Localization of antimicrobial peptides in the tunic of Ciona intestinalis (Ascidiacea, Tunicata) and their involvement in local inflammatory-like reactions

Tunicates comprising a wide variety of different species synthesize antimicrobial peptides as important effector molecules of the innate immune system. Recently, two putative gene families coding for antimicrobial peptides were identified in the expressed sequence tag database of the tunicate Ciona intestinalis. Two synthetic peptides representing the cationic core region of one member of each of the families displayed potent antibacterial and antifungal activities. Moreover, the natural peptides were demonstrated to be synthesized and stored in distinct hemocyte types. Here, we investigated the presence of these natural peptides, namely Ci-MAM-A and Ci-PAP-A, in the tunic of C. intestinalis considering that the ascidian tunic is a body surface barrier exposed to constant microbial assault. Furthermore, as the tunic may represent a major route of entry for pathogen invasion after its damage we monitored the location of these peptides upon a local inflammatory-like reaction induced by injection of foreign cells. Using immunocytochemistry and electron microscopy both peptides were localized to the tunic and were massively present in granulocytes of inflamed tissue. Conclusively, antimicrobial peptides may constitute a chemical barrier within the tunic of urochordates.

Structure and content of the Entamoeba histolytica genome

The intestinal parasite Entamoeba histolytica is one of the first protists for which a draft genome sequence has been published. Although the genome is still incomplete, it is unlikely that many genes are missing from the list of those already identified. In this chapter we summarise the features of the genome as they are currently understood and provide previously unpublished analyses of many of the genes.

Recombinant expression and purification of an enzymatically active cysteine proteinase of the protozoan parasite Entamoeba histolytica

Cysteine proteinases and in particular cysteine proteinase 5 (EhCP5) of Entamoeba histolytica are considered important for ameba pathogenicity. To study EhCP5 in more detail a protocol was elaborated to produce considerable amounts of the enzyme in its active form. The protein was expressed in Escherichia coli as a histidine-tagged pro-enzyme and purified to homogeneity under denaturing conditions in the presence of guanidine-HCl using nickel affinity chromatography. Renaturation was performed by 100-fold dilution in a buffer containing reduced and oxidized thiols, which led to soluble but enzymatically inactive pro-enzyme. Further processing and activation was achieved in the presence of 10 mM DTT and 0.04% SDS at 37 degrees C. Recombinant enzyme (rEhCP5) was indistinguishable from native EhCP5 purified from E. histolytica lysates. Both runs in SDS-PAGE under reducing and nonreducing conditions at positions corresponding to 27 and 29 kDa, respectively, had the same pH optima and displayed similar specific activity against azocasein. Moreover, both enzymes were active against a broad spectrum of biological and synthetic substrates such as mucin, fibrinogen, collagen, human hemoglobin, bovine serum albumin, gelatin, human IgG, Z-Arg-Arg-pNA, and Z-Ala-Arg-Arg-pNA, but not against Z-Phe-Arg-pNA. The identity of rEhCP5 as a cysteine proteinase was confirmed by inhibition with specific cysteine proteinase inhibitors. In contrast, various compounds known to specifically inhibit aspartic, metallo, or serine proteinases had no effect on rEhCP5 activity.

Novel putative saposin-like proteins of Entamoeba histolytica different from amoebapores

Amoebapores, the pore-forming proteins of Entamoeba histolytica, have been shown to play a pivotal role in the pathogenicity of the protozoan parasite. They belong to the functionally diverse family of saposin-like proteins (SAPLIPs) characterized by a conserved pattern of cysteine residues and the ability to interact with lipids. Here, we report the identification of genomic sequences encoding presumably novel SAPLIPs in E. histolytica and classify them in the structural and functional context provided by known family members. The genes of altogether 15 SAPLIPs are transcribed in the axenically cultured trophozoites as evidenced by reverse transcriptase-polymerase chain reaction. Interestingly, a remarkable sequence variety with a strong resemblance to that of known, functionally diverse SAPLIPs is present in this archaic, unicellular organism.

