Kim R. Hardie

Making 'sense' of metabolism: autoinducer-2, LUXS and pathogenic bacteria

Bacteria exploit many mechanisms to communicate with each other and their surroundings. Mechanisms using small diffusible signals to coordinate behaviour with cell density (quorum sensing) frequently contribute to pathogenicity. However, pathogens must also be able to acquire nutrients and replicate to successfully invade their host. One quorum-sensing system, based on the possession of LuxS, bears the unique feature of contributing directly to metabolism, and therefore has the potential to influence both gene regulation and bacterial fitness. Here, we discuss the influence that LuxS and its product, autoinducer-2, have on virulence, relating the current evidence to the preferred niche of the pathogen and the underlying mechanisms involved.

Bacterial cell-to-cell communication: sorry, can't talk now - gone to lunch!

The identification of novel bacterial cell-to-cell communication (quorum sensing) systems based on diffusible signal molecules, such as indole and the LuxS autoinducer-2, requires discrimination between true signalling molecules and metabolites present in culture supernatants. This depends on rigorous chemical characterisation and demonstration that the molecule controls cellular responses beyond those required to metabolise or detoxify the signal.

Insertion of an outer membrane protein in Escherichia coli requires a chaperone-like protein.

Only one of the characterized components of the main terminal branch of the general secretory pathway (GSP) in Gram‐negative bacteria, GspD, is an integral outer membrane protein that could conceivably form a channel to permit protein transport across this membrane. PulD, a member of the GspD protein family required for pullulanase secretion by Klebsiella oxytoca, is shown here to form outer membrane‐associated complexes which are not readily dissociated by SDS treatment. The outer membrane association of PulD is absolutely dependent on another component of the GSP, the outer membrane‐anchored lipoprotein PulS. Furthermore, the absence of PulS resulted in limited proteolysis of PulD and caused induction of the so‐called phage shock response, as measured by increased expression of the pspA gene. We propose that PulS may be the first member of a new family of periplasmic chaperones that are specifically required for the insertion of a group of outer membrane proteins into this membrane. PulS is only the second component of the main terminal branch of the GSP for which a precise function can be proposed.

Establishing bacterial communities by 'word of mouth': LuxS and autoinducer 2 in biofilm development

Multicellular bacterial communities (biofilms) abound in nature, and their successful formation and survival is likely to require cell–cell communication — including quorum sensing — to co-ordinate appropriate gene expression. The only mode of quorum sensing that is shared by both Gram-positive and Gram-negative bacteria involves the production of the signalling molecule autoinducer 2 by LuxS. A survey of the current literature reveals that luxS contributes to biofilm development in some bacteria. However, inconsistencies prevent biofilm development being attributed to the production of AI2 in all cases.

LuxS-dependent quorum sensing in Porphyromonas gingivalis modulates protease and haemagglutinin activities but is not essential for virulence.

Porphyromonas gingivalis is a Gram-negative black-pigmented obligate anaerobe implicated in the aetiology of human periodontal disease. The virulence of P. gingivalis is associated with the elaboration of the cysteine proteases Arg-gingipain (Rgp) and Lys-gingipain (Kgp), which are produced at high bacterial cell densities. To determine whether quorum sensing plays a role in the regulation of Rgp and Kgp, biosensors capable of detecting either N-acylhomoserine lactone (AHLs) or the luxS-dependent autoinducer (AI-2) quorum-sensing signalling molecules in spent culture supernatants were first employed. While no AHLs could be detected, the Vibrio harveyi BB170 biosensor was activated by spent P. gingivalis W50 culture supernatants. The P. gingivalis luxS gene was cloned and demonstrated to restore AI-2 production in the Escherichia coli luxS mutant DH5alpha. Mutation of luxS abolished AI-2 production in P. gingivalis. Western blotting using antibodies raised against the recombinant protein revealed that LuxS levels increased throughout growth even though AI-2 activity was only maximally detected at the mid-exponential phase of growth and disappeared by the onset of stationary phase. Similar results were obtained with E. coli DH5alpha transformed with luxS, suggesting that AI-2 production is not limited by a lack of LuxS protein. Analysis of Rgp and Kgp protease activities revealed that the P. gingivalis luxS mutant produced around 45% less Rgp and 30% less Kgp activity than the parent strain. In addition, the luxS mutant exhibited a fourfold reduction in haemagglutinin titre. However, these reductions in virulence determinant levels were insufficient to attenuate the luxS mutant in a murine lesion model of P. gingivalis infection.

