Distinct contribution of Toxoplasma gondii rhomboid proteases 4 and 5 to micronemal protein protease 1 activity during invasion

Host cell entry by the Apicomplexa is associated with the sequential secretion of invasion factors from specialized apical organelles. Secretion of micronemal proteins (MICs) complexes by Toxoplasma gondii facilitates parasite gliding motility, host cell attachment and entry, as well as egress from infected cells. The shedding of MICs during these steps is mediated by micronemal protein proteases MPP1, MPP2 and MPP3. The constitutive activity of MPP1 leads to the cleavage of transmembrane MICs and is linked to the surface rhomboid protease 4 (ROM4) and possibly to rhomboid protease 5 (ROM5). To determine their importance and respective contribution to MPP1 activity, in this study ROM4 and ROM5 genes were abrogated using Cre‐recombinase and CRISPR‐Cas9 nuclease, respectively, and shown to be dispensable for parasite survival. Parasites lacking ROM4 predominantly engage in twirling motility and exhibit enhanced attachment and impaired invasion, whereas intracellular growth and egress is not affected. The substrates MIC2 and MIC6 are not cleaved in rom4‐ko parasites, in contrast, intramembrane cleavage of AMA1 is reduced but not completely abolished. Shedding of MICs and invasion are not altered in the absence of ROM5; however, this protease responsible for the residual cleavage of AMA1 is able to cleave other AMA family members and exhibits a detectable contribution to invasion in the absence of ROM4.     

Substrate specificity of rhomboid intramembrane proteases is governed by helix-breaking residues in the substrate transmembrane domain

Rhomboid intramembrane proteases initiate cell signaling during Drosophila development and Providencia bacterial growth by cleaving transmembrane ligand precursors. We have determined how specificity is achieved: Drosophila Rhomboid-1 is a site-specific protease that recognizes its substrate Spitz by a small region of the Spitz transmembrane domain (TMD). This substrate motif is necessary and sufficient for cleavage and is composed of residues known to disrupt helices. Rhomboids from diverse organisms including bacteria and vertebrates recognize the same substrate motif, suggesting that they use a universal targeting strategy. We used this information to search for other rhomboid substrates and identified a family of adhesion proteins from the human parasite Toxoplasma gondii, the TMDs of which were efficient substrates for rhomboid proteases. Intramembrane cleavage of these proteins is required for host cell invasion. These results provide an explanation of how rhomboid proteases achieve specificity, and allow some rhomboid substrates to be predicted from sequence information.     

Characterization of multiple enolase genes from Trichomonas vaginalis. Potential novel targets for drug and vaccine design

Trichomonas vaginalis is the protist parasite that causes the most common, non-viral sexually transmitted infection called trichomonosis. Enolase is a moonlighting protein that apart from its canonical function as a glycolytic enzyme, serves as a plasminogen receptor on the cell surface of T. vaginalis and, in consequence, it has been stablished as a virulence factor in this parasite. In the Trichomonas vaginalis sequence database there are nine genes annotated as enolase. In this work, we analyzed these genes as well as their products. We found that seven out of nine genes might indeed perform enolase activity, whereas two genes might have been equivocally identified, or they might be pseudogenes. Furthermore, a combination of qRT-PCR and proteomic approaches was used to assess, for the first time, the expression of these genes in the highly virulent mexican isolate of T. vaginalis CNCD-147 at different iron concentrations. We could find peptides corresponding to enolases encoded by genes TVAG_464170, TVAG_043500 and TVAG_329460. Moreover, we identified two distinctive characteristics within enolases from Trichomonas vaginalis. One of them corresponds to three key substitutions within one of the loops of the active site, compared to host enolase. The other, is a unique N-terminal motif, composed of 15 to 18 residues, on all the potentially active enolases, whose function still has to be stablished. Both differential features merit further studies as potential drug and vaccine targets as well as diagnosis markers. These findings offer new possibilities to fight trichomonosis.     

