Site-specific Mutagenesis of hbp.
Knockout mutants of hbp were created by the use of the counterselectable vector pSG335 (15). The assembly of the suicide vectors used in this assay required a number of intermediate constructions. The structural hbp gene and the flanking regions of the gene were amplified by PCR using the plasmid pET-Hbp as template DNA. The primers used were the 110-reverse primer (see above), introducing a BamHI site and the pET-primer 5'-CCACGTACGTTCCTCT-3'. The obtained DNA fragment was cloned into the XbaI–HindII site of pBluescript. The recombinant plasmid was designated pBS-Hbp. The hbp gene in pBS-Hbp was disrupted by cloning a kanamycin resistance cassette into the EcoRV site of the gene, obtaining the plasmid pBS-Hbp::km^r. The disrupted hbp gene was isolated from pBS-Hbp::km^r by digesting the plasmid with the enzymes XbaI and MluI. As a consequence of the digestion with the enzyme MluI the disrupted hbp gene is also lacking the last 84 bp at the 3' end of the gene. The suicide vector pSG-Hbp4.8 was constructed by cloning the 4.8-kb XbaI–MluI DNA fragment into the counterselectable vector pSG335. The main characteristics of pSG335 are the presence of a sacB gene, which converts sucrose to a product that is lethal to E. coli, and the presence of a chloramphenicol resistance gene (15). Another suicide vector, pSG-Hbp2.2, was assembled by cloning a 2.2-kb XbaI–MluI DNA fragment into pSG335. This 2.2-kb DNA fragment, containing the km^r cassette flanked on both sides by 500 bp of the hbp gene, was obtained by PCR. The plasmid pBS-Hbp::km^r was used as template DNA. The primers used were the XbaI-forward primer 5'-CGATTTCTAGACAATGATGCCCCGGTC-3', introducing a XbaI site (boldface letters), and the MluI-reverse primer 5'-CGAAAACGCGTTGAAGACACTTTTATCTGC-3', introducing a MluI site (boldface letters). The suicide vectors pSG-Hbp2.2 and pSG-Hbp4.8 were used to transform the wild-type strain E. coli EB1 selecting for resistance to kanamycin. Single colonies were subcultured to allow the necessary recombination and plasmid curing events to occur. Then cells were plated on YT containing kanamycin and 3% sucrose, but lacking NaCl (15, 24). The plates were incubated at 30°C. Colonies grown on this selective medium were screened for their inability to synthesize Hbp by means of immunoblotting.

Subcellular Localization of Hbp.
Subcellular fractions of strain BL21(DE3)(pLysS, pET-Hbp) and the wild-type EB1 strain were prepared essentially as previously described (25, 26). Cells were collected by centrifugation, washed, and stored as frozen cells at –30°C. To obtain a total cell lysate, cells were lysed by freezing and thawing combined with a short ultrasonic treatment (27). Cell debris was removed from the cell lysate by centrifugation at 14,000 g for 10 min at 4°C. Subsequently, soluble proteins (cytoplasmic and periplasmic proteins) and membranes were separated by ultracentrifugation. The cytoplasmic membranes were separated from outer membranes by selective solubilization of cytoplasmic membranes using 0.5% sodium lauryl sarcosinate (Sarkosyl). For detection of Hbp in the different subcellular fractions, immunoblotting was carried out with a specific anti-Hbp antiserum.

Heme-binding Assays.
Heme–protein complexes in a polyacrylamide gel can be detected by chemiluminescence as described (28). The supernatant of a mid-logarithmic phase culture of EB1 was concentrated as described above. Hemin or human hemoglobin (Sigma), to a final concentration of 0.30 mM or 1.5 µM respectively, was added to 50 µl of concentrated culture supernatant. The concentration of Hbp in these mixtures was 2 µg. The samples in 50 mM Hepes, pH 7.0 were incubated at 37°C for 1 h. Subsequently, 25 µl of the samples were run on a 11% nondenaturing polyacrylamide gel. Potential heme-protein complexes in the gel were detected by chemiluminescence.

