Porphyromonas gingivalis gingipains: the molecular teeth of a microbial vampire

The gingipains are cell surface Arg- and Lys-specific proteinases of the bacterium Porphyromons gingivalis, which has been associated with periodontitis, a disease that results in the destruction of the teeth-s supporting tissues. The proteinases are encoded by three genes designated rgpA, rgpB and kgp. Arg-specific proteolytic activity is encoded by rgpA/B and the Lys-specific activity by kgp. RgpA and Kgp are polyproteins comprising proteinases with C-terminal adhesin domains that are proteolytically processed. After processing, the domains remain non-covalently associated as complexes on the cell surface. RgpB is also a cell surface proteinase but does not associate with adhesin domains. Using gene knockout P. gingivalis mutants, the proteolytic processing of the gingipain domains has been shown to involve the gingipains themselves as well as C-terminal processing by a carboxypeptidase. A motif in the C-terminal domain of each protein/polyprotein has been identified that is suggested to be involved in attachment to LPS on the cell surface. RgpB lacks a C-terminal adhesin binding motif found in the catalytic domains of RgpA and Kgp. This adhesin binding motif is proposed to be responsible for the non-covalent association of the RgpA and Kgp catalytic domains into the cell surface complexes with the processed adhesin domains. The RgpA-Kgp proteinase-adhesin complexes, through the adhesin domains A1 and A3, have been implicated in colonization of P. gingivalis by binding to other bacteria in subgingival plaque and also binding to crevicular epithelial cells. The RgpA-Kgp complexes also bind to fibrinogen, laminin, collagen type V, fibronectin and hemoglobin. Amino acid sequences likely to be involved in binding to these host proteins have been identified in adhesin domains A1 and A3. It is proposed that these adhesins target the proteolytic activity to host cell surface matrix proteins and receptors. The continual cycle of binding and degradation of the surface proteins/receptors on epithelial, fibroblast and endothelial cells by the RgpA-Kgp complexes in the gingival tissue leading to cell death would contribute to inflammation, tissue destruction and vascular disruption (bleeding). P. gingivalis has an obligate growth requirement for iron and protoporphyrin IX, which it preferentially utilizes in the form of hemoglobin. Kgp proteolytic activity is essential for rapid hydrolysis of hemoglobin and it is suggested therefore that a major role of the RgpA-Kgp complexes is in vascular disruption and the binding and rapid degradation of hemoglobin for heme assimilation by P. gingivalis. The RgpA-Kgp complexes also have a major role in the evasion and dysregulation of the host-s immune response. It is proposed that host pro-inflammatory cytokines and cellular receptors close to the infection site may be rapidly and efficiently degraded by the gingipains while the proteinases at lower concentrations distally could result in the promotion of an inflammatory response through activation of proteinase-activated receptors and cytokine release. The culmination of this dysregulation would be tissue destruction and bone resorption. In animal models of disease the RgpA-Kgp complex when used as a vaccine to produce a high titre antibody response protects against challenge with P. gingivalis. Using recombinant domains of RgpA and Kgp as vaccines, it has been demonstrated that the A1 and A3 domains confer protection.     

The biphasic virulence activities of gingipains: activation and inactivation of host proteins

Gingipains are trypsin-like cysteine proteinases produced by Porphyromonas gingivalis, a major causative bacterium of adult periodontitis. Rgps (HRgpA and RgpB) and Kgp are specific for -Arg-Xaa- and -Lys-Xaa- peptide bonds, respectively. HRgpA and Kgp are non-covalent complexes containing separate catalytic and adhesion/hemagglutinin domains, while RgpB has only a catalytic domain with a primary structure essentially identical to that of the cata-lytic subunit of HRgpA. The multiple virulence activities of gingipains are reviewed in view of the biphasic mechanisms: activation and inactivation of host proteins. Rgps enhanced vascular permeability through prekallikrein activation or direct bradykinin release in combination with Kgp. This Rgp action is potentially associated with gingival edema and crevicular fluid production. Rgps activate the blood coagulation system, leading to progression of inflammation and consequent alveolar bone loss in the periodontitis site. Rgps also activate protease-activated receptors and induce platelet aggregation, which, together with the coagulation-inducing activity, may explain an emerging link between periodontitis and cardiovascular disease. Kgp is the most potent fibrinogen/fibrin degrading enzyme of the three gingipains in human plasma, being involved in the bleeding tendency at the diseased gingiva. Gingipains stimulate expression of matrix metalloproteinases (MMPs) in fibroblasts and activate secreted latent MMPs that can destroy periodontal tissues. Gingipains degrade cytokines, components of the complement system and several receptors, including macrophage CD14, T cell CD4 and CD8, thus perturbing the host-defense systems and thereby facilitating sustained colonization of P. gingivalis. Gingipains are potent virulence factors of P. gingivalis, and in many regards their pathogenic activities constitute new mechanisms of bacterial virulence.     