The secretin-specific, chaperone-like protein of the general secretory pathway: separation of proteolytic protection and piloting functions

The chaperone‐like protein of the main terminal branch of the general secretory pathway from Klebsiella oxytoca, the outer membrane lipoprotein PulS, protects the multimeric secretin PulD from degradation and promotes its correct localization to the outer membrane. To determine whether these are separable functions, or whether resistance to proteolysis results simply from correct localization of PulD, we replaced the lipoprotein‐type signal peptide of PulS by the signal peptide of periplasmic maltose‐binding protein. The resulting periplasmic PulS retained its ability to protect PulD, but not its ability to localize PulD to the outer membrane and to function in pullulanase secretion. Periplasmic PulS competed with wild‐type PulS to prevent pullulanase secretion, presumably again by causing mislocalization of PulD. A hybrid protein comprising the mature part of PulS fused to the C‐terminus of full‐length maltose‐binding protein (MalE–PulS) had similar properties to the periplasmic PulS protein. Moreover, MalE–PulS was shown to associate with PulD by amylose‐affinity chromatography. The MalE–PulS hybrid was rendered completely functional (i.e. it restored pullulanase secretion in a pulS mutant) by replacing its signal peptide with a lipoprotein‐type signal peptide. However, this fatty‐acylated hybrid protein was only functional if it also carried a lipoprotein sorting signal that targeted it to the outer membrane. Thus, the two functions of PulS are separate and fully dissociable. Incorrect localization, rather than proteolysis, of PulD in the absence of PulS was shown to be the factor that causes high‐level induction of the phage shock response. The Erwinia chrysanthemi PulS homologue, OutS, can substitute for PulS, and PulS can protect the secretin OutD from proteolysis in Escherichia coli, indicating the possible existence of a family of PulS‐like chaperone proteins.

RECENT PROGRESS AND FUTURE DIRECTIONS IN STUDIES OF THE MAIN TERMINAL BRANCH OF THE GENERAL SECRETORY PATHWAY IN GRAM-NEGATIVE BACTERIA : A REVIEW

The main terminal branch (MTB) of the general secretory pathway is used by a wide variety of Gram- bacteria to transport exoproteins from the periplasm to the outside milieu. Recent work has led to the identification of the function of two of its 14 (or more) components: an enzyme with type-IV prepilin peptidase activity and a chaperone-like protein required for the insertion of another of the MTB components into the outer membrane. Despite these important discoveries, little tangible progress has been made towards identifying MTB components that determine secretion specificity (presumably by binding to cognate exoproteins) or which form the putative channel through which exoproteins are transported across the outer membrane. However, the idea that the single integral outer membrane component of the MTB could line the wall of this channel, and the intriguing possibility that other components of the MTB form a rudimentary type-IV pilus-like structure that might span the periplasm both deserve more careful examination. Although Escherichia coli K-12 does not normally secrete exoproteins, its chromosome contains an apparently complete set of genes coding for MTB components. At least two of these genes code for functional proteins, but the operon in which twelve of the genes are located does not appear to be expressed. We are currently searching for conditions which allow these genes to be expressed with the eventual aim of identifying the protein(s) that E. coli K-12 can secrete.