Heme affinity chromatography was used to investigate the binding specificity of Hbp for heme. Hbp produced by strain DH5(pHE12.6) was obtained from 1 liter of a mid-logarithmic phase culture. 50 ml of this culture supernatant was mixed with 100 µl of hemin agarose (Sigma Chemical Co., St. Louis, MO), as described (29). The mixtures were incubated at 4°C overnight. The gel beads were collected and washed six times with 0.5 M NaCl and 10 mM sodium phosphate, pH 7.0. The proteins still retained to the gelmatrix were eluted from the beads with SDS sample buffer as described (9). The eluted proteins were analyzed by SDS-PAGE and Coomassie R-250 staining.

Hemoglobin Protease Activity.
Denatured hemoglobin as substrate was used to detect an endopeptidase activity by the purified Hbp protein and culture supernatants of the different E. coli strains (30). The determination of the catalytic type of the peptidase was performed using 3,4-dichloroisocoumarin (3,4-DCI), a specific serine peptidase inhibitor. A new assay was developed to determine the specificity of Hbp for hemoglobin. Purified Hbp (0.5 µg / 50 µl) was mixed with 0.1 µg native hemoglobin in 100 mM phosphate buffer, pH 6.0. The mixture, Hbp and hemoglobin alone were incubated at 37°C for 4 h. Subsequently, 25 µl samples were run on an 8% nondenaturing polyacrylamide gel. Hemoglobin in the gel was detected by incubating the gel first in a chemiluminescence substrate solution and then sprinkling the gel with a H₂O₂ solution to initiate heme-associated peroxidase activity. The gel was immediately exposed to a X-Omat AR film (Eastman Kodak Company, Rochester, NY) to visualize hemoglobin. Subsequently, hemoglobin in this native gel was also visualized by Coomassie R-250.

Antibodies.
The polyclonal anti-Hbp antiserum was raised in rabbit against a peptide which consists of 15 amino acid residues of Hbp located in the NH₂-terminal part of the protein (NELGYQLFRDFAENK). Cross-reactivity was verified by immunoblotting in the presence or absence of the peptide against which the antiserum was raised.

Conjugational Transfer of the EB1 pColV Plasmid.
Strain AN299-23 was first transformed with pACyC184. The resulting strain AN299-23(pACyC184) was used as recipient strain. The EB1 donor cells and recipient cells mixed in a ratio of 8:2 were allowed to conjugate at 37°C in a static liquid culture for 2 h. Thereafter, cells were plated on MA-agar plates containing chloramphenicol resulting in the loss of the EB1 donor cells. The residual colonies were tested on their capacity to produce colicin V. Colicin V activity of possible transconjugants was determined by using a soft agar overlay technique as described previously (31). Colicin-producing colonies gave a clear killing zone surrounding the cell colony. E. coli AN299-23(pACYC184) was used as a colicin V susceptible indicator strain.

Hemagglutination Assay.
Hemagglutination activity of EB1 cells was assayed by their ability to agglutinate rabbit, chicken or human erythrocytes on glass slides as described elsewhere (32). Cells from liquid cultures as well from YT-agar plates both grown at 26 or 37°C were tested in this assay. In addition, purified Hbp (1 µg), purified outer membrane proteins (50 µg) obtained from cells grown at 26 or 37°C, and concentrated culture supernatants were also tested on their ability to agglutinate the different erythrocytes. The outer membrane vesicles were prepared as described elsewhere (33).

Computer Analysis.
For analysis and alignment of DNA sequences the following programs and packages have been used: Gene Works 2.3, DNA Strider 1.0, Sequencher 2.1 and the GCG-package. Putative gene products were searched for similarity to sequences reported previously in nonredundant protein data banks (NCBI BLASTX Search).