Suppression of virulence of Porphyromonas gingivalis by potent inhibitors specific for gingipains

Porphyromonas gingivalis is a Gram-negative anaerobic bacterium that is implicated as a major etiologic agent of adult periodontal disease. This bacterium is asaccharolytic and possesses strong potency for proteolysis. It produces a novel class of cysteine proteinases, termed gingipains, in the cell-associated and secretory forms. Gingipains consist of arginine-X-specific cysteine proteinases (Arg-gingipains, Rgps) and lysine-X-specific cysteine proteinase (Lys-gingipain, Kgp). Previous studies using various P. gingivalis mutants deficient in Rgp- and/or Kgp-encoding genes have revealed that both enzymes are important for the bacterium both to exhibit its virulence and to survive in periodontal pockets. Mammalian internal proteinase inhibitors such as cystatins, a1-antichymotrypsin, and tissue inhibitor of metalloproteinases (TIMPs) have little or no effects on the proteolytic activities of these enzymes, suggesting the evasion of the bacterium from host defense mechanisms. Recent epidemiological reports have shown a significant relation between periodontal diseases and systemic diseases such as cardiovascular diseases and diabetes. Thus, the development of potent inhibitors specific for gingipains provides new therapeutic approaches to treat periodontal diseases and the related systemic diseases. More recently, we have developed novel synthetic inhibitors specific for Rgp and Kgp, based on the specificity and efficacy of cleavage of histatins by each enzyme. We have also isolated a novel and potent inhibitor of Rgp from the culture supernatant of Streptomyces species strain FA-70, now designated as FA-70C1. Here we summarized the usefulness of these new inhibitors in providing a broader application in studies of this important class of enzymes.     

Plant protein proteinase inhibitors: structure and mechanism of inhibition

This review outlines known examples of the three-dimensional structures of protein proteinase inhibitors from plants. Three families of enzymes, serine proteinases, carboxypeptidases and cysteine proteinases, are targeted by at least a dozen inhibitor families, with the majority of them adopting the standard mechanism of inhibition towards the serine proteinases. All of the inhibitors discussed maintain compact and stable inhibitory domains that bind to the active site of their target proteinases and prevent access to the substrate molecules. One interesting highlight is the knottin group. Three separate inhibitor families utilize the overall knottin fold in a different way. This fold can accommodate extensive sequence variation and for each of the squash, Mirabilis and Potato carboxypeptidase families, the proteinase-binding residues are found at a different location. Plants have also evolved additional strategies to regulate proteinase activity, such as linking inhibitory domains and targeting multiple enzymes at once. The structural aspects of these strategies are discussed in the review.     

Novel cysteine proteinase inhibitors homologous to the proregions of cysteine proteinases

Propeptides of papain-like cysteine proteinases such as papain, cathepsins B, L and S are potent inhibitors of their cognate cysteine proteinases with Ki values in the nanomolar range, and they exhibit highest inhibition selectivity for enzymes from which they originate. Recent studies have identified novel inhibitor proteins that are homologous to the proregions of papain-like cysteine proteinases. Mouse activated T-lymphocytes express cytotoxic T-lymphocyte antigen (CTLA-2), which is homologous to the proregion of mouse cathepsin L. CTLA-2 exhibits inhibitory activities to several cysteine proteinases. We have also identified a similar propeptide-like cysteine proteinase inhibitor, Bombyx cysteine proteinase inhibitor (BCPI), in the silkmoth Bombyx mori. BCPI is a slow and tight binding inhibitor of cathepsin L-like cysteine proteinases with Ki values in picomolar range, and the inhibition is highly selective towards these proteinases just like the propeptides. Recent genome analyses have shown the expression of similar propeptide-like proteins in Drosophila and rat, suggesting the presence of a novel class of cysteine proteinase inhibitors in a variety of organisms. Studies of the gene structures and phylogenetic analysis have shown that genes of the propeptide-like cysteine proteinase inhibitors have emerged from ancestor genes of their parental enzymes.     

