Pathogenic Neisseriae Can Use Hemoglobin, Transferrin, and Lactoferrin Independently of the tonB Locus

doi:10.1128/JB.182.19.5586-5591.2000

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Journal of Bacteriology, October 2000, p. 5586-5591, Vol. 182, No. 19
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Pathogenic Neisseriae Can Use Hemoglobin, Transferrin, and Lactoferrin Independently of the tonB Locus

Pragnya Jasvantrai Desai, Eric Garges, and Caroline Attardo Genco^*

The Maxwell Finland Laboratory for Infectious Diseases, Department of Medicine, Boston University School of Medicine, Boston, Massachusetts 02118

Received 24 April 2000/Accepted 6 July 2000

	ABSTRACT

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Redundant TonB systems which function in iron transport from TonB-dependent ligands have recently been identified in severalgram-negative bacteria. We demonstrate here that in addition tothe previously described tonB locus, an alternative system existsfor the utilization of iron from hemoglobin, transferrin, or lactoferrinin Neisseria meningitidis and Neisseria gonorrhoeae. Followingincubation on media containing hemoglobin, N. meningitidis IR3436(tonB exbB exbD deletion mutant) and N. gonorrhoeae PD3401 (tonBinsertional mutant) give rise to colonies which can grow withhemoglobin. Transfer of Hb⁺ variants (PD3437 or PD3402) to media containing hemoglobin, transferrin,and/or lactoferrin as sole iron sources resulted in growth comparableto that observed for the wild-type strains. Transformation ofN. meningitidis IR3436 or N. gonorrhoeae PD3401 with chromosomalDNA from the Hb⁺ variants yielded transformants capable of growth with hemoglobin.When we inactivated the TonB-dependent outer membrane hemoglobinreceptors (HmbR or HpuB) in the Neisseria Hb⁺ variants, these strains could not grow with hemoglobin; however,growth was observed with transferrin and/or lactoferrin. Theseresults demonstrate that accumulation of iron from hemoglobin,transferrin, and lactoferrin in the pathogenic neisseriae canoccur via a system that is independent of the previously describedtonBlocus.

	TEXT

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Acquisition of iron from transferrin, lactoferrin, heme, and heme-containing compounds in the pathogenic Neisseria spp. involvesa family of distinct iron-regulated outer membrane receptors (1,3, 5, 7-11, 14-16, 20, 21). The iron-repressible hemoglobinreceptor HmbR of Neisseria meningitidis (20, 21) and HpuBof N. meningitidis and N. gonorrhoeae (7, 15, 16) are requiredfor binding and utilization of hemoglobin or hemoglobin boundto haptoglobin, respectively. A second gene (hpuA), predictedto encode a lipoprotein, is found upstream of hpuB, and recentstudies have demonstrated that both HpuA and HpuB are requiredfor the utilization of hemoglobin in the pathogenic Neisseriaspp. (7, 16). An N. gonorrhoeae hmbR homolog has been identified;however, the presence of a stop codon in the coding sequence inthe gonococcal hmbR gene indicates that N. gonorrhoeae does notproduce a functional HmbR (7, 21).

Energy for the transport of iron from host iron-binding proteins across the outer membrane into the periplasmic space in anumber of gram-negative organisms is provided by TonB, in associationwith the ExbB and ExbD proteins (6, 12). The TonB systemuses the proton motive force of the cytoplasmic membrane for thepassage of ligands into the periplasm. Receptors which requireenergy supplied via the TonB system are termed TonB dependentand have amino acid homology in several regions termed TonB boxes.The TonB box represents the domain of the bacterial receptor whichphysically interacts with the energy-transducing protein TonB.The Neisseria HmbR and HpuB hemoglobin receptors have homologyto TonB-dependent outer membrane receptors (7, 20), and N.meningitidis and N. gonorrhoeae tonB, exbB, and exbD homologshave been identified (2, 22). N. meningitidis and N. gonorrhoeaetonB, exbB, and exbD insertional mutants were observed to growwith hemin; however, these mutants were reported to be deficientin the ability to utilize hemoglobin, transferrin, and/or lactoferrin(2, 22).