Two Plasmodium rhomboid proteases preferentially cleave different adhesins implicated in all invasive stages of malaria

Invasion of host cells by the malaria pathogen Plasmodium relies on parasite transmembrane adhesins that engage host-cell receptors. Adhesins must be released by cleavage before the parasite can enter the cell, but the processing enzymes have remained elusive. Recent work indicates that the Toxoplasma rhomboid intramembrane protease TgROM5 catalyzes this essential cleavage. However, Plasmodium does not encode a direct TgROM5 homolog. We examined processing of the 14 Plasmodium falciparum adhesins currently thought to be involved in invasion by both model and Plasmodium rhomboid proteases in a heterologous assay. While most adhesins contain aromatic transmembrane residues and could not be cleaved by nonparasite rhomboid proteins, including Drosophila Rhomboid-1, Plasmodium falciparum rhomboid protein (PfROM)4 (PFE0340c) was able to process these adhesins efficiently and displayed novel substrate specificity. Conversely, PfROM1 (PF11_0150) shared specificity with rhomboid proteases from other organisms and was the only PfROM able to cleave apical membrane antigen 1 (AMA1). PfROM 1 and/or 4 was thus able to cleave diverse adhesins including TRAP, CTRP, MTRAP, PFF0800c, EBA-175, BAEBL, JESEBL, MAEBL, AMA1, Rh1, Rh2a, Rh2b, and Rh4, but not PTRAMP, and cleavage relied on the adhesin transmembrane domains. Swapping transmembrane regions between BAEBL and AMA1 switched the relative preferences of PfROMs 1 and 4 for these two substrates. Our analysis indicates that PfROMs 1 and 4 function with different substrate specificities that together constitute the specificity of TgROM5 to cleave diverse adhesins. This is the first enzymatic analysis of Plasmodium rhomboid proteases and suggests an involvement of PfROMs in all invasive stages of the malaria lifecycle, in both the vertebrate host and the mosquito vector.     

Insights into substrate gating in H. influenzae rhomboid

Rhomboids are a remarkable class of serine proteases that are embedded in lipid membranes. These membrane-bound enzymes play key roles in cellular signaling events, and disruptions in these events can result in numerous disease pathologies, including hereditary blindness, type 2 diabetes, Parkinson's disease, and epithelial cancers. Recent crystal structures of rhomboids from Escherichia coli have focused on how membrane-bound substrates gain access to a buried active site. In E. coli, it has been shown that movements of loop 5, with smaller movements in helix 5 and loop 4, act as substrate gate, facilitating inhibitor access to rhomboid catalytic residues. Herein we present a new structure of the Haemophilus influenzae rhomboid hiGlpG, which reveals disorder in loop 5, helix 5, and loop 4, indicating that, together, they represent mobile elements of the substrate gate. Substrate cleavage assays by hiGlpG with amino acid substitutions in these mobile regions demonstrate that the flexibilities of both loop 5 and helix 5 are important for access of the substrates to the catalytic residues. Mutagenesis indicates that less mobility by loop 4 is required for substrate cleavage. A reexamination of the reaction mechanism of rhomboid substrates, whereby cleavage of the scissile bond occurs on the si-face of the peptide bond, is discussed.     

Sharpening rhomboid specificity by dimerisation and allostery

In this issue of The EMBO Journal, mechanistic analyses of substrate cleavage by rhomboid intramembrane proteases suggest that catalytic efficiency towards natural, transmembrane substrates is allosterically stimulated by initial substrate interaction with an intramembrane exosite, whose formation depends on rhomboid dimerisation. In the realm of intramembrane proteolysis, dimerisation and allosteric cooperativity represent new concepts that, once confirmed more broadly, should radically alter our view of how these proteases work.     

Downregulation of an Entamoeba histolytica Rhomboid Protease Reveals Roles in Regulating Parasite Adhesion and Phagocytosis

