Hemin binding,functional expression,and complementation analysis of Pap 31 from Bartonella henselae

Growth of Bartonella henselae is strongly heme dependent, and B. henselae is unable to synthesize heme itself. At least five outer membrane-associated proteins from B. henselae bind hemin, including the 31-kDa protein designated Pap31. The gene of this protein was heterologously expressed in Escherichia coli M15(pREP4) and detected with monoclonal antibodies in the outer membrane fraction. Complementation of the hemA-deficient mutant E. coli K-12 EB53 (aroB tsx malT hemA) with pap31 demonstrated that this protein is involved in heme acquisition and may be an important virulence factor in the pathogenesis of B. henselae.     

Use of Heme-Protein Complexes by the Yersinia enterocolitica HemR Receptor: Histidine Residues Are Essential for Receptor Function

The abilities of two bacterial active heme transporters, HmbR of Neisseria meningitidis and HemR of Yersinia enterocolitica, to use different heme sources were compared. While HmbR-expressing cells used only hemoglobin (Hb) and heme, HemR-expressing bacteria were able to grow on Hb, heme, myoglobin, hemopexin, catalase, human and bovine serum albumin-heme, and haptoglobin-hemoglobin complexes as sources of iron. Expression of functional HemR allowed Escherichia coli cells to respond to heme-containing peptides, microperoxidases MP-8, MP-9, and MP-11, suggesting the ability of HemR to transport heme covalently linked to other molecules. Comparison of HemR with other heme receptors identified several highly conserved histidine residues as well as two conserved amino acid motifs, the FRAP and NPNL boxes. A site-directed mutagenesis approach was used to investigate the roles of His128, His192, His352, and His461 residues in HemR function. The HemR receptor with histidine changed to lysine at position 128 (HemR(H128K)), HemR(H461L), HemR(H461A), and HemR(H128A,H461A) mutant receptors were unable to use Hb, human serum albumin-heme, and myoglobin as sources of porphyrin and iron. Utilization of free heme was also severely affected, with some residual heme uptake in cells expressing HemR(H128K), HemR(H461A), and HemR(H461L). Conversely, the HemR(H192T), HemR(H352A), HemR(H352K), and HemR(H192T,H352K) mutant receptors were fully functional. All mutant HemR proteins were expressed in the outer membrane at levels similar to that of the wild-type HemR receptor. Nonfunctional HemRs were able to bind heme- and Hb-agarose. A hypothetical model of the HemR function in which two conserved histidine residues, His128 and His461, participate in the transport of heme through the receptor pore is postulated.     

Glutamyl-tRNA reductase from Escherichia coli and Synechocystis 6803. Gene structure and expression.

In the cyanobacterium Synechocystis sp. PCC 6803 and in the enterobacterium Escherichia coli delta-amino-levulinic acid (ALA) is formed from glutamyl-tRNA by the sequential action of two enzymes, glutamyl-tRNA reductase (GluTR) and glutamate-1-semialdehyde aminotransferase. E. coli has two GluTR proteins with sizes of 45 kDa (GluTR45) and 85 kDa (GluTR85) (Jahn, D., Michelsen, U., and S?ll, D. (1991) J. Biol. Chem. 266, 2542-2548). The hemA gene, isolated from E. coli and several other eubacteria, has been proposed to encode a structural component of GluTR. Because of the inability to overexpress this gene in E. coli, we demonstrate directly GluTR function for the E. coli hemA gene product by its expression and functional analysis in yeast, which does not form ALA from Glu-tRNA. Gel filtration experiments demonstrated definitively that the yeast-expressed HemA protein corresponded to GluTR45. Furthermore, analysis of GluTR activity in an E. coli strain with a disrupted hemA gene displayed GluTR85, but not GluTR45 activity. The hemA gene from Synechocystis 6803 was cloned by functional complementation in E. coli. DNA sequence analysis revealed an open reading frame capable of encoding a 427-amino acid polypeptide (molecular mass of 47,525 Da). The Synechocystis 6803 amino acid sequence shows significant similarity upon alignment with HemA sequences from E. coli, Bacillus subtilis, Salmonella typhimurium, and Chlorobium vibrioforme but does not contain the amino acid sequence derived from the N terminus of the previously purified GluTR protein (Rieble, S., and Beale, S. I. (1991) J. Biol. Chem. 266, 9740-9745). These experiments are the first direct demonstration of GluTR activity of the HemA protein and provide further evidence for two pathways of ALA formation in prokaryotes.     

