoplasmic portion of FecR
and missense mutants in FecI which restore FecR-dependent FecI
transcription initiation were isolated. The suppressing mutations obtained in FecI were located close to each other in region 2.1 of
FecI. In addition, we isolated mutations in the fecI
promoter which upregulated fecI transcription because they
displayed a reduced binding of the Fe2+ Fur repressor.
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and media.
The E. coli strains and plasmids used in this study are listed in Table
1. Cells were grown in tryptone-yeast
extract (TY) or nutrient broth (NB) as described previously
(2). The antibiotics ampicillin (50 µg/ml),
chloramphenicol (40 µg/ml), and tetracycline (12 µg/ml) were added
to media as required.
Construction of plasmids.
Plasmid pMMO202 was obtained by
removing the cleavage sites for NdeI and BglI in
pHSG576. To construct plasmid pMMO203, the BamHI-HindIII fecIR fragment of
pKW135 (containing an NdeI restriction site at the
start codon of fecR) was cloned into
BamHI/HindIII-digested pMMO202.
fecR was randomly mutagenized by PCR using primers FecR1
(5'-CTGGAGTATGGCATATGAATC-3') and FecIR3. The mutated
fecR fragments
were cloned into pMMO203, restricted with
NdeI and
BglI to replace
the N-terminal 69 amino
acids of wild-type FecR, resulting in
plasmids pMMO222, pMMO247,
pMMO252, and pMMO277. Site-directed
mutagenesis of these plasmids by
PCR was performed to introduce
double nucleotide replacements using
primers PTS222B (5'-CGCTGGCAACAGAAGTATGAACAGGATCAGG-3'),
PTS47A (5'-AGCTGAACGTTGCGCTCGACGGCGGG-3'), PTS52A
(5'-CACGGCATATCTGTGGGAAGCTG-3'),
and PTS277B
(5'-GATAACCAGTGGGCCCGCCAGCAGGTTGAAAACC-3'), yielding
plasmids pPTS222, pPTS247, pPTS252, and pPTS277
respectively.
fecI was randomly mutagenized by PCR using primers SVP1
(5'-CCGACACATGCCAGAAGCAGAGGATCCATCCC-3') and FecIR3. The
resulting
fecIR fragments were cleaved with
BamHI/
NdeI and cloned into the
BamHI/
NdeI-restricted mutant
fecR
plasmids pPTS222, pPTS247, pPTS252,
and pPTS277. To obtain plasmids
pASc1, pASc2, and pASc3, the mutated
fecI fragments were
cloned into
BamHI/
NdeI-cleaved pPTS252, pPTS222,
and pPTS247, respectively. Plasmids pASc11, pASc12, and pASc13
were
constructed by replacing the mutated
fecR fragments in
pASc1,
pASc2, and pASc3 with wild-type
fecR.
Wild-type and mutated
fecI promoter regions were amplified
by PCR using primers PromIEco
(5'-GCGAATTCCCATCCCATTTTATACCTACC-3')
and PromIBam
(5'-CGGGATCCGGAGTGCATCAAAAGTTAATTATC-3'). To construct
plasmids pGFPI, pGFPI1, pGFPI2, and pGFPI3, the resulting PCR
fragments
were digested with
EcoRI/
BamHI and cloned into
EcoRI/
BamHI-restricted
pFPV25.
To avoid mutations in the
fecI promoter region, the mutated
fecIR fragments were restricted with
AseI and
NdeI and ligated
into the
AseI/
NdeI-cleaved mutant
fecR plasmids
pAS222, pAS247,
pAS252, and pAS277, resulting in plasmids pAS321,
pAS312, pAS323,
and pAS344, respectively. Plasmid pAS202 was obtained
by removing
the cleavage site for
AseI in pMMO202. To
construct plasmid pAS203,
the
BamHI-
HindIII
fecIR fragment of pKW135 was cloned into
BamHI/
HindIII-digested
pAS202. For
construction of plasmids pAS222, pAS247, pAS252, and
pAS277, the
NdeI-
HindIII
fecR fragments of
pPTS222, pPTS247, pPTS252,
and pPTS277 were ligated into
NdeI/
HindIII-cleaved
pAS203.