Entamoeba histolytica is a deep-branching eukaryotic pathogen. Rhomboid proteases are intramembrane serine proteases, which cleave transmembrane proteins in, or in close proximity to, their transmembrane domain. We have previously shown that E. histolytica contains a single functional rhomboid protease (EhROM1) and has unique substrate specificity. EhROM1 is present on the trophozoite surface and relocalizes to internal vesicles during erythrophagocytosis and to the base of the cap during surface receptor capping. In order to further examine the biological function of EhROM1 we downregulated EhROM1 expression by >95% by utilizing the epigenetic silencing mechanism of the G3 parasite strain. Despite the observation that EhROM1 relocalized to the cap during surface receptor capping, EhROM1 knockdown [ROM(KD)] parasites had no gross changes in cap formation or complement resistance. However, ROM(KD) parasites demonstrated decreased host cell adhesion, a result recapitulated by treatment of wild-type parasites with DCI, a serine protease inhibitor with activity against rhomboid proteases. The reduced adhesion phenotype of ROM(KD) parasites was noted exclusively with healthy cells, and not with apoptotic cells. Additionally, ROM(KD) parasites had decreased phagocytic ability with reduced ingestion of healthy cells, apoptotic cells, and rice starch. Decreased phagocytic ability is thus independent of the reduced adhesion phenotype, since phagocytosis of apoptotic cells was reduced despite normal adhesion levels. The defect in host cell adhesion was not explained by altered expression or localization of the heavy subunit of the Gal/GalNAc surface lectin. These results suggest no significant role of EhROM1 in complement resistance but unexpected roles in parasite adhesion and phagocytosis.Entamoeba histolytica is an extracellular protozoan parasite and is a leading parasitic cause of death worldwide (48). The factors, which determine the outcome of amebic infection, are currently unknown, although it is likely that a combination of host and parasite determinants influence clinical outcome. A number of parasite factors required for amebic pathogenesis have been identified, including the Gal/GalNAc surface lectin, pore-forming proteins, and cysteine proteases (36,–38, 41).Recently, we identified several members of a class of intramembrane rhomboid proteases in the E. histolytica genome (4). Rhomboid proteases are seven-pass transmembrane proteases first identified in Drosophila melanogaster whose active site lies within the lipid bilayer, allowing them to cleave transmembrane proteins (6, 32). Substrates of rhomboid proteases are largely single-pass transmembrane proteins whose transmembrane domain contains helix-breaking residues (52). Recent work has revealed that there are multiple classes of rhomboid proteases that recognize different types of sequences within the transmembrane domains of their substrates (3). Despite low sequence similarity between individual rhomboid proteases of each class, these enzymes share a remarkable ability to functionally replace one another (16, 28, 52).Rhomboid proteases have been studied in flies, bacteria, mammals, and parasites, and roles ranging from quorum sensing to host cell entry have been identified (3, 11, 25, 33, 35, 46, 47, 49, 54, 59). In apicomplexan parasites, such as Plasmodium falciparum and Toxoplasma gondii, it has been suggested that rhomboid proteases mediate cleavage of surface adhesin proteins to facilitate host cell entry (3, 11, 46, 47). The E. histolytica genome encodes four rhomboid-like genes, with only a single gene containing the necessary catalytic residues for proteolytic activity (4). This gene, EhROM1, is a functional protease with substrate specificity similar to the P. falciparum ROM4 (PfROM4) (3, 4). In trophozoites EhROM1 is localized to the parasite surface and relocalizes to internal vesicles during erythrophagocytosis and to the base of the cap during surface receptor capping. We have shown that the heavy subunit of the amebic surface Gal/GalNAc lectin (Hgl) is a substrate of EhROM1 in vitro. Mutational analyses using a COS cell cleavage assay demonstrated that the cleavage of Hgl requires the catalytic serine in EhROM1 as well as a helix-breaking glycine residue in the transmembrane domain of Hgl (4). These data indicate that EhROM1 is a functional rhomboid protease whose physiological substrate may be Hgl.In order to further elucidate the biological function of EhROM1 we have utilized the epigenetic silencing mechanism of the E. histolytica G3 strain (8, 9). The mechanism of gene silencing in G3 ameba is not well understood. However, it is known that the silencing mechanism is epigenetically maintained, and epigenetic changes in the chromatin state of the silenced genes have been noted (22). G3 parasites transfected with a plasmid containing an upstream region of the 5′ end of EhROM showed almost complete downregulation of expression; we have named these parasites ROM(KD) for ROM knockdown. Phenotypes examined in ROM(KD) parasites included cap formation, complement resistance, adhesion, phagocytosis, hemolysis, and motility. We observed defects in both adhesion and phagocytosis in the ROM(KD) parasites compared to the parent G3 strain but no changes in cap formation or complement resistance. Importantly, the reduced phagocytosis phenotype appears independent of the reduced adhesion phenotype, implying that EhROM1 has distinct roles in both pathways.     