Cecropins, antibacterial peptides from insects and mammals, are potently fungicidal against Candida albicans

Natural products are the major source of lead compounds for drugs against human pathogens. Among the first natural peptides from animals for which a potent antibacterial activity has been recognized were the cecropins. The 30- to 40-residue alpha-helical peptides display their activity by permeabilizing the membranes of bacteria. Although originally isolated from insect hemolymph, a structural and functional correlate was also found in a mammal. Here, we report on the finding that cecropin A and B from the silk moth Cecropia as well as the porcine cecropin P1 are capable of inhibiting the growth of and to kill yeast-phase Candida albicans. The peptides were tested in radial diffusion and microbroth dilution assays. They displayed potent activity against a clinical isolate as well as against defined culture strains of the pathogenic yeast but are of exceedingly low cytotoxicity towards the human cell line Jurkat. The candidacidal properties of the intensely studied molecules known to be highly active against Gram-positive and Gram-negative bacteria may renew the interest in these natural broad-spectrum peptide antibiotics and their limited cytotoxicity to human cells may be exploited for the development of topical therapeutics against pathogens resistant to classical antibiotics.

Membrane-permeabilizing polypeptides of amoebae – constituents of an archaic antimicrobial system

Amoebae may be viewed as primitive, actively phagocytosing eukaryotic cells, many of which use bacteria as a major nutrient source. At a very archaic level, amoebae exert mechanisms which kill bacteria comparable to those found in phagocytic cells of higher organisms. Accordingly, it is tempting to suggest that the ancestors of effector cells of the innate immune system were bacteria-feeding amoebae and that their molecular armament is ancient. Here, we summarize the characteristics of antimicrobial and cytolytic 77-residue polypeptides from the protozoon Entamoeba histolytica for which correlates were found in effector cells of the mammalian immune systems. Based on the current knowledge about these small membrane-destabilizing proteins of phylogenetically extremely diverse origin, we discuss similarities and differences in their structure and activities.

Granulysin, a T cell product, kills bacteria by altering membrane permeability

Granulysin, a protein located in the acidic granules of human NK cells and cytotoxic T cells, has antimicrobial activity against a broad spectrum of microbial pathogens. A predicted model generated from the nuclear magnetic resonance structure of a related protein, NK lysin, suggested that granulysin contains a four alpha helical bundle motif, with the alpha helices enriched for positively charged amino acids, including arginine and lysine residues. Denaturation of the polypeptide reduced the alpha helical content from 49 to 18% resulted in complete inhibition of antimicrobial activity. Chemical modification of the arginine, but not the lysine, residues also blocked the antimicrobial activity and interfered with the ability of granulysin to adhere to Escherichia coli and Mycobacterium tuberculosis. Granulysin increased the permeability of bacterial membranes, as judged by its ability to allow access of cytosolic ss-galactosidase to its impermeant substrate. By electron microscopy, granulysin triggered fluid accumulation in the periplasm of M. tuberculosis, consistent with osmotic perturbation. These data suggest that the ability of granulysin to kill microbial pathogens is dependent on direct interaction with the microbial cell wall and/or membrane, leading to increased permeability and lysis.

Two novel calcium-binding proteins from cytoplasmic granules of the protozoan parasite Entamoeba histolytica

We report on the molecular characterisation of two novel granule proteins of the protozoon and human pathogen Entamoeba histolytica. The proteins, which were named grainin 1 and 2, show a considerable structural similarity to calcium-binding proteins, particularly within EF-hand motifs. Each grainin possesses three of these putative calcium-binding sites. Based on careful inspection of known structures of protein families containing EF-hands, a domain of grainin 1 covering two EF-hand motifs was modeled by homology. Calcium-binding activity of grainins was demonstrated by two independent methods. These granule proteins may be implicated in functions vital for the primitive phagocyte and destructive parasite such as control of endocytotic pathways and granule discharge.

Evidence that hyaluronidase is not involved in tissue invasion of the protozoan parasite Entamoeba histolytica

As previous reports suggested that a hyaluronidase is involved in tissue invasion of Entamoeba histolytica, we searched for such an activity in trophozoite extracts. A hyaluronidase activity was not detectable in long-term cultures or in amoebae freshly passaged through a gerbil liver, as evidenced by four different techniques.

Candidacidal activity of shortened synthetic analogs of amoebapores and NK-lysin

Natural antimicrobial peptides and synthetic analogs thereof have emerged as compounds with potentially significant therapeutical application against human pathogens. Amoebapores are 77-residue peptides with cytolytic and antibacterial activity considered to act by forming ion channels in cytoplasmic membranes of the victim cells. A functionally and structurally similar peptide named NK-lysin exists in mammalian lymphocytes. Several synthetic analogs of amoebapores and NK-lysin, which are substantially reduced in size compared to the parent molecules, were tested for their ability to inhibit the growth of and to kill Candida albicans. Some of the peptides displayed potent activity against a clinical isolate as well as against defined culture strains. Among the most active peptides found are some shortened substitution analogs of amoebapore C and a cationic core region of NK-lysin. As these peptides are also highly active against Gram-positive and Gram-negative bacteria but are of low cytotoxicity towards a human keratinocyte cell line they may provide promising templates for the design of broad-spectrum peptide antibiotics.