To replace the
fos zipper motif of plasmid pMS604, plasmids
pAS203, pAS312, pAS323, and pAS344 were amplified by PCR with
primers
FecIBstEII (5'-GATCGAGGTGACCATGTCTGACCGCGCC-3') and FecIPst
(5'-GGTTAACACTGCAGTCATAACCCATACTC-3'). The resulting
fragments
were cloned into
BstEII/
PstI- or
BstEII/
XhoI-cleaved pMS604, resulting
in plasmids
pSM173, pSM1731, and pSM1732 or plasmids pSM852, pSM853,
and
pSM854.
Plasmids pSM85, pSM8539, and pSM8550 were constructed by PCR
amplification using primers FecRXhoI
(5'-GGAAGTCTCGAGATGAATCCTTTGTTAACC-3')
and FecRBglII
(5'-CAACAGAATCTTCATTTCATCACACGTGACG-3') and plasmids
pAS203,
pAS222, and pAS277 as DNA templates. To replace the
jun zipper motif of plasmid pDP804, the resulting
XhoI/
BglII
fecR1-58 and
mutated
fecR1-58 fragments were ligated into
XhoI/
BglII-digested
pDP804.
For construction of plasmid pLCIRA, the
EcoRI-
BamHI
fecA fragment of pIS711
was ligated into
EcoRI/
BamHI-cleaved pAS203.
Plasmids
pSM10, pSM11, and pSM12 were constructed by PCR using primers
FecR1 and FecR85HindIII (5'-GAGCAAAAGCTTTAATCATTTCATCACGTGACG-3')
with the DNA templates pAS203, pAS222, and pAS277, respectively.
The resulting
NdeI-
HindIII
fecR1-58 fragments were ligated
into
NdeI/
HindIII-cleaved pLCIRA. To obtain
plasmids pSM13, pSM14,
and pSM15, the mutated
BamHI/
NdeI
fecI fragment of plasmid
pAS323
was cloned into
BamHI/
HindIII-digested
pSM10, pSM11, and pSM12,
respectively.
Recombinant DNA techniques.
Standard techniques
(34) or the protocols of the suppliers were used for the
isolation of plasmid DNA, PCR, digestion with restriction
endonucleases, ligation, transformation, and agarose gel
electrophoresis. DNA was sequenced by the dideoxy chain termination method (35) using an AutoRead Sequencing kit (Pharmacia
Biotech, Freiburg, Germany). The reaction products were sequenced on an A.L.F. DNA sequencer (Pharmacia Biotech).
PCR techniques.
PCR amplification was carried out using
Taq polymerase (Qiagen, Hilden, Germany) and standard
conditions. DNA was initially denatured by heating to 94°C for 3 min.
This was followed by 30 cycles consisting of denaturing at 94°C for 1 min, annealing at 54°C for 2 min, and extension at 72°C for 3 min.
Random mutagenesis by PCR was carried out as previously described
(26). Site-directed mutagenesis was performed according to
Feinberg et al. (14).
Determination of 
-galactosidase activity.
-Galactosidase activity was determined according to Miller
(30) and Giacomini et al. (16). For
measurement of induction activity, the cells were grown in NB medium
without additions or supplemented as indicated with 0.2 mM
2,2'-dipyridyl or 1 mM citrate. For the LexA-based repression system,
the cells were grown in TY medium supplemented with 1 mM IPTG
(isopropyl--D-thiogalactopyranoside).
GFP measurements.
Cells were grown in TY or NB medium as
indicated. Green fluorescent protein (GFP) was quantified by
fluorometry in an Bio-Tek FL500 microplate fluorescence reader (Bio-Tek
Instruments Inc., Winooski, Vt.). Specific activity of GFP in bacterial
cultures was expressed as relative fluorescence intensity at 530 nm of cells adjusted to an optical density at 578 nm of 0.5 in
phosphate-buffered saline (44).
Similarity searching and sequence alignments.
