INTRODUCTION

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In Escherichia coli, citrate-mediated iron transport is catalyzed across the outer membrane by the FecA protein and the TonB, ExbB, and ExbD proteins, which presumably energize active transport across the outer membrane through the electrochemical potential of the cytoplasmic membrane. Transport of iron across the cytoplasmic membrane is mediated by an ATP binding cassette transporter, which consists of the periplasmic binding protein FecB, the hydrophobic membrane proteins FecC and FecD, and the FecE ATPase (23, 31).

The special feature of the ferric citrate transport system is the induction of the fecABCDE transport gene operon by ferric citrate, which does not have to be taken up into the periplasm or into the cytoplasm (4). By binding to the FecA outer membrane protein, ferric citrate triggers a signal that is transferred across the outer membrane, the periplasm, and the cytoplasmic membrane into the cytoplasm (10). The N terminus of FecA is located in the periplasm and is required for signaling but is dispensable for transport (16). As in transport, TonB, ExbB, ExbD, and the electrochemical potential of the cytoplasmic membrane are involved in signal transfer across the outer membrane (16). The FecR regulatory protein is required for the response of cells to ferric citrate (21, 36) and activates the FecI protein in the cytoplasm by an unknown mechanism; FecI functions as a sigma factor that directs the RNA polymerase to the promoter upstream of fecA (1, 6, 7, 22). In addition to induction of the fec transport genes by ferric citrate, transcription of the regulatory genes fecI and fecR and of the fec transport genes is repressed by iron via the Fur repressor (6, 13, 41), which binds to the promoter upstream of fecI fecR and of fecABCDE (2).

To understand the surface signaling mechanism of fec transport gene induction, it is important to know the transmembrane topology of the FecR protein. We constructed hybrid proteins between C-terminally truncated FecR derivatives and the BlaM -lactamase and determined the fusion sites of FecR that indicated a periplasmic or a cytoplasmic location of BlaM. Furthermore, all of the FecR'-BlaM hybrid proteins that contained the fusion sites after the proposed transmembrane segment of FecR activated transcription and translation of fecA independent of ferric citrate. In addition, the ampicillin resistance of two FecR'-BlaM hybrid proteins was increased by FecA, suggesting a physical interaction of FecR with FecA.

	MATERIALS AND METHODS

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Bacterial strains and plasmids. The E. coli strains and plasmids used in this study are listed in Table 1; also see Tables 2 to 4.

Media. Cells were grown in TY medium, which contained (per liter) 8 g of tryptone (Difco Laboratories), 5 g of yeast extract, and 5 g of NaCl (pH 7). Growth on ferric citrate as the sole iron source was tested on Fec agar plates, which contained (per liter) 8 g of nutrient broth, 5 g of NaCl, 15 g of nutrient agar, 0.2 mM 2,2-dipyridyl, and 1 mM sodium citrate (pH 7). The antibiotics ampicillin (50 µg/ml), chloramphenicol (25 µg/ml for cells containing low-copy-number plasmids and 40 µg/ml for those containing high-copy-number plasmids), neomycin (50 µg/ml), and tetracycline (15 µg/ml) were added as required.

Recombinant DNA techniques. DNA isolation from bacteria, recovery of DNA fragments from agarose gels, cloning of restriction fragments, and transformation were done by standard methods (27). All of the constructed gene fusions, deletions, nucleotide replacements, and PCR-amplified DNA fragments were sequenced by the enzymatic dideoxy chain termination method (28) with [³⁵S]dATP (Amersham) or fluorescein-15dATP for labeling. The fluorescein-labeled reaction products were analyzed with an A.L.F. DNA sequencer (Pharmacia Biotech, Freiburg, Germany). The primer blaM (5'-CTGGTGCACCCAACTGA-3') was complementary to codons 15 to 21 of mature -lactamase, and other primers complementary to various regions of fecIR were also used. DNA was amplified by PCR, using the Gene Amp process with Taq polymerase (Promega, Madison, Wis.) as described previously (21).

