Analysis of the conserved cysteine periodicity of Paramecium variable surface antigens

The major surface antigens expressed by free-living and parasitic protozoa commonly contain repeating cysteine motifs. Despite the common occurrence of these repeats their functional significance remains largely unexplored. In this paper we investigate the conserved cysteine repeats within the variable surface antigens of Paramecium tetraurelia. We show that deletion of 2 entire repeating units or portions of repeats near the N-terminus does not prevent expression of the A51 variable surface antigen. Alteration of a single cysteine to serine residue also has no effect on A51 expression. In contrast, deletions near the C-terminus of the protein have identified a small segment within the repeats that is required for expression on the surface. The required region contains a number of conserved amino acid residues, yet site-directed mutagenesis of two residues (serine and threonine to alanine) did not prevent expression. These studies demonstrate the feasibility of using deletion analysis to identify regions critical for the expression of cysteine-rich surface antigens. The relationship of these results to the structure and expression of cysteine-rich surface proteins in other protozoa is discussed.     

The I-antigens of Ichthyophthirius multifiliis are GPI-Anchored Proteins

The parasitic ciliate Ichthyophthirius multifiliis has abundant surface membrane proteins (i-antigens) that when clustered, trigger rapid, premature exit from the host. Similar antigens are present in free-living ciliates and are GPI-anchored in both Paramecium and Tetrahymena. Although transmembrane signalling through GPI-anchored proteins has been well-documented in metazoan cells, comparable phenomena have yet to be described in protists. Since premature exit of Ichthyophthirius is likely to involve a transmembrane signalling event, we sought to determine whether i-antigens are GPI-anchored in these cells as well. Based on their solubility properties in Triton X-114, the i-antigens of Ichthyophthirius are amphiphilic in nature and partition with the detergent phase. Nevertheless, following treatment of detergent lysates with phospholipase C, the same proteins become hydrophilic. Concomitantly, they are recognized by antibodies against a cross-reacting determinant exposed on virtually all GPI-anchored proteins following cleavage with phospholipase C. Finally, when expressed in recombinant form in Tetrahymena thermophila, full-length i-antigens are restricted to the membrane, while those lacking hydrophobic C-termini are secreted from the cell. Taken together, these observations argue strongly that the i-antigens of Ichthyophthirius multifiliis are, in fact, GPI-anchored proteins.     

Antigen rearrangements in Colpoda maupasi cells after freezing at −196 °C, and after shortwave ultraviolet irradiation

Changes in the antigenic content of resting cysts of ciliates after freezing at −196 °C have been studied. The results obtained from experiments with native immunosera using the immobilizing and agglutinating activity allow the conclusion that freezing causes significant changes in the cyst surface antigens. Ultraviolet irradiation did not cause any notable shifts in the surface antigen composition.By means of immunodiffusion methods, changes in the soluble antigen set of cysts after freezing have been demonstrated. Freezing induces a specific simplification in the antigen spectrum and a new antigen appearance characteristic of cysts subjected to freezing.     

Diverse modes of reproduction in the marine free-living ciliate <Emphasis Type="Italic">Glauconema trihymene</Emphasis>

Background  

Most free-living ciliates reproduce by equal fission or budding during vegetative growth. In certain ciliates, reproduction occurs inside the cyst wall, viz. reproductive cysts, but more complex reproductive strategies have generally been thought to be confined to parasitic or symbiotic species, e.g. Radiophrya spp.     

Macroevolutionary analyses of ciliates associated with hosts support high diversification rates

Ciliophora is a phylum that is comprised of extremely diverse microorganisms with regard to their morphology and ecology. They may be found in various environments, as free-living organisms or associated with metazoans. Such associations range from relationships with low metabolic dependence such as epibiosis, to more intimate relationships such as mutualism and parasitism. We know that symbiotic relationships occur along the whole phylogeny of the group, however, little is known about their evolution. Theoretical studies show that there are two routes for the development of parasitism, yet few authors have investigated the evolution of these characteristics using molecular tools. In the present study, we inferred a wide dated molecular phylogeny, based on the 18S rDNA gene, for the entire Ciliophora phylum, mapped life habits throughout the evolutionary time, and evaluated whether symbiotic relationships were linked to the variation in diversification rates and to the mode of evolution of ciliates. Our results showed that the last common ancestor for Ciliophora was likely a free-living organism, and that parasitism is a recent adaptation in ciliates, emerging more than once and independently via two distinct routes: (i) a free-living ciliate evolved into a mutualistic organism and, later, into a parasitic organism, and (ii) a free-living ciliate evolved directly into a parasitic organism. Furthermore, we have found a significant increase in the diversification rate of parasitic and mutualistic ciliates compared with their free-living conspecifics. The evolutionary success in different lineages of symbiont ciliates may be associated with many factors including type and colonization placement on their host, as well as physical and physiological conditions made available by the hosts.     