Mass spectrometric sequencing and acylation character analysis of C-terminal anchoring segment from Influenza A hemagglutinin

Influenza A virus hemagglutinin (HA) is a major envelope glycoprotein mediating viral and cell membrane fusion. HA is anchored in the viral envelope by a light HA(2) chain containing one transmembrane domain and a cytoplasmic tail. Three cysteine residues in the C-terminal region, one in the transmembrane domain and two in the cytoplasmic tail, are highly conserved and potentially palmitoylated in all HA subtypes. The HA(2) C- terminal anchoring segments were extracted to organic phase from the bromelain-digested viruses (subviral particles) of three strains: A/X-31 (H3 subtype), A/Puerto Rico/8/34 (H1 subtype) and A/FPV/Weybridge/34 (H7 subtype). Their primary structures were assessed by matrix-assisted laser desorption/ionization time-of-flight time-of- flight mass spectrometry (MALDI-ToF-ToF MS). Trypsin-type protease-cleaved peptides prevailed over bromelain- cleaved ones in the peptide mixtures. All of them included transmembrane domains. Several distinctive features of the C-terminal HA(2) peptides acylation character were discovered by MALDI-ToF MS: 1) the peptides isolated from the viruses, which were digested by bromelain in the absence of beta-mercaptoethanol, were predominantly triply acylated; 2) the peptides were acylated not only by palmitic, but also by stearic acid residues; 3) the palmitate/stearate ratio was different for the three strains studied; 4) the A/FPV/Weybridge/34 strain has a priority to stearate binding. This fatty acid residue was discovered at the first of three conservative cysteine residues located in the transmembrane domain. It was found that presence of thiol reagent during preparation of subviral particles led to the appearence of the C-terminal HA(2) peptides acylated to different degrees. Triply, doubly, mono- and even unacylated peptides were detected. It was demonstrated that the thioester bond in the isolated acylpeptides was extremely sensitive to thiol reagents.     

An electroblotting, two-step procedure for the detection of proteinases and the study of proteinase/inhibitor complexes in gelatin-containing polyacrylamide gels.

A two-step gelatin/polyacrylamide gel electrophoresis (gelatin/PAGE) procedure was devised for the detection of proteinases and the study of proteinase/inhibitor interactions in complex biological extracts. The proteins are first resolved by sodium dodecyl sulfate (SDS)-PAGE under reducing or nonreducing conditions, and electrotransferred into a 0.75 mm-thick accompanying polyacrylamide slab gel containing 0.1% w/v porcine gelatin. The active proteinase bands are developed by a gelatin proteolysis step in the accompanying gel in the presence or absence of diagnostic proteinase inhibitors, allowing the assessment of proteinase classes and the visual discrimination of inhibitor-'sensitive' and -'insensitive' proteinases in complex extracts. Alternatively, protein extracts are preincubated with specific reversible inhibitors before electrophoresis, allowing a rapid discrimination of strong and weak interactions implicating proteinases and reversible inhibitors. In comparison with the standard gelatin/PAGE procedure, that involves copolymerization of gelatin with acrylamide in the resolving gel, this new procedure simplifies proteinase patterns, avoids overestimation of proteinase numbers in complex extracts, and allows in certain conditions the estimation of proteinase molecular weights. Stem bromelain (EC 3.4.22.32), bovine trypsin (EC 3.4.21.4), papain (EC 3.4.22.2), and the extracellular (digestive) cysteine proteinases of five herbivorous pests are used as model enzymes to illustrate the usefulness of this approach in detecting proteinases and in studying their interactions with specific proteinaceous inhibitors potentially useful in biotechnology.     

