Involvement of a Lysine-specific Cysteine Proteinase in Hemoglobin Adsorption and Heme Accumulation by Porphyromonas gingivalis*

Kuniaki OkamotoDagger §, Koji Nakayama, Tomoko KadowakiDagger §, Naoko AbeDagger , Dinath B. Ratnayake, and Kenji YamamotoDagger parallel

From the Departments of Dagger  Pharmacology and  Microbiology, Kyushu University Faculty of Dentistry, Higashi-ku, Fukuoka 812-8582, Japan

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

The oral anaerobic bacterium Porphyromonas gingivalis, a major pathogen of advanced adult periodontitis, produces a novel class of cysteine proteinases in both cell-associated and secretory forms. A lysine-specific cysteine proteinase (Lys-gingipain, KGP), as well as an arginine-specific cysteine proteinase (Arg-gingipain), is a major trypsin-like proteinase of the organism. Recent studies indicate that the secreted KGP is implicated in the destruction of periodontal tissue and the disruption of host defense mechanisms. In this study, we have constructed a KGP-deficient mutant to determine whether the cell-associated KGP is important for pathophysiology of the organism. Although the mutant retained the strong ability to disrupt the bactericidal activity of polymorphonuclear leukocytes, its hemagglutination activity was reduced to about one-half that observed with the wild-type strain. More important, the mutant did not form black-pigmented colonies on blood agar plates, indicating the defect of hemoglobin adsorption and heme accumulation. Immunoblot analysis showed that the expression of a 19-kDa hemoglobin receptor protein, which is thought to be responsible for hemoglobin binding by the organism, was greatly retarded in this mutant. The mutant also showed a marked decrease in the ability to degrade fibrinogen. These results suggest the possible involvement of KGP in the hemoglobin binding and heme accumulation of the organism and in the bleeding tendency in periodontal pockets.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

The proteinases of the Gram-negative, black-pigmented anaerobe Porphyromonas gingivalis are believed to be involved in a wide range of pathologies of progressive periodontal disease (reviewed in Refs. 1 and 2). Recently, the trypsin-like activity associated with the organism is found to be attributable to either Arg-X- or Lys-X-specific cysteine proteinase (where X is an unknown amino acid residue) (3). These two enzymes have now been termed Arg-gingipain (gingipain-R, RGP)1 and Lys-gingipain (gingipain-K, KGP) on the basis of their peptide cleavage specificity after arginine and lysine residues, respectively. Catalytic and structural studies have revealed that these enzymes are a novel class of the cysteine proteinase family (1).

Recently, it has been suggested that the proteolytic activities of RGP and KGP are involved in the pathogenesis of progressive periodontal disease through the following mechanisms: (i) directly degrading structural proteins of the periodontal tissues (4-12), (ii) disrupting host defense mechanisms (7, 13-19), (iii) activating or stimulating the expression of hemagglutinins (20), (iv) processing and translocating adhesion molecules (21), and (v) inducing or stimulating inflammation through the production of chemical mediators (10, 22, 23). Previous studies of RGP-deficient mutants constructed by use of suicide plasmid systems revealed that RGP plays a major role in the disruption of polymorphonuclear leukocyte (PMN) functions and the hemagglutination and fimbriation by the organism (20, 21). However, little information is available about to what extent KGP contributes to the entire virulence of P. gingivalis. To gain some insight into this question, it is necessary to undertake the molecular genetic approach.

So far, three genes encoding Lys-X-specific cysteine proteinases have been cloned and sequenced, but all of the genes seem to be essentially equivalent to one another (24-26). Southern hybridization analyses have also suggested that a single KGP-encoding gene exists on the chromosome of P. gingivalis (24). The nucleotide sequence of the kgp gene of P. gingivalis strain and the deduced amino acid sequence have suggested that the precursor of KGP comprises at least four domains: the signal peptide, the amino-terminal propeptide, the catalytic proteinase domain, and the carboxyl-terminal hemagglutinin domain. In the present study, we have constructed a KGP-deficient mutant via disruption of the kgp gene by use of suicide plasmid systems to analyze the function of KGP in the organism. The results provide evidence suggesting that KGP is associated with hemagglutination, hemoglobin binding and heme accumulation by the organism, and the bleeding tendency in periodontal pockets and that it is not directly implicated in the production of virulence factors responsible for suppression of the bactericidal activity of PMNs.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Media and Conditions for Cell Growth-- P. gingivalis cells were grown anaerobically (10% CO2, 10% H2, 80% N2) in enriched BHI broth (containing, per liter, 37 g of brain heart infusion (Difco), 5 g of yeast extract (Difco), 1 g of cysteine, 5 mg of hemin, and 1 mg of vitamin K1) and on enriched BHI agar (containing, per liter, 15 g of agar (Nakarai, Tokyo, Japan), 37 g of brain heat infusion, 5 g of yeast extract, 1 g of cysteine, 5 mg of hemin, and 1 mg of vitamin K1). L broth (containing, per liter, 10 g of tryptone (Difco), 5 g of yeast extract, and 5 g of sodium chloride) was used for growing Escherichia coli cells. For selection or maintenance of the antibiotic-resistant strains, antibiotics were added to the medium at the following concentrations: ampicilin, 200 µg/ml; erythromycin, 10 µg/ml.

