Variable Carbohydrate Modifications to the Catalytic Chains of the RgpA and RgpB Proteases of Porphyromonas gingivalis W50

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Infection and Immunity, August 1999, p. 3816-3823, Vol. 67, No. 8
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Variable Carbohydrate Modifications to the Catalytic Chains of the RgpA and RgpB Proteases of Porphyromonas gingivalis W50

Michael A. Curtis,¹^,^* Andrea Thickett,¹ Jennifer M. Slaney,¹ Minnie Rangarajan,¹ Joseph Aduse-Opoku,² Philip Shepherd,² Nikolay Paramonov,¹ and Elizabeth F. Hounsell³

MRC Molecular Pathogenesis Group, Department of Oral Microbiology, St. Bartholomew's and the Royal London School of Medicine and Dentistry, Queen Mary and Westfield College, London E1 2AA,¹ Department of Immunology, United Medical and Dental Schools, London SE1 9RT,² and Department of Biochemistry and Molecular Biology, University College London, London WC1E 6BT,³ United Kingdom

Received 7 December 1998/Returned for modification 9 March 1999/Accepted 4 May 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Proteases of Porphyromonas gingivalis are considered to be important virulence determinants of this periodontal bacterium.Several biochemical isoforms of arginine-specific proteases arederived from rgpA and rgpB. HRgpA is a heterodimer composed ofthe catalytic $alpha$ chain noncovalently associated with a $beta$ adhesinchain derived from the C terminus of the initial full-length translationproduct. The catalytic $alpha$ chain is also present as a monomer (RgpA)either free in solution or associated with membranes. rgpB lacksthe coding region for the adhesin domain present in rgpA and yieldsonly monomeric forms (RgpB) which again may be soluble or membraneassociated. In this study, the catalytic chains of this unusualgroup of enzymes are shown to be differentially modified by theposttranslational addition of carbohydrate. A monoclonal antibody(MAb 1B5) raised to the monomeric RgpA did not react with thecorresponding recombinant RgpA $alpha$ chain expressed in Escherichiacoli but was immunoreactive with P. gingivalis lipopolysaccharide.MAb 1B5 also reacted with the membrane-associated forms of RgpAand RgpB but not with the heterodimeric HRgpA and the solubleform of RgpB. RgpA treated with denaturants was capable of bindingto MAb 1B5 whereas treatment with periodate abolished this binding,suggesting the presence of carbohydrate residues within the epitope.Chemical deglycosylation abolished immunoreactivity with MAb 1B5and caused a ~30% reduction in the size of the membrane-associatedenzymes. Monosaccharide analysis of HRgpA and RgpA demonstrated2.1 and 14.4%, respectively, carbohydrate by weight of protein.Furthermore, distinct differences were detected in their monosaccharidecompositions, indicating that these protease isoforms are modifiednot only to different extents but also with different sugars.The variable nature of these additions may have a significanteffect on the structure, stability, and immune recognition ofthese proteaseglycoproteins.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The irreversible tissue destruction which is characteristic of the destructive periodontal diseases is considered to be aconsequence of the reaction by a susceptible host to a complexand variable microbial challenge presented by the subgingivalplaque. Porphyromonas gingivalis, an anaerobic, gram-negativebacterium, is frequently isolated from the subgingival plaqueof periodontal patients and is thought to be an important etiologicalagent in these conditions (28, 46). P. gingivalis producesseveral extracellular proteolytic enzyme activities with differentpeptide bond specificities which have a number of in vitro propertiesconsistent with a role in the periodontal disease process (11).These include deregulatory effects on plasma cascades (21, 35,49) and the specific and innate host defenses (45, 51),activation of matrix metalloproteases (13), degradation of connectivetissue components (22), and interference with host cell function(37). Many of these actions have been shown to be a functionof the activity of P. gingivalis proteases with specificity forArg-x peptide bonds, and therefore there is some justificationfor regarding these enzymes as important virulence determinantsin the periodontaldiseases.

The extracellular Arg-x protease activity of P. gingivalis W50 is composed of three enzyme species (HRgpA, RgpA, and mt-RgpA),all derived from rgpA. These designations replace our earliernomenclature of RI, RIA, and RIB, all derived from prpR1 (1,10, 41). HRgpA is a heterodimer in which the catalytic $alpha$ chain(M_r ~ 54,000) is noncovalently associated with an adhesin chain( $beta$ ), derived from the initial RgpA translation product, whichis capable of mediating binding to the erythrocyte surface andhost macromolecules. RgpA is the free monomeric catalytic chain,and membrane-type RgpA (mt-RgpA) is a highly posttranslationallymodified form of this chain (M_r ~ 70,000 to 80,000) which is exclusivelyassociated with the membrane fraction (1, 10, 41). Twoadditional proteases with Arg-x specificity, RgpB and mt-RgpB(formerly RIIA and RIIB), were detected in the culture supernatantof an rgpA isogenic mutant of P. gingivalis W50 (42). Thesetwo forms, which closely resemble the monomeric proteases derivedfrom rgpA, are produced from a second gene, rgpB (prR2), whichlacks the coding region for the adhesin chain. RgpB and mt-RgpBmay correspond to proteases which are normally cell associatedin the wild-type strain W50. These enzymes have not been demonstratedin the culture supernatants of strainW50.

Analysis of the structures and properties of the RgpA and RgpB proteases of P. gingivalis has provided some insights intothe molecular survival strategies adopted by an organism whosesole ecological site in the oral cavity is the microbial biofilmin the hostile environment of an inflamed periodontal pocket.For example, these enzymes have been described as extremely efficientC3 and C5 convertases whose activity leads to the fluid-phaseinactivation of these key components of the host's defensive armory(51). Furthermore, while a primary function of the $beta$ componentof the HRgpA heterodimer may be to target the action of this isoform(39), analysis of the antibody response to this protease inhumans or experimental animal models indicates that the $beta$ componentmay also have a role in subversion of the very significant, specificimmune response of the colonized host (10, 17, 23). Shieldingthe catalytically active component of the molecule with a highlyimmunogenic protein partner may effectively divert the antibodyresponse from regions of the molecule directly involved in proteolysis.A similar strategy has been described for Trypanosoma cruzi, inwhich a long C-terminal extension to the catalytic domain of thecysteine protease, cruzipain, has been suggested to perform thisrole (31).

