Institute of Infections and Immunity, Queens Medical Centre, University of Nottingham, Nottingham NG7 2UH, UK1
School of Pharmaceutical Sciences, University of Nottingham, University Park, Nottingham NG7 2RD, UK2
SmithKline Beecham Pharmaceuticals, Harlow CM19 5AW, UK3
MRC Molecular Pathogenesis Group, Department of Oral Microbiology, St Bartholomews and the Royal London School of Dentistry, 32 Newark St, London E1 2AA, UK4
Author for correspondence: Paul Williams. Tel: +44 115 9515047. Fax: +44 115 8466296. e-mail: paul.williams{at}nottingham.ac.uk
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ABSTRACT |
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Keywords: Porphyromonas gingivalis, luxS, quorum sensing, gingipains, haemagglutinins
Abbreviations: AHLs, N-acylhomoserine lactones; AI-2, autoinducer 2
a Present address: Alizyme, Granta Park, Great Abington, Cambridge CB1 6GS, UK.
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INTRODUCTION |
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In the periodontal pocket, P. gingivalis is found predominantly as a component of complex biofilms containing multiple bacterial species. As well as a capacity to adhere to a variety of host cell surfaces including the teeth, gingiva, cheek and tongue, P. gingivalis also adheres to other oral bacteria, presumably to facilitate colonization and survival within the oral cavity. P. gingivalis produces multiple cell envelope and exoproduct virulence determinants capable of promoting attachment, degrading host cell tissues and immune effector molecules, acquiring nutrients and facilitating epithelial cell invasion (Holt et al., 1999 ; Kinder & Holt, 1989
; Lamont & Jenkinson, 1998
; Yoneda & Kuramitsu, 1996
). Probably the most intensively investigated P. gingivalis virulence determinants are the exoproteases (Aduse-Opoku et al., 1995
; Kuramitsu et al., 1997
; Nakayama et al., 1995
; Okamoto et al., 1996
). Two major classes of cysteine proteinases specific for Arg-X and Lys-X bonds have been characterized and termed Arg-gingipain (Rgp) and Lys-gingipain (Kgp), respectively (Curtis et al., 1999
). The multiple protease forms present on the P. gingivalis cell surface and in spent culture supernatants arise from the products of three genes: rgpA and rgpB (which encode the Rgp activity) and kgp (which encodes the Kgp activity). The different forms appear to arise from the proteolytic post-translational processing of larger polyprotein precursors (Curtis et al., 1999
). For example, for RgpA, the initial precursor consisting of a pro-region,
-catalytic domain, a ß-adhesin/haemagglutinin domain and a C-terminal
domain is cleaved to generate three mature isoenzyme forms, HRgpA (an
ß-heterodimer of around 110 kDa), RgpAcat (
monomer of approx. 55 kDa) and mt-RgpAcat (a highly post-translationally modified
monomer of 7080 kDa). These proteases degrade a variety of host proteins including immunoglobulins, complement cascade components, collagen, fibrinogen and fibronectin. As a consequence, they not only promote resistance to host defence mechanisms but also generate free amino acids and small peptides for use as nutrients (Shah & Gharbia, 1989
). Furthermore, the haemagglutinin/adhesin domains of RgpA and Kgp share significant amino acid sequence homology with haemagglutinin domain of HagA, a protein containing four contiguous direct repeats each of which contains a functional haemagglutinin domain (Han et al., 1996
). P. gingivalis also possesses four further haemagglutinin genes (hagB, hagC, hagD and hagE; Lépine et al., 1996
), and the ability to agglutinate erythrocytes strongly is a feature which distinguishes the organism from other black-pigmented anaerobes (Mayrand & Holt, 1988
). Although the functions and contribution of these multiple haemagglutinins to virulence are not well understood, they clearly promote adherence and colonization of tissue surfaces and, in conjunction with the exoproteases, promote attachment and detachment to target human cells (Chen et al., 2001
).
