Differential use of protease families for invasion by schistosome cercariae

Schistosomes are parasitic platyhelminths (flatworms) of birds and mammals. As a parasitic disease of humans, schistosomiasis ranks second only to malaria in global importance. Schistosome larvae (cercariae) must invade and penetrate skin as an initial step to successful infection of the vertebrate host. Proteolytic enzymes secreted from the acetabular glands of cercariae contribute significantly to the invasion process. In this comparative study, we analyzed protease activities secreted by cercariae of Schistosoma mansoni, Schistosoma japonicum and Schistosomatium douthitti. Using protease-family specific, irreversible active-site probes, fluorogenic peptidyl substrates, immuno-histochemistry and high-resolution mass spectrometry, considerable species differences were noted in the quantity and character of proteases. Serine proteases, the most abundant enzymes secreted by S. mansoni cercariae, were not identified in S. japonicum. In contrast, the acetabular gland contents of S. japonicum cercariae had a 40-fold greater cathepsin B-like activity than those of S. mansoni. Based on the present data and previous reports, we propose that cysteine proteases represent an archetypal tool for tissue invasion among primitive metazoa and the use of serine proteases arose later in schistosome evolution. Computational analysis of serine protease phylogeny revealed an extraordinarily distant relationship between S. mansoni serine proteases and other members of the Clan PA family S1 proteases.     

Schistosome invasion of human skin and degradation of dermal elastin are mediated by a single serine protease

Aquatic larvae (cercariae) of the trematode parasite Schistosoma mansoni rapidly penetrate human skin by degrading host proteins including elastin. Two serine proteases, one chymotrypsin-like and the second trypsin-like, have been proposed to be involved. To evaluate the relative roles of these two proteases in larval invasion, both were purified, identified by sequence, and then biochemically characterized. The trypsin-like activity was resolved into two distinct serine proteases 76% similar in predicted amino acid sequence. Southern blot analysis, genomic polymerase chain reaction, and immunolocalization demonstrated that the trypsin-like proteases are in fact not from the schistosome, but are released with larvae from the snail host Biomphalaria glabrata. Invasion inhibition assays using selective inhibitors confirmed that the chymotrypsin-like protease is the enzyme involved in skin penetration. Its ability to degrade skin elastin was confirmed, and the three sites of cleavage within elastin help define a new family of elastases.     

A blood fluke serine protease inhibitor regulates an endogenous larval elastase

The larvae of Schistosoma mansoni invade their mammalian host by utilizing a serine protease, cercarial elastase (SmCE), to degrade macromolecular proteins in host skin. The catalytic activity of serine and cysteine proteases can be regulated after activation by serpins. SmSrpQ, one of two S. mansoni serpins found in larval secretions, is only expressed during larval development and in the early stages of mammalian infection. In vitro, (35)S-SmSrpQ was able to form an SDS-stable complex with a component of the larval lysate, but no complex was detected when (35)S-SmSrpQ was incubated with several mammalian host proteases. Formation of a complex was sensitive to the protease active site inhibitors PMSF, Z-AAPF-CMK, and Z-AAPL-CMK. Western blot analysis of parasite lysates from different life stages detected a complex of comparable size to SmCE bound to SmSrpQ using anti-SmSrpQ or anti-SmCE antibodies. SmSrpQ and SmCE are located in adjacent but discrete compartments in the secretion glands of the parasite. Fluorescence immunohistochemical analysis of simulated infection showed co-localization of SmCE and SmSrpQ in host tissue suggesting a post release regulation of parasite protease activity during skin transversal. The results of this study suggest that cercarial elastase degradation of skin tissue is carefully regulated by SmSrpQ.     

The role of malaria merozoite proteases in red blood cell invasion

Invasion of red blood cells by the malaria merozoite is an essential step in the life cycle of this obligate intracellular pathogen. The molecular details of invasion are only recently becoming understood, largely through studies in related apicomplexan parasites such as Toxoplasma. Protease activity is required for successful invasion to disengage interactions between parasite adhesins and host cell receptors. Shedding of at least two essential surface proteins from the merozoite is thought to occur continuously during invasion as the parasite moves into the nascent parasitophorous vacuole. This shedding is performed by way of juxtamembrane cleavage and is mediated by a sheddase, which probably belongs to the subtilisin-like superfamily. Recent revelations have shown that transmembrane adhesins that are secreted onto the Toxoplasma tachyzoite surface and capped to its posterior pole are shed by way of cleavage within their transmembrane domains. A family of intramembrane serine proteases called rhomboids have now been identified within Apicomplexa, and one Toxoplasma rhomboid has been localized to the posterior end of the parasite. This supports their role in capping proteolysis. Proteases involved in invasion constitute potential targets for the development of new protease inhibitor-based drugs.     