Determination of -galactosidase activity. -Galactosidase activity was determined by the method of Miller (20) and Giacomini et al. (9). Cells were grown to the exponential growth phase in M9 medium supplemented with vitamin-free Casamino Acids (Difco Laboratories) and 0.1 mg each of tryptophan, phenylalanine, and tyrosine per ml. The media were supplemented, as indicated, with sodium citrate (1 mM) and 2,2-dipyridyl (50 µM).

Overexpression of FecR'-BlaM hybrid proteins. The fecR'-blaM gene fusions were transcribed by the T7 RNA polymerase encoded on the chromosome of E. coli BL2173. Cells were grown in 2 ml of TY medium at 37°C to the exponential growth phase (optical density at 578 nm, 0.5), and then transcription by the RNA polymerase was induced for 1 h with 2 mM isopropyl--D-thiogalactoside (IPTG).

Detection of inclusion bodies. Plasmids with fecR and fecR'-blaM fusions were transcribed by the temperature-inducible phage T7 RNA polymerase encoded by plasmid pGP1-2, which was contained in E. coli WM1576 (K38) (34). Overexpression of the FecR derivatives and labeling with [³⁵S]methionine were performed by the method of Fischer et al. (8). Spheroplasts were prepared by suspending cells in 500 µl of ice-cold 0.2 M Tris-HCl (pH 8.0)-0.5 M sucrose. The cells were treated for 15 min on ice with 50 µl of lysozyme (5 mg/ml in 50 mM Tris-HCl [pH 8.0]), 50 µl of 5 mM EDTA, and 500 µl of 0.2 M Tris-HCl (pH 8.0)-0.5 mM EDTA. Spheroplasts were collected by centrifugation for 30 min at 15,000 × g in an Eppendorf centrifuge. The proteins in the supernatant were precipitated with 0.5 volume of 30% trichloroacetic acid for 30 min on ice, pelleted for 15 min, washed with 100 µl of acetone and 100 µl of acetone-water (1:1), and then suspended in 20 µl of sodium dodecyl sulfate (SDS) buffer. The sedimented spheroplasts were suspended in 500 µl of H₂O, 3 µl of DNase (2 µg/ml), and 25 µl of 1 M MgSO₄. After 30 min at room temperature, the spheroplasts were lysed by three cycles of freezing to 80°C and thawing. The lysate was centrifuged for 15 min at 600 × g, and the sediment was suspended in 20 µl of SDS-polyacrylamide gel electrophoresis (PAGE) lysis buffer. The supernatant was centrifuged at 6,000 × g and again at 14,000 × g. Proteins of the 14,000 × g supernatant were precipitated with trichloroacetic acid (final concentration, 10%) and washed with acetone and acetone-water.

SDS-PAGE. Cells and proteins in the various cell fractions were dissolved in lysis buffer in a boiling-water bath for 2 min. Proteins were separated by SDS-PAGE (15% polyacrylamide) (18) and identified by staining with Serva Blue (Serva, Heidelberg, Germany).

Computer-assisted analysis. Protein and nucleic acid sequences were analyzed with PC/Gene, release 6.01 (IntelliGenetics Inc., Mountain View, Calif.), Husar and Phd (EMBL, Heidelberg, Germany), and TMbase (Swiss Institute of Experimental Cancer Research, Lausanne, Switzerland) (12).