To facilitate adaptation to life within the oral cavity, P. gingivalis must be capable of sensing and responding to the prevailing environmental conditions, including variations in temperature, oxygen tension, pH, nutrient availability and the presence of other cells. While there is relatively little information on the mechanisms by which gene expression is regulated in this strict anaerobe, it is clear that the levels of virulence factors such as the proteases, fimbriae and haemagglutinins are controlled by temperature and haemin availability and affected by the presence of serum and saliva (Genco et al., 1995 ; Tokuda et al., 1998
; Xie et al., 2000
). Regulation has been shown to occur at both transcriptional and post-transcriptional levels and intriguingly the fimbrillin gene (fimA) has recently been suggested to be controlled by both the fimbrillin protein itself and by Rgp and Kgp (Xie et al., 2000
). Given that Rgp and Kgp are produced maximally in the late stationary phase of growth (Rangarajan et al., 1997
), it is possible that they are regulated in a cell-density-dependent manner via quorum sensing (Williams et al., 2000
; Withers et al., 2001
). This is a cell-to-cell communication mechanism which enables an individual bacterial cell to sense other bacterial cells and, in response, differentially express specific sets of genes. Quorum sensing involves the activation of a sensor or response regulator by a small diffusible signal molecule, and several chemically distinct families of such molecules have been identified. In Gram-negative bacteria, N-acylhomoserine lactones (AHLs) represent the most intensively investigated family of signal molecules, although a number of non-AHL molecules have also been described (Williams et al., 2000
; Withers et al., 2001
). These include a polar molecule termed AI-2, originally discovered in Vibrio harveyi as a second diffusible signal that could activate bioluminescence in the absence of N-(3-hydroxybutanoyl)homoserine lactone (3-hydroxy-C4-HSL; Bassler et al., 1994
). Although the structure of this diffusible signalling molecule has not yet been elucidated, a gene product (LuxS) involved in the production of AI-2 has been identified not only in V. harveyi, but also in a number of human pathogens including Escherichia coli and Salmonella (Surette et al., 1999
; Surette & Bassler, 1998
). However, the genes regulated directly via AI-2 in these Gram-negative pathogens have not yet been identified, although AI-2 has been reported to influence type III secretion in enterovirulent E. coli (Sperandio et al., 1999
) and to modulate expression of virB in Shigella flexneri (Day & Maurelli, 2001
).
In the present paper, we have sought to determine whether P. gingivalis employs AHL- and/or AI-2/LuxS-mediated quorum sensing. While we were unable to detect any AHLs, P. gingivalis was found to produce a signalling molecule(s) capable of activating a V. harveyi-based AI-2 biosensor and to possess an orthologue of LuxS. Mutation of this gene resulted in the loss of AI-2 production and a reduction in protease and haemagglutinating activity which was insufficient to attenuate the luxS mutant in a murine lesion model of P. gingivalis infection.
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METHODS |
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Bioassays for quorum-sensing signal molecules.
Assays to detect the presence of AHLs were carried out as previously described (Cámara et al., 1998 ). Cell-free culture supernatants were extracted with dichloromethane and the extracts were subjected to TLC on reverse phase aluminium backed RP18 F254S TLC plates (20 cm x 20 cm; Merck) with a mobile phase of 60% (v/v) methanol in water. After chromatography, TLC plates were overlaid with soft top agar seeded with an AHL biosensor as described by McClean et al. (1997)
. The AHL biosensors used were the Tn5-generated Chromobacterium violaceum mutant CV026, which responds to a range of AHLs (with from C4 to C8 acyl side chains) by inducing the synthesis of the purple pigment violacein, and the lux-based biosensors (pSB401, pSB536 and pSB1075; Table 1
) described by Winson et al. (1998)
, which are capable of detecting AHLs with acyl side chains from C4 to C14. Bioluminescence was detected using a Luminograph LB980 photon imaging camera (EG&G Berthold).
The AI-2 bioassay, using the V. harveyi biosensor BB170 (luxN negative mutant), was carried out as described by Greenberg et al. (1979) . Bacterial culture supernatants were added to the BB170 biosensor strain and AI-2 activity was measured in an EG&G Wallac Victor2 luminometer as Relative Luminescence Units (RLU).
DNA manipulation techniques.
Plasmid isolation, agarose electrophoresis, restriction digests and transformation of E. coli were performed as described by Sambrook et al. (1989) . PCR amplifications were performed according to Ausubel et al. (1989)
. Bacterial chromosomal DNA was purified using the hexadecyltrimethylammonium bromide (CTAB) method (Murray & Thompson, 1980
). Purification of DNA fragments from agarose gels was carried out using Qiaquick DNA purification columns (Qiagen). Probes for Southern blot analysis were labelled using a DIG-labelling system (Boehringer Mannheim). Oligonucleotide synthesis and DNA sequencing was carried out at the Biopolymer Synthesis and Analysis Unit, Queens Medical Centre, University of Nottingham.
Construction of a P. gingivalis genomic library in E. coli containing lux-based AHL reporters.
