Immune response of fish to parasitic protozoa

Epizootic outbreaks of fish diseases are increasingly common as a result of intensive aquaculture, fish farming and sea ranching. Very few drugs are available for treatment or prophylaxis against fish diseases, and development of such compounds is inhibited by different national regulations governing the use of chemicals in fish for human or animal consumption. Alternative approaches are urgently needed. But although the taxonomy and biology of fish parasites have been extensively studied, relatively little is known about protective immunity in fish and the effects of parasites on the piscine immune system. In this article, Patrick Woo discusses the immune responses of fish to parasitic protozoa, showing that vaccination is a viable control strategy, and stressing the need for a coordinated global research programme on fish diseases.     

TatD DNases of African trypanosomes confer resistance to host neutrophil extracellular traps

African trypanosomatid parasites escape host acquired immune responses through periodic antigenic variation of their surface coat. In this study, we describe a mechanism by which the parasites counteract innate immune responses. Two Tat D DNases were identified in each of Trypanosoma evansi and Trypanosoma brucei. These DNases are bivalent metal-dependent endonucleases localized in the cytoplasm and flagella of the parasites that can also be secreted by the parasites. These enzymes possess conserved functional domains and have efficient DNA hydrolysis activity. Host neutrophil extracellular traps(NETs) induced by the parasites could be hydrolyzed by native and recombinant Tat D DNases. NET disruption was prevented, and the survival rate of parasites was decreased, in the presence of the DNase inhibitor aurintricarboxylic acid. These data suggest that trypanosomes can counteract host innate immune responses by active secretion of Tat D DNases to degrade NETs.     

Coevolution of host immune defence and parasite-induced mortality: relative spleen size and mortality in altricial birds

Animal hosts defend themselves against parasites by the antibodies produced by an immune system. It is an inherent assumption that parasites constitute the selection pressure that has given rise to and maintains the immune system. Thus, greater impact by parasites on host fitness should result in greater investment in immune function across species. We tested this prediction by using field estimates of parasite-induced nestling mortality in altricial birds as an estimate of the fitness cost of parasitism and the relative size of the spleen as an estimate of investment in immune function. The spleen is a peripheral lymphoid tissue that acts as the main site of lymphocyte differentiation and proliferation, and these B- and T-cells are involved in the production of humoral and cell-mediated immune responses. In a comparative study of 21 species of altricial birds we found a significant positive relationship between relative spleen size and parasite-induced mortality, accounting for a third of the variance, even when controlling for potentially confounding variables. This finding provides evidence for the level of investment in immune function being related to the natural selection pressure imposed by parasites.     

Toll-like receptor 4 (TLR4) is required for protective immunity to larval Strongyloides stercoralis in mice

TLR4 is important for immunity to various unicellular organisms and has been implicated in the immune responses to helminth parasites. The immune response against helminths is generally Th2-mediated and studies have shown that TLR4 is required for the development of a Th2 response against allergens and helminth antigens in mice. C3H/HeJ mice, which have a point mutation in the Tlr4 gene, were used in this study to determine the role of TLR4 in protective immunity to the nematode Strongyloides stercoralis. It was demonstrated that TLR4 was not required for killing larval S. stercoralis during the innate immune response, but was required for killing the parasites during the adaptive immune response. No differences were seen in the IL-5 and IFN-gamma responses, antibody responses or cell recruitment between wild type and C3H/HeJ mice after immunization. Protective immunity was restored in immunized C3H/HeJ mice by the addition of wild type peritoneal exudate cells in the environment of the larvae. It was therefore concluded that the inability of TLR4-mutant mice to kill larval S. stercoralis during the adaptive immune response is due to a defect in the effector cells recruited to the microenvironment of the larvae.     

