The complement system and its biological activities

The complement system is a non specific humoral defence mechanism which can be triggered by various effectors : immune-complexes, extrinsic proteases, bacterial cell-wall polysaccharides, viral membranes. Different peptides or multimolecular complexes are formed by a cascade of proteolytic cleavages; they take an active part in the inflammatory response and may contribute to different pathological manifestations.     

Variable and tissue-specific subunit composition of mitochondrial m-AAA protease complexes linked to hereditary spastic paraplegia

The m-AAA protease, an ATP-dependent proteolytic complex in the mitochondrial inner membrane, controls protein quality and regulates ribosome assembly, thus exerting essential housekeeping functions within mitochondria. Mutations in the m-AAA protease subunit paraplegin cause axonal degeneration in hereditary spastic paraplegia (HSP), but the basis for the unexpected tissue specificity is not understood. Paraplegin assembles with homologous Afg3l2 subunits into hetero-oligomeric complexes which can substitute for yeast m-AAA proteases, demonstrating functional conservation. The function of a third paralogue, Afg3l1 expressed in mouse, is unknown. Here, we analyze the assembly of paraplegin into m-AAA complexes and monitor consequences of paraplegin deficiency in HSP fibroblasts and in a mouse model for HSP. Our findings reveal variability in the assembly of m-AAA proteases in mitochondria in different tissues. Homo-oligomeric Afg3l1 and Afg3l2 complexes and hetero-oligomeric assemblies of both proteins with paraplegin can be formed. Yeast complementation studies demonstrate the proteolytic activity of these assemblies. Paraplegin deficiency in HSP does not result in the loss of m-AAA protease activity in brain mitochondria. Rather, homo-oligomeric Afg3l2 complexes accumulate, and these complexes can substitute for housekeeping functions of paraplegin-containing m-AAA complexes. We therefore propose that the formation of m-AAA proteases with altered substrate specificities leads to axonal degeneration in HSP.     

Protease-dependent mechanisms of complement evasion by bacterial pathogens

Abstract The human immune system has evolved a variety of mechanisms for the primary task of neutralizing and eliminating microbial intruders. As the first line of defense, the complement system is responsible for rapid recognition and opsonization of bacteria, presentation to phagocytes and bacterial cell killing by direct lysis. All successful human pathogens have mechanisms of circumventing the antibacterial activity of the complement system and escaping this stage of the immune response. One of the ways in which pathogens achieve this is the deployment of proteases. Based on the increasing number of recent publications in this area, it appears that proteolytic inactivation of the antibacterial activities of the complement system is a common strategy of avoiding targeting by this arm of host innate immune defense. In this review, we focus on those bacteria that deploy proteases capable of degrading complement system components into non-functional fragments, thus impairing complement-dependent antibacterial activity and facilitating pathogen survival inside the host.     

Plasminogen activators and their inhibitors in the neuromuscular system: II. Serpins and serpin: protease complex receptors increase during in vitro myogenesis

In the course of studies on the regulation of plasminogen activator-mediated extracellular matrix degradation in muscle we found the presence of a factor, a cellular inhibitor of serine proteases having features similar to the serpin protease nexin I (PNI). This factor was present in the medium and at maximum concentration following fusion of skeletal muscle cells in culture. The ability of the PNI homologue in mouse muscle to inhibit ECM degradation by urokinase in myoblast medium was compared to that of human PNI purified from human fibroblasts. Stable (to SDS) 1:1 molar ratio complex formation between PNI and proteases, the proposed means by which these enzymes are regulated and removed, was also detected. Cell surface receptors for protease:PNI complexes, the specific binding sites for inactive complex internalization, were found on multinucleated myotubes, while little or no receptor activity was detected on myoblasts. These data suggest that developmental regulation of a) increased PNI proteolytic inhibitory activity expression and b) the appearance of protease:inhibitor complex receptors on muscle cell surfaces during myogenesis may constitute important regulatory features of muscle surface proteolytic activity. They complement previous studies of proteoglycan metabolism in muscle, which itself contains molecules capable of regulating the activity of myotube surface proteases.     