A New Class of Rhomboid Protease Inhibitors Discovered by Activity-Based Fluorescence Polarization

Rhomboids are intramembrane serine proteases that play diverse biological roles, including some that are of potential therapeutical relevance. Up to date, rhomboid inhibitor assays are based on protein substrate cleavage. Although rhomboids have an overlapping substrate specificity, substrates cannot be used universally. To overcome the need for substrates, we developed a screening assay using fluorescence polarization activity-based protein profiling (FluoPol ABPP) that is compatible with membrane proteases. With FluoPol ABPP, we identified new inhibitors for the E. coli rhomboid GlpG. Among these was a structural class that has not yet been reported as rhomboid inhibitors: β-lactones. They form covalent and irreversible complexes with the active site serine of GlpG. The presence of alkyne handles on the β-lactones also allowed activity-based labeling. Overall, these molecules represent a new scaffold for future inhibitor and activity-based probe development, whereas the assay will allow inhibitor screening of ill-characterized membrane proteases.     

Structure and Mechanism of Rhomboid Protease

Rhomboid protease was first discovered in Drosophila. Mutation of the fly gene interfered with growth factor signaling and produced a characteristic phenotype of a pointed head skeleton. The name rhomboid has since been widely used to describe a large family of related membrane proteins that have diverse biological functions but share a common catalytic core domain composed of six membrane-spanning segments. Most rhomboid proteases cleave membrane protein substrates near the N terminus of their transmembrane domains. How these proteases function within the confines of the membrane is not completely understood. Recent progress in crystallographic analysis of the Escherichia coli rhomboid protease GlpG in complex with inhibitors has provided new insights into the catalytic mechanism of the protease and its conformational change. Improved biochemical assays have also identified a substrate sequence motif that is specifically recognized by many rhomboid proteases.     

Proteome Analysis of the Surface of Trichomonas vaginalis Reveals Novel Proteins and Strain-dependent Differential Expression