	Results

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Detection of an Extracellular Heme-binding Protein.
E. coli can use heme and hemoglobin as iron sources (10). In Serratia marcescens (9), the extracellular protein HasA is involved in the uptake of heme from hemoglobin, whilst in Hemophilus influenzae the extracellular protein HxuA recognizes heme bound to hemopexin (8). E. coli may also secrete proteins that are able to scavenge heme from the environment. To test this hypothesis, supernatant of a culture in the mid-exponential phase of growth from the human pathogenic E. coli strain EB1 was examined for the presence of extracellular heme-binding proteins. EB1 was cultured in a chemically defined medium to avoid contamination of the extracellular proteins by constituents of the culture medium. The culture supernatant was concentrated by means of ultrafiltration and then analyzed by SDS-PAGE. At least four proteins with estimated molecular masses of 110, 40, 38, and 37 kD were present (Fig. 1 B, lane 2). These proteins were assayed for heme-binding properties. The proteins were incubated with hemin and subsequently subjected to nondenaturing PAGE. Heme–protein complexes in the gel were visualized by chemiluminescence. One prominent heme-associated protein band was detected. That band was cut out from the gel and reanalyzed by means of SDS-PAGE revealing its relative molecular mass of 110 kD (data not shown). This heme-binding protein also proved to possess proteolytic activity against hemoglobin and it was designated Hbp for hemoglobin protease (see below).

DNA Sequence of the HindIII–EcoRI Fragment of 12.6 kb.
Analysis of Hbp revealed the NH₂-terminal amino acid sequence GTVNNELGYQLFRD. This amino acid sequence was found to be 100% identical to that of the deduced amino acid sequence of Tsh (temperature sensitive hemagglutination; reference 34). The Tsh protein has a deduced molecular weight of 118,000 daltons and was found to be significantly homologous to IgA1 proteases, a family of proteins that are secreted by some pathogenic bacteria. The resemblance in characteristics between Tsh detected in the avian pathogenic E. coli strain x7122 and Hbp isolated from a human pathogen suggests that the proteins are identical. A DNA probe was prepared based on the nucleotide sequence of tsh and a 12.6-kb HindIII–EcoRI DNA fragment was isolated by means of Southern blot experiments. The nucleotide sequence of this fragment was determined and analyzed for the location of open reading frames (ORFs; Fig. 2). In total, 12 ORFs were detected (Table 1).

View larger version (6K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Organization of ORFs of the 12,606-bp contig. The scale is given in kb. The positions of the unique HindIII, BamHI, and EcoRI sites and two EcoRV sites are indicated. ORFs are indicated by thick black arrows and the arrowheads show the direction of transcription/ translation. The names of the genes are indicated above the arrows; bold characters indicate genes of which the nucleotide sequence has been published before, plain characters indicate newly discovered ORFs. Possible terminator structures and promoter regions found by computer analysis are indicated by the symbol (o) or a P, respectively. The position where the DNA-probe hybridized to the 12.6-kb fragment in Southern blot experiments is indicated by a straight line. The sequence data of this contig have been deposited in the EMBL Nucleotide Sequence Database under accession number AJ223631.

View larger version (12K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Analysis of the secretion of Hbp by the wild-type strain EB1, DH5 carrying pHE12.6 or pBR322 and strain LG1522 carrying pColV-K30. Supernatants of mid logarithmic phase cultures grown in MA-medium were collected. The proteins in the supernatants were TCA precipitated, separated by SDS-PAGE and immunodetected with anti-Hbp antiserum. The amounts loaded are expressed as OD660 equivalents. Lanes 1 and 4, 1.0 OD660 units; lanes 2 and 3, 2.0 OD660 units.