In this work, we wished to extend our previous immunochemical investigations (8, 10) to examine the structure and immunogenicityof each of the RgpA and RgpB proteases by the development of monoclonalantibodies (MAbs) to the catalytic chain of each of these enzymes.To avoid complications arising from the immunogenicity of the $beta$ component of HRgpA, these experiments were performed with thesingle-chain RgpA isoform. The results of the study demonstratethe presence of immunogenic, covalently linked carbohydrate additionsto the catalytic chain of some of the enzymes of this family ofproteases. Glycosylation of these bacterial proteins may havean influence on the stability of not only the resulting glycoconjugatebut also their immunerecognition.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacteria and growth conditions. P. gingivalis W50 and W501 (rgpA) were cultured in brain heart infusion-hemin medium (34, 41) or blood agar base containing5% defibrinated horse blood in an atmosphere of N₂, H₂, and CO₂(80:10:10; Don Whitley anaerobic work station). Escherichia coliXL-1 Blue MRF' (Stratagene) and M15(pREP4) (Qiagen) were grownin Luria-Bertani (44) medium. If required, tetracycline wasadded to 20 µg/ml. In E. coli, plasmids were selected by incorporationof ampicillin (50 µg/ml) for pUC (53), pJF119 (16), and pGEX-derivedconstructs (Pharmacia) or kanamycin (25 µg/ml) for pREP4 (Qiagen).Plasmids were purified by the method of Clark-Curtiss and Curtiss(6) or by ion-exchange chromatography using Qiagentips.

Generation of recombinant RgpA proteins. A region containing the catalytic $alpha$ domain of RgpA was expressed in E. coli as an N-terminal polyhistidine (His₆) fusion proteinto facilitate purification. Plasmid KpL is a subclone of the originalrgpA clone, pJM2 (1), and contains the coding region for RgpAM1-T949. An internal fragment of the pKpL insert, correspondingto the coding region for RgpA G149-S737, was excised by SmaI/BamHIrestriction digestion and blunted with Klenow DNA polymerase.Following gel purification, the 1,764-bp fragment was cloned intothe SmaI site of the multiple cloning site of pQE30 under controlof the Tn5 promoter (Qiagen) in E. coli XL-1 Blue to generatepQ3010. For expression of the recombinant protein, pQ3010 wasused to transform E. coli M15, which harbors pREP4 containinglacI.

Variable levels of expression of the recombinant protein were obtained with this system. As an alternative, the entire codingregion for the fusion protein, including the ribosome bindingsite and the ATG initiation codon, was removed from pQ3010 byrestriction digestion with EcoRI/SalI and directionally clonedinto pJF119EH (16), which contains lacI^q for tighter control of expression under the tac promoter. Expressionfrom the resulting construct, pJFQ3010, was performed in E. coliXL-1 Blue. A C-terminal His₆ fusion protein of dihydrofolate reductase(DHFR) which was used as a control antigen was expressed frompQE16 (Qiagen) in E. coliM15.

His₆ recombinant proteins were purified under denaturing conditions by nickel chelate chromatography on Ni-nitrilotriaceticacid resin following solubilization of the cells in 6 M guanidine-HClas instructed by the manufacturer (Qiagen). Correct identity ofthe resulting homogeneous protein preparation was confirmed byN-terminal sequence analysis of the first 20 residues as previouslydescribed (41). Throughout this report, the His₆-RgpA fusionprotein is referred to as recombinant RgpA $alpha$ component (rec RgpA $alpha$ ).

An internal region (D784 to V1130) of the $beta$ domain of RgpA was expressed as a glutathione S-transferase (GST) N-terminal fusionprotein in Spodoptera frugiperda (Sf9 insect cell line) via baculovirustechnology and was purified by affinity chromatography on glutathione-agaroseby using methods to be described elsewhere (8a). This is referredto as recombinant RgpA $beta$ component (rec RgpA $beta$ ). Recombinant GSTwas expressed from pGEX-3X (Pharmacia) in E. coli XL-1Blue.

P. gingivalis W50 proteases and LPS purifications. HRgpA, RgpA, and mt-RgpA proteases were purified from the culture supernatant of P. gingivalis W50 as previously described(41). RgpB and mt-RgpB proteases were prepared in a similarmanner from the culture supernatant of an isogenic rgpA (prpR1)mutant of P. gingivalis W50 (W501), again as described previously(42). Lipopolysaccharide (LPS) from P. gingivalis W50 was preparedby the method of Darveau and Hancock (12), and purity was determinedvia sodium dodecyl sulfate-polyacrylamide gel electrophoresis(SDS-PAGE) followed by silver staining (52).

MAb production. Female BALB/c mice were immunized intraperitoneally and intramuscularly with 10 µg of P. gingivalis W50 RgpA emulsified withFreund's incomplete adjuvant on three occasions at 4-week intervals.After a further 4 weeks, and 3 days prior to fusion, the micewere boosted with a further 10 µg of RgpA intravenously. Hybridomaswere raised as described by Kohler and Milstein (24). Hybridculture media and reagents were described previously (8). TheNSI/Ag4.1 mouse myeloma cell line was used as the fusion partnerand was grown in spinner cultures in RPMI 1640 (Bethesda ResearchLaboratories) plus 10% fetal calf serum (FCS) at 37°C in a 5%CO₂ atmosphere and maintained in log-phase growth prior to fusionwith spleen cells in a 1:3ratio.