Proteomic analysis of skin invasion by blood fluke larvae

Background

During invasion of human skin by schistosome blood fluke larvae (cercariae), a multicellular organism breaches the epidermis, basement membrane, and dermal barriers of skin. To better understand the pathobiology of this initial event in schistosome infection, a proteome analysis of human skin was carried out following invasion by cercariae of Schistosoma mansoni.

Methodology and Results

Human skin samples were exposed to cercariae for one-half hour to two hours. Controls were exposed to water used to collect cercariae in an identical manner, and punctured to simulate cercarial tunnels. Fluid from both control and experimental samples was analyzed by LC/MS/MS using a linear ion trap in “triple play” mode. The coexistence of proteins released by cercariae and host skin proteins from epidermis and basement membrane confirmed that cercarial tunnels in skin were sampled. Among the abundant proteins secreted by cercariae was the cercarial protease that has been implicated in degradation of host proteins, secreted proteins proposed to mediate immune invasion by larvae, and proteins implicated in protection of parasites against oxidative stress. Components of the schistosome surface tegument, previously identified with immune serum, were also released. Both lysis and apoptosis of epidermal cells took place during cercarial invasion of the epidermis. Components of lysed epidermal cells, including desmosome proteins which link cells in the stratum granulosum and stratum spinosum, were identified. While macrophage-derived proteins were present, no mast cell or lymphocyte cytokines were identified. There were, however, abundant immunoglobulins, complement factors, and serine protease inhibitors in skin. Control skin samples incubated with water for the same period as experimental samples ensured that invasion-related proteins and host protein fragments were not due to nonspecific degeneration of the skin samples.

Conclusions

This analysis identified secreted proteins from invasive larvae that are released during invasion of human skin. Analysis of specific host proteins in skin invaded by cercariae served to highlight both the histolytic events facilitating cercarial invasion, and the host defenses that attempt to arrest or retard invasion. Proteins abundant in psoriatic skin or UV and heat-stressed skin were not abundant in skin invaded by cercariae, suggesting that results did not reflect general stress in the surgically removed skin specimen. Abundant immunoglobulins, complement factors, and serine protease inhibitors in skin form a biochemical barrier that complements the structural barrier of the epidermis, basement membrane, and dermis. The fragmentation of some of these host proteins suggests that breaching of host defenses by cercariae includes specific degradation of immunoglobulins and complement, and either degradation of, or overwhelming the host protease inhibitor repertoire.     

Regulation of fibroblast migration on collagenous matrix by a cell surface peptidase complex

The invasion of migratory cells through connective tissues involves metallo- and serine types of cell surface proteases. We show that formation of a novel protease complex, consisting of the membrane-bound prolyl peptidases seprase and dipeptidyl peptidase IV (DPPIV), at invadopodia of migratory fibroblasts is a prerequisite for cell invasion and migration on a collagenous matrix. Seprase and DPPIV form a complex on the cell surface that elicits both gelatin binding and gelatinase activities localized at invadopodia of cells migrating on collagenous fibers. The protease complex participates in the binding to gelatin and localized gelatin degradation, cellular migration, and monolayer wound closure. Serine protease inhibitors can block the gelatinase activity and the localized gelatin degradation by cells. Antibodies to the gelatin-binding domain of DPPIV reduce the cellular abilities of the proteases to degrade gelatin but do not affect cellular adhesion or spreading on type I collagen. Furthermore, expression of the seprase-DPPIV complex is restricted to migratory cells involved in wound closure in vitro and in connective tissue cells during closure of gingival wounds but not in differentiated tissue cells. Thus, we have identified cell surface proteolytic activities, which are non-metalloproteases, seprase and DPPIV, that are responsible for the tissue-invasive phenotype.     