The identification of surface proteins on the plasma membrane of pathogens is of fundamental importance in understanding host-pathogen interactions. Surface proteins of the extracellular parasite Trichomonas are implicated in the initial adherence to mucosal tissue and are likely to play a critical role in the long term survival of this pathogen in the urogenital tract. In this study, we used cell surface biotinylation and multidimensional protein identification technology to identify the surface proteome of six strains of Trichomonas vaginalis with differing adherence capacities to vaginal epithelial cells. A combined total of 411 proteins were identified, and of these, 11 were found to be more abundant in adherent strains relative to less adherent parasites. The mRNA levels of five differentially expressed proteins selected for quantitative RT-PCR analysis mirrored their observed protein levels, confirming their up-regulation in highly adherent strains. As proof of principle and to investigate a possible role in pathogenesis for differentially expressed proteins, gain of function experiments were performed using two novel proteins that were among the most highly expressed surface proteins in adherent strains. Overexpression of either of these proteins, TVAG_244130 or TVAG_166850, in a relatively non-adherent strain increased attachment of transfected parasites to vaginal epithelial cells ∼2.2-fold. These data support a role in adhesion for these abundant surface proteins. Our analyses demonstrate that comprehensive profiling of the cell surface proteome of different parasite strains is an effective approach to identify potential new adhesion factors as well as other surface molecules that may participate in establishing and maintaining infection by this extracellular pathogen.The flagellated protozoan parasite Trichomonas vaginalis is the etiologic agent of trichomoniasis, the most common non-viral sexually transmitted infection worldwide with an estimated 174 million new cases annually (1). Although asymptomatic infection by T. vaginalis is common, multiple symptoms and pathologies can arise in both men and women, including vaginitis, urethritis, prostatitis, low birth weight infants and preterm delivery, premature rupture of membranes, and infertility (2–5). T. vaginalis has also emerged as an important cofactor in amplifying human immunodeficiency virus spread (6) as individuals infected with T. vaginalis have a significantly increased incidence of human immunodeficiency virus transmission (7, 8). T. vaginalis infection likewise increases the risk of cervical and aggressive prostate cancers (9–11).Despite the serious consequences that can arise from trichomoniasis, the underlying biochemical processes that lead to T. vaginalis pathogenesis are not well defined. Because T. vaginalis is an obligate extracellular pathogen, adherence to epithelial cells is critical for parasite survival within the human host (12). Several in vitro studies indicate that adhesion of the parasite to target mucosal epithelial cells is essential for the maintenance of infection and for cytopathogenicity (13, 14). T. vaginalis adherence to host cells is mediated, in part, by a lipophosphoglycan (LPG)¹ that coats the surface of the parasite, and altering the sugar content of this LPG reduces both adherence and cytotoxicity (15). Moreover, the mammalian protein galectin-1 binds to T. vaginalis in a carbohydrate-dependent manner via a direct interaction with parasite LPG (16). Knockdown of galectin-1 in mammalian cells, however, reduces parasite binding only by ∼17% (16). Although galectin-1-mediated interactions between T. vaginalis LPG and host cell glycoconjugates may be central in establishing infection, it is clear that parasite adhesion factors in addition to LPG are likely to be involved in host-parasite interaction. Surface proteins are likely to play important roles in the initial adherence to mucosal tissue as well as the long term survival of the pathogen on mucosal surfaces.The outcome of infection with T. vaginalis is highly variable. Possible explanations for this phenomenon include host immunity, host nutritional status, and the vaginal microbiota. Additionally, genetic differences between T. vaginalis isolates leading to differences in adherence and cytotoxicity capacities are likely to result in differences in disease progression. Recently, geographically diverse T. vaginalis strains that are significantly more cytotoxic to host cells than laboratory-adapted strains have become available (17, 18), paving the way toward comparative studies aimed at identifying proteins that correlate with virulent phenotypes.Despite the importance of T. vaginalis surface proteins as a critical interface for pathogen-host interactions, there has been no systematic investigation of the surface proteins of this parasite. The T. vaginalis genome is large and encodes a massive proteome with a considerable and diverse repertoire of candidate surface proteins (19). For example, sequence analysis programs that predict transmembrane protein topology identified over 5100 T. vaginalis proteins with one or more transmembrane domains (20). Furthermore, over 300 annotated proteins with predicted transmembrane domains also contain protein motifs common to surface proteins from other pathogens known to contribute to mucosal colonization and other pathogenic processes (20). The vast number and diversity of possible surface proteins necessitates a multitiered approach using complementary genomics and proteomics analyses to identify candidates for focused functional studies.Biotinylation of proteins at the cell surface with an impermeable reagent followed by specific purification of these proteins using streptavidin has successfully been used for the enrichment and identification of surface proteins (21–24). The high avidity binding of biotin to streptavidin greatly enhances membrane protein purification, a challenging feat because of the low abundance of membrane proteins in total cellular extracts. Here, we used this approach to profile the surface plasma membrane proteome of T. vaginalis and to identify proteins that are differentially expressed in adherent relative to less adherent strains of the parasite. To the best of our knowledge, this is the first study to systematically identify and characterize proteins at the surface of Trichomonas parasites. Defining the parasite cell surface proteome is a critical step toward understanding the relative abundance of surface proteins in strains with varying virulence properties. This information will be critical for defining the role surface proteins play in mediating contact between the parasite and host cells as well as the resulting intracellular and extracellular signals that contribute to establishing and maintaining infection. Additionally, conserved surface molecules unique to T. vaginalis that might serve as specific vaccine candidates can be revealed using this approach. The prevalence of trichomoniasis among women of reproductive age (25) and its correlation with AIDS transmission and cervical and prostate cancers (6, 8–11) provide strong arguments for the need to develop vaccines against this human pathogen.     

Rhomboid proteases in invasion and replication of Apicomplexa

In this issue of Molecular Microbiology, Rugarabamu and colleagues investigate the role of rhomboid proteases responsible for adhesin shedding during invasion of the apicomplexan parasite Toxoplasma gondii. This study, together with several other recent publications, raises new questions about the function of these rhomboids in Toxoplasma, while also strongly arguing against other recently proposed roles for these proteases.     

Role of rhomboid proteases in bacteria

The first member of the rhomboid family of intramembrane serine proteases in bacteria was discovered almost 20 years ago. It is now known that rhomboid proteins are widely distributed in bacteria, with some bacteria containing multiple rhomboids. At the present time, only a single rhomboid-dependent function in bacteria has been identified, which is the cleavage of TatA in Providencia stuartii. Mutational analysis has shown that loss of the GlpG rhomboid in Escherichia coli alters cefotaxime resistance, loss of the YqgP (GluP) rhomboid in Bacillus subtilis alters cell division and glucose uptake, and loss of the MSMEG_5036 and MSMEG_4904 genes in Mycobacterium smegmatis results in altered colony morphology, biofilm formation and antibiotic susceptibilities. However, the cellular substrates for these proteins have not been identified. In addition, analysis of the rhombosortases, together with their possible Gly-Gly CTERM substrates, may shed new light on the role of these proteases in bacteria. This article is part of a Special Issue entitled: Intramembrane Proteases.     