Pore-forming peptides of Entamoeba dispar. Similarity and divergence to amoebapores in structure, expression and activity

Amoebapore, a 77-residue peptide with pore-forming activity from the human pathogen Entamoeba histolytica, is implicated in the killing of phagocytosed bacteria and in the cytolytic reaction of the amoeba against host cells. Previously, we structurally and functionally characterized three amoebapore isoforms in E. histolytica but recognized only one homolog in the closely related but non-pathogenic species Entamoeba dispar. Here, we identified two novel amoebapore homologs from E. dispar by molecular cloning. Despite strong resemblance of the primary structures of the homologs, molecular modeling predicts a species-specific variance between the peptide structures. Parallel isolation from trophozoite extracts of the two species revealed a lower amount of pore-forming peptides in E. dispar and substantially higher activity of the major isoform from E. histolytica towards natural membranes than that from E. dispar. Differences in abundance and activity of the lytic polypeptides may have an impact on the pathogenicity of amoebae.

Antisense inhibition of amoebapore expression in Entamoeba histolytica causes a decrease in amoebic virulence

Amoebapores have been proposed to be a major pathogenicity factor of the protozoan parasite Entamoeba histolytica, which is responsible for the killing of target cells. These 77-residue peptides are structural and functional analogues of NK-lysin and granulysin of porcine and human cytotoxic lymphocytes. Inhibition of amoebapore gene expression in amoebae was obtained following transfection with a hybrid plasmid construct (pAP-R2) containing the Neo resistance gene and the gene coding for amoebapore A, including its 5' and 3' untranslated region (UTR) sequences, in reverse orientation under a promoter (g34) taken from one of the E. histolytica ribosomal protein (RP-L21) gene copies. Transfectants of virulent E. histolytica strain HM-1:IMSS, in which the expression of amoebapore was inhibited by approximately 60%, were significantly less pathogenic. Cytopathic and cytolytic activities of viable trophozoites against mammalian nucleated cells, as well as lysis of red blood cells, were markedly inhibited. Moreover, trophozoite extracts of pAP-R2 transfectant displayed lower pore-forming activity and were less potent in inhibiting bacterial growth compared with controls. Notably, liver abscess formation in hamsters by the pAP-R2 transfectant was substantially impaired. These results demonstrate for the first time that amoebapore is one of the pathogenicity factors by which trophozoites of E. histolytica exert their remarkable cytolytic and tissue destructive activity.

Comparative modeling of amoebapores and granulysin based on the NK-lysin structure-structural and functional implications

Amoebapores, the pore-forming polypeptides of the protozoan parasite Entamoeba histolytica, and effector proteins of porcine and human lymphocytes, namely NK-lysin and granulysin, reveal a substantial sequence similarity despite their enormous evolutionary distance. Moreover, all these polypeptides display antibacterial activity and are in higher concentrations cytolytic to eukaryotic cells. The recently solved NMR structure of NK-lysin enabled us to build the three dimensional structures of amoebapores and granulysin by comparative modeling. The generated models revealed the expected similarities, but also fundamental differences with respect to charge distribution, hydrophobicity and core packing. The combination of these structural properties and known biochemical data provides insight in the different membrane-interacting mechanisms of the proteins. For amoebapores, exposed hydrophobic grooves and a locally loosely packed protein core may allow a rearrangement of the protein and therefore may account for its ability to penetrate the target membrane and to form defined ion channels in planar lipid bilayers. In contrast, the structural features of NK-lysin and granulysin appear to be suitable for a membrane-perturbing mode of action rather than for channel formation.

Antimicrobial and cytolytic polypeptides of amoeboid protozoa--effector molecules of primitive phagocytes

Amoebae are primitive, actively phagocytosing eukaryotic cells, many of which use bacteria as a major nutrient source. One may suppose that amoebae possess an array of potent antimicrobial molecules acting in synergy to combat bacterial growth inside their phagosomes. Lysosome-like granular vesicles of Entamoeba histolytica contain a family of 77-residue peptides with a compact alpha-helical, disulfide-bonded fold. These polypeptides, named amoebapores, exhibit antibacterial and cytolytic activity by forming pores in membranes of various origin. It is of particular interest that amoebapores are structurally and functionally most similar to polypeptides of mammalian cytotoxic lymphocytes. In addition, amoebic granules contain bacteriolytic proteins with lysozyme-like properties. Some amoebic polypeptides may represent archaic analogs of effector molecules from invertebrates and vertebrates.