Simultaneous quantitative profiling of N-acyl-l-homoserine lactone and 2-alkyl-4(1H)-quinolone families of quorum-sensing signaling molecules using LC-MS/MS

An LC-MS/MS method, using positive mode electrospray ionization, for the simultaneous, quantitative and targeted profiling of the N-acyl-l-homoserine lactone (AHL) and 2-alkyl 4-(1H)-quinolone (AQ) families of bacterial quorum-sensing signaling molecules (QSSMs) is presented. This LC-MS/MS technique was applied to determine the relative molar ratios of AHLs and AQs produced by Pseudomonas aeruginosa and the consequences of mutating individual or multiple QSSM synthase genes (lasI, rhlI, pqsA) on AHL and AQ profiles and concentrations. The AHL profile of P. aeruginosa was dominated by N-butanoyl-l-homoserine lactone (C4-HSL) with lesser concentrations of N-hexanoyl-l-homoserine lactone (C6-HSL) and 3-oxo-substituted longer chain AHLs including N-(3-oxodecanoyl)-l-homoserine lactone (3-oxo-C10-HSL) and N-(3-oxododecanoyl)-l-homoserine lactone (3-oxo-C12-HSL). The AQ profile of P. aeruginosa comprised the C7 and C9 long alkyl chain AQs including 2-heptyl-4-hydroxyquinoline (HHQ), 2-nonyl-4-hydroxyquinoline, the “pseudomonas quinolone signal” (2-heptyl-3-hydroxy-4-quinolone) and the N-oxides, 2-heptyl-4-hydroxyquinoline N-oxide and 2-nonyl-4-hydroxyquinoline N-oxide. Application of the method showed significant effects of growth medium type on the ratio and the nature of the QSSMs synthesized and the dramatic effect of single, double and triple mutations in the P. aeruginosa QS synthase genes. The LC-MS/MS methodology is applicable in organisms where either or both AHL and AQ QSSMs are produced and can provide comprehensive profiles and concentrations from a single sample.

The C‐terminal domain of the secretin PulD contains the binding site for its cognate chaperone, PulS, and confers PulS dependence on pIVf1 function

Related outer membrane proteins, termed secretins, participate in the secretion of macromolecules across the outer membrane of many Gram‐negative bacteria. In the pullulanase‐secretion system, PulS, an outer membrane‐associated lipoprotein, is required both for the integrity and the proper outer membrane localization of the PulD secretin. Here we show that the PulS‐binding site is located within the C‐terminal 65 residues of PulD. Addition of this domain to the filamentous phage secretin, pIV, or to the unrelated maltose‐binding protein rendered both proteins dependent on PulS for stability. A chimeric protein composed of bacteriophage f1 pIV and the C‐terminal domain of PulD required properly localized PulS to support phage assembly. An in vivo complex formed between the pIV‐PulD65 chimera and PulS was detected by co‐immunoprecipitation and by affinity chromatography.

Functional association between the Helicobacter pylori virulence factors VacA and CagA

The Helicobacter pylori virulence factors CagA and VacA are implicated in the development of gastroduodenal diseases. Most strains possessing CagA also possess the more virulent vacuolating form of VacA. This study assessed the significance of possession of both virulence factors in terms of their effect on gastric epithelial cells, using a set of minimally passaged, isogenic VacA, CagA and CagE mutants in H. pylori strains 60190 and 84-183. The cagA and cagE mutants were found to significantly increase VacA-induced vacuolation of epithelial cells, and the vacA mutants significantly increased CagA-induced cellular elongations, compared with wild-type strains, indicating that CagA reduces vacuolation and VacA reduces hummingbird formation. Although epithelial cells incubated with the wild-type H. pylori strains may display both vacuolation and hummingbird formation, it was found that (i) hummingbird length was significantly reduced in vacuolated cells compared with those without vacuolation; (ii) the number of vacuoles was significantly reduced in vacuolated cells with hummingbird formation compared with those without hummingbirds; and (iii) cells displaying extensive vacuolation did not subsequently form hummingbirds and vice versa. VacA did not affect the phosphorylation of CagA. These data show that VacA and CagA downregulate each others effects on epithelial cells, potentially allowing H. pylori interaction with cells whilst avoiding excessive cellular damage.