DNA Double-Strand Breaks and Telomeres Play Important Roles in Trypanosoma brucei Antigenic Variation

Human-infecting microbial pathogens all face a serious problem of elimination by the host immune response. Antigenic variation is an effective immune evasion mechanism where the pathogen regularly switches its major surface antigen. In many cases, the major surface antigen is encoded by genes from the same gene family, and its expression is strictly monoallelic. Among pathogens that undergo antigenic variation, Trypanosoma brucei (a kinetoplastid), which causes human African trypanosomiasis, Plasmodium falciparum (an apicomplexan), which causes malaria, Pneumocystis jirovecii (a fungus), which causes pneumonia, and Borrelia burgdorferi (a bacterium), which causes Lyme disease, also express their major surface antigens from loci next to the telomere. Except for Plasmodium, DNA recombination-mediated gene conversion is a major pathway for surface antigen switching in these pathogens. In the last decade, more sophisticated molecular and genetic tools have been developed in T. brucei, and our knowledge of functions of DNA recombination in antigenic variation has been greatly advanced. VSG is the major surface antigen in T. brucei. In subtelomeric VSG expression sites (ESs), VSG genes invariably are flanked by a long stretch of upstream 70-bp repeats. Recent studies have shown that DNA double-strand breaks (DSBs), particularly those in 70-bp repeats in the active ES, are a natural potent trigger for antigenic variation in T. brucei. In addition, telomere proteins can influence VSG switching by reducing the DSB amount at subtelomeric regions. These findings will be summarized and their implications will be discussed in this review.     

Antigenic variation in Giardia lamblia

Giardia lamblia undergo surface antigenic variation in vitro and in vivo. The presence of variant trophozoites can be detected in clones after exposure to cytotoxic monoclonal antibodies. Surviving Giardia (progeny) no longer possess the initial major surface antigen which is replaced by new antigens. Exposure of a clone from one progeny to another cytotoxic mAb specific to one newly appearing surface antigen resulted in the loss of this antigen and replacement by another set of antigens. The frequency of change was rapid (1:100-1:1000) and was dependent upon the isolate. The presence of variant populations in clones was confirmed by direct and indirect immunofluorescence using mAbs to major surface antigens of subsequent progeny. The putative amino acid sequence of a portion of one antigen revealed a cysteine-rich composition which was confirmed in this variant protein as well as others by preferential uptake of [35S]cysteine. The mechanism(s) responsible most likely involves genomic rearrangements since Southern blots revealed a family of related genes which changed frequently compared to other areas of the genome. However, expression-linked copies have not been detected. Loss and gain of surface antigens have also been found in gerbils and humans infected with defined clones, but there does not appear to be cyclical appearance of variant populations. The biological importance of antigenic variation is not known but it may contribute to chronic and/or repeated infections.     

Serological Comparison of Selected Parasitic and Free-Living Amoebae in vitro,Using Diffusion-Precipitation and Fluorescent-Antibody Technics*

SYNOPSIS. The present study has been directed to a serological comparison of three closely similar species of Entamoeba: E. histolytica, E. invadens and E. moshkovskii, and two free-living soil amoebae: Hartmannella rhysodes and Mayorella palestinensis. Except for E. histolytica and E. moshkovskii, the other amoebae used here were grown axenically; this is the first report of the use of antigenic extracts from axenic cultures of parasitic amoebae. The method described here provides a potent antigen that elicits a good antibody titer and is generally applicable to both parasitic and free-living amoebae. Amoebae pooled from well-grown cultures were thoroughly washed, sonicated and mixed with Freund's Adjuvant; this antigenic preparation was injected into rabbits. Two subcutaneous injections were given at three-week intervals, and 2-3 weeks thereafter blood was withdrawn to obtain antiserum. Agar-gel diffusion, cellulose acetate paper and fluorescent antibody technics were used to test the antigen-antibody (Ag-Ab) reactions. Results of the Ag-Ab reactions can be summarized as follows: 1) The homologous Ag-Ab reaction was obtained in all cases tested. 2) There was no serological reaction between the parasitic and free-living amoebae tested. 3) There was a definite serological reaction between H. rhysodes and M. palestinensis. 4) Multiple antigens were found in E. invadens (PZ strain) and E. histolytica (DKB strain) when they were tested against anti-PZ serum and anti-DKB serum, respectively, and no reaction was found when the other test antigens were exposed to these two antisera in gel-diffusion tests. 5) With the fluorescent antibody technic, E. histolytica (Laredo strain), E. moshkovskii (DSR strain) and E. histolytica (DKB strain) showed some degree of serological reaction in descending order when they were stained with conjugated anti-E. invadens serum.     