New roles for perforins and proteases in apicomplexan egress

Egress is a pivotal step in the life cycle of intracellular pathogens initiating the transition from an expiring host cell to a fresh target cell. While much attention has been focused on understanding cell invasion by intracellular pathogens, recent work is providing a new appreciation of mechanisms and therapeutic potential of microbial egress. This review highlights recent insight into cell egress by apicomplexan parasites and emerging contributions of membranolytic and proteolytic secretory products, along with host proteases. New findings suggest that Toxoplasma gondii secretes a pore-forming protein, TgPLP1, during egress that facilitates parasite escape from the cell by perforating the parasitophorous membrane. Also, in a cascade of proteolytic events, Plasmodium falciparum late-stage schizonts activate and secrete a subtilisin, PfSUB1, which processes enigmatic putative proteases called serine-repeat antigens that contribute to merozoite egress. A new report also suggests that calcium-activated host proteases called calpains aid parasite exit, possibly by acting upon the host cytoskeleton. Together these discoveries reveal important new molecular players involved in the principal steps of egress by apicomplexans.     

Molecular basis of anticoagulant and anticomplement activity of the tick salivary protein Salp14 and its homologs

During feeding, a tick''s mouthpart penetrates the host''s skin and damages tissues and small blood vessels, triggering the extrinsic coagulation and lectin complement pathways. To elude these defense mechanisms, ticks secrete multiple anticoagulant proteins and complement system inhibitors in their saliva. Here, we characterized the inhibitory activities of the homologous tick salivary proteins tick salivary lectin pathway inhibitor, Salp14, and Salp9Pac from Ixodesscapularis in the coagulation cascade and the lectin complement pathway. All three proteins inhibited binding of mannan-binding lectin to the polysaccharide mannan, preventing the activation of the lectin complement pathway. In contrast, only Salp14 showed an appreciable effect on coagulation by prolonging the lag time of thrombin generation. We found that the anticoagulant properties of Salp14 are governed by its basic tail region, which resembles the C terminus of tissue factor pathway inhibitor alpha and blocks the assembly and/or activity of the prothrombinase complex in the same way. Moreover, the Salp14 protein tail contributes to the inhibition of the lectin complement pathway via interaction with mannan binding lectin–associated serine proteases. Furthermore, we identified BaSO₄-adsorbing protein 1 isolated from the tick Ornithodoros savignyi as a distant homolog of tick salivary lectin pathway inhibitor/Salp14 proteins and showed that it inhibits the lectin complement pathway but not coagulation. The structure of BaSO₄-adsorbing protein 1, solved here using NMR spectroscopy, indicated that this protein adopts a noncanonical epidermal growth factor domain–like structural fold, the first such report for tick salivary proteins. These data support a mechanism by which tick saliva proteins simultaneously inhibit both the host coagulation cascade and the lectin complement pathway.     

Measurement of protease activity of live Uronema marinun (Ciliata: Scuticociliatida) by fluorescence polarization

The proteolytic activity of live Uronema marinum was analyzed by a fluorescence polarization (FP) technique. Protease activity was measured as a decrease in the FP value using fluorescein isothiocynate (FITC)-casein as a protein substrate. A time-dependent decrease in FP occurred in plate wells containing live U. marinum. Supplementation with the cysteine protease inhibitor E-64 had no significant inhibitory effect on the decrease in FP at any of the concentrations used. In contrast, supplementation with 1,10-phenanthroline resulted in complete inhibition of proteolysis for 30 min at 1 mM and for 1 h at 2 and 5 mM. Effective inhibition of the proteolytic activity of live U. marinum by 1,10-phenanthroline indicated that metalloproteases are the main proteases excreted by U. marinum. As U. marinum has a high potential for systemically invading and destroying fish tissues, the metalloproteases excreted by live U. marinum are likely to be involved in the invasion of host tissues and the pathogenicity of the parasite.     

Interaction of intracellular proteases and immune mechanisms

Intracellular proteases play an important role both in nonspecific and specific immune reactions. Results concerning the interaction of these enzymes with phagocytic factors responsible for killing microorganisms are presented. In inflammatory foci, proteases released from destroyed leukocytes have been found to modify the function of antibodies present. They particularly reduce their complement fixation activity. Macrophages with differing proteolytic activity demonstrated diverse effects on the formation of antibodies tested by Jerne's plaque technique in young rabbits immunized with sheep erythrocytes. Whereas alveolar macrophages diminished antigen immunogenicity, peritoneal macrophages enhanced it.     