To clone any putative P. gingivalis AHL synthases, the functional complementation assay described by Swift et al. (1993) was used. Genomic DNA from P. gingivalis W50 was digested with HindIII, KpnI, PstI, BamHI or EcoRI, purified from agarose gels and ligated into pBluescript SK(+) previously digested with the appropriate restriction enzyme and dephosphorylated. The ligation mixtures were electroporated into E. coli JM109 containing either the lux-based AHL reporter pSB401 or pSB1075 (Winson et al., 1998
; Laue et al., 2000
) and plated on antibiotic selective media. Bioluminescent transformants were sought by viewing colonies with a Luminograph LB980 photon imaging camera (EG&G Berthold).
Cloning of luxS.
For cloning of the P. gingivalis luxS gene, preliminary sequence data were obtained from The Institute for Genomic Research through the website at http://www.tigr.org. PCR amplification of luxS from P. gingivalis W50 chromosomal DNA was carried out using primers Por11 (5'-GTATTATCAGCGGAATTCCCGGCGAAGGTCG-3') and Por12 (5'-GATACCGCCTCCGGATCCAATAATCCATCCGG-3'), which were designed using the published information on the P. gingivalis W83 genome sequence and contained EcoRI and BamHI restriction sites, respectively (see underlined sequences above). The PCR product was purified from an agarose gel and ligated into pHG327 (Table 1), previously digested with EcoRI and BamHI, to generate pNB1 (Table 1
).
Generation of a P. gingivalis luxS mutant.
A deletion mutant of luxS lacking 231 internal nucleotides and containing an erythromycin (erm)-resistance cassette was constructed as follows. Two separate pairs of primers introducing NotI restriction sites (see underlined) were used: Por11 (see above) with Por13B (5'-GCGGCCGCCACCAAATGCTCGATCGTATGCCAG-3') (to amplify the 5'-end of luxS) and Por14B (5'-TGGCGGCCGCGCGTGAGGTACTCGATGTAGCG-3') with Por12 (see above) (to amplify the 3'-end of luxS). P. gingivalis W50 chromosomal DNA was used as a template. Subsequently, each of the purified PCR products served as a template in a second PCR amplification using primers Por11 and Por12. The PCR product was digested with BamHI and EcoRI and ligated into similarly digested pHG327 to generate pNB2 (Table 1). This plasmid was then digested with EcoRI and BamHI to release the truncated luxS and ligated into pUC18, to generate pHGin18. To insert an erm cassette in the NotI site of the truncated luxS, the erm cassette from pVA2198 (Rangarajan et al., 1997
) was excised using EcoRI and BamHI digestion and cloned into pUC18Not, similarly digested. The erm cassette was then isolated from pUC18Not by digestion with NotI and subsequently cloned into the NotI site of pHGin18, thus creating pGinerm. This construct was electroporated into P. gingivalis W50 as described by Rangarajan et al. (1997)
, except that the plasmid was not linearized prior to electroporation. Transformants were selected on FAA containing clindamycin.
Overexpression, purification and detection of the P. gingivalis LuxS.
luxS was amplified from P. gingivalis W50 chromosomal DNA, ligated into the EcoRI/BamHI sites of pMal-c2 (New England BioLabs) to generate pNB3, and electroporated into E. coli DH5. The soluble recombinant MalE-LuxS fusion obtained was purified on an amylose resin column and bound protein was eluted with 10 mM maltose. The purified MalE-LuxS fusion protein was cleaved using Factor Xa protease (New England BioLabs) and, following SDS-PAGE, the protein was electro-eluted and used to raise polyclonal antibodies in rabbits.
For the detection of recombinant or native LuxS protein, cell lysates from E. coli DH5, P. gingivalis W50 and the luxS mutant were obtained by harvesting cells throughout the growth curve. The protease inhibitor N
-p-tosyl-L-lysine chloromethyl ketone (TLCK) was added, at a concentration of 50 mM, to P. gingivalis cells prior to lysis. Samples were standardized for protein content, boiled, resolved by SDS-PAGE and transferred to nitrocellulose membranes. LuxS was detected by incubation with the LuxS polyclonal antiserum followed by a protein A-peroxidase conjugate and developed with an Amersham ECL kit (Amersham International).
Rgp and Kgp protease assays.