The C-terminal domain of pancreatic lipase: functional and structural analogies with c2 domains

The 3D structure of pancreatic lipase (PL) consists of two functional domains. The N-terminal domain belongs to the alpha/beta hydrolase fold and contains the active site, which involves a catalytic triad analogous to that present in serine proteases. The beta-sandwich C-terminal domain of PL plays an important part in the binding process between the lipase and colipase, the specific PL cofactor. Recent structure-function studies have suggested that the PL C-terminal domain may have an extra role apart from that of binding colipase. This domain contains an exposed hydrophobic loop (beta5') which was found to be located on the same side as the hydrophobic loops surrounding the active site, and it may be involved in the lipid binding process. Indirect evidence for this new function of the PL C-terminal domain has been provided by studies with monoclonal antibodies directed against the beta5' loop. The catalytic activity of the PL-antibody complexes on water insoluble substrates decreased drastically, whereas their esterase activity on a soluble substrate remained unchanged. During the last few years, a number of protein structures (15-lipoxygenase, alpha-toxin from Clostridium perfringens) have been determined that contain domains with close structural homologies with the beta-sandwich C-terminal domain of PL. Generally speaking, these domains show structural homologies with the C2 domains occurring in a wide range of proteins involved in signal transduction (e.g. phosphoinositide-specific phospholipase C, protein kinase C, cytosolic phospholipase A2), membrane traffic (e.g. synaptotagmin I, rabphilin) and membrane disruption (e.g. perforin). Here it is proposed to review the structure and function of the C2 domains, based on the recent 3D structures and improved sequence alignments.     

Preparation and preliminary characterization of poly(ethylene glycol)-pepstatin conjugate

The carboxyl function of pepstatin has been coupled, through an amide bond, to methoxypoly(ethylene glycol) (5 kDa), to which an amino function had been previously grafted. The mPEG-pepstatin conjugate inhibits hog pepsin (aspartic proteinase) in vitro as pepstatin itself, however, with a 400 times higher apparent K_i. The conjugate apparently does not inhibit proteinases belonging to other proteinase families such as serine (trypsin, carboxypeptidase Y), cysteine (Papaya proteinase III), or metallo (collagenase) proteinases.     

Aspartic proteinase content of the Arabidopsis genome

The sequence of the Arabidopsis genome has given us information about one plant's complement of aspartic proteinases. Using an in silico analysis based on the homology to known aspartic proteinase genes, we have uncovered 51 sequences that potentially encode these enzymes. This is substantial more than the number predicted for other eukaryotic systems. We have grouped the deduced amino acid sequences into 3 classes - typical plant aspartic proteinase, nucellin-like and atypical aspartic proteinase sequences-, depending on their putative domain organizations and their active site sequence motifs. Searching databases has revealed cDNAs or ESTs for nearly 90% of these genes. Sequence analysis using software that detects targeting signals indicates most of the predicted proteins have the expected localization in the secretory system although several of these are membrane bound. The analysis also predicts 8 chloroplast localized proteins and 2 mitochondria-localized aspartic proteinase-like proteins. The wide variety of structures and subcellular locations implies multiple functions for aspartic proteinases in plants.     

The Cysteine proteinases

The cysteine proteinases form a group of enzymes which depend for their activity on the thiol group of a cysteine residue. They occur in mammals plants and bacteria and fulfil a wide variety of functions. This report focuses attention on the plant proteinases, papain, ficin and stem-bromelain, and streptococcal proteinase from haemolytic streptococci. Papain is the most extensively studied member of this family and its tertiary structure is known. The review highlights therefore the present state of knowledge of the structure, specificity and mechanism of action of this enzyme.     