Distinct pathways of mannan-binding lectin (MBL)- and C1-complex autoactivation revealed by reconstitution of MBL with recombinant MBL-associated serine protease-2

Mannan-binding lectin (MBL) plays a pivotal role in innate immunity by activating complement after binding carbohydrate moieties on pathogenic bacteria and viruses. Structural similarities shared by MBL and C1 complexes and by the MBL- and C1q-associated serine proteases, MBL-associated serine protease (MASP)-1 and MASP-2, and C1r and C1s, respectively, have led to the expectation that the pathways of complement activation by MBL and C1 complexes are likely to be very similar. We have expressed rMASP-2 and show that, whereas C1 complex autoactivation proceeds via a two-step mechanism requiring proteolytic activation of both C1r and C1s, reconstitution with MASP-2 alone is sufficient for complement activation by MBL. The results suggest that the catalytic activities of MASP-2 split between the two proteases of the C1 complex during the course of vertebrate complement evolution.     

Regulation of skeletal muscle myofibrillar protein degradation: relationships to fatigue and exercise

1. Exercise results in large alterations in cellular metabolic homeostasis and protein turnovers. Exhaustive exercise (as well as starvation, dystrophy, motor nerve disease) results in myofibrillar degradation and has been associated with the decreased force generating capabilities of muscle at fatigue. 2. Complete protein degradation is accomplished by the combined actions of non-lysosomal and lysosomal proteases and the initial breakdown of myofibrillar protein appears to be non-lysosomal mediated. 3. Current evidence suggests that covalent modification (mixed-function oxidation, formation of mixed disulfides, oxidation of methionine residues and phosphorylation) of proteins may mark them for degradation by rendering them more susceptible to proteolytic attack. 4. The rate of covalent modification can be controlled by the level of stabilizing and destabilizing ligands and by factors affecting the activity of the marking reaction. 5. The activities of individual proteases may be controlled by activators and inhibitors. 6. It is suggested that the large alterations in metabolism (hormonal profiles, energy status, redox status and Ca2+ levels) which accompany exercise serve to activate specific proteases and/or induce covalent modifications which mark specific myofibrillar proteins for subsequent proteolytic attack.     

Characterization of the necrotic protein that regulates the Toll-mediated immune response in Drosophila

Necrotic (Nec) is an important component of the proteolytic cascade that activates the Toll-mediated immune response in Drosophila. The Nec protein is a member of the serpin (SERine Protease INhibitor) superfamily and is thought to regulate the cascade by inhibiting the serine protease Persephone. Nec was expressed in Escherichia coli, and the purified protein folded to the active native conformation required for protease inhibitory activity. Biochemical analysis showed that Nec had a broad inhibitory specificity and inhibited elastase, thrombin, and chymotrypsin-like proteases. It did not inhibit trypsin or kallikrein. These data show that Necrotic is likely to inhibit a wide range of proteases in Drosophila and that Nec has the specificity requirements to act as the physiological inhibitor of Persephone in vivo.     

Degradation of insect cuticle by Paecilomyces farinosus proteases

The entomopathogenic fungus Paecilomyces farinosus showed proteolytic activity in both solid and semi-liquid culture with gelatin as sole N and C source. Semi-liquid cultures were used to characterise proteases. Zymography of crude culture filtrates showed several bands of gelatin degradation in electrophoresis gels. Gel filtration chromatography of these filtrates revealed two peaks of proteolytic activity. Ion-exchange absorption eliminated gelatin from culture filtrates while retaining activity and was used to semipurify P. farinosus proteases. Semipurified culture filtrates had basic pH (8.5 approx.) optimum for proteolytic activity. Treatment of these filtrates with effectors revealed that P. farinosus proteases are serine proteases containing sulphydryl groups. Isoelectrofocusing combined with zymography revealed the presence of several active basic isoforms. Larvae of the lepidopteran Galleria mellonella showed cuticle damage and protein release 1h after incubation with semipurified extracts of P. farinosus. These results indicate that proteolytic enzymes could be involved in insect host penetration by P. farinosus.     