It was recently reported that in Vibrio cholerae, a second TonB ExbB ExbD system is operative, and this system was demonstratedto functionally replace the TonB1 system for the acquisition ofTonB-dependent ligands associated with the accumulation of iron(17). Likewise, in V. parahaemolyticus, V. alginolyticus, Serratiamarcescens, Yersinia pestis, and Pseudomonas aeruginosa, two tonBgenes have been identified (13, 18, 24). Based on theserecent reports, we have examined a newly constructed N. meningitidistonB exbB exbD deletion mutant and an N. gonorrhoeae tonB insertionalmutant for the ability to grow with heme, hemoglobin, transferrin,and/or lactoferrin as sole iron sources. We have demonstratedthat in addition to the previously described tonB locus, an alternativesystem is operative in N. meningitidis and N. gonorrhoeae forthe utilization of iron from hemoglobin, transferrin, and/or lactoferrin.We have clearly demonstrated that this system can function withthe TonB-dependent receptors HmbR in N. meningitidis and HpuBin N. gonorrhoeae for growth withhemoglobin.

Bacterial strains and growth conditions. N. meningitidis strain IR1072 is a serogroup C clinical isolate which is hmbR hpuB. Attempts to PCR amplify the hpuB genein IR1072 failed; however, we were able to amplify the hpuB genefrom IR1075 using the same primers (data not shown). In addition,strain IR1072 is unable to grow with hemoglobin complexed to haptoglobin(20, 21). N. meningitidis IR3436 is a tonB exbB exbD deletionmutant constructed following transformation of strain IR1072 witha plasmid construct in which the tonB exbB exbD locus was deletedand replaced with the spectinomycin gene (I. Stojiljkovic, unpublisheddata). Genomic DNA isolated from IR3436 was used to transformN. meningitidis MC58, the serogroup B clinical isolate which hasbeen fully sequenced, generating strain MC5801, an additionaltonB exbB exbD deletion mutant. The N. gonorrhoeae tonB insertionalmutant was constructed by transformation (4) of N. gonorrhoeae340 with N. meningitidis IR2200 chromosomal DNA (Table 1). N.gonorrhoeae strain 340 does not utilize lactoferrin as an ironsource. N. meningitidis or N. gonorrhoeae strains were typicallymaintained on gonococcal base (GCB) medium containing 1% Kelloggsupplement and incubated aerobically (5% CO₂) at 37°C for 16 to18 h (9). When necessary, kanamycin (50 µg/ml), erythromycin(1.5 µg/ml), or spectinomycin (100 µg/ml) was used.

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TABLE 1. Bacterial strains used in this study

Characterization of Neisseria tonB mutants. The tonB mutation in N. meningitidis and N. gonorrhoeae strains was confirmed by either colony or genomic PCR analysis. Thedeletion of the tonB exbB exbD genes in N. meningitidis strainsIR3436, PD3437, and PD3439, as well as in strain MC5801, was confirmedusing primers del-A and del-D, designed to amplify the entiretonB exbB exbD locus and 400 bp of flanking DNA upstream of tonBgene and downstream of the exbD gene (Table 2). To confirm thedisruption of the tonB gene in the N. gonorrhoeae insertionalmutant, primers tonB-F2 and tonB-R1 were designed to amplify homologousregions between the 5' end of the gene, upstream of the ATG codon,and the 3' end of the gene, upstream of the stop codon. Briefly,a single colony was suspended in 100 µl of distilled H₂O and incubatedat 80 to 100°C for 5 min. A 10-µl volume of this crude preparationwas then used for colony PCR analysis. Growth of N. meningitidisand N. gonorrhoeae strains was examined in a plate assay or inbroth as described in the figure legends.

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TABLE 2. Oligonucleotide primers for PCR confirmation of N. meningitidis and N. gonorrhoeae tonB, hmbR, and hpuBmutations

Construction of N. meningitidis hmbR and N. gonorrhoeae hpuB mutants. N. meningitidis hmbR and N. gonorrhoeae hpuB insertional mutants were constructed in N. meningitidis strain PD3437 and N.gonorrhoeae strain PD3402, respectively, by transformation aspreviously described (4). To disrupt the hpuB gene, N. gonorrhoeaestrain PD3402 was transformed using chromosomal DNA (1.0 µg) fromN. gonorrhoeae strain PD340E (Table 1) and transformants wereselected on GCB plates containing erythromycin (1.5 µg/ml) andkanamycin (2 µg/ml). To disrupt the hmbR gene, N. meningitidisstrain PD3437 was transformed using chromosomal DNA (1.0 µg) fromN. meningitidis strain IR1098 (Table 1) and transformants wereselected on GCB plates containing kanamycin (25 µg/ml) and spectinomycin(50 µg/ml). The inactivation of hmbR and hpuB genes in strainsPD3437 and PD3402 was confirmed by PCR (data notshown).