Strongyloides stercoralis: identification of a protease that facilitates penetration of skin by the infective larvae

Host invasion and tissue migration of several helminths have been linked to the expression and release of parasite-derived proteases. One of the most remarkable examples of tissue migration is that of larvae of the nematode parasite Strongyloides stercoralis, which can move through tissue at speeds of up to 10 cm per hour. We have shown the Strongyloides L3 larvae secrete a potent histolytic metalloprotease to facilitate their rapid migration. This protease has elastase activity and catalyzes the degradation of a model of dermal extracellular matrix. The importance of this enzyme in the pathogenesis of strongyloidiasis is underscored by the observation that invasion by larvae of skin in vitro is prevented by metalloprotease inhibitors. These results substantiate the role of proteases as virulence factors in strongyloidiasis, as well as other related parasitic infections, and suggest new approaches to therapy.     

A conserved subtilisin-like protein TgSUB1 in microneme organelles of Toxoplasma gondii

Proteolytic processing plays a significant role in the process of invasion by the obligate intracellular parasite Toxoplasma gondii. We have cloned a gene, TgSUB1, encoding for a subtilisin-type serine protease found in T. gondii tachyzoites. TgSUB1 protein is homologous to other Apicomplexan and bacterial subtilisins and is processed within the secretory pathway of the parasite. Initial cleavage occurs in the endoplasmic reticulum, after which the protein is transported to micronemes, vesicles that secrete early during host cell invasion. Upon stimulation of microneme secretion, TgSUB1 is cleaved into smaller products that are secreted from the parasite. This secondary processing is inhibited by brefeldin A and serine protease inhibitors. TgSUB1 is a candidate processing enzyme for several microneme proteins cleaved within the secretory pathway or during invasion.     

Surface-expressed enolases of Plasmodium and other pathogens

Enolase is the eighth enzyme in the glycolytic pathway, a reaction that generates ATP from phosphoenol pyruvate in cytosolic compartments. Enolase is essential, especially for organisms devoid of the Krebs cycle that depend solely on glycolysis for energy. Interestingly, enolase appears to serve a separate function in some organisms, in that it is also exported to the cell surface via a poorly understood mechanism. In these organisms, surface enolase assists in the invasion of their host cells by binding plasminogen, an abundant plasma protease precursor. Binding is mediated by the interaction between a lysine motif of enolase with Kringle domains of plasminogen. The bound plasminogen is then cleaved by specific proteases to generate active plasmin. Plasmin is a potent serine protease that is thought to function in the degradation of the extracellular matrix surrounding the targeted host cell, thereby facilitating pathogen invasion. Recent work revealed that the malaria parasite Plasmodium also expresses surface enolase, and that this feature may be essential for completion of its life cycle. The therapeutic potential of targeting surface enolases of pathogens is discussed.     

Novel secretory vesicle serpins,endopin 1 and endopin 2: endogenous protease inhibitors with distinct target protease specificities

Secretory vesicles of neuroendocrine cells possess multiple proteases for proteolytic processing of proteins into biologically active peptide components, such as peptide hormones and neurotransmitters. The importance of proteases within secretory vesicles predicts the presence of endogenous protease inhibitors in this subcellular compartment. Notably, serpins represent a diverse class of endogenous protease inhibitors that possess selective target protease specificities, defined by the reactive site loop domains (RSL). In the search for endogenous serpins in model secretory vesicles of neuroendocrine chromaffin cells, the presence of serpins related to alpha1-antichymotrypsin (ACT) was detected by Western blots with anti-ACT. Molecular cloning revealed the primary structures of two unique serpins, endopin 1 and endopin 2, that possess homology to ACT. Of particular interest was the observation that distinct RSL domains of these new serpins predicted that endopin 1 would inhibit trypsin-like serine proteases cleaving at basic residues, and endopin 2 would inhibit both elastase and papain that represent serine and cysteine proteases, respectively. Endopin 1 showed selective inhibition of trypsin, but did not inhibit chymotrypsin, elastase, or subtilisin. Endopin 2 demonstrated cross-class inhibition of the cysteine protease papain and the serine protease elastase. Endopin 2 did not inhibit chymotrypsin, trypsin, plasmin, thrombin, furin, or cathepsin B. Endopin 1 and endopin 2 each formed SDS-stable complexes with target proteases, a characteristic property of serpins. In neuroendocrine chromaffin cells from adrenal medulla, endopin 1 and endopin 2 were both localized to secretory vesicles. Moreover, the inhibitory activity of endopin 2 was optimized under reducing conditions, which required reduced Cys-374; this property is consistent with the presence of endogenous reducing agents in secretory vesicles in vivo. These new findings demonstrate the presence of unique secretory vesicle serpins, endopin 1 and endopin 2, which possess distinct target protease selectivities. Endopin 1 inhibits trypsin-like proteases; endopin 2 possesses cross-class inhibition for inhibition of papain-like cysteine proteases and elastase-like serine proteases. It will be of interest in future studies to define the endogenous protease targets of these two novel secretory vesicle serpins.     