Molecular characterization of an exceptionally acidic lysozyme-like protein from the protozoon Entamoeba histolytica

The protozoan parasite Entamoeba histolytica contains a second antibacterial protein with lysozyme-like properties. The newly recognized bacteriolytic protein was purified from extracts of amoebic trophozoites to allow amino-terminal sequencing. Subsequent molecular cloning revealed that it is an isoform of the amoeba lysozyme described previously but also demonstrated a substantial sequence divergence of the two forms. As lysozymes typically are basic proteins, the novel amoebic protein differs markedly in having a pI of 4.5. There is no significant similarity of both amoeba lysozymes with any bacteriolytic protein of other organisms reported so far; however, striking sequence identity is found with predicted gene products of unknown function derived from the bacteria-feeding nematode Caenorhabditis elegans.

Isolation and molecular characterization of a surface-bound proteinase of Entamoeba histolytica

Major pathogenic functions of Entamoeba histolytica involved in destruction of host tissues are the degradation of extracellular matrix proteins mediated by secreted cysteine proteinases and contact-dependent killing of host cells via membrane-active factors. A soluble protein with an affinity for membranes was purified from amoebic extracts to apparent homogeneity. N-terminal sequencing and subsequent molecular cloning of the factor revealed that it is a member of the cysteine proteinase family of E. histolytica, which we termed CP5. Further experiments with the purified protein showed that it has potent proteolytic activity that is abrogated in the presence of inhibitors specific for cysteine proteinases. The enzyme firmly associates with membranes retaining its proteolytic activity and it produces cytopathic effects on cultured monolayers. A model of the three-dimensional structure of CP5 revealed the presence of a hydrophobic patch that may account for the potential of the protein to associate with membranes. Immunocytochemical localization of the enzyme to the surface of the amoeba in combination with the recent finding that the gene encoding CP5 is missing in the closely related but non-pathogenic Entamoeba dispar suggests a potential role of the protein in host tissue destruction of E. histolytica.

Necrosis versus apoptosis as the mechanism of target cell death induced by Entamoeba histolytica

The human pathogen Entamoeba histolytica is known to kill a variety of host cells, including leukocytes. Using human myeloid cells as targets, we studied whether cytotoxicity of amoebic trophozoites in vitro is equivalent to the induction of apoptosis or whether these target cells die via necrosis. Based upon morphological criteria, incubation of target cells with amoebae resulted in necrosis, with cell swelling, rupture of plasma membrane, and release of cell contents including nucleic acids being detected by light and transmission electron microscopy. On the other hand, the characteristic features of apoptosis such as cell shrinking, surface blebbing, and chromatin condensation were not observed. Moreover, internucleosomal fragmentation of genomic DNA within target cells as a characteristic feature of apoptotic cell death did not occur as judged by the terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling technique in combination with flow cytometry. Consistently, cleavage of DNA was detectable upon agarose gel electrophoresis only after a substantial part of the target cell population had already been lysed. We also analyzed the mechanism of cell death induced by amoebapores, pore-forming peptides and primary candidate molecules for mediating the cytolytic activity of E. histolytica. At a time point at which the majority of target cells showed membrane injury upon incubation with purified amoebapores, no DNA degradation was detectable in the victim cells. The data suggest that the target cells used in our study undergo necrosis rather than apoptosis when they are killed by viable trophozoites as well as by isolated amoebapores.

Amoebapores

The enormous cytolytic potential of Entamoeba histolytica appeals to parasitologists and immunologists because it kills target cells in a contact-dependent reaction resembling that of cytotoxic lymphocytes. In this review, Matthias Leippe summarizes what is currently known about a family of pore-forming peptides termed 'amoebapores', to which the cytolytic effect has been attributed, and describes the structural and functional properties of these potent factors, as well as their structure-activity relationships. Finally, a comparison is made with effector molecules of the mammalian defensive system.

Molecular modeling of amoebapore and NK-lysin: a four-alpha-helix bundle motif of cytolytic peptides from distantly related organisms

BACKGROUND

Amoebapore of the protozoan Entamoeba histolytica and NK-lysin of porcine cytotoxic lymphocytes are effector peptides from organisms separated extremely early in their evolutionary paths. The peptides intrigued us, however, with indications of some functional similarity. We thus wanted to derive and compare predictions for their as yet unknown three-dimensional structures as a guide for and to be tested by further experiments.