	RESULTS

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Determination of the transmembrane topology of the FecR protein. To determine the arrangement of the FecR protein in the cytoplasmic membrane of E. coli, hybrid proteins between FecR and the mature TEM -lactamase, lacking its own signal sequence, were constructed. Since only periplasmic -lactamase confers resistance to ampicillin, it is inferred that hybrid proteins which render cells ampicillin resistant contain -lactamase fused to sites in FecR that are exposed to the periplasm. This method was developed by Broome-Smith and Spratt (5) and has been successfully used for the determination of the transmembrane topology of a number of proteins (3, 15, 24). Plasmid pDW20 (fecR) was cleaved with SalI, digested for various periods with Bal 31 exonuclease, blunt ended, cleaved with PvuII upstream of blaM, religated, and transformed into E. coli 5K. For selection of inframe fusions, neomycin-resistant colonies were streaked on nutrient agar plates containing ampicillin (200 µg/ml). The ampicillin resistance was tested with single cells on agar plates containing ampicillin concentrations from 5 to 1,600 µg ml¹. The fusion sites between fecR and blaM were determined by DNA sequencing.

1

View larger version (37K): [in this window] [in a new window]   FIG. 1.   Alternative topologies of FecR in the cytoplasmic membrane showing four membrane-spanning segments (A) and one membrane-spanning segment (B).

View larger version (55K): [in this window] [in a new window]   FIG. 2.   Stained gel after SDS-PAGE of FecR'-BlaM hybrid proteins carrying fusions at residues 8, 21, 25, 61, 75, 81, 127, 133, 159, 172, 209, 230, 237, 241, 259, 274, 281, and 301 of FecR (lanes 3 to 20, respectively). The proteins were synthesized in E. coli BL2173 in which the hybrid genes were transcribed by the phage T7 RNA polymerase, whose synthesis was induced by 2 mM IPTG. Lane 1, standard proteins of 14.3, 20.1, 26.6, 39.2, 55.6, and 85.2 kDa. Lane 2, FecR (35.5 kDa) and its 20.2-kDa N-terminal and 15.3-kDa C-terminal degradation fragments (arrows). FecR230-BlaM and the larger hybrid proteins were proteolytically cleaved.

Increase of FecR-BlaM activity in protease-negative and chaperone-overproducing cells. The E. coli 5K fecR-blaM transformants that were resistant to 5 µg of ampicillin/ml were clearly not fully sensitive, suggesting that secretion of BlaM into the periplasm by the FecR fragments had occurred (Table 2). The corresponding fecR-blaM transformants of E. coli AA93 fec all showed resistance to 5 µg of ampicillin/ml, and none were fully sensitive (except E. coli AA93 carrying fecR8-blaM to fecR81-blaM and fecR). Therefore, we examined whether ampicillin resistance could be increased in cells transformed with plasmids encoding chaperones or in mutants lacking certain proteases. Three of the low-resistance FecR'-BlaM proteins and, as controls, a high-resistance FecR'-BlaM (FecR107-BlaM) and a sensitive FecR-BlaM (FecR78-BlaM) (encoded on plasmids of the pDW26 series) were synthesized in E. coli 5K together with plasmid-encoded GroEL GroES (pMS2) or SecB (pDW102). Most transformants grown at 28°C displayed a twofold-higher resistance in the presence of overexpressed GroEL GroES and overexpressed SecB (Table 3). The same results were obtained with GroEL GroES at 37°C. Cells grown at 42°C exhibited a fourfold-reduced resistance compared to cells grown at 28 and 37°C, and this resistance was not increased by the chaperones. DnaK did not increase ampicillin resistance (data not shown).

Evidence against additional transmembrane segments in FecR. If FecR contains transmembrane segments in addition to the hydrophobic sequence between residues 85 and 100, BlaM could be secreted into the periplasm by FecR-BlaM proteins lacking residues 85 to 100. Residues 25 to 185 were deleted in the high-resistance proteins FecR230-BlaM, FecR248-BlaM, and FecR259-BlaM and in the low-resistance protein FecR281-BlaM (Table 1, pDW53 series). All transformants of E. coli 5K were completely sensitive to ampicillin, which suggests that there is no transmembrane region beyond residue 186 of FecR that secretes BlaM independent of residues 85 to 100. To confirm this conclusion, Gly-91 and Gly-93 were replaced by Asp in the high-resistance proteins FecR107-BlaM and FecR237-BlaM. E. coli 5K carrying the resulting plasmids pDW57.107 and pDW57.237 were fully sensitive to ampicillin. Sensitivity was not caused by the lack of the proteins since, as will be shown below, a FecR protein containing the double amino acid replacement displayed regulatory activities.