Adaptive surface antigen variation in Mycoplasma bovis to the host immune response

Abstract The variability of predominant Mycoplasma bovis surface antigens in the presence of specific immune pressure was analyzed in an in vitro assay to determine if M. bovis could escape immune destruction. We have shown that serum antibodies from immunized or experimentally infected calves and monoclonal antibodies which specifically react with previously characterized or as yet undefined major M. bovis membrane surface proteins cause repression of expression or shortening of the target protein, or induce switching to expression of an antigenically distinct variant protein. We have further demonstrated that removal of the inducing antibody results in reversion to the original phenotype. These results suggest that the level of expression and the length of M. bovis surface antigens in the host is modulated by cognate antibodies. According to the surface antigenic variation systems, random selection of preexisting variants resistant to antibody-mediated inhibition or direct regulation of gene expression may be means by which this organism evades host immune defences.     

Changes in antigenic profile during culture of Neoparamoeba sp., causative agent of amoebic gill disease in Atlantic salmon

Amoebic gill disease (AGD), the most serious infectious disease affecting farmed salmon in Tasmania, is caused by free-living marine amoeba Neoparamoeba sp. The parasites on the gills induce proliferation of epithelial cells initiating a hyperplastic response and reducing the surface area available for gaseous exchange. AGD can be induced in salmon by exposure to freshly isolated Neoparamoeba from AGD infected fish, however cultured Neoparamoeba are non-infective. We describe here antigenic differences between freshly isolated and in vitro cultured parasites, and within individual isolates of the parasite cultured under different conditions. Immunoblot analysis using polyclonal antisera, revealed differences in the antigen profiles of two cultured isolates of Neoparamoeba sp. when they were grown on agar versus in liquid medium. However, the antigen profiles of the two isolates were very similar when they were grown under the same culture conditions. Comparison of these antigen profiles with a preparation from parasites freshly isolated from infected gills revealed a very limited number of shared antigens. In addition monoclonal antibodies (mAbs) raised against surface antigens of cultured parasites were used in an indirect immunofluorescence assay to assess the expression of specific surface antigens of Neoparamoeba sp. after various periods in culture. Significant changes in antigen expression of freshly isolated parasites were observed after 15 days of in vitro culture. The use of mAb demonstrated progressive exposure/expression of individual antigens on the surface of the freshly isolated parasites during the period in culture.     

Genome hyperevolution and the success of a parasite

The strategy of antigenic variation is to present a constantly changing population phenotype that enhances parasite transmission, through evasion of immunity arising within, or existing between, host animals. Trypanosome antigenic variation occurs through spontaneous switching among members of a silent archive of many hundreds of variant surface glycoprotein (VSG) antigen genes. As with such contingency systems in other pathogens, switching appears to be triggered through inherently unstable DNA sequences. The archive occupies subtelomeres, a genome partition that promotes hypermutagenesis and, through telomere position effects, singular expression of VSG. Trypanosome antigenic variation is augmented greatly by the formation of mosaic genes from segments of pseudo-VSG, an example of implicit genetic information. Hypermutation occurs apparently evenly across the whole archive, without direct selection on individual VSG, demonstrating second-order selection of the underlying mechanisms. Coordination of antigenic variation, and thereby transmission, occurs through networking of trypanosome traits expressed at different scales from molecules to host populations.     

Surface antigens of Paramecium primaurelia : Membrane-bound and soluble forms

The surface antigens of Paramecium constitute a family of high molecular weight (ca 300 kD) iso-proteins whose alternative expression, adjusted to environmental conditions, involves both intergenic and interallelic exclusion. Since the surface antigen molecules had previously been shown to play a key role in the control of their own expression, it seemed important to compare the structural particularities of different surface antigens: the G and D antigens of P. primaurelia expressed at different temperatures, and which are coded by two unlinked loci. Here we demonstrate that in all cases a given surface antigen presents two biochemically distinct basic forms: a soluble form recovered from ethanolic extraction of whole cells, and a membrane-bound form recovered from ciliary membranes solubilized by detergent. The membrane-bound form differs from the soluble one by its mobility on SDS gels and by an electrophoretic mobility shift in the presence of anionic or cationic detergents. Furthermore, two 40-45 kD polypeptides sharing common determinants with soluble antigens were found exclusively in ethanolic extracts but not in ciliary membranes: the cross-reactivity of these light polypeptides with ethanol-extracted antigens could be demonstrated only after beta-mercaptoethanol treatment. Immunological comparisons between allelic and non-allelic soluble antigens demonstrate that allelic antigens share a great number of surface epitopes, most of which are not accessible in vivo, while non-allelic antigens appear to share essentially sequence-antigenic determinants. The significance of these results is discussed in relation to the mechanism of antigenic variation.     