A global
similarity search of the current National Center for Biotechnology
Information nucleic acid databases with the advanced BLAST search and
the specialized BLAST search of finished and unfinished microbial
genomes was used to look for amino acid sequences homologous to the
FecR sequence. Preliminary sequence data for Bordetella
pertussis and Bordetella bronchiseptica were obtained from The Institute for Genomic Research website at http://www.tigr.org. Sequence data for Pseudomonas putida and Caulobacter
crescentus were from the Sanger Center and can be obtained from
ftp://ftp.sanger.ac.uk/pub/yyy. Sequences of Pseudomonas
aeruginosa were obtained from the Pseudomonas Genome Project at
http://www.pseudomonas.com/data.html. The sequences of E. coli FecR (M63115), P. aeruginosa HasR (AF127223) and PigE (AF060193), and P. putida PupR (X77918) were
translated from the GenBank entries given in parentheses. Protein
sequences were aligned by using CLUSTAL W.
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RESULTS |
Isolation of induction-negative fecR mutations.
To
identify functionally important residues of FecR and to determine
regions of interaction between FecR and FecI, we isolated inactive
fecR point mutants and examined restoration of transcription initiation of the fec transport genes by fecI
point mutants. fecR was mutagenized by PCR, and the
fragments encoding residues 1 to 69 of FecR were cloned into the
low-copy-number plasmid pMMO203 fecIR to replace residues 1 to 69 of wild-type FecR. E. coli MO704 fecI::Kan 'fecR fecB-lacZ was used to
select fecR mutants. Insertion of the kanamycin resistance
box resulted in the deletion of the 3' end of fecI and the
5' end of fecR (32). Transformants with the
mutagenized pMMO203 plasmids were screened on MacConkey agar plates
containing 1 mM citrate, which forms ferric citrate with iron contained
in the nutrient agar. Under these conditions, fecB-lacZ transcription is induced by wild-type fecIR, and red
colonies are formed; mutated fecIR does not induce
fecB-lacZ transcription, and white and pink colonies are
formed. The fecR genes of plasmids from white and pink
colonies were sequenced; four missense mutations with a
leucine-to-glutamine change at position 13 and three different tryptophan-to-arginine changes at residues 19, 39, and 50 were identified (Table 2).
-Galactosidase activity of
E. coli MO704 cells
transformed with the pMMO203
fecR mutant derivatives and
grown in NB medium
with and without citrate supplementation was
determined to verify
the results obtained on the MacConkey plates. All
four mutants
with point mutations in
fecR displayed very low
ferric citrate-dependent
fecB-lacZ transcription compared to
the 35-fold increase of the
wild-type
fecR+
strain in the presence of citrate (Table
2). The threefold increased
activity of the
fecR mutants in the presence of citrate may
result
from iron starvation, which derepresses
fecIR and
fecABCDE transcription,
caused by the lack of
citrate-mediated iron uptake of the
fecB-lacZ transport
mutant. The increased levels of mutant FecR and wild-type
FecI could
enhance the residual functional interaction between
the proteins.
Synthesis of the mutant FecR proteins was confirmed
by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis after
overexpression in an
IPTG-inducible T7 promoter system (data not
shown). Since the
fecR point mutants reverted to wild type in
the subsequent
suppression analysis with
fecI mutants, a second
nucleotide
replacement was introduced into the mutated
fecR codons
(Table
1).
Mutations in the fecI coding region that restore
transcription initiation by the fecR mutants.
To
determine sites of FecI that might interact with FecR, fecI
mutations that suppress the fecR missense point mutations
were isolated. To prevent mutations in the fecI promoter
region, fecI lacking the promoter region was randomly
mutagenized by PCR, and the DNA fragments were inserted into the
pMMO203 fecIR derivatives encoding the fecR
mutants with two mutations in one codon. Red colonies of E. coli MO704 transformants were screened on MacConkey plates,
plasmids were isolated, and the fecI regions were sequenced. Four mutants were identified (Fig. 1B).