A two-stage screening approach was used for the detection of MAbs to the peptide chain of RgpA. The initial screen used anRgpA enzyme-linked immunoabsorption assay (ELISA) to determinewhich culture supernatants contained antibody reactive with theimmunizing antigen. Positive hybridomas were maintained in culture,and the supernatants were then screened by ELISA for antibodyreactive with RgpA, rec RgpA $alpha$ , rec RgpA $beta$ , P. gingivalis W50LPS, and the two control proteins, His₆-DHFR andGST.

Ninety-six-well flat-bottomed microtiter plates were coated with P. gingivalis RgpA (5 µg/ml; 100 µl/well) and incubated for4 h at room temperature. After the antigen was removed and theplates were washed with 0.5 mM sodium carbonate buffer (pH 9.6)blocking with 1% FCS proceeded for a further 2 h. The remainingantigen plates were prepared in the same way. Tissue culture supernatantsfrom wells containing hybridomas were added to the wells (100µl/well) of the screening assay plates and incubated for 2 h.Following washing of the plates with Tris-buffered saline-Tween20 (0.5%), 100 µl of alkaline phosphatase-conjugated goat anti-mouseimmunoglobulin G antibody (1:5,000) in RPMI plus 1% FCS was addedand incubated for 1 h. Bound secondary antibody was detected byusing p-nitrophenyl phosphate, and color development was monitoredat 405 nm. Positive binding was taken as twice the normal backgroundvalue of RPMI 1640 control wells on each antigen plate. Hybridomasthat gave strong signals by ELISA were then cloned by limit dilutionand retested against the panel ofantigens.

PAGE and immunochemistry. PAGE in the presence of SDS (25) was carried out at 5°C in 7.5 or 12.5% (wt/vol) polyacrylamide slab gels. Samples of protease(10 to 20 µg) were first treated with 50 µl of leupeptin (1 mM)at 25°C for 20 min, heated at 100°C for 5 min, and dried in vacuo.PAGE in the presence of 8 M urea at pH 8.8 in 7.5% (wt/vol) slabgels was carried out as described by Marshall and Inglis (30).Western immunoblotting was performed following electroblottingonto nitrocellulose. N-terminal amino acid sequencing was performedfollowing electroblotting of proteins onto polyvinylidene difluoridemembranes. The rabbit antiserum to P. gingivalis W50 whole cellshas been described previously (10).

Denaturant treatment of RgpA. Samples of RgpA (10 µg) in sodium acetate buffer (0.2 M, pH 5.3) were incubated for 60 min in 6.4 M urea (55°C), 3.3% SDS(55°C), or 75% formic acid (22°C). The formic acid-treated RgpAwas evaporated to dryness to remove the acid, and then aliquotsof all samples (corresponding to 0.5 µg of RgpA) were subjectedto SDS-PAGE and Western blotting onto nitrocellulose. For periodateoxidation, leupeptin-inhibited RgpA (0.5 µg) was subjected toSDS-PAGE, and electroblotted onto nitrocellulose, and the blotswere then incubated in 1% periodic acid-7% acetic acid in thedark at 4°C. Leupeptin-inhibited RgpA acted as thecontrol.

Biotinylation of glycosylated proteins. The presence of covalently linked carbohydrate on individual proteases was determined by periodate oxidation at pH 5.5 followedby treatment with biotin hydrazide to biotinylate any resultantfree aldehyde groups. Biotinylation of the proteases was thendetected with streptavidin conjugated to alkaline phosphatasefollowing Western blotting onto polyvinylidene difluoride membranes.Control samples were treated identically except that the periodateoxidation step was omitted. All procedures were performed as instructedby the manufacturer of the Glycotrack carbohydrate detection system(Oxford GlycoSystems, Abingdon, UnitedKingdom).

Deglycosylation procedures. Proteases were treated with peptide-N4-(N-acetylglucosaminyl) asparagine amidase (PNGase F; Genzyme) to hydrolyze any asparagine-linkedoligosaccharides at the $beta$ -aspartylglycosylamine bond between theinnermost N-acetylglucosamine and asparagine residue. The proteases(1 mg/ml) were first denatured by heating at 100°C for 5 min in0.5% SDS. Hydrolysis was performed for 18 h in Tris-HCl (50 mM,pH 8.0)-EDTA (50 mM)- $beta$ -mercaptoethanol (50 mM). CHAPS {3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonatenonionic detergent was added to 2.5% (wt/vol) to protect the PNGaseF from SDS denaturation. Ovalbumin was used as a positive control.The removal of susceptible asparagine-linked oligosaccharide wasthen determined by examining the mobility of the treated proteaseson SDS-PAGE and by Western blotting using MAbs to the carbohydrateadditions.

Proteases RgpA and mt-RgpA were subjected to chemical deglycosylation using a GlycoFree TM deglycosylation kit (Oxford GlycoSystems).The enzymes were first treated with anhydrous trifluoromethanesulfonic acid (TFMS), which effectively cleaves N- and O-linkedglycans nonselectively from glycoproteins, leaving the primarystructure of the protein intact. Toluene was used as a scavengerspecies to neutralize reactive groups formed during the deglycosylationreaction. Excess TFMS was later neutralized by reaction withpyridine.

Monosaccharide analysis of HRgpA and RgpA. HRgpA (0.2 mg) and RgpA (0.2 mg) proteases were dialyzed against 5% (vol/vol) aqueous acetic acid to remove salts and detergentsand were then freeze-dried. Dulcitol (10 µg) was added to eachprotease sample, and the mixture was subjected to methanolysisin 200 µl of 0.5 M solution of HCl in methanol (Supelco, Bellefonte,Pa.) at 85°C for 4.5 h. After removal of excess methanolic-HClunder vacuo, the mixture was N-acetylated in a mixture of 200µl of methanol, 25 µl of pyridine, and 25 µl of acetic anhydrideat 22°C for 30 min. After removal of reagents under vacuo, themonosaccharides were analyzed by GC-MS (gas chromatography-massspectrometry) following derivatization to their O-trimethylsilyl(O-TMS) ethers (20). The relative molar response factors foreach monosaccharide with respect to dulcitol were calculated fromanalysis of standardmonosaccharides.