View larger version (28K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Screening of plasmid DNA on the presence of hbp by PCR and Southern blot hybridization experiments. The pColV plasmids of the wild-type strain EB1, the K-12 strain LG1522 (pColV-K30) and the transconjugant TC003 were isolated, purified on an agarose gel and used as templates. Strain TC003 obtained the pColV plasmid from EB1 by conjugational transfer. (A) Amplification of hbp by PCR. Primers used in these experiments were the 110-forward and 110-reverse (see Materials and Methods). Lane 1, 1 kb DNA ladder; lane 2, wild-type strain EB1; lane 3, K-12 strain LG1522 (pColV-K30); lane 4, recipient strain AN299-23(pACyC184); and lane 5, transconjugant TC003. (B) Southern blot hybridization with a 1,022-bp long DNA fragment from hbp as probe. Arrow points to 4,130-bp PCR product. Plasmid DNA of both strains was digested with various restriction enzyme combinations and hybridized with the digoxygenin labeled 1,022-bp DNA fragment as probe. Single lanes represent plasmid digests with HindIII, EcoRI, SacI, or SalI only (lanes 1–4, respectively) or EcoRI in addition to HindIII (lane 5), SalI (lane 6), SacI (lane 7).

Heme-binding Properties of Hbp.
The heme-binding properties of Hbp were tested by incubating concentrated supernatant proteins of strain EB1 with hemoglobin or hemin, which is the oxidized form of heme. The mixtures were subjected to nondenaturing PAGE and heme-associated protein bands were detected by chemiluminescence. As shown in Fig. 5 B, Hbp was visualized by this assay indicating that this protein can bind heme (lane 2). Furthermore, the protein was able to acquire heme from hemoglobin (Fig. 5 B, lane 1). This implies that Hbp had to interact with hemoglobin in such a way that heme will be released from hemoglobin. A mechanism for the release of heme could be a proteolytic degradation of hemoglobin by Hbp.

View larger version (39K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Heme-binding properties of Hbp. (A) Isolation of Hbp by hemin affinity chromatography and binding specificity as measured by competition experiments. 50 ml of culture supernatant of strain DH5- (pHE12.6) was incubated with hemin-agarose, as described in Materials and Methods. Lane 1, marker proteins (in kD); lane 2, Hbp not retained on hemin-agarose; lane 3, Hbp retained on hemin-agarose alone; lanes 4–6, Hbp retained in the presence of 15, 3 and 1.5 µM hemin (Hm); lane 7, Hbp retained in the presence of 15 µM protoporphyrin IX (Pp); lanes 8–10, Hbp retained in the presence of 3.0, 1.5, and 0.75 µM hemoglobin. (B) Detection of heme-protein complexes in a nondenaturing polyacrylamide gel system. Concentrated supernatant proteins of strain EB1 were incubated with hemin or hemoglobin for 1 h. Samples of these mixtures were run on a 11% polyacrylamide gel. Heme-associated protein bands in the gel were visualized by means of chemiluminescence as described in Materials and Methods. Lane 1, supernatant proteins incubated with hemoglobin; lane 2, supernatant proteins incubated with hemin. The positions of heme-saturated Hbp and hemoglobin in the gel are indicated.

Hemoglobin Protease Activity.
Hbp belongs to a group of related proteins named the Tsh family (43). All members of this family contain a consensus motif for the catalytic site of serine proteases, suggesting that all these proteins are proteolytic enzymes. Therefore, the recruitment of heme from hemoglobin could be the result of a proteolytic breakdown of hemoglobin by Hbp. A general protease assay with denatured hemoglobin as substrate was used to detect an endopeptidase activity by Hbp. As shown in Table 3, a proteolytic activity of Hbp against denatured hemoglobin was detected. To prove that this activity was caused by a serine protease, the specific inhibitor 3,4-DCI, was used. Indeed, preincubation of Hbp with this irreversible inhibitor completely abolished the observed protease activities (Table 3). A knockout mutant of Hbp (mutant mHbp18) was obtained by site-directed mutagenesis experiments with the suicide vector pSG-Hbp2.2 (see below). The culture supernatant of mutant mHbp18 showed almost no proteolytic activity (Table 3). The observed background activity by this strain is probably due to leakage of intracellular enzymes into the growth medium. The insertion of the kanamycin cassette into hbp in mHbp18 could also result in inactivation of the orf2 downstream of hbp by polarity, since both genes are transcribed in the same orientation (as shown in Fig. 2). Although a putative terminator structure was found between hbp and orf2, the possibility exists that orf2 contributes to the proteolytic activity of Hbp. To exclude this possibility strain DH5(pBRHbp) was used in the protease assay. This strain contains only the structural hbp gene under control of its own promoter. Hbp is secreted by this strain (data not shown). A proteolytic activity by DH5(pBRHbp) comparable to that of EB1 was detected (Table 3). This indicates that orf 2 is not responsible for the observed proteolytic activity. Taken together, these results indicate that Hbp is a serine protease.