Three of the four mutants showed a serine-to-alanine change at position
15 (S15A); one was a single mutation, one contained an additional
alanine-to-glycine change (A5G), and one contained an additional
threonine-to-serine change (T12S) (Table
3). These differences showed that all
three S15A mutations resulted from independent events. All three
mutants had similar citrate-dependent -galactosidase activities, 21 to 28% of wild-type activity (Table 3), which suggests that the S15A
mutation causes the partial restoration of transcription initiation
(regarding A5G, see Discussion). In comparison to the -galactosidase
values of cells with wild-type fecI (Table 2), the
fecI mutants displayed a three- to fivefold-higher
citrate-dependent activity. The fourth mutant, with a single
histidine-to-glutamic acid change at position 20, had -galactosidase
activity twofold higher than that of FecR(W50R) combined with wild-type
FecI.
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FIG. 1.
(A) Promoter sequence upstream of the fecI
fecR operon. Positions of mutations are indicated by asterisks,
positions of  35 and 10 promoter regions are illustrated in bold
letters, and the transcription start point is indicated by an arrow.
The consensus sequence of the Fur box is illustrated below. (B)
Schematic map of FecI illustrating regions homologous to
70. The sites of amino acid substitutions are indicated
below FecI.
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Since the
fecI suppressor mutations were observed in
combination with distinct
fecR point mutations, we tested
allele specificity.
Each of the four
fecI suppressor
mutations was combined with each
of the four
fecR mutant
genes in
E. coli MO704. The
-galactosidase
activities of
the FecI derivatives with each of the FecR mutants
were similar,
244 ± 10 U for FecI(S15A, T12S), 198 ± 6 U for FecI(S15A,
A5G), 267 ± 7 U for FecI(S15A), and 159 ± 6 U for
FecI(H20E),
which indicated no allele
specificity.
FecI(S15A), FecI(S15A, W12S), and FecI(H20E) are located close together
in region 2.1 of the sigma factor; this region in
70 is
implicated in RNA polymerase core binding (
25,
38).
Therefore,
the missense mutations in
fecI could have
increased the affinity
of FecI to the RNA polymerase core enzyme,
resulting in a higher
level of
fec transport gene
transcription. To examine this possibility,
the
fecI
suppressor mutations were combined with the wild-type
fecR
gene. The
-galactosidase activities measured were similar
to those
of wild-type
fecIR, on average 18 U in NB medium and
797 U
in NB medium supplemented with citrate. In addition, the
-galactosidase activities of the FecI mutants in the absence
of FecR
were measured; the activities were lower than those of
wild-type FecI
(8 to 10 U and 20 U, respectively). These results
provide no evidence
that the S15A and H20E mutations alter the
interaction of FecI with the
RNA polymerase core enzyme or increase
the amount of active
FecI.
In vivo interaction of the FecI suppressor mutants with mutated
FecR.
We have recently shown that FecI interacts with the
cytoplasmic N terminus of FecR (FecR1-85) by using a
bacterial two-hybrid system (13). To determine the
physical interactions between the mutants of FecI and FecR,
translational fusions were constructed between
LexA1-87408, which binds to one site of the
sulA promoter (9), and the wild-type
FecR1-85 (FecR1-85WT) derivatives, and
between LexA1-87, which binds to another site of the
sulA promoter, and the FecI derivatives (Table
4). FecR1-85 had to be used
because it represents the cytoplasmic portion of FecR. Mutated
FecR1-85 combined with mutated FecI or wild-type FecI did
not repress sulA-lacZ transcription, indicating that the
mutated FecR1-85 fragments did not interact with FecI.
This could explain inactivity of the mutated FecR proteins. In
contrast, FecR1-85WT combined with mutated or wild-type FecI repressed sulA-lacZ transcription (Table 4).
Since the complete FecR and FecR mutant proteins combined with the FccJ
mutant proteins induced transcription of
fecB-lacZ,
the
induction of transcription of the truncated FecR
1-85 and
mutant FecR
1-85 proteins was studied.
-Galactosidase
activities were determined in
E. coli AA93
fec/pMMO1034
fecA-lacZ transformed with
low-copy-number plasmids encoding
fecA and the
fecR1-85 and
fecI derivatives (Table
5). No transcription
induction was
recorded with the FecR
1-85 mutant proteins.
These results
agree with the lack of interaction of the truncated
FecR mutant
proteins in the bacterial two-hybrid system. In the
control,
FecR
1-85WT combined with wild-type or mutated FecI
displayed constitutive
fecA-lacZ transport gene
transcription,
as found previously for the wild-type combination
(
31).