Release of oligosaccharides by $beta$ elimination. O-linked oligosaccharides in HRgpA and RgpA were released from the protein by treatment with 1 M NaBH₄ (sodium borohydride)in 50 mM NaOH at 50°C for 16 h essentially as described by Lechnerand Wieland (27). Oligosaccharides were separated by high-pressureliquid chromatography (HPLC) on a porous graphitized carbon (PGC)column (Shandon, Runcorn, Cheshire, United Kingdom), using a gradientof acetonitrile from 0 to 40% (vol/vol) in 0.1% trifluoroaceticacid in water. The absorbance of column effluent was monitoredat 210nm.

Release of oligosaccharides by hydrazinolysis and 2-AB (2-aminobenzamide) labelling. The monosaccharides present were confirmed after release of the oligosaccharides from the proteases by hydrazinolysis andtheir analysis by GC-MS of O-TMS ethers of methylglycosides.

Salt- and detergent-free solutions of proteases HRgpA (0.8 mg) and RgpA (0.15 mg) were dried in vacuo and then dried in adesiccator over P₂O₅ overnight. Hydrazinolysis of proteases wasperformed at 60°C for 4 h to release O-linked chains, using anOxford GlycoSystems kit, and at 95°C for 4 h to release O- andN-linked chains. Released oligosaccharides were labelled with2-AB according to the kit manufacturer'sinstructions.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Antigens. High yields of rec RgpA $alpha$ were attained both from pQ3010 in E. coli M15(pREP4) and from JFQ3010 in E. coli XL-1 Blue. Therecombinant protein was enzymatically inactive, in keeping withour previous experience of heterologous expression of this genein E. coli (1). However, significant reductions in recombinantprotein expression by these clones were observed following resuscitationof frozen stocks, and hence all purifications were performed onpreparative scale batches of newly transformed cells. RecombinantRgpA $alpha$ is composed of RgpA G149-S737, which incorporates the $alpha$ domain of RgpA (Y228 to R719) and an N-terminally truncated propeptideregion (G149 to R227), as well as some vector-derived sequenceswhich mainly consist of the N-terminal His₆ purification tag.Hence the molecular weight of the rec RgpA $alpha$ (67,700) is significantlyhigher than that of the wild-type P. gingivalis RgpA. The immunizingantigen for the MAb protocol (RgpA) and the screening antigensrec RgpA $alpha$ , DHFR, and P. gingivalis W50 LPS are shown in Fig.1.

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FIG. 1. P. gingivalis W50 and recombinant antigens used in the MAb protocol and the specificity of MAb 1B5. Samples (2 µg) in lanes 1 to 4 were subjected to PAGE on an SDS-12.5% polyacrylamide gel and stained with Coomassie blue (lanes 1 to 3) or silver (lane 4). Lanes: 1, rec RgpA $alpha$ ; 2, DHFR; 3, P. gingivalis RgpA; 4, P. gingivalis LPS. Lanes 5 to 7, Western blot probed with MAb 1B5 of P. gingivalis RgpA (lane 5), rec RgpA $alpha$ , and P. gingivalis LPS, respectively.

MAbs to RgpA are LPS reactive. A total of six myeloma cell-spleen cell fusions were performed, and similar results were generated on each occasion. A consistentfinding was that hybridoma supernatants which were positive inthe primary and secondary screen ELISAs for antibody to P. gingivalisRgpA were negative in rec RgpA $alpha$ ELISAs. For example, in Pg10fusion, a total of 14 hybridoma supernatants contained antibodyreactive with RgpA by ELISA in the primary screen. Of these, sixproved stable to long-term culture. In the secondary screen, allsix were still strongly positive in the RgpA ELISA but none werereactive with rec RgpA $alpha$ . Significantly, however, all of theseRgpA hybridomas were also strongly positive in the P. gingivalisW50 LPS ELISA. Throughout the six fusions, we did not obtain asingle hybridoma which produced antibody reactive with the recRgpA $alpha$ . One of the Pg10 hybridomas (1B5) which was positive forboth P. gingivalis RgpA and LPS was selected for further studyand cloned by limit dilution. Subsequent isotyping demonstratedthat MAb 1B5 is an immunoglobulinG2a.

To establish whether MAb 1B5 was reacting with contaminating LPS in the RgpA preparation, Western blots of RgpA, rec RgpA $alpha$ , and LPS on nitrocellulose membranes were probed with this MAb(Fig. 1, lanes 5 to 7). MAb 1B5 reacted with a single band inthe RgpA preparation coincident with the position of the proteinband. No other immunoreactive components were present, suggestingthat MAb 1B5 recognizes a determinant on RgpA which is not dissociatedby SDS-PAGE. As predicted from the ELISA data, MAb 1B5 was immunoreactivewith multiple bands in the P. gingivalis LPS preparation but didnot recognize the rec RgpA $alpha$ .