Ectopic Expression of a Neospora caninum Kazal Type Inhibitor Triggers Developmental Defects in Toxoplasma and Plasmodium

Regulated proteolysis is known to control a variety of vital processes in apicomplexan parasites including invasion and egress of host cells. Serine proteases have been proposed as targets for drug development based upon inhibitor studies that show parasite attenuation and transmission blockage. Genetic studies suggest that serine proteases, such as subtilisin and rhomboid proteases, are essential but functional studies have proved challenging as active proteases are difficult to express. Proteinaceous Protease Inhibitors (PPIs) provide an alternative way to address the role of serine proteases in apicomplexan biology. To validate such an approach, a Neospora caninum Kazal inhibitor (NcPI-S) was expressed ectopically in two apicomplexan species, Toxoplasma gondii tachyzoites and Plasmodium berghei ookinetes, with the aim to disrupt proteolytic processes taking place within the secretory pathway. NcPI-S negatively affected proliferation of Toxoplasma tachyzoites, while it had no effect on invasion and egress. Expression of the inhibitor in P. berghei zygotes blocked their development into mature and invasive ookinetes. Moreover, ultra-structural studies indicated that expression of NcPI-S interfered with normal formation of micronemes, which was also confirmed by the lack of expression of the micronemal protein SOAP in these parasites. Our results suggest that NcPI-S could be a useful tool to investigate the function of proteases in processes fundamental for parasite survival, contributing to the effort to identify targets for parasite attenuation and transmission blockage.     

BLT1-mediated O-GlcNAcylation is required for NOX2-dependent migration,exocytotic degranulation and IL-8 release of human mast cell induced by Trichomonas vaginalis-secreted LTB4

Trichomonas vaginalis is a sexually-transmitted protozoan parasite that causes vaginitis and cervicitis. Although mast cell activation is important for provoking tissue inflammation during infection with parasites, information regarding the signaling mechanisms in mast cell activation and T. vaginalis infection is limited. O-linked N-acetylglucosamine (O-GlcNAc) is a post-translational modification of serine and threonine residues that functions as a critical regulator of intracellular signaling, regulated by O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA). We investigated if O-GlcNAcylation was associated with mast cell activation induced by T. vaginalis-derived secretory products (TvSP). Modified TvSP collected from live trichomonads treated with the 5-lipooxygenase inhibitor AA861 inhibited migration of mast cells. This result suggested that mast cell migration was caused by stimulation of T. vaginalis-secreted leukotrienes. Using the BLT1 antagonist U75302 or BLT1 siRNA, we found that migration of mast cells was evoked via LTB₄ receptor (BLT1). Furthermore, TvSP induced protein O-GlcNAcylation and OGT expression in HMC-1 cells, which was prevented by transfection with BLT1 siRNA. TvSP-induced migration, ROS generation, CD63 expression and IL-8 release were significantly suppressed by pretreatment with OGT inhibitor ST045849 or OGT siRNA. These results suggested that BLT1-mediated OGlcNAcylation was important for mast cell activation during trichomoniasis.     

The Pathogenesis of Human Cervical Epithelium Cells Induced by Interacting with Trichomonas vaginalis

Background

Trichomonas vaginalis is a protozoan parasite that occurs in the urogenital-vaginal tract and is the primary causative agent of trichomoniasis, a common sexually transmitted disease in humans. The aggregation of this protozoan tends to destroy epithelial cells and induce pathogenesis.

Principal Findings

This study cultured T. vaginalis and human cervical epithelial cells (Z172) under the same conditions in the experiments. Following co-culturing for ten hours, the protozoans became attached to Z172, such that the cells presented a round shape and underwent shrinkage. Time-lapse recording and flow cytometry on interacted Z172 revealed that 70% had been disrupted, 18% presented a necrosis-like morphology and 8% showed signs of apoptosis. Gene expression profiling revealed in the seven inflammatory Z172 genes as well as in T. vaginalis genes that code for adhesion proteins 65 and 65-1.