RESULTS

Molecular models were generated by use of a genetic algorithm that selects according to basic protein structure principles exploiting available information such as the primary structures, secondary structure predictions and positions of disulfide bonds. Topological differences aside, the structural motif of an antiparallel four-alpha-helix bundle with adjacent connections and intramolecular crosslinks is predicted for both types of peptides. It combines the feature of amphipathic alpha-helices with a disulfide-bonded compact structure known from the beta-sheeted defensins and small toxins.

CONCLUSIONS

The models presented here strengthen the notion that amoebapore and NK-lysin are particular among cytolytic and antibacterial polypeptides and share a similar function and structural motif. They also allow experimental testing and a better comparison of the two proteins in view of the predicted similarities and differences of their respective folds.

Entamoeba histolytica and Entamoeba dispar: differences in numbers and expression of cysteine proteinase genes

In order to identify molecules that might be responsible for the difference in pathogenicity between the two closely related protozoan parasites Entamoeba histolytica and Entamoeba dispar, we focussed on cysteine proteinases because this class of enzymes has been considered important for pathogenic tissue destruction. By screening a genomic library derived from an E. histolytica isolate, a total of six distinct genes (ehcp1-ehcp6) encoding typical prepro-forms of cysteine proteinases were identified which differed from each other by 40% to 85% of their nucleotide sequences. Three of these genes, ehcp1, ehcp2, and ehcp5, which exhibited high levels of expression, were found to be responsible for approximately 90% of cysteine proteinase transcripts, whereas the remaining three were either not or only marginally expressed. Expression of the different genes directly correlated with the level of activity of the respective enzymes in trophozoite lysates. Purification of the enzymes and N-terminal sequencing revealed that virtually all cysteine proteinase activity of E. histolytica can be attributed to three enzymes namely EhCP1, EhCP2 and EhCP5. Southern blot analysis indicated that just two of these abundantly expressed genes are missing in E. dispar. On the other hand, genes analogous to four of the six genes identified in E. histolytica were found to be present in E. dispar, but only two of these are expressed within the trophozoite stage.

Shortened amoebapore analogs with enhanced antibacterial and cytolytic activity

Amoebapores are cytolytic peptides of Entamoeba histolytica which function by the formation of ion channels in target cell membranes. Three isoforms (amoebapore A, B, and C) exist in amoebic cytoplasmic granules. They are composed of 77 amino acid residues arranged in four alpha-helical domains. In order to analyze the structure-function relationships, 15 synthetic peptides of 24-25 residues were constructed based on the assumption that the third helix is the membrane-penetrating domain and on the previous finding that positively charged residues are significant for activity. Activity of these short versions of amoebapores was determined towards artificial and natural targets, such as liposomes, bacteria, erythrocytes and a human tumor cell line. It was found that some of the novel peptides were highly active and showed a broader activity spectrum compared to the parent molecules.

Spontaneous release of cysteine proteinases but not of pore-forming peptides by viable Entamoeba histolytica

Invasive properties of pathogenic Entamoeba histolytica have been postulated to depend on the secretion or release of cysteine proteinases and pore-forming peptides (amoebapores) by trophozoites. To establish whether such toxic molecules are released by viable trophozoites or upon cellular disintegration, amoebae were maintained in various culture media, and activities in supernatants were monitored over time in correlation to cellular integrity. By measuring the release of the cytoplasmic marker enzyme NADP(+)-alcohol dehydrogenase, it became apparent that release of amoebapore was accompanied by cellular disintegration. In contrast, considerable quantities of cysteine proteinases were found to be present in culture supernatants also when amoebae remained intact. Treatment of amoebae with concanavalin A, bacterial lipopolysaccharides or the calcium ionophore A23187 did not result in amoebapore secretion suggesting that here target cell contact is required as an essential stimulus.

Purification and molecular cloning of a major antibacterial protein of the protozoan parasite Entamoeba histolytica with lysozyme-like properties

A protein with potent antibacterial activity was purified to apparent homogeneity from pathogenic Entamoeba histolytica. It resembles lysozyme in that it is a basic protein which degrades cell walls of Micrococcus luteus, displays optimal activity at acidic pH, and shows a preference for Gram-positive bacteria. The protein has a molecular mass of approximately 23 kDa upon SDS/PAGE and is localized inside the cytoplasmic granules of the amoebae. The primary structure was elucidated by protein analysis and molecular cloning of the corresponding cDNA. It yielded a protein of 198 residues with structural similarity to the distinct class of lysozymes found in Streptomyces species and the fungus Chalaropsis.