Microneme rhomboid protease TgROM1 is required for efficient intracellular growth of Toxoplasma gondii

Rhomboids are serine proteases that cleave their substrates within the transmembrane domain. Toxoplasma gondii contains six rhomboids that are expressed in different life cycle stages and localized to different cellular compartments. Toxoplasma rhomboid protein 1 (TgROM1) has previously been shown to be active in vitro, and the orthologue in Plasmodium falciparum processes the essential microneme protein AMA1 in a heterologous system. We investigated the role of TgROM1 to determine its role during in vitro growth of T. gondii. TgROM1 was localized in the secretory pathway of the parasite, including the Golgi apparatus and micronemes, which contain adhesive proteins involved in invasion of host cells. However, unlike other micronemal proteins, TgROM1 was not released onto the parasite surface during cell invasion, suggesting it does not play a critical role in cell invasion. Suppression of TgROM1 using the tetracycline-regulatable system revealed that ROM1-deficient parasites were outcompeted by wild-type T. gondii. ROM1-deficient parasites showed only modest decrease in invasion but replicated more slowly than wild-type cells. Collectively, these results indicate that ROM1 is required for efficient intracellular growth by T. gondii.     

Cercarial elastase is encoded by a functionally conserved gene family across multiple species of schistosomes

Water borne cercaria(ae) of the trematode genus Schistosoma rapidly penetrate host skin. A single serine protease activity, cercarial elastase, is deposited in advance of the invading parasite by holocytosis of vesicles from ten large acetabular gland cells. Cercarial elastase activity is a composite of multiple isoforms. Genes coding for the isoforms can be divided into two classes by amino acid and promoter sequence homology. Two of the five genes identified in Schistosoma mansoni account for over 90% of the activity and protein released. The remaining genes produce little protein or are silent. Positional scanning synthetic combinatorial substrate libraries demonstrate that the two major isoforms have similar substrate specificities and are, therefore, isoenzymes. The closely related Schistosoma hematobium and the distantly related Schistosomatium douthitti also contain multiple orthologous cercarial elastase genes suggesting that gene duplication may have occurred after speciation in Schistosoma evolution and that this duplication has been conserved.     

Identification of the secreted neutral proteases from Anisakis simplex

Ingestion of larval nematodes (family: Anisakidae) can cause the human disease known as anisakiasis. After ingestion, Anisakis larvae can be invasive, penetrating host stomach or intestinal wall. Observation of larvae penetrating the tissue layers of human stomach in vitro by SEM showed tunnels and burrows were formed in the mucosa and submucosa. Based on these observations, we hypothesized that secreted proteases may be involved in the degradation of host tissue macromolecules to allow tunnel formation. Using a model of connective tissue extracellular matrix (ECM), we found that as few as 5 Anisakis simplex larvae could degrade approximately 25% of the ECM in a 16-mm culture well in 24 hr. Further characterization of the secreted proteases using synthetic peptide substrates and inhibitors revealed that there were 2 classes of proteases present: a metallo aminopeptidase and a trypsinlike serine protease. Extracts of Anisakis larvae contained a 25-kDa protease that was recognized by rabbit anti-rat trypsin antibody on western blots. This suggests that there is structural as well as functional similarity between the Anisakis trypsin and vertebrate trypsins.     

A new release on life: emerging concepts in proteolysis and parasite invasion

Cell invasion by apicomplexan pathogens such as the malaria parasite and Toxoplasma is accompanied by extensive proteolysis of zoite surface proteins (ZSPs) required for attachment and penetration. Although there is still little known about the proteases involved, a conceptual framework is emerging for the roles of proteolysis in cell invasion. Primary processing of ZSPs, which includes the trimming of terminal peptides or segmentation into multiple fragments, is proposed to activate these adhesive ligands for tight binding to host receptors. Secondary processing, which occurs during penetration, results in the shedding of ZSPs by one of two mechanistically distinct ways, shaving or capping. Resident surface proteins are typically shaved from the surface whereas adhesive ligands mobilized from intracellular secretory vesicles are capped to the posterior end of the parasite before being shed during the final steps of penetration. Intriguingly, recent studies have revealed that ZSPs can be released either by being cleaved adjacent to the membrane anchor or actually within the membrane itself. Mounting evidence suggests that intramembrane cleavage is catalysed by one or more integral membrane serine proteases of the Rhomboid family and we propose that several malaria adhesive ligands may be potential substrates for these enzymes. We also discuss the evidence that the key reason for ZSP shedding during invasion is to break the connection between parasite surface ligands and host receptors. The sequential proteolytic events associated with invasion by pathogenic protozoa may represent vulnerable pathways for the future development of synergistic anti-protozoal therapies.     