MAb 1B5 determinant on RgpA is periodate sensitive and stable to denaturants. To determine whether the MAb 1B5 determinant on P. gingivalis RgpA represents a covalent modification, the stability of theimmunoreactivity to denaturing conditions was examined (Fig. 2).The results were compared to the immunoreactivity of identicalsamples with rabbit P. gingivalis whole-cell antiserum which recognizesboth the LPS and peptide chain of RgpA. There was no significantreduction in the immunoreactivity of MAb 1B5 with RgpA which hadbeen treated with SDS or formic acid. Similar results were obtainedwith samples treated with 6.4 M urea or 6 M guanidine-HCl for60 min at 55°C (not shown). However, following periodate oxidationof RgpA, there was a significant reduction in the immunoreactivitywith MAb 1B5 but no change in the reactivity with whole-cell antiserum.Together with the results presented above, these data stronglysuggest that the peptide chain of RgpA is covalently modifiedwith periodate-sensitive carbohydrate residues which are commonto the LPS of this organism. We have previously suggested thatcovalent modification of the $alpha$ chain of mt-RgpA with carbohydratecommon to the LPS of P. gingivalis accounted for the increasedsize of this enzyme on SDS-PAGE (10, 41). The modificationsto RgpA and mt-RgpA were then further investigated by biotinylationof periodate-oxidized proteases, using biotin hydrazide.

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FIG. 2. Effects of denaturants on immunoreactivity of P. gingivalis RgpA with MAb 1B5. P. gingivalis RgpA was treated with leupeptin (control; lane 1), 3.3% SDS (lane 2) or 75% formic acid (lane 3) as described in the text and then subjected to PAGE on a SDS-12.5% polyacrylamide gel prior to Western blotting. For periodate treatment (lane 4), leupeptin-inhibited RgpA was first subjected to SDS-PAGE and electroblotted onto nitrocellulose; the blots then treated with 1% periodic acid in 7% acetic acid. Immunoreactivities with anti-P. gingivalis whole-cell antiserum (A) and MAb 1B5 (B) are shown.

Proteases RgpA and mt-RgpA of P. gingivalis are glycoproteins. The two proteases were labelled in solution with biotin hydrazide following pretreatment with periodate or buffer control.The extent of labelling was then determined by using streptavidinconjugated to alkaline phosphatase. Significant periodate-dependentbiotin labelling of both RgpA and mt-RgpA was detected with thissystem, with a lower limit of detection of approximately 75 ngof each enzyme (Fig. 3). However, we were unable to detect periodate-sensitivecarbohydrate residues on either chain of the heterodimeric HRgpAprotease of P. gingivalis by this method (not shown). We thereforeexamined the MAb 1B5 immunoreactivity of all of the arginine-specificproteases derived from rgpA and rgpB of this organism in orderto establish whether the glycosylation process occurs selectively.

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FIG. 3. Detection of carbohydrate modifications to RgpA and mt-RgpA by using biotin hydrazide labelling following periodate oxidation. Increasing amounts (75, 150, and 300 ng) of RgpA (A) and mt-RgpA (B) were incubated with (lanes 1 to 3) and without (lanes 4 to 6) periodate prior to labelling with biotin hydrazide. Samples were then subjected to electrophoresis, and bound biotin was detected with streptavidin-alkaline phosphatase. The greater incorporation of biotin in the periodate-treated samples in lanes 1 to 3 than in lanes 4 to 6 reflects the presence of periodate-sensitive carbohydrate residues on RgpA and mt-RgpA.

MAb 1B5 reacts differentially with the isoforms of the RgpA and RgpB proteases. The MAb 1B5 reaction with HRgpA, RgpA, and mt-RgpA from the culture supernatant of P. gingivalis W50 and with RgpB and mt-RgpBfrom the supernatant of strain W501 (rgpA) was assessed by Westernblot analysis (Fig. 4). RgpA and the two highly modified proteasesmt-RgpA and mt-RgpB reacted very strongly with this MAb. However,there was no immunoreactivity with HRgpA or RgpB. Identical results(not shown) were obtained with two other MAbs (6B3 and 7B4) whichwe have shown previously to be reactive with P. gingivalis LPS(8, 10).

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FIG. 4. Immunoreactivity of the isoforms of the RgpA and RgpB proteases with MAb 1B5 HRgpA (lane 1), RgpA (lane 2), mt-RgpA (lane 3), RgpB (lane 4), and mt-RgpB (lane 5) (2 µg of each) were run on an SDS-12.5% polyacrylamide gel and stained with Coomassie blue (A) or Western blotted and reacted with MAb 1B5 (B).

Deglycosylation of RgpA and mt-RgpA. Chemical deglycosylation of RgpA by using TFMS did not result in a discernible decrease in the molecular mass compared tothe untreated enzyme on SDS-PAGE. However, mt-RgpA, which normallyruns as a diffuse heterogeneous band of 70 to 80 kDa, showed adramatic decrease in molecular mass to ~54 kDa, the molecularmass of RgpA (Fig. 5A). This finding suggests that mt-RgpA containsapproximately 20 to 30% (by weight) carbohydrate. As expected,the immunoreactivity of RgpA and mt-RgpA with MAb 1B5 and MAb7B4 was completely abolished following deglycosylation with TFMS,while significant reactivity with the anti-whole-cell antiserum,which recognizes epitopes in the peptide chain, was maintained(Fig. 5B to D).

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FIG. 5. Effect of TFMS deglycosylation on SDS-PAGE mobility and immunoreactivity of RgpA (upper panels) and mt-RgpA (lower panels). Untreated (lanes 1) or TFMS-treated (lanes 2) proteases were run on SDS-12.5% polyacrylamide gels and stained with Coomassie blue (A) or Western blotted and developed by using anti-P. gingivalis whole-cell antiserum (B), MAb 1B5 (C), or MAb 7B4 (D).

Treatment of RgpA and mt-RgpA with PNGase F failed to alter the molecular weights of these two enzymes on SDS-PAGE and didnot affect their immunoreactivity with MAb 1B5 (not shown). Asn-linkedglycans representing all major eucaryotic oligosaccharide classesare hydrolyzed by PNGase F (29), which releases the oligosaccharidewith an amino group attached, while the Asn in the protein isconverted to Asp. Asn-linked oligosaccharides containing an $alpha$ (1 $right-arrow$ 6)-fucosesubstituent on the Asn-proximal N-acetylglucosamine residue areeasily hydrolyzed, but the corresponding $alpha$ (1 $right-arrow$ 3)-fucose substituentfound in plant glycoproteins completely blocks deglycosylation(50). RgpA may not contain Asn-GlcNAc linkages, or there maybe substituents on GlcNAc which block deglycosylation by PNGaseF.