Amoebapores, a family of membranolytic peptides from cytoplasmic granules of Entamoeba histolytica: isolation, primary structure, and pore formation in bacterial cytoplasmic membranes

Three peptides with pore-forming activity were isolated from the cytoplasmic granules of pathogenic Entamoeba histolytica by acidic extraction, gel filtration and reversed-phase high-performance liquid chromatography. Partial amino acid sequence analysis of the three active peptides revealed that the most abundant of them was amoebapore and the other two were isoforms thereof. Cloning and sequencing of genomic DNA resolved the amino acid sequence of the two newly recognized peptides. The three peptides designated amoebapores A, B and C were found to have the same molecular size but to differ markedly in their primary structure, although all six cysteine residues are conserved. Despite sequence divergence, structural implications predict for the three peptides a similar amphipathic alpha-helical conformation stabilized by disulphide bonds. All three isoforms exhibit pore-forming activity toward lipid vesicles, but they differ in their kinetics. They also are capable of perturbing the integrity of bacterial cytoplasmic membranes and thereby kill Gram-positive bacteria. The amoebapores represent a distinct family of membrane-active peptides that may function intracellularly as antimicrobial agents but may also confer cytolytic activity on the parasite.

Pore-forming peptide of Entamoeba histolytica. Significance of positively charged amino acid residues for its mode of action

Amoebapore is a 77-residue pore-forming peptide from Entamoeba histolytica with antibacterial and cytolytic properties. It contains eight lysine residues and one histidine residue. Chemical modifications of amoebapore with various reagents affecting either both types of cationic residues or lysine and histidine residues separately resulted in virtually complete loss of pore-forming activity. The activity was restored by reversal of modifications. Whereas amoebapore was no longer capable of binding to phospholipid vesicles when its lysine residues were modified, the modification of the single histidine primarily affected oligomerization of the peptide upon membrane association.

Cytolytic and antibacterial activity of synthetic peptides derived from amoebapore, the pore-forming peptide of Entamoeba histolytica

The pore-forming peptide amoebapore is considered part of the cytolytic armament of pathogenic Entamoeba histolytica. Amoebapore is composed of 77 amino acid residues arranged in four alpha-helical domains. For structure-function analysis, synthetic peptides were constructed corresponding to these four domains: H1 (residues 1-22), H2 (25-39), H3 (40-64), and H4 (67-77). The peptides H1 and H3, representing two highly amphipathic alpha-helical regions of amoebapore, possessed pore-forming activity. Peptide H3 displayed cytolytic and antibacterial functions similar to those of natural amoebapore. The most potent antibacterial activity and the broadest activity spectrum were expressed by H1-Mel, a hybrid molecule composed of the N-terminal alpha-helix of amoebapore and the C-terminal hexapeptide of melittin from the venom of Apis mellifera.

The pore-forming peptide of Entamoeba histolytica, the protozoan parasite causing human amoebiasis

Amoebapore, the pore-forming peptide of E. histolytica has been isolated and its structure elucidated on the cDNA and protein level. The peptide is composed of 77 amino acid residues including six cysteine residues and has a molecular mass of 8244 Da. The primary translation product contains a signal sequence of 21 mostly hydrophobic amino acid residues. The active peptide has been located in the cytoplasmic granules of the amoebae. Circular dichroism spectroscopy revealed an all alpha-helical conformation and computer-aided secondary structure prediction yielded a structure of four helices. The helical conformation and three intramolecular disulfide bonds impart a highly compact and rigid structure upon the molecule. The activity of amoebapore, measured by a liposome depolarization assay, is resistant to heating at 100 degrees C in the absence of reducing agents. Synthetic peptides corresponding to the helices 1 and 3 exhibited pore-forming activity. Two minor, biologically active isoforms of amoebapore have amino acid sequence identity of 57% and 47%, respectively. Whereas amoebapore is a constituent of pathogenic E. histolytica isolates, nonpathogenic E. histolytica produce a structurally very similar peptide, the specific activity of which is approximately one third that of amoebapore. The biological significance of amoebapore for the pathogenicity of E. histolytica and specifically for its cytolytic activity remains to be determined.