A biochemical comparison of proteases from pathogenic naegleria fowleri and non-pathogenic Naegleria gruberi

Naegleria fowleri is the etiologic agent of primary amoebic meningoencephalitis (PAM). Proteases have been suggested to be involved in tissue invasion and destruction during infection. We analyzed and compared the complete protease profiles of total crude extract and conditioned medium of both pathogenic N. fowleri and non-pathogenic Naegleria gruberi trophozoites. Using SDS-PAGE, we found differences in the number and molecular weight of proteolytic bands between the two strains. The proteases showed optimal activity at pH 7.0 and 35 degrees C for both strains. Inhibition assays showed that the main proteolytic activity in both strains is due to cysteine proteases although serine proteases were also detected. Both N. fowleri and N. gruberi have a variety of different protease activities at different pH levels and temperatures. These proteases may allow the amoebae to acquire nutrients from different sources, including those from the host. Although, the role of the amoebic proteases in the pathogenesis of PAM is not clearly defined, it seems that proteases and other molecules of the parasite as well as those from the host, could be participating in the damage to the human central nervous system.     

Immunolocalization and characterization of two novel proteases in Leishmania donovani: Putative roles in host invasion and parasite development

Two novel intracellular proteases having identical molecular mass (58 kDa) were purified from virulent Indian strain of Leishmania donovani by a combination of aprotinin-agarose affinity chromatography, ion exchange chromatography and finally continuous elution electrophoresis. Both of these proteases migrate in SDS-PAGE as a single homogeneous bands suggesting monomeric nature of these proteases. The enzyme activity of one of the proteases was inhibited by serine protease inhibitor aprotinin and another one was inhibited by metalloprotease inhibitor 1, 10 phenanthroline. The purified enzymes were thus of serine protease (SP-Ld) and metalloprotease (MP-Ld) type. The optimal pH for protease activity is 8.0 and 7.5 for SP-Ld and MP-Ld respectively. The temperature optimum for SP-Ld is 28 °C and for MP-Ld is 37 °C showing their thermostability upto 60 °C. Broad substrate (both natural and synthetic) specificity and the effect of Ca²⁺ upon these enzymes suggested novelty of these proteases. Kinetic data indicate that SP-Ld is of trypsin like as BAPNA appears to be the best substrate and MP-Ld seems to be collagenase type as it degrades azocoll with maximum efficiency. Both immunofluorescence and immune-gold electron microscopy studies revealed that the SP-Ld is localized in the flagellar pocket as well as at the surface of the parasite, whereas MP-Ld is located extensively near the flagellar pocket region. This work also suggests that the uses of anti SP-Ld and anti MP-Ld antibodies are quite significant in interfering with the process of parasite invasion and multiplication respectively. Thus the major role of SP-Ld could be predicted in invasion process as it down regulates the phagocytic activity of macrophages, and MP-Ld appears to play important roles in parasitic development.     

Infestin 1R, an intestinal subtilisin inhibitor from Triatoma infestans able to impair mammalian cell invasion by Trypanosoma cruzi

Infestins are Kazal-type serine protease inhibitors described in the midgut of Triatoma infestans, Chagas disease vector. Of all infestins, only infestin 1R (INF1R) does not control host blood coagulation, due to its inhibitory specificity for chymotrypsin-like proteases. We further investigated the effect of INF1R on cell infection by Trypanosoma cruzi. The importance of INF1R reactive site to inhibit T. cruzi cell invasion was confirmed using 1RSFTI, a synthetic cyclic peptide containing the inhibitor reactive site region hybridized to the Sunflower Trypsin Inhibitor-1 (SFTI-1). Our results suggest that INF1R efficiently inhibited parasite cell invasion. For the first time, a serine protease inhibitor, derived from T. infestans, was shown to impair cell invasion by T. cruzi, representing possible new target in parasite cell invasion.