Cloning, sequencing, and characterization of the gene encoding FrpB, a major iron-regulated, outer membrane protein of Neisseria gonorrhoeae.

FrpB (for Fe-regulated protein B) is a 76-kDa outer membrane protein that is part of the iron regulon of Neisseria gonorrhoeae and Neisseria meningitidis. The frpB gene from gonococcal strain FA19 was cloned and sequenced. FrpB was homologous to several TonB-dependent outer membrane receptors of Escherichia coli as well as HemR of Yersinia enterocolitica and CopB of Moraxella catarrhalis. An omga insertion into the frpB coding sequence caused a 60% reduction in 55Fe uptake from heme, but careful analysis suggested that this effect was nonspecific. While FrpB was related to the family of TonB-dependent proteins, a function in iron uptake could not be documented.     

Characterization of heme uptake cluster genes in the fish pathogen Vibrio anguillarum

Vibrio anguillarum can utilize hemin and hemoglobin as sole iron sources. In previous work we identified HuvA, the V. anguillarum outer membrane heme receptor by complementation of a heme utilization mutant with a cosmid clone (pML1) isolated from a genomic library of V. anguillarum. In the present study, we describe a gene cluster contained in cosmid pML1, coding for nine potential heme uptake and utilization proteins: HuvA, the heme receptor; HuvZ and HuvX; TonB, ExbB, and ExbD; HuvB, the putative periplasmic binding protein; HuvC, the putative inner membrane permease; and HuvD, the putative ABC transporter ATPase. A V. anguillarum strain with an in-frame chromosomal deletion of the nine-gene cluster was impaired for growth with heme or hemoglobin as the sole iron source. Single-gene in-frame deletions were constructed, demonstrating that each of the huvAZBCD genes are essential for utilization of heme as an iron source in V. anguillarum, whereas huvX is not. When expressed in Escherichia coli hemA (strain EB53), a plasmid carrying the gene for the heme receptor, HuvA, was sufficient to allow the use of heme as the porphyrin source. For utilization of heme as an iron source in E. coli ent (strain 101ESD), the tonB exbBD and huvBCD genes were required in addition to huvA. The V. anguillarum heme uptake cluster shows some differences in gene arrangement when compared to homologous clusters described for other Vibrio species.     

Transport of haemin across the cytoplasmic membrane through a haemin-specific periplasmic binding-protein-dependent transport system in Yersinia enterocolitica

The Yersinia enterocolitica O:8 periplasmic binding-protein-dependent transport (PBT) system for haemin was cloned and characterized. It consisted of four proteins: the periplasmic haemin-binding protein HemT, the haemin permease protein HemU, the ATP-binding hydrophilic protein HemV and the putative haemin-degrading protein HemS. Y. enterocolitica strains mutated in hemU or hemV genes were unable to use haemin as an iron source whereas those mutated in the hemT gene were able to use haemin as an iron source. As Escherichia coli strains expressing only the haemin outer membrane receptor protein HemR from Y. enterocolitica were capable of using haemin as an iron source the existence of an E. coli K-12 haemin-specific PBT system is postulated. The first gene in the Y. enterocolitica haemin-specific PBT system encoded a protein, HemS, which is probably involved in the degradation of haemin in the cytoplasm. The presence of the hemS gene was necessary to prevent haemin toxicity in E. coli strains that accumulate large amounts of haemin in the cytoplasm. We propose a model of haemin utilization in Y. enterocolitica in which HemT, HemU and HemV proteins transport haemin into the cytoplasm where it is degraded by HemS thereby liberating the iron.     