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TABLE 5.
Induction of fecA-lacZ transcription by
cytoplasmic FecR derivatives combined with wild-type and mutant FecI
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fecI promoter mutants that restore induction of the
fecR mutants.
Originally we randomly mutagenized
complete fecI by PCR. E. coli MO704 carrying one
of the fecR mutant genes (Table 2) was transformed with the
pooled fecI plasmids, and red colonies were isolated on
MacConkey agar plates supplemented with 1 mM citrate. They displayed
-galactosidase activities two- to threefold higher (Table
6) than the values obtained with
wild-type FecI (Table 2), which indicated a citrate-independent
transcription initiation by the mutated fecI region. An
additional two- to threefold increase was recorded in the presence of 1 mM citrate in the growth medium; this increase could be caused by iron
limitation and ferric citrate induction.
Sequencing of the mutated
fecI regions revealed nucleotide
replacements upstream of the
fecI open reading frame (Table
6).
The A1120G replacement is located 28 bp upstream of the postulated
35 region; A1174T is in the
10 region and together with A1180G
rests in the predicted Fur box to which the Fe
2+ Fur
repressor binds under iron-replete conditions (Fig.
1A).
A1210G is
located 24 bp downstream of the transcription start
site. The
fecI promoter mutants combined with wild-type
fecR displayed
in the absence of ferric citrate 12-, 29-, and 42-fold, and in
the presence of ferric citrate 1.6-, 2.4-, and
2.4-fold, increases
in
fecB-lacZ transcription (Table
6).
Constitutive transcription by the
fecI promoter mutants was
also determined in
E. coli AA93
fec grown in
NB medium with and
without addition of 1 mM citrate. Since the
fec strain cannot
take up ferric citrate, addition of
citrate results in trapping
of iron, making it unavailable to cells.
Ferric citrate cannot
act as an inducer since the cells lack FecA and
FecR. Transcription
initiation controlled by the mutated
fecI promoter regions was
examined by inserting the promoter
regions upstream of a promoterless
gfp gene. Two of the
promoter mutants, A1174T, A1210G, and A1180G,
displayed a two- to
threefold increase in fluorescence relative
to that of the strain
carrying nonmutated
fecI, whereas the A1120G
mutation
increased transcription only slightly (Table
7). In
the latter mutant, iron starvation
by addition of citrate increased
transcription 2.4-fold, whereas the
already strongly induced mutants
showed only 1.2- and 1.6-fold
enhancements of transcription.
To demonstrate differences in Fe
2+ Fur repressor binding to
the mutants as the cause of their distinct induction levels,
Fe
2+ Fur repressor binding to
fecI wild-type and
fecI mutant promoters
was examined in a Fur titration assay
using
E. coli H1717
fhuF-lacZ;
transcription of
fhuF is particularly sensitive to the level of
the iron
supply (
41). TY medium, which provides sufficient iron
to
cells, was used to eliminate experimentally imposed iron limitation.
As
shown in Table
8, the promoters of
fecI(A1174T, A1210G) and
fecI(A1180G) bound less
Fe
2+ Fur than the
fecI(A1120G) and wild-type
fecI promoters, resulting
in an increased concentration of
free Fe
2+ Fur, which could then bind to the
fhuF
promoter and repress
fhuF-lacZ transcription. Since also
fecR transcription is controlled by
the promoter upstream of
fecI, an increase of one or both proteins
resulted in the
suppression phenotype. It is conceivable that
residual activities of
the mutated FecR proteins together with
an increased level of FecI
suffice to initiate transcription of
the
fec transport
genes. The titration results do not explain
the slight increase of
fecI transcription by the A1120G mutation.
| |
DISCUSSION |
Since no transcription initiation mechanism that starts at the
cell surface and requires a cytoplasmic membrane protein for induction
has been characterized to date, we further investigated our proposed
model by examination of FecR missense mutants. Point mutants with amino
acid replacements in the cytoplasmic portion of FecR were isolated and
failed to induce transcription of fecB-lacZ. The mutations
L13Q, W19R, W39R, and W50R are located in the region from residues 9 to
49, which was previously shown to interact with FecI (13).