Protease activity was measured as described by Rangarajan et al. (1997) . P. gingivalis whole cultures, cell lysates (prepared by sonication of cells in PBS, pH 7·4) or cell-free supernatants prepared from cells grown to the same optical density (OD600) were each added to a solution of 10 mM L-cysteine, 10 mM CaCl2, 100 mM Tris/HCl buffer (pH 8·1) containing 0·5 mM N-
-benzoyl-DL-arginine-p-nitroanilide (DL-BApNA) or 0·5 mM N-
-benzoylcarbonyl-L-lysine-p-nitroanilide (Ac-Lys-pNA). Samples were incubated for 1 h at 30 °C and the reaction was monitored by following the increase in A405 due to release of p-nitroaniline. Experiments were repeated three times in duplicate.
Haemagglutination assay.
The haemagglutination assay was performed as described by Dusek et al. (1993) . Essentially, sheep red blood cells (SRBCs) were harvested and washed twice in PBS (pH 7·4) at 4 °C by centrifugation at 2000 g for 3 min and diluted to 0·5% (v/v) in PBS. P. gingivalis W50 wild-type and luxS mutant were grown to an approximate OD580 of 0·8, washed once in PBS and resuspended to an OD580 of 1·0. Doubling dilutions of bacterial cells (50 µl) were performed in V-shaped 96-well plates. The SRBCs (50 µl) were added to the plates followed by incubation at 4 °C overnight and scored for haemagglutination.
P. gingivalis murine infection model.
The model described by Kesavalu et al. (1992) was used to determine whether the luxS mutant NBS1 exhibited reduced virulence. BALB/c mice (eight mice per group) were challenged s.c. for each strain with either 2·5x1010, 5x1010 or 1x1011 c.f.u. of P. gingivalis W50, the isogenic luxS mutant or the kgp mutant K1A (Aduse-Opoku et al., 2000
). K1A is known to be attenuated in this animal model (M. A. Curtis, unpublished data). For each strain, the mean survival time was determined for each of three challenge doses and the entire experiment was repeated twice. The data obtained were analysed statistically using standard methods for survival analysis allowing for right-censoring of time to death when animals survived to the scheduled end of the experiment. Life-table methods were used to display cumulative survival probabilities during experiments, while Cox proportional hazards models were used to estimate hazard ratios for comparisons of interest controlling for the effects of bacterial dose and for between-experiment variation in cumulative survival (Cox & Oakes, 1984
).
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RESULTS |
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Characterization of a P. gingivalis LuxS orthologue
To determine whether P. gingivalis possesses an AI-2/LuxS-based quorum-sensing system, the P. gingivalis genome database was searched using the predicted amino acid sequence of the V. harveyi LuxS protein. A 159 amino acid residue (18·5 kDa) LuxS orthologue was identified. When compared with other LuxS orthologues present in the databases, the P. gingivalis LuxS protein is most closely related to the LuxS of Borrelia burgdorferi (similarity 68%; identity 50%) and shares 33% identity (53% similarity) with the E. coli LuxS protein. Examination of the DNA sequence surrounding P. gingivalis luxS (Fig. 1a) revealed the presence of an adjacent ORF, the translated amino acid sequence of which shares significant homology (37% identity; 54% similarity) with the E. coli pfs gene product, a 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase (Cornell & Riscoe, 1998
). This pfs gene is separated from luxS by only 24 bp, suggesting that the two genes constitute an operon. Homologues of the P. gingivalis W50 47 kDa immunodominant antigen (GenBank accession no. AF153770) and a tRNA guanine transglycosylase (Tgt; Reuter et al., 1991
) were located approximately 700 bp upstream and downstream of the pfs/luxS locus, respectively (Fig. 1a
).
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AI-2 levels in both P. gingivalis and E. coli do not correlate with LuxS levels
To investigate the relationship between AI-2 levels and LuxS production as a function of growth in both E. coli and P. gingivalis, antibodies were first raised against the recombinant P. gingivalis LuxS protein expressed from pNB3 (Table 1) as a MalE-LuxS fusion. The 62 kDa fusion protein was purified by amylose affinity chromatography, cleaved using Factor Xa and the recombinant LuxS protein obtained for antibody production via electro-elution of the protein from SDS-polyacrylamide gels used to separate LuxS from MalE (Fig. 1b
).
E. coli DH5 transformed with pNB3 (Table 1
) produced AI-2, indicating either that the MalE-LuxS fusion protein was functional or that sufficient LuxS for AI-2 synthesis was cleaved by endogenous E. coli proteases. Western blotting of E. coli DH5
(pNB3) whole-cell extracts using antibodies raised against LuxS revealed that the LuxS protein accumulates throughout growth (data not shown). In addition, analysis of culture supernatants from E. coli DH5
(pNB3) taken throughout the growth curve showed increasing levels of AI-2 activity from mid-exponential phase disappearing by early-stationary phase when LuxS levels are still increasing (data not shown). The levels of AI-2 production were higher when cells were grown in the presence of glucose (0·4%, w/v) than when this sugar was omitted (data not shown).