Genetics and regulation of heme iron transport in Shigella dysenteriae and detection of an analogous system in Escherichia coli O157:H7.

Shigella species can use heme as the sole source of iron. In this work, the heme utilization locus of Shigella dysenteriae was cloned and characterized. A cosmid bank of S. dysenteriae serotype 1 DNA was constructed in an Escherichia coli siderophore synthesis mutant incapable of heme transport. A recombinant clone, pSHU12, carrying the heme utilization system of S. dysenteriae was isolated by screening on iron-poor medium supplemented with hemin. Transposon insertional mutagenesis and subcloning identified the region of DNA in pSHU12 responsible for the phenotype of heme utilization. Minicell analysis indicated that a 70-kDa protein encoded by this region was sufficient to allow heme utilization in E. coli. Synthesis of this protein, designated Shu (Shigella heme uptake), was induced by iron limitation. The 70-kDa protein is located in the outer membrane and binds heme, suggesting it is the S. dysenteriae heme receptor. Heme iron uptake was found to be TonB dependent in E. coli. Transformation of an E. coli hemA mutant with the heme utilization subclone, pSHU262, showed that heme could serve as a source of porphyrin as well as iron, indicating that the entire heme molecule is transported into the bacterial cell. DNA sequences homologous to shu were detected in strains of S. dysenteriae serotype 1 and E. coli O157:H7.     

Cloning and characterisation of the serC and aroA genes of Yersinia enterocolitica, and construction of an aroA mutant

A gene library of Yersinia enterocolitica 8081 was constructed in the cosmid vector pHC79. Recombinants containing the aroA gene, encoding 5-enolpyruvylshikimate 3-phosphate synthase, were identified by complementation of the aroA mutation in Escherichia coli K-12 strain AB2829. All six recombinant plasmids which complemented aroA also complemented the serC mutation in E. coli K-12 strain KL282. Tn5 mutagenesis suggested serC encoding 3-phosphoserine aminotransferase was the proximal gene in an operon with aroA. The nucleotide sequence of a 3-kb HindII-EcoRV fragment encoding the two genes was determined. The serC and aroA open reading frames contain 362 and 428 codons, respectively, and the deduced amino acid sequences share 78% and 81% homology, respectively, with the corresponding E. coli genes. Sequence inspection revealed no obvious terminators or promoters in the intergenic region. The cloned Y. enterocolitica aroA gene was inactivated in vitro and reintroduced into the parental Y. enterocolitica 8081 strain using the suicide vector pJM703.1. Stable aroA insertion mutants of Y. enterocolitica were isolated.     

Cloning and characterization of the hemA region of the Bacillus subtilis chromosome.

A 3.8-kilobase DNA fragment from Bacillus subtilis containing the hemA gene has been cloned and sequenced. Four open reading frames were identified. The first is hemA, encoding a protein of 50.8 kilodaltons. The primary defect of a B. subtilis 5-aminolevulinic acid-requiring mutant was identified as a cysteine-to-tyrosine substitution in the HemA protein. The predicted amino acid sequence of the B. subtilis HemA protein showed 34% identity with the Escherichia coli HemA protein, which is known to code for the NAD(P)H:glutamyl-tRNA reductase of the C5 pathway for 5-aminolevulinic acid synthesis. The B. subtilis HemA protein also complements the defect of an E. coli hemA mutant. The second open reading frame in the cloned fragment, called ORF2, codes for a protein of about 30 kilodaltons with unknown function. It is not the proposed hemB gene product porphobilinogen synthase. The third open reading frame is hemC, coding for porphobilinogen deaminase. The fourth open reading frame extends past the sequenced fragment and may be identical to hemD, coding for uroporphyrinogen III cosynthase. Analysis of deletion mutants of the hemA region suggests that (at least) hemA, ORF2, and hemC may be part of an operon.     