Database searches of complete and incomplete sequenced bacterial
genomes revealed genes homologous to the fec regulatory
genes fecI and fecR in P. aeruginosa,
P. putida, B. bronchiseptica, B. pertussis, and C. crescentus (Fig.
2). Of 23 complete and partial FecR
homologous sequences available, all contained W19, W39, and W50 with
the exception of three F and four Y replacement in W50. Since the
replacements conserved the aromatic nature of the amino acids, it is
conceivable that aromatic amino acids are essential at these sites.
Random mutagenesis used in this study clearly identified these highly
conserved amino acid residues as important for FecR activity. L13 is
less conserved and is replaced mostly by apolar amino acids but in two
sequences also by charged arginine. The sequences align perfectly with
FecR with two exceptions where sequence gaps of only one and two amino acids, respectively, had to be introduced. The identity between E. coli K-12 FecR and the putative FecR sequences range from
24 to 37%, with an average identity of 30%. In the various genomes, fecI and fecR are arranged as in E. coli and are presumably transcriptionally coupled. Furthermore,
downstream of the regulatory genes are sequences that show similarity
to ECF sigma factor-dependent promoters. Only the PupI-PupR system of
P. putida has been studied to the extent that the outer
membrane transporter, PupI, and PupR were shown to be required for
induction (23). In the absence of inducer, PupR seems to
repress synthesis of the outer membrane transporter, as one would
expect from an anti-sigma factor and in agreement with other ECF sigma
factor systems in which the regulator functions negatively as an
anti-sigma factor. No evidence exists for a negative FecR function in
the fec system. For the homologous genes other than
pup, it is not known whether sequence similarity reflects similar functions and whether the mechanism of fec
regulation represents the paradigm of other gene transcription
regulatory devices.
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|
FIG. 2.
Alignment of the N termini of E. coli FecR
homologs. Similarity search and sequence alignment were done as
described in Materials and Methods. E. c., E. coli; P. a., P. aeruginosa; P. p., P. putida; B. b., B. bronchiseptica; B. p., B. pertussis;
C. c., C. crescentus. Note the highly conserved
tryptophan (W) residues corresponding to positions 19, 39, and 50 of
E. coli FecR.
|
|
Restoration of transcription induction of the FecR mutants depended on
the FecI mutants and ferric citrate in the medium. Wild-type FecI was
inactive. We assume that the FecI mutant proteins can be converted to
an active sigma factor more easily than wild-type FecI, so that the
presumed residual activities of the mutated FecR derivatives are
sufficient for FecI activation. The mutant FecR1-85
derivatives were not active, in contrast to FecR1-85WT, which together with FecI initiated fec transport gene
transcription in the absence of ferric citrate. This result suggests
that FecR1-85 does not entirely reflect the conformation
of the cytoplasmic portion of the complete FecR once it has received
the signal from FecA occupied by ferric citrate. This interpretation is
supported by the lack of interaction of
FecR1-85(W39R) and FecR1-85(W50R) with either
wild-type FecI, FecI(S15A), or FecI(H20E), as revealed by the
two-hybrid system.
The fecI mutations were confined to a narrow region at the
FecI N terminus, even though the entire fecI gene was
mutagenized by PCR. The S15A mutation was obtained three times and
represents a conservative alteration from a polar to an apolar amino
acid, both of which require a similar amount of space. The average
-galactosidase activity induced by the FecI S15A mutants amounted to
25% of the activity displayed by wild-type FecI; the mutations
increased the fecB-lacZ -galactosidase activity of
the FecR missense mutants three- to fivefold. The FecI H20E mutant was
less active; it had 16% of the -galactosidase activity of the
wild-type and a twofold increase in fecB-lacZ
-galactosidase activity of the FecR mutant cells.
Each of the single fecI mutations is located in region 2.1 of FecI. Deletion of subregion 2.1 of 70 reduces
70 binding to the RNA polymerase core enzyme (25,
38). The recently determined structure of a large part of
70 revealed that regions 2.1 and 2.2 form two
-helices at the surface of 70 that are linked by a
loop and interact primarily through hydrophobic contacts
(29). We found no evidence for an improved interaction between mutated FecI with RNA polymerase core subunits, which might
have explained restoration of induction in the FecR mutants. The FecI
mutants did not show higher activity with wild-type FecR and did not
display higher residual activity in the absence of FecR.