A comparative biochemical analysis of the NS2B(H)-NS3pro protease complex from four dengue virus serotypes

The two-component protease NS2B-NS3 of dengue virus mediates proteolytic processing of the polyprotein precursor and therefore represents a target for the development of antiviral drugs. The amino acid sequences of the NS3 serine protease and the NS2B cofactor exhibit relatively low degrees of conservation among the 4 serotypes thus suggesting that differences in enzyme activity exist which could modulate their susceptibility to future protease inhibitors. In this study we have addressed the question of functional similarity among the NS2B(H)-NS3pro proteases from 4 dengue virus serotypes by employing a uniform approach to clone, purify and assay proteolytic activity of these enzymes. Significant differences were observed for patterns of protein formation and expression levels in the E. coli host. Renaturation of the NS2B(H)-NS3pro precursors from dengue virus serotypes 2, 3 and 4 mediated by artificial chaperone-assisted refolding yielded enzymatically active proteases, whereas the enzyme from serotype 1 was obtained as soluble protein. Kinetic experiments using the GRR-amc substrate revealed comparable K(m) values while k(cat) values as obtained by active-site titration experiments displayed minor variations. Denaturation experiments demonstrated significant differences in half-life of the NS3 proteases from serotypes 2, 3 and 4 at 50 degrees C, whereas pH optima for all 4 enzymes were comparable.     

Digestive enzyme complement of white sturgeon (Acipenser transmontanus)

Digestive processes of 250-day-old white sturgeon were analyzed for enzyme concentrations, protein content and pH. Digestion is initiated in the gastric region by secretion of acid and pepsin; however, diversity of digestive enzymes is highest in the post-gastric alimentary canal with the greatest proteolytic activity in the spiral valve. Domination of the enzyme complement by proteases is consistent with this species carnivorous feeding habits.     

Intracellular localization of protein C inhibitor (PCI) and urinary plasminogen activator in renal tubular epithelial cells from humans and human PCI gene transgenic mice

Urinary plasminogen activator (uPA) is a serine protease that plays important roles in various extracellular proteolytic processes. In humans, protein C inhibitor (PCI) is known to regulate the activity of the serine proteases involved in blood coagulation, wound healing, and tumor metastasis, whereas PCI is not present in murine plasma or tissues other than the reproductive tissues. The large amount of uPA–PCI complexes found in human urine suggests that these complexes are formed in the kidneys. In the present study, we performed immunofluorescence double labeling and electron microscopic immunocytochemistry using renal tissues from humans and human PCI gene transgenic (PCI-TG) mice. In human renal tissues, PCI and uPA colocalized in the cytoplasm of renal proximal tubular epithelial cells (RPTECs), and juxtaposition of PCI and uPA immunoreactive particles was detected in the microvilli and lysosomes in the RPTECs. The intracellular distributions of PCI and uPA in the RPTECs from PCI-TG mice were similar to those observed in human RPTECs. These findings hint at the physiological roles of uPA and PCI in human kidneys, and also suggest that the PCI-TG mice will be useful for evaluating the roles of PCI in human physiological and pathological conditions.     

In vitro effects of Echis carinatus venom on the human plasma proteome

Echis carinatus venom (EV) is a complex mixture of toxins that contribute to its lethality. EV proteolytic activity was analyzed by zymography, chromogenic assays, and SDS-PAGE. To understand the molecular mechanism of the envenomation, we investigated the in vitro effect of EV on human plasma proteins. We looked for EV protein substrates and their proteolytic fragments. We analyzed EV proteolytic activity on standard proteins such as prothrombin or fibrinogen. To set up the optimal EV:plasma protein ratio conditions, plasma was incubated with EV (treated plasma), depleted of abundant proteins, and subjected to SDS-PAGE. Samples from control and treated plasma were also analyzed by 2-DE/MALDI-TOF MS, leading to the identification of four classes of plasma proteins cleaved by EV: proteases, protease inhibitors, binding proteins, and transporters. EV mainly proteolyzes entire proteins but can also act on physiological fragments. In summary, the physiological effects of EV proteases involve other important processes in addition to blood coagulation; complement activation and hemoglobin metabolism are also affected. In particular, the cleavage of protease inhibitors appears to be the mechanism through which the venom neutralizes the body's defenses.     