Utilization of hemoglobin, transferrin, and lactoferrin is not absolutely dependent on the tonB locus in the pathogenic Neisseria spp. To determine if an alternate system independent of the previously described tonB locus could function in hemoglobin utilizationin N. meningitidis, we examined the ability of an N. meningitidistonB exbB exbD deletion (IR3436) mutant to grow with differentiron sources. Both the wild-type and tonB N. meningitidis strainswere capable of growth with Fe or heme as sole iron sources (datanot shown). Discrete colonies around hemoglobin disks were observedwith N. meningitidis strains IR3436 (tonB exbB exbD deletion)(Fig. 1B) and MC5801 (tonB exbB exbD deletion) (data not shown).Furthermore, when a single colony of N. meningitidis IR3436 isolatedfrom around a hemoglobin disk was transferred to fresh GCB platessupplemented with desferal, spectinomycin, and hemoglobin andincubated for 18 h, confluent growth was observed (data not shown).We designated this hemoglobin-utilizing variant strain PD3437.When PD3437 was examined for the ability to use other iron sourcesin a plate assay, growth comparable to that of the wild-type strainIR1072 around disks containing hemoglobin, transferrin, or lactoferrinwas observed (Fig. 1B). Furthermore, we also examined the growthof N. meningitidis strain PD3437 in liquid culture with hemoglobinor hemin as a sole iron source. For these studies, hemoglobinwas supplemented with human serum albumin. In agreement with theresults of the plate assays, we found that with hemoglobin asthe sole iron source, N. meningitidis strain PD3437 grew at levelscomparable to the original wild-type strain IR1072 (data not shown).

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FIG. 1. (A) The tonB exbB exbD deletion in N. meningitidis strains IR3436, PD3437, and PD3439 was confirmed by PCR. The tonB gene was amplified by colony PCR using N. meningitidis primers specific for the tonB gene (Table 2). Lanes: M, molecular size standard; 1, IR1072; 2, IR3436; 3, PD3437; 4, PD3438. Molecular sizes are indicated on the left; those on the right correspond to the approximate sizes of the expected amplified products. (B) Growth of N. meningitidis IR3436, PD3437, and PD3438 with various iron sources. A 10-µl volume of human hemoglobin (Hb) (10 mg/ml) or an iron-saturated human transferrin (Tf) (50 mg/ml) or lactoferrin (Lf) (25 mg/ml) was used. These solutions were applied to paper disks and placed onto the GCB-desferal (60 µM) plates seeded with bacteria (10⁸ CFU). Strain IR1072 is the wild-type strain from which IR3436 and PD3437 were derived. Growth was recorded after 18 to 36 h; results are from one experiment and are representative of three separate experiments.

The tonB exbB exbD deletion in N. meningitidis strains IR3436 and PD3437 was confirmed by PCR analysis. As expected, we amplifieda 2.8-kb fragment in the wild-type strain IR1072 and a 3.0-kbfragment in the tonB exbB exbD deletion mutants, strains IR3436and PD3437 (Fig. 1A). Taken together, these results indicate thata stable change allowing the acquisition of iron from hemoglobin,transferrin, and lactoferrin had occurred and suggest that a locusindependent of tonB exbB exbD can be utilized for growth withTonB-dependent ligands. Such a phenotype would be expected ifa silent homolog of the tonB locus was present in N. meningitidis.

Using genomic DNA from the N. meningitidis tonB mutant (IR2200), we constructed a gonococcal tonB mutant in strain 340 anddemonstrated that this strain (PD3401) grew with heme and ferricnitrate as sole iron sources (data not shown). As observed withthe N. meningitidis tonB deletion mutant, we also observed coloniesaround disks containing hemoglobin and transferrin with strainPD3401 (Fig. 2B). We further characterized a hemoglobin-utilizingvariant of strain PD3401 and designated this variant PD3402. WhenPD3402 colonies were transferred to GCB plates supplemented withdesferal, kanamycin, and hemoglobin, confluent growth was observed(Fig. 2B). Furthermore, when PD3402 was transferred to media containingdisks with various iron sources, growth was observed around thetransferrin and hemoglobin disks, and this was comparable to thegrowth observed for the wild-type strain (strain 340) (Fig. 2B).To confirm that the hemoglobin utilization phenotype was not dueto a reversion of the tonB mutation, we amplified the tonB genefrom strains 340, PD3401, and PD3402 by PCR using primers specificfor the tonB gene. As expected, the wild-type tonB gene was amplifiedas a ~760-bp fragment from strain 340 whereas a ~2.0-kb fragmentwas amplified in strains PD3401 and PD3402 (Fig. 2A). This wasalso confirmed by Southern blot hybridization analysis using thetonB gene as a probe; one intact copy of the tonB gene was observedin strain 340, and one copy of the disrupted tonB gene was observedin PD3401 and PD3402 (data not shown).