Bioluminescence assays using V. harveyi BB170 failed to reveal the presence of AI-2 in culture supernatants taken throughout the growth curve of P. gingivalis W50 grown in BHI medium. However, when this organism was grown in a chemically defined medium (DM), AI-2 was maximally detected at mid-exponential phase of growth (Fig. 2a), disappearing at the beginning of the stationary phase, while Western blots still detected increasing levels of LuxS (Fig. 2b
). These results are consistent with those obtained in E. coli DH5
(pNB3), suggesting that AI-2 production is not limited by LuxS protein levels.
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To quantify the levels of protease activity produced by P. gingivalis W50 and the isogenic luxS mutant, whole culture, cell lysates and cell-free culture supernatants were incubated with either the Kgp substrate Ac-Lys-pNA or the Rgp substrate DL-BApNA. Fig. 3(a) shows that after 48 h growth, each fraction prepared from the luxS mutant contained around 30% less Kgp activity than the parent strain. For Rgp, each fraction prepared from the luxS mutant contained around 45% less Rgp protease activity (Fig. 3b
).
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luxS and the virulence of P. gingivalis
BALB/c mice were challenged s.c. with the wild-type, luxS mutant NBS1 or kgp mutant K1A. Table 2shows that there were no differences in the mean survival times of mice infected with either the wild-type strain or luxS mutant. These data contrast with the kgp mutant, which was clearly attenuated as revealed by the extended survival times of mice inoculated with 5x1010 or 1x1011 c.f.u.
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DISCUSSION |
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AI-2 appears to represent a new class of quorum-sensing signal molecule involved in cross-communication between different bacteria because Gram-negative and Gram-positive organisms both contain LuxS orthologues (Bassler et al., 1997 ; Bassler, 1999
). However, at present, the chemical identity of the V. harveyi AI-2 molecule is not known although Schauder et al. (2001)
have very recently reported that it is probably a furanone derived from 4,5-dihydroxy-2,3-pentadione and that the function of LuxS is to generate 4,5-dihydroxy-2,3-pentadione from S-adenosylhomocysteine. Thus, in contrast to the AHLs, where a family of signal molecules with different N-linked acyl chains has been identified (Withers et al., 2001
), it has been suggested that AI-2 is structurally invariant, i.e. that despite their sequence divergence, LuxS orthologues all drive the synthesis of the same molecule (Schauder et al., 2001
).
In P. gingivalis, the luxS gene is located adjacent to pfs; RT-PCR analysis suggests that they constitute an operon (N. Burgess, unpublished data; Chung et al., 2001 ). The pfs gene product is a 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase which can cleave the glycosidic bond releasing adenine and the corresponding thiopentose (either methylthioribose or S-ribosylhomocysteine; Cornell & Riscoe, 1998
). Indeed, during the preparation of this manuscript, Schauder et al. (2001)
reported that AI-2 can be generated in vitro from the purified LuxS proteins of E. coli, V. harveyi, Vibrio cholerae, Salmonella typhimurium and Enterococcus faecalis in conjunction with Pfs and S-adenosylhomocysteine. We have also shown that the production of AI-2 in vitro via the P. gingivalis LuxS protein and S-adenosylhomocysteine depends on the presence of the P. gingivalis pfs gene product (Winzer et al., 2002
).
By growing P. gingivalis in a chemically defined medium, we were able to show that AI-2 is produced during mid-exponential growth but appears to have been degraded by the stationary phase. These data are consistent with results obtained for E. coli DH5 harbouring the P. gingivalis luxS gene (this paper) and with those of Surette et al. (1999)
for Sal. typhimurium. Similarly, in H. pylori, AI-2 activity is maximal in early-exponential phase and rapidly decreases as the organism enters stationary phase (Joyce et al., 2000
). These data suggest that LuxS-mediated quorum sensing is only operational during periods of rapid, nutrient-rich growth. Interestingly, Western blot analysis of LuxS production in P. gingivalis and E. coli throughout the growth curve revealed that despite the LuxS protein being present, AI-2 activity is absent from stationary phase samples. In both E. coli and Sal. typhimurium, the existence of a degradation pathway has been proposed, given the rapid loss of AI-2 when carbohydrate is depleted from the medium or when the cells enter stationary phase (Surette & Bassler, 1998
). This implies that the substrates necessary for AI-2 synthesis are not available in stationary phase and/or that the levels of LuxS are maintained to enable the cells to take immediate advantage of any changes in environmental parameters (e.g. nutrient availablity) without the need for transcription (Surette & Bassler, 1999
). Alternatively, the retention of the LuxS protein may be required to prevent accumulation of S-ribosylhomocysteine, which is an inhibitor of all S-adenosylmethionine-dependent methylation reactions (Cornell & Riscoe, 1998
), or to function as a component of a salvaging pathway for adenine and methionine synthesis.