Relationship of the $alpha$ chains of HRgpA, RgpA, and mt-RgpA. Although the catalytic component of HRgpA and RgpA are both derived from the $alpha$ coding region of rgpA, the presence of theMAb 1B5 determinant only on RgpA suggested that the $alpha$ chains ofthese two enzymes may be resolved by electrophoretic separationsbased on properties other than size. This was examined by usingurea-PAGE, which separates peptides based on the charge/size ratioand which we have used previously to separate the $alpha$ and $beta$ componentsof HRgpA (41). Based on migration patterns on these gels (Fig.6), RgpA appears to be significantly more negatively charged thanthe $alpha$ component of HRgpA. However, this charge difference doesnot appear to be a direct consequence of the glycan modificationsto RgpA, since deglycosylation of RgpA with TFMS did not affectits mobility. Hence, the difference in mobilities of HRgpA andRgpA is more likely due to variation at the C terminus of the $alpha$ chain of these two isoforms. Conversely, the mobility of deglycosylatedmt-RgpA on 8 M urea-PAGE was identical to that of the RgpA samples,suggesting that the only difference between these two monomericspecies is the extent of glycan addition.

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FIG. 6. Analysis by 8 M urea-PAGE of HRgpA, RgpA, and deglycosylated RgpA and mt-RgpA. Leupeptin-inhibited HRgpA (lane 1) and RgpA (lane 2) and TFMS-treated RgpA (lane 3) and mt-RgpA (lane 4) were subjected to 8 M urea-PAGE in 7.5% acrylamide gels and then stained with Coomassie blue. Arrows indicate positions of the $alpha$ and $beta$ chains of HRgpA.

Analysis of carbohydrate in HRgpA and RgpA. The monosaccharide composition of proteases HRgpA and RgpA was determined after consecutive methanolysis, N-acetylation, andconversion of N-acetyl-O-methyl glycosides to O-TMS ethers followedby GC-MS. RgpA contained Ara, Rha, Fuc, Man, Gal, Glc, GalN(Ac),GlcN(Ac), and N-acetylneuraminic acid (NANA) totalling 14.4% byweight of protein. HRgpA contained Rha, Man, Gal, Glc, GalN(Ac),and GlcN(Ac) (i.e., lacking Ara, Fuc, and NANA) totalling 2.1%by weight of protein. The molar ratios of monosaccharides areshown in Table 1. The presence of these monosaccharides was alsoconfirmed after release of several O-linked oligosaccharides fromthe proteases by $beta$ elimination and analysis by methanolysis aspreviously described. The sugar which is covalently linked toSer/Thr residues in proteins is reduced to its corresponding alditolduring the $beta$ -elimination reaction. This gives a characteristicGC retention time and MS fingerprint for each monosaccharide.Figure 7 shows the GC total ion chromatogram of monosaccharidesfrom an O-linked oligosaccharide released from RgpA by $beta$ eliminationand purified by HPLC on a PGC column. This shows that GalN(Ac)is the monosaccharide linked to Ser/Thr in RgpA, as it occursas its alditol (Fig. 7, peak 6). In addition to confirming thatmost of the monosaccharides detected previously are released by $beta$ elimination, these data also indicate that the sugars in RgpAare present predominantly in O-linked chains (results not shown).However, Ara was detected only in oligosaccharides released byhydrazine under extremely harsh conditions (95°C for 4 h), whichsuggests it is present in N-linked oligosaccharide (results notshown). A control sample of RgpA (0.2 mg) which was not treatedwith hydrazine but directly labelled with 2-AB followed by subsequentpurification and derivatization for GC-MS did not reveal the presenceof any monosaccharides.

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TABLE 1. GC-MS analysis of O-TMS ethers of methyl glycosides showing the molar ratios of monosaccharides in the oligosaccharides of HRgpA, RgpA, and LPS of P. gingivalis W50 after methanolysis

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FIG. 7. GC total-ion chromatogram of the O-TMS ethers of methyl glycosides of monosaccharides from an O-linked oligosaccharide released from RgpA by $beta$ elimination. Peaks: 1 to 3, Gal; 4 and 5, Glc; 6, GalN(Ac)-ol; 7, GlcN(Ac); 8, NANA. *, no fragmentation ions consistent with monosaccharides were present.

Table 1 also presents the molar ratios of monosaccharides found in the P. gingivalis LPS after methanolysis, N-acetylation,and GC-MS. Rha, Gal, Glc, GalN(Ac), and GlcN(Ac) are all presentin P. gingivalis LPS, but Ara, Fuc, Man and NANA, which are componentsof the oligosaccharides of RgpA, areabsent.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

It is widely acknowledged that most eucaryotic proteins do not exist in a free form but are modified by the covalent attachmentof carbohydrate chains. Glycosylation of a protein can have significanteffects on the intrinsic properties of the resulting glycoproteinby altering the stability, resistance to proteolysis, and tertiarystructure. Furthermore, the large size of oligosaccharides mayallow them to cover functionally important areas of the protein,to modulate the interaction of the glycoconjugate with other molecules,and to affect the rate of processes which involve conformationalchanges. In addition to the modulation of protein function, oligosaccharidesalso serve an important role as recognition markers (14).