Since the FecI S15A and H20E mutations are located close to each other
and the FecR mutations L13Q, W10R, W39R, and W50R are confined to a
short region that may fold such that the side chains are positioned
close to each other, it is tempting to assume that these two sites
disclose regions of interaction between the two proteins. The lack of
allele specificity does not rule out this interpretation since, for
example, the sites of interaction between the TonB protein (around
residue 160) and the so-called TonB box of the BtuB (17)
and FhuA proteins (36), as identified by suppressor
analyses, also lack allele specificity, yet recent cysteine
cross-linking studies established beyond doubt interaction of the TonB
box of BtuB with region 160 of TonB (8). Since no specific
side chain recognition was observed, it has been concluded that the
mutations distort the secondary structure of the interacting regions
and thus impair functional interaction (17). The same conclusion could apply to the FecI-FecR interaction.
The fecI promoter mutations that partially restored
induction of fecB gene transcription of the inactive
fecR mutants bound less Fe2+ Fur and
consequently led to a higher fecI and fecR
transcription than in the wild-type fecIR strain under the
same conditions. Derepression could still be enhanced by withdrawing
iron by addition of citrate or dipyridyl to the medium. The same
explanation as given above may account for this finding. Increase of
FecI and mutant FecR proteins increases the probability of a functional interaction that leads to induction-active FecI. A comparable situation
exists in the case of E which is one of the stress
response factors of E. coli that belongs to the ECF
family and is negatively regulated by the transmembrane anti-sigma
factor RseA. The activity of E is determined by the
relative levels of E and RseA, and RseA is regulated by
controlled proteolysis (1). FecI is positively regulated
by FecR, and the amount of active FecI certainly depends on the amounts
of active FecR. Activation of FecI does not necessarily imply an
alteration in the conformation of FecI or a chemical modification of
FecI. Rather, if FecI is synthesized in an active form but rapidly
loses activity, stabilization of the active FecI form by active FecR
would also account for the data hitherto collected. FecI while bound to
FecR would be inactive. When FecR receives the transcription initiation
signal from ferric citrate-loaded FecA, it changes the conformation in the cytoplasmic portion, and FecI dissociates from FecR and immediately binds to the RNA polymerase.
The ECF factors lack large portions of the conserved region 1 (28), which in 70 appears to primarily
affect DNA binding by region 4. This led to the proposal that binding
of the factors to the core subunits induces a conformational change
that exposes the DNA binding region to allow promoter recognition by
the holoenzyme (11). FecI completely lacks region 1.1 and
has only nine amino acids in region 1.2. Deletion of residues 2 to 8 did not affect FecI activity (data not shown), and therefore region 1 is not essential for ferric citrate-dependent fec transport
gene transcription. This result makes it unlikely that the A5G mutation
of pAS302 transformants contributed to the phenotype. This conclusion
is supported by our data on SigX of Bacillus subtilis, which
completely lacks regions 1.1 and 1.2 and can replace FecI in that it
initiates transcription of the fec transport genes in
E. coli in the absence of ferric citrate and FecR
(6).
| |
ACKNOWLEDGMENTS |
We thank A. Angerer, U. H. Stroeher, and K. Hantke for helpful
discussions and K. A. Brune for critical reading of the manuscript.
This work was supported by the Deutsche Forschungsgemeinschaft (SFB
323, project B1, Graduiertenkolleg Mikrobiologie) and the Fonds der
Chemischen Industrie.
| |
FOOTNOTES |
*
Corresponding author. Mailing address:
Mikrobiologie/Membranphysiologie, Universität Tübingen, Auf
der Morgenstelle 28, D-72074 Tübingen, Germany. Phone:
49-7071-2972096. Fax: 49-7071-295843. E-mail:
volkmar.braun{at}mikrobio.uni-tuebingen.de.
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Journal of Bacteriology, January 2001, p. 162-170, Vol. 183, No. 1
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.1.162-170.2001
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Abstract
Introduction