Regulatory activities of FecR-BlaM hybrid proteins. E. coli WA176 fecR does not grow on minimal agar with ferric citrate as the sole iron source (Fec plates) (39) since fecR contains a stop codon giving rise to a truncated FecR of only 18 N-terminal amino acids (21). All FecR'-BlaM proteins with at least 61 FecR residues restored growth of E. coli WA176 fecR on Fec plates (Table 2); this indicates that the fec transport genes were expressed when the FecR protein had a minimal size. To study the regulatory activity of the FecR'-BlaM proteins, some of the fecR-blaM fusion genes were transformed into E. coli AA93 fec, which carries a plasmid-encoded fecA-lacZ gene fusion. Of the genes required for the induction of fec transport gene transcription, fecA was carried on the fecA-lacZ plasmid, fecI was carried on the fecR-blaM plasmids, and tonB, exbB, and exbD were on the chromosome.

View this table: [in this window] [in a new window]   TABLE 4.   Expression of fecA-lacZ in E. coli AA93 fec

Evidence that FecR interacts with FecA. FecR248-BlaM and FecR257-BlaM conferred on E. coli 5K fec⁺(pDW26.248) and E. coli 5K(pDW26.257) resistance to 100 µg of ampicillin/ml, but they conferred on E. coli AA93 fec only resistance to 5 and 10 µg of ampicillin/ml, respectively. To examine whether this difference is caused by the lack of the FecA protein in strain AA93, E. coli AA93(pDW26.248) and E. coli AA93(pDW26.257) were transformed with pSV6fecA. Both transformants were resistant to 100 µg of ampicillin/ml. The strongly increased BlaM activity may indicate interaction between FecA and the FecR-BlaM proteins. Interaction between FecA and FecR would involve a region preceding residue 248 of FecR directly, or this region influences a FecR binding site. E. coli 5K synthesizing FecR259-BlaM was resistant to 50 µg of ampicillin/ml, and E. coli AA93 FecR259-BlaM was resistant to 5 µg/ml. Transformation with fecA increased the resistance of strain AA93 to only 10 µg/ml. The other FecR'-BlaM hybrids in E. coli AA93 were not affected by fecA.

	DISCUSSION

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The presence of only one hydrophobic sequence suggested that FecR consists of three topologically distinct regions extending from residues 1 to 84 in the cytoplasm, 85 to 100 within the cytoplasmic membrane, and 101 to 317 in the periplasm. Additional transmembrane regions were not obvious by inspection of the amino acid sequence and were not predicted by various computer-assisted membrane protein analysis programs (12, 26). The full ampicillin sensitivity of cells that synthesized BlaM fused to one of seven FecR sites from the N terminus up to residue 81 was consistent with this prediction. The unexpected finding was that BlaM fused to FecR residues beyond residue 107 did not confer a similar high resistance but, instead, conferred a pattern of high, low, high, low resistance. Interpretation of this finding has to take into account intracellular precipitation of the FecR'-BlaM proteins. All FecR'-BlaM proteins formed inclusion bodies, and an extensive analysis by differential centrifugation and SDS-PAGE of the amounts of protein present in the cell debris, the membrane fraction, and the soluble fraction showed that most of FecR'-BlaM was in the cell debris (inclusion bodies), regardless of whether larger or smaller amounts of hybrid proteins were synthesized. A decrease in the amount of the FecR'-BlaM proteins by using the weak natural ribosome binding site or through transcription by uninduced amounts of the T7 RNA polymerase did not prevent the formation of the inclusion bodies. Only the FecR'-BlaM proteins that conferred high-level resistance when strongly overexpressed conferred low-level resistance when they were weakly synthesized by cloning into a low-copy-number vector. Attempts to reduce the precipitation of FecR'-BlaM by overexpression of the chaperones GroEL GroES (11) and SecB (25) resulted in an increased periplasmic -lactamase activity of all FecR'-BlaM proteins tested. Presumably, by binding of FecR'-BlaM to the chaperones, kinetic competition between insertion into the cytoplasmic membrane and precipitation was shifted in favor of insertion. Moreover, proteolysis of FecR'-BlaM decreased periplasmic -lactamase activity since degP and ompT mutants carrying FecR'-BlaM proteins were resistant to ampicillin concentrations higher than that of the corresponding degP and ompT wild-type strains. Both the chaperones and the mutations in the proteases increased the -lactamase activity of the FecR'-BlaM proteins that conferred only resistance to 5 µg of ampicillin/mland therefore would tentatively be localized in the cytoplasmto levels which indicate a periplasmic location of BlaM. Ampicillin-sensitive cells that synthesized BlaM fused to FecR' fragments not larger than 81 N-terminal residues remained sensitive in the presence of the overexpressed chaperones and in the absence of the DegP and OmpT proteases. These results make it likely that cytoplasmic -lactamase did not confer the low-level ampicillin resistance.