Significance

These results suggest that cytopathogenic effects progress while Z172 is in contact with T. vaginalis, and the resulting morphological changes can be categorized as disruption.     

Unnatural amino acids increase activity and specificity of synthetic substrates for human and malarial cathepsin C

Mammalian cathepsin C is primarily responsible for the removal of N-terminal dipeptides and activation of several serine proteases in inflammatory or immune cells, while its malarial parasite ortholog dipeptidyl aminopeptidase 1 plays a crucial role in catabolizing the hemoglobin of its host erythrocyte. In this report, we describe the systematic substrate specificity analysis of three cathepsin C orthologs from Homo sapiens (human), Bos taurus (bovine) and Plasmodium falciparum (malaria parasite). Here, we present a new approach with a tailored fluorogenic substrate library designed and synthesized to probe the S1 and S2 pocket preferences of these enzymes with both natural and a broad range of unnatural amino acids. Our approach identified very efficiently hydrolyzed substrates containing unnatural amino acids, which resulted in the design of significantly better substrates than those previously known. Additionally, in this study significant differences in terms of the structures of optimal substrates for human and malarial orthologs are important from the therapeutic point of view. These data can be also used for the design of specific inhibitors or activity-based probes.     

Shedding of TRAP by a Rhomboid Protease from the Malaria Sporozoite Surface Is Essential for Gliding Motility and Sporozoite Infectivity

Plasmodium sporozoites, the infective stage of the malaria parasite, move by gliding motility, a unique form of locomotion required for tissue migration and host cell invasion. TRAP, a transmembrane protein with extracellular adhesive domains and a cytoplasmic tail linked to the actomyosin motor, is central to this process. Forward movement is achieved when TRAP, bound to matrix or host cell receptors, is translocated posteriorly. It has been hypothesized that these adhesive interactions must ultimately be disengaged for continuous forward movement to occur. TRAP has a canonical rhomboid-cleavage site within its transmembrane domain and mutations were introduced into this sequence to elucidate the function of TRAP cleavage and determine the nature of the responsible protease. Rhomboid cleavage site mutants were defective in TRAP shedding and displayed slow, staccato motility and reduced infectivity. Moreover, they had a more dramatic reduction in infectivity after intradermal inoculation compared to intravenous inoculation, suggesting that robust gliding is critical for dermal exit. The intermediate phenotype of the rhomboid cleavage site mutants suggested residual, albeit inefficient cleavage by another protease. We therefore generated a mutant in which both the rhomboid-cleavage site and the alternate cleavage site were altered. This mutant was non-motile and non-infectious, demonstrating that TRAP removal from the sporozoite surface functions to break adhesive connections between the parasite and extracellular matrix or host cell receptors, which in turn is essential for motility and invasion.     

Toxoplasma gondii transmembrane microneme proteins and their modular design

Host cell invasion by the Apicomplexa critically relies on regulated secretion of transmembrane micronemal proteins (TM‐MICs). Toxoplasma gondii possesses functionally non‐redundant MIC complexes that participate in gliding motility, host cell attachment, moving junction formation, rhoptry secretion and invasion. The TM‐MICs are released onto the parasite's surface as complexes capable of interacting with host cell receptors. Additionally, TgMIC2 simultaneously connects to the actomyosin system via binding to aldolase. During invasion these adhesive complexes are shed from the surface notably via intramembrane cleavage of the TM‐MICs by a rhomboid protease. Some TM‐MICs act as escorters and assure trafficking of the complexes to the micronemes. We have investigated the properties of TgMIC6, TgMIC8, TgMIC8.2, TgAMA1 and the new micronemal protein TgMIC16 with respect to interaction with aldolase, susceptibility to rhomboid cleavage and presence of trafficking signals. We conclude that several TM‐MICs lack targeting information within their C‐terminal domains, indicating that trafficking depends on yet unidentified proteins interacting with their ectodomains. Most TM‐MICs serve as substrates for a rhomboid protease and some of them are able to bind to aldolase. We also show that the residues responsible for binding to aldolase are essential for TgAMA1 but dispensable for TgMIC6 function during invasion.