DNA Manipulation-- Chromosomal DNA was isolated from P. gingivalis cells by the guanidine isothiocyanate method (27) with the IsoQuick DNA extraction kit (MicroProbe, Garden Grove, CA) for Southern blot analyses.

Plasmid Construction-- Suicide plasmids constructed in this study are depicted in Fig. 1. An ~3.5-kbp BamHI fragment of plasmid pNKV (24), containing the gene of whole KGP proteinase domain, was ligated to pUC118, which was digested with EcoRI, filled in by the Klenow enzyme, digested with BamHI, and treated with alkaline phosphatase. The resulting plasmid was then digested with EcoRI and self-ligated to make a deletion within the kgp gene, giving rise to plasmid pNKV-2. A BamHI chromosomal fragment (3.3 kbp) of pNKV-2 was then ligated to pKD283 DNA (28) that had been linearized with BamHI and treated with alkaline phosphatase, resulting in plasmid pNKD.


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Fig. 1.   Plasmid construction. Amp, ampicilin resistance; Em, erythromycin resistance; GUS, beta -glucuronidase gene; ori, replication origin functioning in E. coli; f1(-)1G, f1(-) intergenic region; lacZ, beta -galactosidase gene; ColE1 ori, replication origin. The black region is a partial kgp gene (signal sequence, amino-terminal prodomain, proteinase domain, and a part of carboxyl-terminal prodomain). Restriction sites: B, BamHI; H, HindIII; RI, EcoRI; RV, EcoRV.

DNA Probes and Southern Blot Hybridization-- Two synthetic oligonucleotides, 5'-GCTAGTGCTGCTCCGGTCTTCTTGG-3' (Probe I) and 5'-GCGAGGACTACTATTGGAGTGTCGG-3' (probe II), were obtained from Greiner Japan (Tokyo, Japan) and Kurabo (Osaka, Japan), respectively, and were labeled with fluorescein-dUTP (Amersham Pharmacia Biotech, Little Chalfont, UK). Chromosomal DNA of wild-type and KGP-deficient strains was digested with HindIII and subjected to a 0.8% agarose gel for Southern blot analysis. Digested genome DNA was transferred to a nitrocellulose membrane (Schleicher & Schuell) essentially according to Southern (29). Hybridization with probes I and II and detection of signals were done by using the ECL 3'-oligolabeling (Amersham) and the SuperSignalTM Nucleic Acid (Pierce), respectively.

Electrotransformation of P. gingivalis with pNKD Plasmid DNA-- P. gingivalis cells were anaerobically grown to 6 × 108/ml at 37 °C in enriched BHI broth. The cells were then harvested by centrifugation, washed with the electroporation solution (300 mM sucrose), and resuspended in 0.1 volume of the same solution. 10 µl of pNKD plasmid DNA solution (300 µg of DNA/ml in TE buffer) were added to 0.4 ml of the cell suspension. The whole volume of the DNA-containing cell suspension was poured into a cuvette for electroporation (PulserTM cuvette with 0.2-cm electrode gap, Bio-Rad). Electroporation was performed at 2.0 kV with an electroporation apparatus (Gene PulserTM, Bio-Rad). These procedures were carried out at 4 °C. The cell suspension was immediately mixed with 10 ml of prewarmed enriched BHI broth and incubated anaerobically at 37 °C for 15 h. Cells of the culture were spread on enriched tryptic soy agar containing erythromycin and incubated anaerobically at 37 °C for 7 days.