Structure-reactivity relationships among metallothionein three-metal domains: role of non-cysteine amino acid residues in lobster metallothionein and human metallothionein-3

Metallothionein (MT) domains of different origins, exhibiting distinct, highly conserved cysteine positions, show differences in metal-cysteine coordination and reactivity. Lobster MT, which includes two Cd3S9 beta domains, was chosen as a basic model to study the structure-function relationship among the clusters. The possible influence of (1) the position of the cysteine residues and (2) the steric and electrostatic effects of neighboring amino acids on the folding and stability of MT clusters have been examined with the native lobster beta C and beta N domains, each having nine cysteines and binding three M2+ ions, and a modified domain beta C-->N, in which the cysteines of the C-terminal domain are relocated so they are spaced as in the N-terminal domain. Each has been synthesized and characterized by UV, CD, 113Cd NMR, and 1H NMR spectroscopies. The synthetic native domains (Cd3 beta C and Cd3 beta N) displayed spectroscopic properties, metal-binding affinities, and kinetic reactivity similar to those of the holo protein. In contrast, the modified Cd3 beta C-->N domain was unusually reactive and, in the presence of Chelex, a metal-ion chelating resin, was converted to a Cd5(beta C-->N)2 dimer. These differences in structure and reactivity demonstrate that the requirements for formation of a stable type-B, Cd3S9, beta cluster are more stringent than simply the sequential positions of the cysteines along the peptide chain and include specific interactions with neighboring amino acids. Molecular mechanics calculations suggest that changes of even a single amino acid in lobster Cd3 beta N toward lobster Cd3 beta C-->N or in mammalian MT1 or MT2 toward Cd3 beta-MT3 (GIF) can destabilize their structures.     

Beta-lactones as a new class of cysteine proteinase inhibitors: inhibition of hepatitis A virus 3C proteinase by N-Cbz-serine beta-lactone

[reaction: see text] N-Benzyloxycarbonyl-L-serine beta-lactone (1) is shown to irreversibly inactivate the 3C cysteine proteinase of hepatitis A virus (HAV) with k(inact) = 0.70 min(-1), K(I) = 1.84 x 10(-4) M and k(inact)/K(I) = 3800 M(-1) min(-1) at an enzyme concentration of 0.1 microM. Mass spectrometric and HMQC NMR studies using 13C-labeled 1 show that the active site cysteine (Cys-172) thiol of the HAV 3C proteinase attacks the beta-position (i.e. C-4) of the oxetanone ring, thereby leading to ring opening and alkylation of the sulfur. In contrast, the enantiomer of this beta-lactone, 2, is a reversible competitive inhibitor (Ki = 1.50 x 10(-6) M) at similar enzyme concentrations. The beta-lactone motif represents a new class of inhibitors of cysteine proteinases.     

Synthesis and evaluation of keto-glutamine analogues as inhibitors of hepatitis A virus 3C proteinase

Hepatitis A virus (HAV) 3C enzyme is a picornaviral cysteine proteinase involved in the processing of the initially synthesized viral polyprotein and is therefore important for viral maturation and infectivity. Although it is a cysteine proteinase, this enzyme has a topology similar to those of the chymotrypsin-like serine proteinases. Since the enzyme recognizes peptide substrates with a glutamine residue at the P(1) site, a number of ketone-containing glutamine compounds analogous to nanomolar inhibitors of cathepsin K were synthesized and tested for inhibition against HAV 3C proteinase. In addition, a 3-azetidinone scaffold was incorporated into the glutamine fragment but gave only modest inhibition. However, introduction of a phthalhydrazido group alpha to the ketone moiety gave significantly better inhibitors with IC(50) values ranging from 13 to 164 microM, presumably due to the effect of intramolecular hydrogen bonding to the ketone. In addition, the tetrapeptide phthalhydrazide 24 was found to be a competitive reversible inhibitor (K(i) = 9 x 10(-6) M) and also showed no loss of inhibitory potency in the presence of dithiothreitol.     

Biochemical, Immunological and Kinetic Characterisation of Thiol Protease Inhibitor (Cystatin) from Liver

Regulation of the cysteine protease activity is imperative for proper functioning of the various organ systems. Elevated activities of cysteine proteinases due to impaired regulation by the endogenous cysteine proteinase inhibitors (cystatins) have been linked to liver malignancies. To gain an insight into these regulatory processes, it is essential to purify and characterise the inhibitors, cystatins. Present study was undertaken to purify the inhibitor from the liver. The purification was accomplished in four steps: alkaline treatment, ammonium sulphate fractionation, acetone precipitation and gel filtration column (Sephacryl S-100 HR). The eluted protein exhibited inhibitory activity towards papain, and its purity was further reaffirmed using western blotting and immunodiffusion. The purified inhibitor (liver cystatin (LC)) was stable in the pH range of 6–8 and temperature up to 45 °C. In view of the significance of kinetics parameters for drug delivery, the kinetic parameters of liver cystatin were also determined. LC showed the greatest affinity for papain followed by ficin and bromelain. UV and fluorescence spectroscopy results showed that binding of LC with thiol proteases induced changes in the environment of aromatic residues. Recent advances in the field of proteinase inhibitors have drawn attention to the possible use of this collected knowledge to control pathologies.     