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FIG. 2. (A) Insertional inactivation of the tonB gene in N. gonorrhoeae strains PD3401, PD3402, and PD3404, was confirmed by PCR as described in the legend to Fig. 1. Lanes: M, molecular size standard; 1, 340; 2, PD3401; 3, PD3402; 4, PD3403. Molecular sizes are indicated on the left. (B) Growth of N. gonorrhoeae PD3401, PD3402, and PD3403 with various iron sources. Strains were examined for their ability to utilize various iron sources in a plate assay as described in the legend to Fig. 1. N. gonorrhoeae strain 340 is the wild-type strain from which strains PD3401 and PD3402 were derived. Growth was recorded after 18 to 36 h; results are from one experiment and are representative of three separate experiments. Hb, hemoglobin; Tf, transferrin.

Utilization of hemoglobin independently of the tonB locus is dependent on the N. meningitidis HmbR and N. gonorrhoeae HpuB hemoglobin receptors. We next inactivated the hemoglobin receptors HmbR in N. meningitidis PD3437 and HpuB in N. gonorrhoeae PD3402. N. meningitidisstrain IR3436, from which strain PD3437 was derived, is naturallyhpuB, and thus inactivation of hmbR in this strain should resultin a strain unable to grow with hemoglobin as a sole iron source.Likewise, since the hmbR locus is not expressed in N. gonorrhoeae(7, 21), the inactivation of the hpuB gene in N. gonorrhoeaestrain PD3402 should result in a strain unable to grow with hemoglobinas the sole iron source. If the ability to utilize hemoglobinindependently of the tonB locus was due to the removal of hemeindependent of HmbR or HpuB and subsequent transport into thecell via a heme acquisition pathway, we would expect that hmbRhpuB strains should still utilize heme from hemoglobin for growth,since hemin transport in N. meningitidis and N. gonorrhoeae occursvia an HmbR- and HpuB-independent mechanism (16, 20). Theinactivation of hmbR or hpuB in these strains was confirmed byPCR. As expected, we observed a ~744-bp PCR fragment using primersspecific to an internal fragment of the hmbR gene in N. meningitidisstrain PD3437 (data not shown). A PCR fragment of ~1.9 kb wasobserved in the N. meningitidis hmbR insertional mutant strainPD3438, corresponding to the insertion of the kanamycin cassette.Likewise, using primers specific for the N. gonorrhoeae hpuB gene,we observed a ~2.4-kb fragment in N. gonorrhoeae strain PD3402(data not shown). A PCR fragment of ~3.7 kb was observed in N.gonorrhoeae strain PD3403, corresponding to the insertion of theerythromycin cassette into this strain (data notshown).

N. meningitidis PD3438 and N. gonorrhoeae PD3403 exhibited normal growth with heme (data not shown), transferrin, and/or lactoferrincompared to the wild-type strains IR1072 and 340 (Fig. 1B and2B). However, we did not observe any growth of strain PD3438 orPD3403 with hemoglobin as the sole iron source (Fig. 1B and 2B).These results clearly indicate that the ability to utilize hemoglobinindependently of the above-described tonB locus in N. meningitidisand N. gonorrhoeae does not result from the removal of heme andsubsequent transport into the cell via a heme acquisition pathway.These results also indicate that in N. meningitidis and N. gonorrhoeaea second TonB system must function with HmbR or HpuB for the transportof iron from hemoglobin. Furthermore, our observations suggestthat the putative second tonB locus may be silent, and expressioncan be detected only when the first tonB locus isinactive.

The ability to utilize hemoglobin independently of the tonB locus can be genetically transformed into N. meningitidis IR3436 or N. gonorrhoeae PD3401. The frequency of the appearance of N. meningitidis hemoglobin-utilizing (Hb⁺) variants for strain IR3436 was determined to be 1.37 × 10⁷. Likewise, the frequency of the appearance of N. gonorrhoeaeHb⁺ variants for strain PD3401 was similar to that observed for N.meningitidis (2.9 × 10⁷). To determine if the ability to utilize hemoglobin independentlyof the tonB locus was encoded by a gene which was now functionalin the Hb⁺ variant (strain PD3437), we transformed N. meningitidis IR3436with chromosomal DNA isolated from strain PD3437. Transformationof N. meningitidis strain IR3436 with chromosomal DNA from strainPD3437 yielded transformants capable of growth with hemoglobinat a frequency of 1.07 × 10⁴. We randomly picked Hb⁺ transformants and transferred these colonies to media containingdisks with various iron sources; for all Hb⁺ transformants tested, growth was observed around hemoglobin-,transferrin-, and lactoferrin-containing disks and was comparableto that observed for strain PD3437 (data not shown). The deletionof the tonB exbB exbD genes in N. meningitidis strain PD3439 wasconfirmed by PCR analysis (Fig. 1A).