The presence of glycoproteins in procaryotes has been demonstrated and accepted only recently. However, there are now numerousexamples of microbial glycoproteins. These include cell wall proteinsin the archaea (32), secreted or cell wall-associated enzymesof clostridia and flavobacteria (18, 33, 43), and proteinsfrom human pathogens involved in interactions with host cell componentssuch as the pilin proteins of pathogenic neisseriae (48) andPseudomonas aeruginosa (5), a platelet aggregation-associatedprotein of Streptococcus sanguis (15), and surface antigensof Mycobacterium tuberculosis (19). Given the importance ofcarbohydrate modifications to protein function, stability, andrecognition, it is highly likely that glycosylation of bacterialproteins is of major relevance to the molecular basis of infectiousdisease processes. An example of this potential involvement wasdescribed recently for Chlamydia trachomatis. The major outermembrane protein of this intracellular pathogen is an N-linkedglycoprotein containing a high-mannose-type oligosaccharide whichwas shown to have a direct role in mediating the attachment andinfectivity of the bacterium to an epithelial cell line (25).

In the present investigation, several lines of evidence suggested that the catalytic chains of the RgpA and RgpB arginine-specificproteases of P. gingivalis undergo variable degrees of glycosylation.MAbs raised to RgpA reacted with the homologous antigen and P.gingivalis LPS but not with heterologously expressed recombinantprotein on Western blots following SDS-PAGE. The periodate sensitivityof the immunoreaction indicated that the epitope contained carbohydrateresidues with cis-hydroxyl groups. To ascertain that the reactivitywas a consequence of covalently linked determinants rather thannonspecific complex formation with LPS, RgpA was subjected toa number of harsh denaturant treatments, all of which failed toinfluence the MAb recognition. Furthermore, the determinants wereremoved from RgpA and mt-RgpA by reaction with anhydrous TMFS,which nonspecifically cleaves the O- and N-linked glycans withoutdestroying the protein. The presence of carbohydrate additionsto RgpA and mt-RgpA was also demonstrated by labelling free aldehydesgenerated by periodate oxidation with biotinhydrazide.

Analysis of HRgpA and RgpA to determine the monosaccharide composition after consecutive methanolysis, N-acetylation, derivatization,and GC-MS showed that HRgpA contained Rha, Man, Gal, Glc, GalN(Ac),and GlcN(Ac) totalling 2.1% by weight of protein, whereas RgpAcontained Ara, Rha, Fuc, Man, Gal, Glc, GalN(Ac), GlcN(Ac) andNANA totalling 14.4% by weight of protein. The constituent monosaccharideswere confirmed by the analysis of oligosaccharides released fromHRgpA and RgpA by $beta$ elimination. Analysis of the subsequentlypurified oligosaccharides by methanolysis and GC-MS unambiguouslyidentified the monosaccharides covalently bound to these enzymes.The released oligosaccharides could be purified by HPLC on a PGCcolumn, and the oligosaccharide-specific reducing end could beidentified as the corresponding alditol. No monosaccharides weredetected in enzyme samples which had not been subjected to hydrazinolysisprior to 2-ABlabelling.

Deglycosylation of RgpA with TFMS does not significantly influence its migration on SDS-PAGE. In contrast, the glycan moietyof mt-RgpA is a major constituent. In earlier reports, we hadsuggested that mt-RgpA of P. gingivalis was a highly glycosylatedform of the RgpA $alpha$ chain principally on the basis of its stainingby the periodic acid-Schiff reagent on SDS-polyacrylamide gels(41). The glycoprotein nature of mt-RgpA was further substantiatedin the present work through its reactivity with the RgpA MAbsand by chemical deglycosylation with TMFS, which reduced the molecularmass of this isoform by approximately 30 kDa to that of an unmodifiedRgpA $alpha$ chain. Hence, RgpA and mt-RgpA are both glycoproteins comprisingthe same RgpA $alpha$ chain with different amounts of glycanaddition.

In contrast to the monomeric forms, the heterodimeric HRgpA, the third isoenzyme product of rgpA, contains less carbohydrate.The lack of recognition of this form by the RgpA and anti-LPSMAbs may be explained by the absence of Ara, Fuc, and NANA inthe carbohydrate moiety. This suggests a difference in glycosylationof the $alpha$ chain of all three enzymes, although all are derivedfrom the same rgpA coding sequence. Ara appears to be presentin the N-linked sugar in RgpA, which could indicate that somesites for glycan addition within the HRgpA isoform are masked.In either case, it is clear that the maturation pathway of rgpA-derivedenzymes contains a critical branch point which determines theglycosylation status of the final products of this gene. We areunable to demonstrate at which stage in the growth of the culturethese processes occur. Throughout, we have used late-stationary-phasecultures in order to maximize extracellular enzymeyields.

Previous analysis of a rgpA isogenic mutant of P. gingivalis W50 had demonstrated the production of two more monomeric Arg-xspecific proteases (RgpB and mt-RgpB) derived from rgpB. On thebasis of their kinetic behavior and charge and mass characteristics,these enzymes appeared almost indistinguishable from RgpA andmt-RgpA, respectively. Thus, mt-RgpB appeared to represent a highlyposttranslationally modified form analogous to mt-RgpA derivedfrom rgpA, and as expected, mt-RgpB was strongly reactive withthe RgpA and LPS MAbs (42). However, the presence of these majormodifications does not appear to be required for membrane associationbecause unmodified RgpB can be isolated from the membrane fractionof P. gingivalis W50/BE1 (7).

RgpB did not appear to contain carbohydrate modifications on the basis of immunochemical recognition. However, RgpB isolatedfrom an rgpA isogenic mutant of P. gingivalis W50 (42) was foundto contain Ara, Rha, Fuc, Gal, Glc, GlcA, and GlcN(Ac) totalling10% by weight of protein, raising the possibility that there maybe glycan additions to the RgpB isoform which are not cross-reactivewith the MAbs used in this investigation. The data in the presentreport are supported by a recent investigation of the structureand activity of RgpB from P. gingivalis H66. Different isoformsof RgpB were detected by chromatofocusing, which the authors suggestedmay reflect variability in a posttranslational addition to thepeptide chain of this enzyme (40). A scheme of the putativeRgpA and RgpB protease maturation pathway based on the findingsof this and earlier studies is shown in Fig. 8.