Heme degrading protein HemS is involved in oxidative stress response of Bartonella henselae

Bartonellae are hemotropic bacteria, agents of emerging zoonoses. These bacteria are heme auxotroph Alphaproteobacteria which must import heme for supporting their growth, as they cannot synthesize it. Therefore, Bartonella genome encodes for a complete heme uptake system allowing the transportation of this compound across the outer membrane, the periplasm and the inner membranes. Heme has been proposed to be used as an iron source for Bartonella since these bacteria do not synthesize a complete system required for iron Fe3? uptake. Similarly to other bacteria which use heme as an iron source, Bartonellae must transport this compound into the cytoplasm and degrade it to allow the release of iron from the tetrapyrrole ring. For Bartonella, the gene cluster devoted to the synthesis of the complete heme uptake system also contains a gene encoding for a polypeptide that shares homologies with heme trafficking or degrading enzymes. Using complementation of an E. coli mutant strain impaired in heme degradation, we demonstrated that HemS from Bartonella henselae expressed in E. coli allows the release of iron from heme. Purified HemS from B. henselae binds heme and can degrade it in the presence of a suitable electron donor, ascorbate or NADPH-cytochrome P450 reductase. Knocking down the expression of HemS in B. henselae reduces its ability to face H?O? induced oxidative stress.     

Crystal structure of AGR_C_4470p from Agrobacterium tumefaciens

We report here the crystal structure at 2.0 A resolution of the AGR_C_4470p protein from the Gram-negative bacterium Agrobacterium tumefaciens. The protein is a tightly associated dimer, each subunit of which bears strong structural homology with the two domains of the heme utilization protein ChuS from Escherichia coli and HemS from Yersinia enterocolitica. Remarkably, the organization of the AGR_C_4470p dimer is the same as that of the two domains in ChuS and HemS, providing structural evidence that these two proteins evolved by gene duplication. However, the binding site for heme, while conserved in HemS and ChuS, is not conserved in AGR_C_4470p, suggesting that it probably has a different function. This is supported by the presence of two homologs of AGR_C_4470p in E. coli, in addition to the ChuS protein.     

Characterization of the Plesiomonas shigelloides genes encoding the heme iron utilization system

Plesiomonas shigelloides is a gram-negative pathogen which can utilize heme as an iron source. In previous work, P. shigelloides genes which permitted heme iron utilization in a laboratory strain of Escherichia coli were isolated. In the present study, the cloned P. shigelloides sequences were found to encode ten potential heme utilization proteins: HugA, the putative heme receptor; TonB and ExbBD; HugB, the putative periplasmic binding protein; HugCD, the putative inner membrane permease; and the proteins HugW, HugX, and HugZ. Three of the genes, hugA, hugZ, and tonB, contain a Fur box in their putative promoters, indicating that the genes may be iron regulated. When the P. shigelloides genes were tested in E. coli K-12 or in a heme iron utilization mutant of P. shigelloides, hugA, the TonB system genes, and hugW, hugX, or hugZ were required for heme iron utilization. When the genes were tested in a hemA entB mutant of E. coli, hugWXZ were not required for utilization of heme as a porphyrin source, but their absence resulted in heme toxicity when the strains were grown in media containing heme as an iron source. hugA could replace the Vibrio cholerae hutA in a heme iron utilization assay, and V. cholerae hutA could complement a P. shigelloides heme utilization mutant, suggesting that HugA is the heme receptor. Our analyses of the TonB system of P. shigelloides indicated that it could function in tonB mutants of both E. coli and V. cholerae and that it was similar to the V. cholerae TonB1 system in the amino acid sequence of the proteins and in the ability of the system to function in high-salt medium.     

Haem iron-transport system in enterohaemorrhagic Escherichia coli O157:H7

In this study, we identified the iron-transport systems of Escherichia coli O157:H7 strain EDL933. This strain synthesized and transported enterobactin and had a ferric citrate transport system but lacked the ability to produce or use aerobactin. It used haem and haemoglobin, but not transferrin or lactoferrin, as iron sources. We cloned the gene encoding an iron-regulated haem-transport protein and showed that this E. coli haem-utilization gene ( chuA ) encoded a 69 kDa outer membrane protein that was synthesized in response to iron limitation. Expression of this protein in a laboratory strain of E. coli was sufficient for utilization of haem or haemoglobin as iron sources. Mutation of the chromosomal chuA and tonB genes in E. coli O157:H7 demonstrated that the utilization of haemin and haemoglobin was ChuA- and TonB-dependent. Nucleotide sequence analysis of chuA revealed features characteristic of TonB-dependentFur-regulated, outer membrane iron-transport proteins. It was highly homologous to the shuA gene of Shigella dysenteriae and less closely related to hemR of Yersinia enterocolitica and hmuR of Yersinia pestis . A conserved Fur box was identified upstream of the chuA gene, and regulation by Fur was confirmed.     