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Hemoglobin protease activity by Hbp at different pH. Hemoglobin was incubated with purified Hbp, as described in Materials and Methods. Samples were analyzed by nondenaturing PAGE and PhotoImaging. (A) Hemoglobin visualized by means of chemiluminescence. Lane 1, hemoglobin not incubated with Hbp, pH 6.0; lanes 2–5, hemoglobin incubated with Hbp at pH 8.0, 7.0, 6.5, and 6.0, respectively. A quantitation of the PhotoImage data is presented at the right hand of the image. The initial amount of hemoglobin present in the reaction mixture was set at 100%. (B) Hemoglobin visualized by means of Coomassie R-250 staining. Lanes 1–5, same samples as in A.

View larger version (52K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Subcellular localization of Hbp. Cells of the wild-type strain EB1 (A) and IPTG-induced cells of strain BL21(pET-Hbp) (B) were grown in LB medium at 26°C and 37°C. Outer membrane (OM), inner membrane (IM) and crude membrane (M) fractions were derived from 1.3 OD660 units. Soluble (S), membrane and soluble (M+S), cellular debris (D), and total lysate (T) fractions were derived from 0.33 OD660 units. Culture supernatant (Sup) fractions were derived from 3.0 OD660 units. The fractions were analyzed by immunoblotting with the anti-Hbp antiserum. The secretory intermediates of Hbp and molecular mass markers (kD) are indicated at the right and left side of the panels, respectively.

Two independent hbp-knockout mutants were made by site-directed mutagenesis (Fig. 8). Mutant mHbp18 was the result of a double crossover event (Fig. 8 A). This mutant lacks the expression of Hbp and loosed its proteolytic activity against hemoglobin (as shown in Table 3). The expected truncated Hbp of 52 kD was only detectable in total cell lysates of mHbp18 at OD₆₆₀ units of >2.0 in these immunoblot experiments (data not shown). The other mutant (mHbp1) was mutated in the COOH-terminal part of Hbp, due to a single crossover event (Fig. 8 B). The COOH-terminal domain of IgA protease precursors provides the essential transport function for the proteases across the outer membrane. Mutations in this so-called β-domain blocked the translocation of the passenger proteins across the membrane (44). Mutant mHbp1, lacks the last 84 bp at the 3'-end of the gene and expresses a truncated precursor protein of 144.783 kD (Fig. 8 B, lane 2). Due to this mutation secretion of Hbp in the environment was inhibited (Fig. 8 B, lane 3). These results strongly suggested that Hbp is an autotransporter, but the efficiency of the translocation of this protein over the cell envelope depends on the host that is used.

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Figure 8 Analysis of the expression of Hbp by Hbp-mutants. The mutants mHbp18 and mHbp1 were obtained by site-directed mutagenesis experiments with the suicide vectors pSG-Hbp2.2 and pSG-Hbp4.8, respectively. See Materials and Methods for a detailed description of the construction of these suicide vectors. Culture supernatant fractions and total lysate fractions were derived from 4.0 and 0.5 OD660 units, respectively. The fractions were analyzed by immunoblotting with the anti-Hbp antiserum. (A) Expression of Hbp by mHbp18. Lanes 1 and 4, lysate and supernatant of the wild-type strain EB1; lanes 2 and 3, lysate and supernatant of mHbp18. (B) Expression of Hbp by mHbp1. Lanes 1 and 4, same samples as in A; lanes 2 and 3, lysate and supernatant of mHbp1. The secretory intermediates of Hbp and molecular mass markers (kD) are indicated at the right and left side of the panels, respectively. A schematic representation of the recombination events of the suicide vectors is depicted at the right side of this figure. Mutant mHbp18 was the result of a double crossover and mutant mHbp1 of a single crossover event. Symbols in this diagram are: M, MluI restriction site; P, promoter; km, kanamycin cassette.