Interaction of C1q and mannan-binding lectin (MBL) with C1r, C1s, MBL-associated serine proteases 1 and 2, and the MBL-associated protein MAp19

Mannan-binding lectin (MBL) and C1q activate the complement cascade via attached serine proteases. The proteases C1r and C1s were initially discovered in a complex with C1q, whereas the MBL-associated serine proteases 1 and 2 (MASP-1 and -2) were discovered in a complex with MBL. There is controversy as to whether MBL can utilize C1r and C1s or, inversely, whether C1q can utilize MASP-1 and 2. Serum deficient in C1r produced no complement activation in IgG-coated microwells, whereas activation was seen in mannan-coated microwells. In serum, C1r and C1s were found to be associated only with C1q, whereas MASP-1, MASP-2, and a third protein, MAp19 (19-kDa MBL-associated protein), were found to be associated only with MBL. The bulk of MASP-1 and MAp19 was found in association with each other and was not bound to MBL or MASP-2. The interactions of MASP-1, MASP-2, and MAp19 with MBL differ from those of C1r and C1s with C1q in that both high salt concentrations and calcium chelation (EDTA) are required to fully dissociate the MASPs or MAp19 from MBL. In the presence of calcium, most of the MASP-1, MASP-2, and MAp19 emerged on gel-permeation chromatography as large complexes that were not associated with MBL, whereas in the presence of EDTA most of these components formed smaller complexes. Over 95% of the total MASPs and MAp19 found in serum are not complexed with MBL.     

Serine proteases of the complement system

The complement system in blood plasma is a major mediator of innate immune defence. The function of complement is to recognize, then opsonize or lyse, particulate materials, including bacteria, yeasts and other microrganisms, host cell debris and altered host cells. Recognition occurs by binding of complement proteins to charge or saccharide arrays. After recognition, a series of serine proteases is activated, culminating in the assembly of complex unstable proteases called C3/C5 convertases. These activate the complement protein C3, which acts as an opsonin. The complement serine proteases include the closely related C1r, C1s, MASPs 1-3 (80-90 kDa), C2 and Factor B (100 kDa), Factor D (25 kDa) and Factor I (85 kDa). Each of these has unusually restricted specificity and low enzymic activity. The C1r, C1s and MASP group occur as proenzymes. When activated, they are regulated, like many plasma serine proteases, by a serpin, C1-inhibitor. C2 and Factor B, however, have complex multiple regulation by a group of complement proteins called the Regulation of Complement Activation (or RCA) proteins, whereas Factors I and D appear to have no natural inhibitors. Advances in structure determination and protein-protein interaction properties are leading to a more detailed understanding of the complement-system proteases, and are indicating possible new routes for potential therapeutic control of complement.     

Stoichiometry of complexes between mannose-binding protein and its associated serine proteases. Defining functional units for complement activation

Serum mannose-binding protein (MBP) initiates the lectin branch of the complement cascade by binding to sugars on the surfaces of microorganisms and activating two MBP-associated serine proteases (MASP-1 and MASP-2). Rat serum MBP consists of oligomers containing up to four copies of a subunit that is composed of three identical polypeptide chains. Biophysical analysis of intact and truncated MASPs indicates that each MASP is a homodimer that is stabilized through interactions involving an N-terminal CUB domain. The binding sites for MBP are formed from the three N-terminal MASP domains, in which two CUB modules interact with MBP. Each MASP dimer contains binding sites for two MBP subunits. Both sites must be occupied by subunits from a single MBP oligomer to form a stable complex. Thus, the smallest functional unit for complement activation consists of MBP dimers bound to MASP-1 or MASP-2 homodimers. Trimers and tetramers of MBP form complexes containing up to two MASPs. The results reveal how MASP-1 and MASP-2 can function independently to activate the complement cascade.