Preparation of Culture Supernatants and Cell Extracts-- 24-hour cultures were harvested by centrifugation at 10,000 × g for 30 min at 4 °C. Ammonium sulfate was added to the culture supernatant to a final concentration of 75% saturation. The precipitated proteins were collected by centrifugation at 10,000 × g for 20 min and suspended in 10 mM sodium phosphate buffer (pH 7.0) containing 0.05% Brij 35. After overnight dialysis against the same buffer at 4 °C, insoluble materials were removed by centrifugation at 25,000 × g for 30 min. The resulting supernatant was used as a culture supernatant in this study. On the other hand, bacterial cells were washed with phosphate-buffered saline (PBS) and resuspended in 10 mM sodium phosphate buffer (pH 7.0) containing 0.05% Brij 35. Cell extracts were prepared by ultrasonication followed by centrifugation at 25,000 × g for 30 min.

Gel Electrophoresis and Immunoblot Analysis-- SDS-polyacrylamide gel electrophoresis was performed according to the method of Laemmli (30). The proteinase inhibitor leupeptin was added to a solubilizing buffer to avoid proteolysis by endogenous proteinases. For immunoblotting, proteins on SDS gels were electrophoretically transferred to nitrocellulose membranes according to the method of Towbin et al. (31). The blotted membranes were immunostained with the antibodies immunoreacting both RGP and KGP (20) or the antibodies specific for the 19-kDa hemoglobin receptor protein purified essentially according to the procedure described previously (32).

Enzymatic Assay-- Lys-X- and Arg-X-specific cysteine proteinase activities were determined by use of the synthetic substrates t-butyloxycarbonyl-Val-Leu-Lys-MCA and carbobenzoxy-Phe-Arg-MCA, respectively, as described previously (7, 33). Briefly, the reaction mixture (1 ml) contained various amounts of the cell extracts or the culture supernatants, 10 µM each synthetic substrate, and 5 mM cysteine in 20 mM sodium phosphate buffer (pH 7.5). After incubation at 40 °C for 10 min, the reaction was terminated by adding 1 ml of 10 mM iosoacetic acid (pH 5.0), and the released 7-amino-4-metylcoumarin was measured at 460 nm (excitation at 380 nm) on a fluorescence spectrophotometer.

Degradation of Fibrinogen-- The cell-free culture supernatants of the P. gingivalis strains were obtained by centrifugation at 10,000 × g for 20 min at 4 °C. Ammonium sulfate was added to the culture supernatant to give 75% saturation. The precipitated proteins were collected by centrifugation at 10,000 × g for 20 min and resuspend in 10 mM sodium phosphate buffer (pH 7.0) containing 0.05% Brij 35. After dialysis against the same buffer at 4 °C overnight, insoluble materials were removed by centrifugation at 25,000 × g for 30 min. 20 µg of human fibrinogen were incubated with the respective dialysates (1 µg) for 4 h at 37 °C, and then electrophoresis was performed on SDS gels. The gel was stained with Coomassie Brilliant Blue R-250. Five points of each band were measured and averaged by Microcomputer Imaging Device.

Determination of Hemoglobin Adsorption of P. gingivalis Cells-- Hemoglobin adsorption was determined essentially according to Fujimura et al. (34). Briefly, P. gingivalis cells were grown anaerobically in enriched BHI broth overnight. The cells were harvested from 1 ml of the culture, washed with 50 mM acetate buffer (pH 6.0), and resuspended in the original volume of the same buffer. Cell density of the suspension was then adjusted to an optical density (650 nm) of 0.73. The cell suspension (730 µl) was mixed with 270 µl of human hemoglobin (1 mg/ml in the same buffer). The mixture was incubated at 37 °C for 30 or 60 min and centrifuged at 10,000 × g for 15 min. The absorbance of the supernatant was then measured at 410 nm. Adsorbed hemoglobin was evaluated by decrease of absorbance of the supernatant.

Measurement of Luminol-dependent CL Response-- CL response of PMNs was measured according to the method described previously (7).

Hemagglutination Assay-- Overnight cultures of P. gingivalis strains were centrifuged, washed twice with PBS, and resuspended in PBS at an optimal density at 660 nm of 0.44. The bacterial suspensions were then diluted in a 2-fold series with PBS. A 100-µl aliquot each of the dilutions was mixed with an equal volume of sheep erythrocyte suspension (2.5% in PBS) and incubated in a round-bottom microtiter plate at room temperature for 3 h.