Site-Directed Mutagenesis and Analysis of Second-Site Revertants Indicates a Requirement for C-Terminal Amino Acids of PsaB for Stable Assembly of the Photosystem I Reaction Center Complex in Chlamydomonas reinhardtii

The PsaA and PsaB polypeptides form the reaction center core heterodimer of photosystem I (PSI). Both PsaA and PsaB are predicted to have 11 hydrophobic domains, although it is unclear how both polypeptides fold within the thylakoid membrane. If all 11 hydrophobic regions form membrane-spanning domains, the N- and C-terminus must be located on opposite sides of the membrane. The C-terminus of PsaB is very conserved in a wide range of organisms and may be important for PSI assembly or function. Using chloroplast transformation in Chlamydomonas reinhardtii we have generated a series of C-terminal extension and deletion mutants of the PsaB polypeptide. Analysis of these mutants and spontaneous revertants indicates that the C-terminus may be extended by at least 14 amino acids without impairing PSI assembly. Deletion of amino acids 732–736 also has no impact on PSI, whereas deletion of amino acids 727–736 results in no accumulation of the complex. The site of truncation in the 727–736 deletion coincides with the end of the hydrophobic domain XI supporting a location of the C-terminus of PsaB on the lumenal side of PSI.     

Domain shapes, coarsening, and random patterns in ternary membranes

A number of morphological and statistical aspects of domain formation in singly and doubly supported ternary membranes have been investigated. Such ternary membranes produce macroscopic phase separation in two fluid phases and are widely used as raft models. We find that membrane interactions with the support surface can have a critical influence on the domain shapes if measures are not taken to screen these interactions. Combined AFM and fluorescence microscopy demonstrate small (500 nm) irregular domains and incomplete formation of much larger (5 microm) round domains. These kinetically trapped structures are the result of interactions between the membrane and the support surface, and they can be effectively removed by employing doubly supported membranes under physiological salt concentrations. These decoupled supported membranes display macroscopic round domains that are easily perturbed by fluid shear flow. The system allows a quantitative characterization of domain coarsening upon being cooled into the coexistence region. We determine the domain growth exponent alpha = 0.31, which is in close agreement with the theoretical value of 1/3. Analysis of the spatial domain pattern in terms of Voronoi polygons demonstrates a close similarity to equilibrated cellular structures with a maximized configurational entropy.     

Predicting three-dimensional structures of transmembrane domains of β-barrel membrane proteins

β-Barrel membrane proteins are found in the outer membrane of gram-negative bacteria, mitochondria, and chloroplasts. They are important for pore formation, membrane anchoring, and enzyme activity. These proteins are also often responsible for bacterial virulence. Due to difficulties in experimental structure determination, they are sparsely represented in the protein structure databank. We have developed a computational method for predicting structures of the transmembrane (TM) domains of β-barrel membrane proteins. Based on physical principles, our method can predict structures of the TM domain of β-barrel membrane proteins of novel topology, including those from eukaryotic mitochondria. Our method is based on a model of physical interactions, a discrete conformational state space, an empirical potential function, as well as a model to account for interstrand loop entropy. We are able to construct three-dimensional atomic structure of the TM domains from sequences for a set of 23 nonhomologous proteins (resolution 1.8-3.0 ?). The median rmsd of TM domains containing 75-222 residues between predicted and measured structures is 3.9 ? for main chain atoms. In addition, stability determinants and protein-protein interaction sites can be predicted. Such predictions on eukaryotic mitochondria outer membrane protein Tom40 and VDAC are confirmed by independent mutagenesis and chemical cross-linking studies. These results suggest that our model captures key components of the organization principles of β-barrel membrane protein assembly.