Apart from modulation of bioluminescence in V. harveyi (Bassler et al., 1994 ), the identification and characterization of the signal transduction pathways and target genes of the AI-2 quorum-sensing system in other bacteria has met with limited success. For H. pylori, mutation of luxS did not influence expression of any of the established virulence factors (e.g. vacA) and analysis of the two-dimensional protein profiles of wild-type and mutant failed to reveal any differences (Joyce et al., 2000
; Forsyth & Cover, 2000
). In enteropathogenic E. coli, Sperandio et al. (1999)
reported that LuxS weakly regulates operons encoding the type III secretion apparatus, intimin receptor and intimin. Although the virulence of pathogenic E. coli luxS mutants was not evaluated, an Shig. flexneri luxS mutant was discovered to be as invasive and virulent as the parental strain despite the contribution of LuxS in enhancing expression of virB in the late-exponential phase (Day & Maurelli, 2001
). In P. gingivalis, Chung et al. (2001)
have very recently used the qualitative techniques of differential display (DD)-PCR and RT-PCR to show that mutation of luxS influenced the transcript levels of several genes involved in haemin acquisition and an exinuclease ABC homologue. Although their analysis of rgpA expression gave equivocal results depending on which technique was used, Chung et al. (2001)
reported that rgpA transcript levels were increased in the luxS mutant. However, no data were shown and no direct quantitative assays of Rgp protease activity were undertaken. In the present paper, we have established that mutation of luxS in P. gingivalis results in a 3045% reduction in the levels of the Rgp and Kgp proteases. While this may at first appear to conflict with the results of Chung et al. (2001)
, a 30% reduction in protein is unlikely to be accompanied by a reduction in transcript level of sufficient magnitude to be detectable by DD-PCR or by RT-PCR. It is also possible that the regulation is at the post-transcriptional level. Both RgpA and Kgp are subject to significant post-translational processing (Curtis et al., 1999
) which may also be influenced by the luxS mutation. Indeed, preliminary analysis of the Rgp isoforms in the luxS mutant NBS1 revealed a reduction in the level of the membrane-type RgpB isoform (mt-RgpB; unpublished data), the main vesicle-associated form of the Arg-gingipains (Aduse-Opoku et al., 1998
). This suggests that LuxS may influence the post-translational modification pathway of these enzymes.
Furthermore, the luxS mutant exhibits reduced whole-cell haemagglutinin activity compared with the parent. This finding is consistent with previous reports that cysteine proteases and haemagglutinin activities of P. gingivalis appear to be structurally related (Pavloff et al., 1995 ; Yoneda & Kuramitsu, 1996
). This phenotype may therefore be associated with RgpA and Kgp, which contain haemagglutinin/adhesion domains (Curtis et al., 1999
). Alternatively, it may be a consequence of reduced expression of haemagglutinins such as hagA, which encodes a surface protein haemagglutinin containing domains homologous to the adhesion domains of Rgp and Kgp. Thus given the central role of proteases in the pathogenicity of P. gingivalis, we sought to determine whether the reduced production of Rgp and Kgp by the luxS mutant influenced virulence. In an acute mouse model of soft tissue infection, there were no obvious differences in the virulence of the P. gingivalis luxS mutant when compared with the parent strain. However, although frequently used to assess the virulence of, and immunity to, P. gingivalis, the infection model used (Kesavalu et al., 1992
) depends on a high bacterial challenge dose and does not follow the natural course of periodontal disease. In addition, P. gingivalis is generally found only in low numbers within the oral cavity such that under these conditions the expression of proteases/haemagglutinins may be reduced. In disease, P. gingivalis can represent a significant proportion of the total flora and, under these conditions, it remains possible that AI-2/LuxS may a play a role in up-regulation of these virulence properties and hence the development of disease.
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ACKNOWLEDGEMENTS |
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Received 8 August 2001;
revised 9 October 2001;
accepted 18 October 2001.