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Construction of a KGP-deficient Mutant and Southern Blot Analyses-- A KGP-deficient mutant was constructed via gene disruption by use of a suicide plasmid containing a part of the kgp gene. The suicide plasmid pNKD contained an amino-terminal region of the kgp gene lacking a 132-bp EcoRI region within the gene. Emr transformants were obtained after introduction of pNKD plasmid DNA into P. gingivalis ATCC33277 by electroporation (Fig. 2A). Four possible chromosomal structures may arise from integration of the plasmid DNA: single cross-over types (a and b) and apparent gene conversion types (c and d) (Fig. 2A). Types a and b could be accounted for by reciprocal recombination between homologous DNA regions of the chromosome and the plasmid, whereas types c and d would be generated by multiple reciprocal recombination or nonreciprocal recombination (gene conversion) (35, 36). Southern analyses revealed that we only obtained two types of Emr transformants: one (type c) with the intact kgp gene (KDM16) and the other (type d) with a deletion in kgp (KDM35), whereas Emr transformants of types a and b could not be obtained. Thus, Southern hybridization analysis of their chromosomes was carried out with two synthetic oligonucleotides to determine which types of transformants were produced. Probe I was a 25-bp oligonucleotide hybridizing to one region of the KGP proteinase domain, whereas probe II was a 25-bp oligonucleotide hybridizing a region within the 132-bp EcoRI region. The chromosomal DNA of the Emr transformants of types a and b has two HindIII DNA fragments (1.2 and 1 kbp) hybridizing to probe I and II. The chromosomal DNA of c-type transformants has one HindIII fragment (1.2 kbp) hybridizing to probe I and II, whereas that of d-type transformants has one HindIII fragment (1 kbp) hybridizing to probe I and no DNA fragment hybridizing to probe II. The chromosomal DNA of the wild-type parent has one HindIII fragment (1.2 kbp) hybridizing to probes I and II. Southern analysis using probes I and II revealed that KDM16 and KDM35 were of types c and d, respectively (Fig. 2B).


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Fig. 2.   Chromosomal structures around the kgp regions of the Emr transformants (A) and Southern blot analysis of their chromosomal DNA (B). A, DNA regions complementary to the kgp-specific oligonucleotides that were used as DNA probes for Southern blot analysis were indicated under the physical map of the chromosomal DNA of the wild-type strain. Four possible structures arise from plasmid integration by a single cross-over (a and b) and gene conversion (c and d). The white boxes indicate the EcoRI segment of the kgp gene. Arrowheads show a deletion of the segment. Restriction sites: B, BamHI; H, HindIII; RI, EcoRI; RV, EcoRV. Emr, erythromycin resistance. B, chromosomal DNAs of the wild-type strain and KGP-mutants were digested with HindIII and subjected to a 0.8% agarose gel for Southern blot analysis. Probe I, 5'-GCTAGTGCTGCTCCGGTCTTCTTGG-3', and probe II, 5'-GCGAGGACTACTATTGGAGTGTCGG-3'. Lanes 1, the wild-type ATCC33277; lanes 2, KDM16; lanes 3, KDM35.

Western Blot Analysis with Antibodies Recognizing Both KGP and RGP and the KGP Activity-- To determine whether the transformant KDM35 was devoid of KGP protein, immunoblot analysis of the mutant was performed by use of antibodies reacting with both KGP and RGP (Fig. 3). The culture supernatant of ATCC33277 (wild-type parent) showed four clear protein bands with apparent molecular masses of 51, 44, 40 and 32 kDa and a smearing band of 70-100 kDa. There was no significant difference in electrophoretic profiles between KDM16 and ATCC33277, although the 40- and 32-kDa proteins were markedly decreased in KDM16. The 32-kDa protein was also detected in KDM35. However, both the cell extract and culture supernatant of KDM35 was devoid of the 51-kDa band. The 40-kDa protein could be detected by immunoblotting of a large amount of the supernatant proteins of KDM35, whereas the 51-kDa protein was not observed under the same conditions (data not shown). Therefore, the 51-kDa protein appeared to be KGP. On the other hand, the proteins of 44, 40, 32, and 70-100 kDa seemed to be derived from the rgp gene products, although its expression level was slightly different between the wild-type parent and its mutants, which was consistent with a previous study (20).