	Discussion

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Recently, an exported protease (PssA) from a Shiga toxin-producing E. coli has been characterized (43). Sequence comparison showed that PssA is related to the family of autotransporter proteins, especially to SepA of S. flexneri (46), Tsh of E. coli (34) and EspC from EPEC (47). These proteins belong to a family of proteins that is only distantly related to the IgA1 proteases of Neisseria and Haemophilus (43). It was proposed to designate this group of related proteins the Tsh family. The protein PssA showed a moderate serine protease activity in a casein-based assay. The conservation of the putative catalytic center of serine proteases in all members of the Tsh family suggests similar proteolytic activities for these proteins. However, the natural substrate for these proteins remained unclear because casein is unlikely to be the natural substrate. We found that Hbp has a high affinity to hemoglobin and acquires its heme from hemoglobin by degradation of this protein. It is tempting to speculate that hemoglobin is also the natural substrate for the other members of the Tsh family. An activity of 300 pmol/h/mg of Hbp was found and the enzyme showed a pH optimum of 6.0–6.5, which is consistent with the physiological pH during an infection, since at the site of infection the pH will fall to 6.0 in response to inflammation.

This study shows that elution of Hbp from hemin-agarose is possible with hemin or hemoglobin. Otherwise, very rigid conditions, like boiling the beads in denaturing buffers or high salt buffers, are needed to elute Hbp from hemin-agarose, indicating high affinity binding of Hbp to hemin and hemoglobin. Hbp shares these characteristics with HasA of S. marcescens, a heme-binding shuttle protein responsible for the uptake of heme from hemoglobin by an unknown mechanism (9). We demonstrated that Hbp can obtain heme from hemoglobin by a proteolytic interaction. A remarkable observation in the heme affinity chromatography experiments was that low concentrations of free heme molecules favor the binding of Hbp to hemin-agarose. Presumably, heme induced a conformational change of Hbp in such a way that the protein gets a higher affinity to hemin-agarose. This suggests the presence of two heme-binding sites in Hbp, one with a moderate and the other with a high affinity for heme.

Hbp has to be shuttled back to the cell surface if it is involved in a heme-acquisition system. Hence, E. coli must possess a specific outer membrane receptor that will recognize the heme-saturated Hbp protein. Results of preliminary studies suggested that E. coli indeed has a receptor that is able to discriminate between the apo- and holo-form of Hbp (unpublished results). Recently, a putative 69-kD heme receptor (ChuA) in E. coli has been described (48). Utilization of heme and hemoglobin by E. coli was ChuA dependent. It would be of interest to find out whether this receptor is also involved in the Hbp-mediated heme uptake. Work is in progress to further characterize the receptor for Hbp in E. coli EB1.

This study also demonstrates that hbp is located on pColV-K30. The pColV-K30 plasmid (144 Kbp) belongs to a heterogeneous group of virulence plasmids (42). The plasmids encode the production of a colicin known as colicin V and are commonly found in invasive strains of E. coli from human and domestic animals (18). ColV plasmids encode several virulence-related properties in addition to colicin V (42). One of the properties that clearly contributes to the virulence of pColV-K30 is the aerobactin iron assimilation system. This shuttle-mediated iron uptake system has been extensively reviewed (5, 11, 42). It seems that pColV-K30 encodes two shuttle-mediated iron uptake systems; one for the acquisition of iron and another for heme. It would be of great interest to find out if these two iron uptake systems are in some way related. In pColV-K30 hbp is located on a HindII–BamHI DNA fragment of 6,453 bp. We examined HindIII–BamHI restriction enzyme profiles of different pColV plasmids (42) for the presence of similar sized HindII–BamHI DNA fragments. The profiles reveal DNA fragments of 6,500 bp in pColV-292, pColV-F70 and pColV-F54, suggesting that hbp is present in these plasmids. We propose that Hbp contributes to the virulence properties of pColV plasmids.