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FIG. 8. Proposed maturation pathways leading to the generation of five differentially modified enzymes from rgpA and rgpB of P. gingivalis. HRgpA, RgpA, and mt-RgpA are all products of rgpA. The catalytic chain of the monomeric enzymes may be derived either from the translation product of the full-length rgpA transcript or via translation of a truncated transcript. Variable levels of glycan addition then leads to the formation of either RgpA or mt-RgpA. RgpB and mt-RgpB are derived from translation of an rgpB transcript. RgpB may acquire different carbohydrate modifications compared to RgpA. mt-RgpB is glycosylated to a similar extent as mt-RgpA. The rgpA and rgpB loci on the P. gingivalis chromosome are shown as thick bold lines with the direction of transcription denoted by arrows; mRNA transcripts are shown as thin lines below the genes. Rectangular boxes represent the translation products of the genes and are organized into domains corresponding to propeptide (pro), catalytic domain ( $alpha$ ), adhesin domain ( $beta$ ), and C-terminal extension ( $gamma$ ). Sequence differences at the C termini of the $alpha$ domains of RgpA and RgpB are shown by additional shading on RgpB. Triangles denote proteolytic processing sites on the initial translation products. Carbohydrate modifications to the mature enzymes are indicated by circles (for those which contain the MAb 1B5 determinant), squares, and inverted triangles. Carbohydrate symbols can represent single or multiple oligosaccharide side chains and in the case of HRgpA may be present on either chain or both chains. The double-circle symbols on mt-RgpA and mt-RgpB signify the high level (>30%) of posttranslational addition to these two isoforms.

To our knowledge, this is the first report of bacterial glycoproteins in which the glycan addition contains antigenic determinantscommon to the LPS of the organism. The chemical structure of lipidA from P. gingivalis LPS has been determined (36), and lipidA was found to be a glucosamine $beta$ -(1-6)-disaccharide-1-monophosphateacylated by 3-hydroxy-15-methyl hexadecanoic acid and 3-hexadecanoyloxy-15-methylhexadecanoic acid at the 2 and 2' positions, respectively. Inthis work, we have analyzed the monosaccharides present in LPS(Table 1) and shown the presence of Rha, Gal, Glc, GalN(Ac),and GlcN(Ac) and also detected two other sugars which were notpresent in RgpA. Furthermore, analysis of sugars in the core regionof LPS showed the absence of GalN(Ac) and GlcN(Ac). Therefore,RgpA has distinct sugar modifications which could not have arisenfrom LPScontamination.

It is not unprecedented for LPS to play a significant role in the functional stabilization of a gram-negative extracellularprotein. The extracellular hemolysin of pathogenic E. coli (HlyA)purified from culture supernatants has been shown to contain LPSby both chemical and immunological techniques (3, 4, 38),and in strains harboring the hlyCABD operon, mutations in rfaPand rfaC, genes involved in LPS core biosynthesis, result in asignificant reduction in the biological activity of the resultantextracellular HlyA (2, 47). Since chaotropic agents can restorethe hemolytic activity of the culture supernatant HlyA in suchmutants, it has been suggested that association with LPS containinga complete core may be essential for the formation or maintenanceof an active conformation of HlyA, which thereby prevents itsaggregation ordegradation.

The critical distinction between the HlyA-LPS macromolecule and the RgpA and mt-RgpA glycoproteins described in the presentreport lies in the stability of these molecules to denaturingconditions. In the case of HlyA and LPS, the macromolecule isreadily dissociated into its component parts by the sample preparationprocedures routinely used for reducing SDS-PAGE. Conversely, inthe case of RgpA and mt-RgpA, we were unable to remove the glycancomponents with any of the harsh denaturing conditions used exceptfor treatment with anhydrous TFMS, which is a well-establishedprocedure for the removal of covalently attached carbohydratefrom the protein backbone ofglycoconjugates.

Given the importance of glycosylation of eucaryotic proteins to their stability, structure, resistance to proteolysis, andrecognition, the modifications to the proteases described in thisreport are likely to have a functional role in the propertiesof these enzymes. In this regard, it is perhaps relevant thatthe half-life of HRgpA, which appears to carry lower levels ofglycan modifications, is some 50-fold lower than that of bothRgpA and mt-RgpA at pH 8.0 and 30°C (41). Furthermore, in lightof our inability to generate MAbs to the peptide chain of RgpAfollowing immunization with this enzyme, it is possible that theseglycan additions influence the immune recognition of RgpA andmt-RgpA in a manner similar to the way in which the $beta$ chain ofHRgpA diverts the recognition of the catalytic chain of thisisoform.

In conclusion, the data in this report indicate that glycosylation of the catalytic chains of the RgpA and RgpB proteasesis a selective process during the maturation of these enzymes.Ongoing analysis of the biochemical nature and sites of thesemodifications and characterization of the mechanism of additionmay allow the generation of mutants impaired in this system inorder to study the physiological relevance of glycoprotein synthesisin this periodontalpathogen.

	ACKNOWLEDGMENT

This work was supported by the Medical Research Council (grantPG9318173).

	FOOTNOTES

^* Corresponding author. Mailing address: MRC Molecular Pathogenesis Group, Department of Oral Microbiology, St. Bartholomew'sand the Royal London School of Medicine and Dentistry, Queen Maryand Westfield College, 32 Newark St., London E1 2AA, United Kingdom.Phone: 0171 377 0444. Fax: 0171 247 3428. E-mail: M.A.Curtis{at}mds.qmw.ac.uk.

Editor: J. R. McGhee

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