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Fig. 3.   Immunoblot analyses of cell extracts and culture supernatants of the kgp mutant with antibodies recognizing RGP and KGP. Both cell extracts (lanes 1-3) and culture supernatants (lanes 4-6) from ATCC33277, KDM16, and KDM35 (each 20 µg of protein) were subjected to SDS-polyacrylamide gel electrophoresis on 10% gel. Proteins separated on the gels were transferred to nitrocellulose membranes and immunostained with antibodies recognizing both RGP and KGP. Lanes 1 and 4, ATCC33277; lanes 2 and 5, KDM16; lanes 3 and 6, KDM35. The 51-kDa protein of the ATCC33277 that is lacking in KDM35 is indicated by closed circles.

KGP can specifically cleave the Lys-X peptide bond. The proteolytic activity on the synthetic substrate t-butyloxycarbonyl-Val-Leu-Lys-MCA was scarcely detectable in either the cell extract or the culture supernatant of KDM35, whereas KDM16 showed the same activity in these fractions as the parent ATCC33277 (Fig. 4A). On the other hand, the hydrolyzing activity on the synthetic substrate carbobenzoxy-Phe-Arg-MCA, which represents the RGP activity, was not significantly changed in either fraction of KDM35, as well as KDM16 (Fig. 4B). Thus, KDM35 was found to be devoid of KGP at the protein and activity levels, indicating that KDM35 is a KGP-deficient mutant that possesses a deletion within the proteinase domain region of the kgp gene.


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Fig. 4.   Proteolytic activities of the KGP-deficient mutant. Lys-X-specific (A) and Arg-X-specific cysteine proteinase activities (B) in the cell extracts and culture supernatants of ATCC33277 (WT), KDM16 (16), and KDM35 (35) were assayed with t-butyloxycarbonyl-Val-Leu-Lys-MCA and carbobenzoxy-Phe-Arg-MCA, respectively. Each point is the mean ± S.D. of three experiments. **, p < 0.01 for differences from the wild-type ATCC33277.

Effect on CL Response of PMNs-- The culture supernatant of the wild-type strain contained potent virulence factors, which disrupt the bactericidal function of PMNs (37). Both RGP and KGP purified from the culture supernatant of P. gingivalis exhibited the potent suppressive activity against the CL response of PMNs stimulated by serum-activated zymosan (7, 33). Further, in agreement with the previous results (20), the culture supernatant of the RGP-null mutant (the rgpA rgpB double mutant, KDP112) was shown to almost completely lose the inhibitory effect on the CL response of PMNs, confirming that RGP is responsible for suppression of the bactericidal function of PMNs (Fig. 5A). In contrast, the culture supernatant of the KGP-deficient mutant (KDM35), like the wild-type strain and KDM16, resulted in the intense inhibition of the CL response of PMNs, suggesting that contribution of KGP to the inhibition of the bactericidal activity of PMNs by the culture supernatant of P. gingivalis is not as much as that of RGP and that KGP is not directly involved in the production of P. gingivalis factors responsible for the inhibition.


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Fig. 5.   Suppressive activity on the bactericidal activity of PMNs (A) and hemagglutinating activity (B) of the kgp mutant. A, guinea pig PMNs (1 × 107 cells/ml) were preincubated with the culture supernatants of ATCC33277, KDM16, KDM35, and KDP112 (50 mg of protein each) at 37 °C for 30 min. Then, PMNs were washed and resuspended in PBS at a final concentration of 2 × 107 cells/ml). The CL response of the PMNs was measured after stimulating by opsonized zymosan. The values are expressed as percentages of that obtained with PBS. Each point is the mean ± S.D. of two experiments. B, the hemagglutinin titers of ATCC33277, KDM16, KDM35, and KDP112 were determined as the last dilution exhibiting full agglutination. The values were expressed as percentages of that obtained with the wild-type strain ATCC33277.

Hemagglutination-- In our previous study (20), we found that the RGP-null mutant showed a greater decrease in the hemagglutinating activity observed with the wild-type strain. Because the initial translation product of KGP appeared to contain the hemagglutinin domain in the carboxyl-terminal region (24), which is significantly homologous to that of the RGP gene product (38), it is of special importance to determine whether KGP is related to hemagglutination of P. gingivalis. The RGP-null mutant almost completely lost the intense hemagglutinating activity observed with the wild-type strain. Although KDM16 had the same hemagglutinating activity as the wild-type strain, KDM35 reduced the extent of hemagglutination to one-half those of the wild-type strain and KDM16 (Fig. 5B). These results indicate a significant contribution of the cell-associated KGP to the hemagglutination of P. gingivalis.