Point mutations that replaced two glycine residues in the hydrophobic region (residues 85 to 100) of FecR'-BlaM with hydrophilic, charged aspartate residues converted ampicillin-resistant cells to ampicillin-sensitive cells, presumably by abolition of BlaM translocation into the periplasm. This result shows that there are no other FecR transmembrane segments that can translocate BlaM into the periplasm independent of the hydrophobic region. Taken together, these data are consistent with a topology model of FecR that proposes the N-terminal residues 1 to 84 in the cytoplasm, residues 85 to 100 in the cytoplasmic membrane, and residues 101 to 317 in the periplasm (Fig. 1B).

The transmembrane model of FecR agrees with the finding that cells that synthesize FecR'-BlaM proteins containing 61 or more FecR residues transcribe fecA-lacZ constitutively. This should occur only if the FecR N terminus is located in the cytoplasm, because the N-terminal FecR fragments can interact with the cytoplasmic FecI and convert FecI to an active sigma factor. BlaM fused to the FecR' fragments does not seem to interfere sterically with FecR' activity. Alternatively, BlaM could be proteolytically cleaved from a small proportion of FecR'-BlaM, below the detection limit of SDS-PAGE, and the free FecR' molecules would be active. The smallest FecR fragment that supports growth on ferric citrate contained 56 N-terminal residues (FecR56-LacZ). Ferric citrate-independent transcription induction by C-terminally truncated FecR' fragments, of which the smallest derivative contained 68 residues, has been shown previously (21). The 3'-deleted fecR genes were cloned on the same low-copy-number vector (pHSG576) as the fecR-blaM genes. The levels of constitutive fecA-lacZ transcription and translation caused by FecR' and FecR'-BlaM were very similar, which argues against the need of a proportion of FecR' from FecR'-BlaM to be released in order to exert activity. The largest FecR' studied contained 273 residues, displayed activation in the absence of ferric citrate, and did not respond to ferric citrate (21).

Evidence of an interaction of FecA with FecR was obtained with two FecR'-BlaM hybrids. FecR248-BlaM conferred to E. coli AA93 fec only 5% of the ampicillin resistance conferred to E. coli 5K, and FecR257-BlaM conferred only 10%. Transformation of E. coli AA93 with a fecA plasmid restored ampicillin resistance to 100%. The increase of -lactamase activity could be caused by stabilization of membrane-inserted FecR'-BlaM through binding to FecA or, less likely, by an increase in the amount of membrane-inserted FecR'-BlaM through cosynthesis with FecA.

The transmembrane topology of FecR makes FecR a suitable candidate for transduction of the signal, initiated by binding of ferric citrate to FecA, across the cytoplasmic membrane into the cytoplasm.