Questions about gonococcal pilus phase- and antigenic variation

Pathogenic organisms inhabit one of several defined locations within a host where temperature, pH, and nutrients are relatively constant. While the microorganism must adapt to different environments within the host, the host immune system is the most formidable predator that can limit the growth of a pathogen. Neisseria gonorrhoeae (the gonococcus, Gc) is the causative agent of gonorrhoea, and has evolved several systems for varying the antigenicity of different surface antigens, presumably to help evade the effects of the human immune system. The On/Off/On phase variation of surface structure expression also alters the antigenic characteristics of the bacterial cell surface. Antigenic variation of the major subunit of the pilus, pilin, occurs by unidirectional, homologous recombination between a silent locus and the expression locus. The silent loci lie from 1 to 900 kb from the expression locus in the chromosome yet all can donate their sequences to the expression locus. The genetic composition of the pilin loci of two Gc strains has been elucidated, and the types of changes that lead to altered forms of the pilus have been extensively characterized. However, little is known about the precise molecular mechanisms used to allow high-frequency, non-reciprocal, chromosomal recombination between pilin loci or about what regulates the process of maintaining chromosome fidelity.     

Immune complex antigens as a tool in serodiagnosis of kala-azar

The 63 kDa surface antigen of Leishmania promastigotes is one of the most important virulent factors in establishing the host parasite relationship. This glycoprotein is revealed by surface iodination study as well as by metabolic labeling and immunoblot methods. In search of this specific antigen for serodiagnosis, immune complexes (ICs) were isolated from kala-azar patient sera and analysed by SDS-PAGE and Western immunoblotting. The immunoblot of kala-azar IC with patient sera, antipromastigote sera and anti gp63 sera detected the major antigen of 55 kDa. This recognition suggests that 55 kDa antigen and gp63 have common antigenic epitope(s). Normal IC did not react with anti gp63 sera indicating absence of this antigen in normal IC. To confirm the parasitic origin of the 55 kDa antigen of kala-azar IC, in vitro IC was formed with parasite antigen and acid dissociated kala-azar IC antibody. This indicated the antigenic similarity of the 55 kDa antigen and gp63 antigen of the parasite. This also suggested that the former antigen may have been processed from gp63. In summary, identification of parasite antigen (55 kDa) in IC of kala-azar patients' sera may be useful in developing a serodiagnostic assay of visceral leishmaniasis. Several other antigens are visualized in kala-azar IC when developed with patient sera. But specificity and efficacy of these antigens have not yet been evaluated in serodiagnosis of the disease.     

Protist Biogeography1

Autecology (cellular organelles and secretions, encystment and dispersal abilities), environmental conditions (physiological tolerances and interaction with other organisms), and evolutionary history contribute to protist biogeography, which manifests ecological and historical aspects. Ecological biogeography is seen in the influence of geochemistry on the distribution of fresh-water phytoflagellates and algae, and of moisture and vegetation type on soil-litter protists. A temporal feature is often present because many protists encyst and respond only to certain ranges of temperature and organic content. Historical biogeography has occurred by radiative host evolution on symbiotic protozoa (e.g., termite flagellates and rumen ciliates), and by the isolating effects of water currents, temperature, and density gradients on oceanic protists (coccoliths, dinoflagellates, foraminifera, radiolaria, and tintinnines). These two aspects combine in protists living on animal surfaces. Humans affect protist biogeography by increasing parasite ranges through human migrations and by water pollution. They can diminish these situations by disease control and exploiting appropriate ciliates in sewage disposal. Many free-living protozoa appear to be cosmopolitan, but mating types and isoenzyme studies suggest that speciation with its geographic connotations may be more widespread than presently appreciated.     

Genetic engineering applied to the development of vaccines

The simplest application of the modern genetic manipulation methods to vaccine development is the expression in microbial cells of genes from pathogens that encode surface antigens capable of inducing neutralizing antibodies in the host of the pathogen involved. This procedure has been exploited successfully for development of a vaccine against hepatitis B virus (HBV) that is now widely used. Similar approaches have been directed towards formulations for immunization against several other animal and human diseases and some of these preparations are now presently in trials. Of no less importance is the impact of biotechnology in providing reagents for fundamental studies of topics such as the determination of virulence, antigenic variation, virus receptors and the immunological response to viral antigens. The core antigen of HBV is a good example of a product of genetic engineering that is a valuable diagnostic reagent, and that is finding important use in immunological studies of particular pertinence to vaccine development.