Unusual gene organization in the protozoan parasite Entamoeba histolytica

We have analyzed three independent genomic loci of the protozoan parasite Entamoeba histolytica that contain coding regions for the iron-containing superoxide dismutase, the pore-forming peptide, and the galactose-inhibitable lectin. All of the three structural genes were found to be closely linked unidirectionally to other coding sequences. The intergenic regions did not exceed 1,350 nucleotides. Nuclear run-on data demonstrated that at least the galactose-inhibitable lectin gene is transcribed in a monocistronic fashion. Comparison of the genomic sequences described here with several others reported previously for E. histolytica revealed a number of invariable peculiarities for the gene organization of this parasite: (i) Coding sequences are not interrupted by introns; (ii) 5' untranslated regions are rather short and transcription starts at the consensus sequences ATTCA or ATCA; (iii) an unusual TATA-motif is located about 30 nucleotides upstream of the start of transcription and comprises the sequence TATTTAAA, which reveals protein binding activity as determined by gel retardation assays; (iv) the conserved pentanucleotide motif TAA/TTT is found within the relatively short 3' untranslated regions and functions putatively as the transcription termination signal; and (v) a stretch of up to 12 pyrmidine residues is located at the end of transcribed sequences.

Comparison of pore-forming peptides from pathogenic and nonpathogenic Entamoeba histolytica

Similar to the findings obtained with pathogenic Entamoeba histolytica, nonpathogenic isolates were found to kill mammalian cells in vitro, and cell extract caused pore formation in liposome membranes. A pore-forming peptide termed APnp was isolated from a nonpathogenic isolate using the schedule developed for the purification of APp or amoebapore, the homologous peptide of the pathogenic isolate HM-1:IMSS. Compared to APp, the specific activity of APnp in pore formation was 60% lower. cDNA sequencing indicated 95% identity of the primary structures of APnp and APp, and secondary structure predictions revealed a high degree of similarity. Notably, a glutamic acid residue at position 2 of APp is in APnp replaced by proline, which shortens one of the two amphipathic alpha-helices considered crucial for the pore-forming function. This structural divergence of the two peptides might explain the difference in their pore-forming activities.

Role of fibrinogen in complement inhibition by streptococcal M protein

M protein, the major virulence factor of group A streptococci, has antiopsonic activity in that it inhibits activation of the alternative complement pathway on the streptococcal surface. Two properties of M protein have been claimed to account for the inhibitory activity, namely, (i) its binding affinity for complement factor H, which is an inhibitor of alternative pathway activation, and (ii) its high binding affinity for fibrinogen. We have recently shown that fibrinogen, like M protein, inhibits alternative pathway activation by possessing binding affinity for factor H. Here we report that fibrinogen effectively competes with factor H for binding to M protein but retains its own binding affinity for factor H. The presence of fibrinogen did not significantly affect alternative pathway inhibition on the streptococcal surface.

Recent progress in the molecular biology of Entamoeba histolytica

Entamoeba histolytica, a protozoan parasite causing human amoebiasis, has recently been found to comprise two genetically distinct forms, potentially pathogenic and constitutively nonpathogenic ones. Host tissue destruction by pathogenic forms is believed to result from cell functions mediated by a lectin-type adherence receptor, a pore-forming peptide involved in host cell lysis, and abundant expression of cysteine proteinases. Comparisons of these products from pathogenic and nonpathogenic E. histolytica suggest that they have evolved to serve functions in free-living or commensal behaviour. Isolation of the corresponding genes have provided the tools for detailed structural studies and manipulations of amoeba cell functions.

Primary and secondary structure of the pore-forming peptide of pathogenic Entamoeba histolytica

A pore-forming peptide is implicated in the potent cytolytic activity of pathogenic Entamoeba histolytica. Using NH2-terminal sequence information of this peptide, the corresponding cDNA was isolated. The cDNA-deduced amino acid sequence revealed a putative signal peptide and a mature peptide of 77 amino acids including six cysteine residues. Computer-aided secondary structure analysis predicted that the peptide would be composed of four adjacent alpha-helices, and CD spectroscopy indicated an all alpha-helical conformation. The tertiary structure appears to be stabilized by three disulfide bonds; the pore-forming activity was not sensitive to heat but was lost in the presence of reducing agents. Sequence homology was found to the saposins and to surfactant-associated protein B, both mammalian polypeptides of similar size and secondary structure but of non-lytic function. In particular, the six cysteine residues were found to be conserved, suggesting a common motif for stabilizing a favourable tertiary structure. Compared with previously characterized toxic peptides also containing three disulfide bonds, the amoeba peptide may represent a distinct class of biologically active peptides.