Black Pigmentation-- As shown in Fig. 6, P. gingivalis strains produce black-pigmented colonies on laked blood agar plates. It is generally accepted that the black pigments are heme, which is an absolute requirement for growth of P. gingivalis (39, 40), and that it is probably derived from erythrocytes in the natural niche for the organism. Therefore, it is particularly important for the organism to aggregate and lyse erythrocytes to survive in vivo (41, 42). To determine whether KGP is involved in the formation of black-pigmented colonies, KDM35 was grown on laked sheep blood agar. Although KDM16, like the wild-type strain, developed black-pigmented colonies, KDM35 formed less pigmented colonies (Fig. 6). Further, it is questionable whether KDM35, the RGP-null mutant, and the wild-type strain can form black-pigmented colonies when grown on enriched tryptic soy agar plates with or without 2% hemoglobin (data not shown). On the plate without hemoglobin, neither of them showed both cell growth and black pigmentation. However, in the presence of hemin in enriched tryptic soy agar plates each strain resulted in the cell growth but not black pigmentation. In the presence of hemoglobin, only KDM35 did not form black-pigmented colonies, but it retained the cell growth activity. These findings indicate that KGP seems to be involved in the hemoglobin adsorption and the heme accumulation by the organism.


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Fig. 6.   Clonial pigmentation. P. gingivalis strains (ATCC33277, KDM16, and KDM35) were inoculated on the laked sheep blood agar plate and incubated anaerobically at 37 °C for 7 days.

Hemoglobin Adsorption and Hemoglobin Receptor Protein Production-- More recent work in our laboratory has resulted in the identification and purification of a prominent 19-kDa protein that was significantly expressed in P. gingivalis when grown on blood agar plate (32). This protein was found to be the hemoglobin receptor (HbR) protein (34) that was intragenically encoded by the rgp1, kgp, and hagA genes of P. gingivalis (24, 43, 44). Also, it was interesting to note that HbR protein was not expressed in nonpigmented mutants (BE1 and BR1) that were isolated from the W50 strain of P. gingivalis (45) and that the ability of these mutants to bind hemoglobin was markedly decreased (34). Therefore, to determine whether the decreased pigmentation of KDM35 is attributable to a defect of hemoglobin adsorption, we examined the mutant for the ability to bind hemoglobin. The results indicate that KDM35 binds hemoglobin to a lesser extent than the kgp+ sibling strain KDM16 (Fig. 7A). Immunoblot analysis with anti-HbR antiserum revealed that the cell extract of KDM35 grown on the laked blood agar for 3 days produced no HbR protein, whereas that of KDM16 produced a single protein band with an apparent molecular mass of 19 kDa (Fig. 7B). However, after 7 days of incubation KDM35 produced a small amount of the HbR protein, and after 17 days it produced as much as that of KDM16.


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Fig. 7.   Analyses of the hemoglobin adsorption and HbR protein expression in the KGP-deficient mutant. A, the cell suspensions of kgp+ sibling strain (KDM16) and KGP-deficient mutant (KDM35) were incubated with human hemoglobin at pH 6.0 and 37 °C for 30 or 60 min and centrifuged. Hemoglobin adsorption was evaluated by decrease in the absorbance of supernatants at 410 nm. Closed and open circles indicate KDM35 and KDM16, respectively. Bars represent the means ± S.D. of three experiments. B, the cell extracts of KDM16 and KDM35 were separated by SDS-polyacrylamide gel electrophoresis and subjected to immunoblot analysis with antiserum to HbR.

Degradation of Fibrinogen-- Fibrinogen is a 300-kDa protein that consists of three pairs of polypeptide chains (designated Aalpha , Bbeta , and gamma ) covalently linked by disulfide bonds. Thrombin is known to convert fibrinogen to fibrin monomers, leading to forming of a fibrin gel. Because of the bleeding tendency in periodontal pockets and the observation that P. gingivalis gingipains cleave fibrinogen (46-48), we examined whether KGP contributes to blocking blood coagulation in the periodontal pockets. For this, the culture supernatants freshly harvested from KDM35, KDP112, and the wild-type strain were incubated with human fibrinogen at 37 °C for 4 h (Fig. 8A). All of the chains were extensively degraded by the culture supernatants of the wild-type strain and the RGP-null mutant, although the former was more effective than the latter. However, the culture supernatant of the KGP-deficient mutant KDM35 was less effective in proteolysis of these chains, especially Bbeta and gamma  chains. Densitometric scanning revealed that the degradation by the culture supernatant of KDM35 was reduced to about one-half that of the wild-type strain for the Aalpha and Bbeta chains and one-fourth that of the wild-type strain for the gamma  chain (Fig. 8B).