Likewise, we obtained similar results when we transformed N. gonorrhoeae strain PD3401 with chromosomal DNA isolated fromthe Hb⁺ variant (strain PD3402). Transformation of N. gonorrhoeae strainPD3401 with chromosomal DNA isolated from strain PD3402 yieldedtransformants capable of growth with hemoglobin at a frequencyof 4.9 × 10³. We also randomly picked N. gonorrhoeae Hb⁺ transformants and transferred these colonies to media containingdisks with various iron sources. As observed for N. meningitidisPD3439, we observed proficient growth of strain PD3404 aroundtransferrin- and hemoglobin-containing disks. We also confirmedthe tonB mutation in strain PD3404 by PCR analysis (Fig. 2A).These results indicate that the ability to utilize hemoglobinindependently of the previously described tonB locus is encodedby a gene which is functional and stable in N. meningitidis strainPD3437 and N. gonorrhoeae strainPD3402.

Concluding remarks. The results obtained in this study indicate that the previously described tonB locus is not solely responsible for the utilizationof hemoglobin, transferrin, or lactoferrin in the pathogenic Neisseriaspp. Based on these results, we postulate that N. meningitidisand N. gonorrhoeae possess a second, alternative TonB system forthe utilization of iron from TonB-dependent ligands. Our resultsalso indicate that in N. meningitidis and N. gonorrhoeae the secondTonB system clearly functions with HmbR or HpuB for the acquisitionof iron from hemoglobin. We found that the frequency of colonieswhich could grow with hemoglobin and transferrin was relativelylow. Indeed, this may explain why, in previous studies (2,22), these colonies either were not observed or appeared ata relatively low frequency (depending on the duration of incubation)and therefore were not reported. In addition, differences in thegrowth assays, the media used for plate assays (complex versusdefined), the concentration of the various iron sources, or theconcentration of organisms used may explain this discrepancy.In our studies we utilized plate assays with 100 µg of hemoglobinper disk (1.5 µM final concentration), whereas Stojiljkovic andSrinivasan (22) used plate assays with 50 µg of hemoglobin perdisk (0.75 µM final concentration). In studies reported by Biswaset al. (2), the ability of gonococcal tonB exbB exbD mutantsto utilize various iron sources was examined by streaking colonieson CDM plates containing various iron sources with a final hemoglobinconcentration of 1 µM. Our observations suggest that the putativesecond tonB locus may be silent and that expression can be detectedonly when the first tonB locus is inactive. Furthermore, the abilityto obtain stable Hb⁺ transformants following transformation with chromosomal DNA fromthe N. meningitidis or N. gonorrhoeae Hb⁺ variants (PD3437 or PD3402 respectively) indicates that, oncethis silent second tonB locus is expressed, its expression isstable.

In summary, we propose that the pathogenic Neisseria spp. possess a second TonB system which functions to transduce energyto TonB-dependent outer membrane receptors. Examination of thegonococcal and recently completed meningococcal database for NeisseriatonB homologs did not reveal any open reading frames with significanthomology to any previously described tonB locus. This is not anunexpected finding, given that V. cholerae tonB2 has only 23%homology with Neisseria tonB. Similarly, P. aeruginosa tonB2 demonstrates28% homology to P. aeruginosa tonB. Attempts to find conservedregions in both tonB proteins among these species were unsuccessful.We have constructed a genomic library from the hemoglobin-utilizingvariant N. meningitidis PD3437, and studies are currently in progressto identify the second Neisseria tonB locus by complementationanalysis.

	ACKNOWLEDGMENTS

This study was supported by Public Health Service grant AI30797 from the National Institute of Allergy and InfectiousDiseases.

We thank Igor Stojiljkovic for providing N. meningitidisstrains.

	FOOTNOTES

^* Corresponding author. Mailing address: The Maxwell Finland Laboratory for Infectious Diseases, Department of Medicine, BostonUniversity School of Medicine, 650 Albany St., Boston, MA 02118.Phone: (617) 414-5305. Fax: (617) 414-5280. E-mail: caroline.genco{at}bmc.org.

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