[Recent findings on the pathogenicity of Entamoeba histolytica]

Entamoeba histolytica is the causative agent of human amoebiasis. During recent years, research in amoebiasis has concentrated on two subjects: 1. the dual manifestation of the infection as harmless colonization of the intestinal cavity or pathogenic tissue invasion and 2. the molecular analysis of functions of E. histolytica that are considered essential for pathogenicity. Besides epidemiological studies and isoenzyme analyses, molecular genetics have revealed additional evidence that two genetically distinct forms of E. histolytica do exist, named "pathogenic" and "nonpathogenic" forms, respectively. Both can infect humans but only the "pathogenic" form is able to invade the tissue and cause disease whereas the "nonpathogenic" is not. Questions remain open about the mechanism that triggers "pathogenic" E. histolytica to become invasive and about the molecules that are involved. Current data indicate that at least three functions of the amoebae are considered essential for pathogenic tissue invasion. Pathogenicity is viewed as a result of 1. adherence of the amoeba to host cells, predominantly mediated by a galactose- and N-acetylgalactosamine-inhibitable lectin, 2. killing of host cells by a pore-forming peptide known as amoebapore, and 3. proteolysis of the host's extracellular matrix mediated by cysteine proteinases. Structural detailed molecular analysis including cloning of the corresponding genes have led to a better understanding of the function of these proteins.

Host tissue destruction by Entamoeba histolytica: molecules mediating adhesion, cytolysis, and proteolysis

Entamoeba histolytica, the protozoan parasite causing human amoebiasis, has recently been found to comprise two genetically distinct forms, potentially pathogenic and constitutively nonpathogenic ones. Host tissue destruction by pathogenic forms is believed to result from cell functions mediated by a lectin-type adherence receptor, a pore-forming peptide involved in host cell lysis, and abundant expression of cysteine proteinase(s). Isolation and molecular cloning of these amoeba products have provided the tools for structural analyses and manipulations of cell functions including comparisons between pathogenic and nonpathogenic forms.

Pore-forming peptide of pathogenic Entamoeba histolytica

A polypeptide that causes pore formation in target-cell membranes is implicated in the potent cytolytic activity of pathogenic Entamoeba histolytica. Pore-forming material was purified to apparent homogeneity by a multistep procedure, and its analysis by NaDodSO4/PAGE revealed one peptide of 4-5 kDa under nonreducing or under reducing conditions. Pore-forming activity was measured by depolarization of liposome membrane potential and was found to be optimally expressed at low pH. Active material preferentially inserted into negatively charged lipid vesicles. Treatment of purified amoeba peptide in solution or bound to liposomes with glutaraldehyde revealed oligomers upon NaDodSO4/PAGE, suggesting functionally relevant peptide-peptide interactions. The NH2-terminal amino acid sequence of the amoeba peptide was determined by protein sequencing and revealed a structural similarity to melittin, the membranolytic peptide of bee venom.

Two major serum components antigenically related to complement factor H are different glycosylation forms of a single protein with no factor H-like complement regulatory functions

Factor H is a 150-kDa serum glycoprotein with key regulatory functions in the alternative pathway of complement activation. Two glycoproteins with a molecular mass of approximately 42 and 37 kDa that react with an antiserum against factor H were purified from human plasma. The two glycoproteins have identical N-terminal amino acid sequences but differ in glycosylation. Sequence comparisons indicated that they both correspond to a 1.4-kb mRNA recently cloned from human liver cDNA. The serum concentration of the two glycoproteins together was estimated to be approximately 40 mg/liter. They were found not to exert factor H-like regulatory functions in the alternative pathway. Thus, the 42-kDa glycoprotein described here appears to be distinct from the previously characterized factor H-related protein of similar size, suggesting that human serum contains two factor-H related molecules which both have a molecular mass of 41 to 43 kDa but which differ largely in structure.

Two major serum components antigenically related to complement factor H are different glycosylation forms of a single protein with no factor H-like complement regulatory functions

Factor H is a 150-kDa serum glycoprotein with key regulatory functions in the alternative pathway of complement activation. Two glycoproteins with a molecular mass of approximately 42 and 37 kDa that react with an antiserum against factor H were purified from human plasma. The two glycoproteins have identical N-terminal amino acid sequences but differ in glycosylation. Sequence comparisons indicated that they both correspond to a 1.4-kb mRNA recently cloned from human liver cDNA. The serum concentration of the two glycoproteins together was estimated to be approximately 40 mg/liter. They were found not to exert factor H-like regulatory functions in the alternative pathway. Thus, the 42-kDa glycoprotein described here appears to be distinct from the previously characterized factor H-related protein of similar size, suggesting that human serum contains two factor-H related molecules which both have a molecular mass of 41 to 43 kDa but which differ largely in structure.