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Fig. 8.   Degradation of human fibrinogen by the culture supernatants of the RGP-deficient and KGP-deficient mutants. A, human fibrinogen (20 µg) was incubated with the culture supernatants of the wild-type parent (ATCC33277), the RGP-null mutant (KDP112), and the KGP-null mutant (KDM35) (1 µg of protein each) for 4 h at 37 °C and then analyzed by SDS-polyacrylamide gel electrophoresis (10% polyacrylamide gel) under reducing conditions. The gel was stained with Coomassie Brilliant Blue R-250. Lane 1, 20 µg of fibrinogen; lane 2, ATCC33277; lane 3, KDP112; lane 4, KDM35. Numbers on the left indicate relative molecular masses (kDa) of standard proteins. Arrows indicate protein bands corresponding to the Aalpha , Bbeta , and gamma  chains of fibrinogen. B, each chain of fibrinogen was quantitated by scanning densitometry, and the integrated optical densities were converted to a relative protein value expressed as a percentage relative to the value observed with fibrinogen as a standard. White bars, fibrinogen; hatched bars, ATCC33277; black bars, KDP112; gray bars, KDM35. Each point is the mean ± S.D. of five experiments.

    DISCUSSION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

In our previous study (20), we constructed RGP-deficient mutants from P. gingivalis ATCC33277 and provided evidence suggesting that RGP plays critical roles in inhibition of the bactericidal activity of PMNs and the hemagglutination by the organism. In this study, we have constructed the KGP-deficient mutant, designated KDM35, from P. gingivalis ATCC33277 by integration of the Emr suicide plasmid pNKD containing a DNA fragment of the gene to clarify the KGP function in the organism. The cell extract and culture medium of KDM35 showed no Lys-X-specific cysteine proteinase activity but still retained the same Arg-X-specific cysteine proteinase activity as that of the wild-type strain in both fractions, indicating that only the KGP proteinase gene is disrupted.

We have previously shown that the initial translation product of KGP, like RGP, contains the hemagglutinin-related sequence in the carboxyl-terminal domain (24) and that the RGP-null mutant KDP112 is almost devoid of the hemagglutinating activity and loses the inhibitory effect on the bactericidal activity of PMNs (20). More recently, we have also found that the purified KGP significantly inhibits the bactericidal activity of PMNs (37). Therefore, in this study we determined to what extent KGP contributes to the disruption of host defense mechanisms and the hemagglutinating activity by P. gingivalis by biochemical analysis of the KGP-deficient mutant KDM35. Morphologically, KDM35 possessed a similar number of characteristic kinky fimbriae on the cell surface of the wild-type strain. Taken together, the precursors of fimbrilin, a major component of fimbriae, and a 75-kDa cell surface protein have been shown to undergo normal processing in KDM35.2 These results suggest that KGP is not significantly involved in processing and translocation of the cell surface proteins. The culture supernatant of this mutant also had the same suppressive activity on the CL response of PMNs as that of the wild-type strain, indicating that KGP has little contribution to production of virulence factor(s) responsible for disruption of the bactericidal activity of PMNs. This is consistent with the observation that the culture supernatant of RGP-null mutant almost completely lost the inhibitory effect of the culture supernatant of P. gingivalis on the CL response of PMNs (Fig. 5) (20). In contrast, KDM35 showed a significant decrease in the hemagglutinating activity, suggesting that KGP significantly contributes to the generation of hemagglutinins from the initial translation products of hemagglutinin-related genes, such as rgp1, kgp, and hagA, B, C (49), in P. gingivalis strains. However, because the RGP-null mutant is almost devoid of the hemagglutinating activity, KGP seems likely to make a relatively small contribution to the production of hemagglutinins, as compared with RGP.