The gene for 2-phosphoglycolate phosphatase (gph) in Escherichia coli is located in the same operon as dam and at least five other diverse genes

Downstream of the dam gene in the Escherichia coli genome the following three genes are located: first rpe, then a gene encoding a 27 kDa protein and finally trpS. Here we present evidence that the 27 kDa protein has 2-phosphoglycolate phosphatase activity, and we name the gene gph. Phosphoglycolate phosphatase is needed in autotrophic organisms performing the Calvin-Benson-Bassham (CBB) reductive pentose-phosphate cycle. E. coli is not capable of autotrophic growth and probably utilizes Gph activity for other function(s) than in the CBB cycle. We found no physiological effect of deleting gph and its function in E. coli remains unclear. The use of fusion plasmids, where lacZ was inserted into gph and trpS, and deletion derivatives of these fusion plasmids, showed that rpe, gph and trpS are all members of the dam-containing operon. A novel promoter was identified in the distal part of the dam gene. The operon, which contains aroK, aroB, urf74.3, dam, rpe, gph, and trpS, can be termed a superoperon, since it consists of (at least) seven apparently unrelated genes which are under complex regulatory control.     

Accumulation of iron by yersiniae.

Escherichia coli, Bacillus megaterium, and three species of yersiniae grew rapidly without significant production of soluble siderophores in a defined iron-sufficient medium (20 microM Fe3+). In iron-deficient medium (0.1 to 0.3 microM Fe3+) all organisms showed reduced growth, and there was extensive production of siderophores by E. coli and B. megaterium. Release of soluble siderophores by Yersinia pestis, Y. pseudotuberculosis, or Y. enterocolitica in this medium was not detected. Citrate (1 mM) inhibited growth of yersiniae in iron-deficient medium, indicating that the organisms lack an inducible Fe3+-citrate transport mechanism. Uptake of 59Fe3+ by all yersiniae was an energy-dependent saturable process, showing increased accumulation after adaptation to iron-deficient medium. Growth of Y. pseudotuberculosis and Y. enterocolitica but not Y. pestis on iron-limited solid medium was enhanced to varying degrees by exogenous siderophores (desferal, schizokinen, aerobactin, and enterochelin). Only hemin (0.1 pmol) or a combination of inorganic iron plus protoporphyrin IX promoted growth of Y. pestis on agar rendered highly iron deficient with egg white conalbumin (10 microM). Growth of Y. pseudotuberculosis and Y. enterocolitica was stimulated on this medium by Fe3+ or hemin. These results indicate that hemin can serve as a sole source of iron for yersiniae and that the organisms possess an efficient cell-bound transport system for Fe3+.     

Identification of an operon required for ferrichrome iron utilization in Vibrio cholerae

Mutagenesis of Vibrio cholerae with TnphoA, followed by screening for fusions that were activated under low-iron conditions, led to the identification of seven independent fusion strains, each of which was deficient in the ability to utilize ferrichrome as a sole iron source for growth in a plate bioassay and had an insertion in genes encoding products homologous to Escherichia coli FhuA or FhuD. Expression of the gene fusions was independent of IrgB but regulated by Fur. We report here a map of the operon and the predicted amino acid sequence of FhuA, based on the nucleotide sequence. Unlike those of the E. coli fhu operon, the V. cholerae ferrichrome utilization genes are located adjacent and opposite in orientation to a gene encoding an ATP-binding cassette transporter homolog, but this gene, if disrupted, does not affect the utilization of ferrichrome in vitro.