We show that Hbp is synthesized as a polyprotein precursor which is processed following export to the cell surface. The kinetics of protein translocation across the outer membrane and subsequent cleavage are very rapid, whilst the transfer through the cytoplasmic membrane appears to be a slower process. Hbp is also efficiently secreted by a K12-strain in which the structural hbp gene was introduced. Furthermore, secretion of Hbp is inhibited by a mutation in the β-domain of its precursor. Comparable results were found for the IgA protease of N. gonorrhoeae (44, 45). These results strongly suggest that Hbp is an autotransporter protein. Autotransporters are large polyproteins that are organized in functional domains and are eventually processed at the cell surface. The necessary translocation functions are carried by the polyprotein precursor itself. The β-domain of the precursor is responsible for the transport of the protein across the outer membrane (44). However, in strain BL21(pET-Hbp) we found that the secretion of the protein was less efficient. Accumulation of the 148-kD precursor in the cytoplasmic membrane and traces of the mature protein were detected in the periplasmic and cytoplasmic membrane fractions of this strain. Accumulation of the 148-kD precursor in the membrane might cause changes in the conformation of the precursor in such a way that the proteolytic site of the β-domain becomes accessible to periplasmic proteases. It seems that the efficiency of transport across this membrane and or cleavage of the signal peptide is dependent on the host type used. Thus, it cannot be excluded that other, yet unknown factors are involved in this pathway of secretion.

It has been shown that tsh is responsible for a mannose-resistant hemagglutination activity in E. coli (34). This activity was best expressed at 26°C. However, it remains unclear which role an extracellular Tsh protein might play in hemagglutination, since microbial adhesins are normally membrane-associated. E. coli strain EB1 was also tested for its ability to agglutinate erythrocytes from human and different animals. The EB1 cells were cultured under different conditions and subsequently tested as described in Materials and Methods. Purified Hbp, outer membrane proteins and concentrated culture supernatants were also tested for hemagglutination activity. None of these experiments yielded a positive reaction (data not shown). The reason for the apparent difference between Hbp and Tsh in hemagglutination activity remains unclear. It seems that only under very specific conditions hemagglutination activity by Tsh can be detected.

Recently, the complete nucleotide sequence was determined of the plasmid from Rhizobium sp. NGR234 that endows the bacterium with the ability to associate symbiotically with leguminous plants (40). The results of this study showed that pNGR234a has functioned as a transposon trap. Potential genes detected on this plasmid appear to be all involved in the symbiosis between Rhizobium and legumes. No genes essential for transcription, translation or primary metabolism were found (40). Presumably, colicin V virulence plasmids also function as ‘transposon traps' and consequently these plasmids may only contain virulence genes. Therefore, it will be interesting to clarify the functions of the orfs located on the 12.6-kb DNA fragment.

In conclusion, the results of this study demonstrate that Hbp is a heme-binding protein that obtains its heme from hemoglobin by degradation of this protein. The protein is likely to be the shuttle protein of a hemophore-dependent heme acquisition system in this human pathogenic E. coli strain. Hbp is a member of the Tsh family and its structural gene is located on a ColV virulence plasmid. All these characteristics strongly suggest that Hbp is an important virulence factor that may play a significant role in the pathogenesis of E. coli infections. However, the role of this protease as a virulence factor remains to be tested in vivo. Further studies are needed to prove if the other IgA1 protease-like autotransporters are also heme-binding proteins with a proteolytic activity specific for hemoglobin. We are currently investigating the nature of binding of Hbp at the cell surface of E. coli and the proteolytic properties of the protein in more detail.