A noteworthy and unforeseen property of KDM35 was the reduced black pigmentation. The characteristic black colonies of P. gingivalis on blood agar is thought to be caused by accumulation of heme. The ability to utilize heme and heme-containing compounds has also been found in several pathogenic microorganisms (50). Black pigmentation of colonies by heme accumulation, however, is known in limited bacterial species in the genera Porphyromonas and Prevotella. Although this property is thought to be related to virulence of P. gingivalis (51), it is not yet clear how P. gingivalis cells acquire heme from erythrocytes and other host components. Recently, Fujimura et al. (34) isolated the 19-kDa hemoglobin-binding protein from the envelope of P. gingivalis by affinity chromatography. Then we found that the 19-kDa hemoglobin-binding protein was encoded by internal domain regions (e.g. HGP15 in rgp1) of multiple genes: rgp1, kgp, and hagA (32). We proposed renaming the hemoglobin-binding protein the hemoglobin receptor (HbR) domain protein. In addition, we found that nonpigmented mutants (BE1 and BR1) isolated from P. gingivalis W50 did not express the HbR domain protein and showed deficiency in hemoglobin adsorption, which indicated a close relationship among HbR production, hemoglobin adsorption, and pigmentation of P. gingivalis. P. gingivalis W50 BE1 also showed reduced virulence in mouse infection model, a decrease in trypsin-like proteinase production, and loss of hemagglutination (45, 51). The HbR domain protein is likely to be generated by proteolytic processing of the polyproteins from rgp1, kgp, and hagA. The HbR protein has a Lys residue at the carboxyl terminus, indicating involvement of KGP in this cleavage. Immunoblot analysis with anti-HbR antiserum revealed that KDM35 growing on the laked blood agar for 3 days had no proteins immunoreacted with the antiserum, whereas the kgp+ sibling strain KDM16 showed an immunoreactive 19-kDa protein band. The results suggest the contribution of KGP to the production of the HbR domain protein. However, the HbR protein was produced in the cells of the KGP-deficient mutant after prolonged incubation. This slow expression of the HbR domain protein of KDM35 might account for its reduced pigmentation. Why was the 19-kDa HbR domain protein detected in KDM35 after prolonged incubation? It could be explained by the fact that the carboxyl-terminal processing of the HbR domain protein in the KDM35 might be done in a much slower mode by an unknown proteinase. The proteinase should not be specific for Lys-X, because the KGP-deficient mutant showed no lysine-specific proteinase activity. Molecular mass of the HbR protein expressed in the KGP-deficient mutant was almost the same as those of the wild-type strain and KDM16. Therefore, the cleavage site by the unknown proteinase should be very close to the carboxyl-terminal Lys residue. Another possibility is that some of the HbR domains in the rgp1 and hagA genes of strain ATCC33277 may possess a different residue such as Arg at the carboxyl terminus because the nucleotide sequences of these genes of the strain have not been determined. Furthermore, we cannot rule out the possibility of the presence of another anti-HbR cross-reactive protein with a molecular mass of 19-kDa that might be expressed after prolonged incubation on blood agar plates.

The final characterization of the KGP-deficient mutant KDM35 was the association of KGP with the fibrinogenolytic activity. Fibrinogen is a major component of the coagulation cascade. Upon cleavage by thrombin, fibrin monomers polymerize and form a meshwork that traps platelets and blood cells. Although the culture supernatants of the wild-type strain and the RGP-null mutant extensively degraded all of the chains of fibrinogen, that of the KGP-deficient mutant showed a marked decrease in their degradation (especially the gamma  chain). It has been demonstrated that the fibrinogen Aalpha chain is rapidly degraded by both Arg-X- and Lys-X-specific cysteine proteinases from P. gingivalis and that Lys-X-specific cysteine proteinase(s) is a much more potent fibrinogenolytic enzyme than Arg-specific cysteine proteinase(s) (46-48). Our data in this report are also consistent with these observations. The intense fibrinogenolytic activity of KGP appears to render fibrinogen unclottable and may contribute to a propensity for bleeding in periodontal pockets of periodontitis patients. This may therefore represent another virulence that facilitates the bacterial survival and invasion of host tissues.

    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ Research Fellow of the Japan Society for the Promotion of Science.

parallel To whom all correspondence should be addressed. Tel.: 81-92-642-6339; Fax: 81-92-642-6342; E-mail: kyama{at}dent.kyushu-u.ac.jp.

The abbreviations used are: RGP, Arg-gingipain; CL, chemiluminescence; KGP, Lys-gingipain; MCA, 4-methyl-7-coumarl-amide; PBS, phosphate-buffered saline; PMN, polymorphonuclear leukocyte; kbp, kilobase pair(s); bp, base pair.

2 T. Kadowaki, K. Nakayama, F. Yoshimura, K. Okamoto, and K. Yamamoto, submitted for publication.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

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