Molecular mimicry revisited

The host immune response is an important line of defence against parasites. Tactics to evade this response are therefore expected in host-parasite relationships, and the clearest example is the antigenic variation displayed by African trypanosomes. But while few other parasites seem to have quite this ability, many seem to display a form of antigenic convergence with the host - allowing them a degree of molecular camouflage against the host's immune system. Ideas about such antigenic convergence were developed some 30 years ago, with, for example, John Sprent's theory of 'adaptation tolerance', John Dineen's 'selection for fitness antigens' and Raymond Damian's concept of 'antigen sharing' between host and parasite which was subsequently formulated in a now classical exposition on 'molecular mimicry'. Damian's theory, that one of the mechanisms by which parasites could avoid the host immune response was by mimicking host molecules, has greatly influenced both the theoretical and practical approaches to immunoparasitology. Earlier this year, at a UCLA Symposium, Professor Damian discussed how the theory had progressed since its original exposition. This article is based on that presentation.     

The kidney form of Trypanosoma musculi: A distinct stage in the life cycle?

Trypanosoma musculi is a parasite specific to mice, which resides in the blood and lacks intracellular stages. After immune clearance of the flagellates from the general circulation, mice are resistant to reinfection. Yet, long after parasites are no longer detected in the peripheral blood, they persist in the vasa recta of the kidneys and it has been proposed that this is an immunologically privileged site for T. musculi. This relationship provides a useful model for studies of latent or chronic infections in immune hosts. Here, Fernando Monroy and Donald Dusanic consider the immune responses of mice to T. musculi and compare characteristics of the parasites from the vasa recta (kidney forms, KFs) of mice with latent infections to trypanosomes from the peripheral blood (bloodstream forms, BSFs) of animals during active infections. They consider how KFs evade immune destruction and suggest that these sequestered parasites represent a distinct stage in the life cycle.     

Niche theory for within-host parasite dynamics: Analogies to food web modules via feedback loops

Why do parasites exhibit a wide dynamical range within their hosts? For instance, why does infecting dose either lead to infection or immune clearance? Why do some parasites exhibit boom-bust, oscillatory dynamics? What maintains parasite diversity, that is coinfection v single infection due to exclusion or priority effects? For insights on parasite dose, dynamics and diversity governing within-host infection, we turn to niche models. An omnivory food web model (IGP) blueprints one parasite competing with immune cells for host energy (PIE). Similarly, a competition model (keystone predation, KP) mirrors a new coinfection model (2PIE). We then drew analogies between models using feedback loops. The following three points arise: first, like in IGP, parasites oscillate when longer loops through parasites, immune cells and resource regulate parasite growth. Shorter, self-limitation loops (involving resources and enemies) stabilise those oscillations. Second, IGP can produce priority effects that resemble immune clearance. But, despite comparable loop structure, PIE cannot due to constraints imposed by production of immune cells. Third, despite somewhat different loop structure, KP and 2PIE share apparent and resource competition mechanisms that produce coexistence (coinfection) or priority effects of prey or parasites. Together, this mechanistic niche framework for within-host dynamics offers new perspective to improve individual health.     

Chemokines and chemokine receptors: Insights from human disease and experimental models of helminthiasis

Infection with helminth parasites affects more than 1.5 billion people and is concentrated in global areas of extreme poverty, having a significant impact on public health, social life and the economy. Upon entry into the host, helminth parasites often migrate through specific tissues triggering host immunity. The immune response triggered by helminth infections is complex and depends on parasite load, site of infection, acuteness/chronicity of the infection and is species-dependent. In general, susceptibility or resistance to the infection involves the participation of the innate immune response and then the balance between several effector CD4⁺ T cells subsets, such as Th1, Th2, Th9, Th17, Tfh and Treg, coordinated by immune mediators such as cytokines and chemokines. Chemokines guide the recruitment and activation of leukocytes under inflammatory and homeostatic states. The chemokine system has been associated with several diseases and experimental models with a significant inflammatory component, including infection with helminth parasites. Therefore, this critical review will highlight the main findings concerning chemokine responses elicited by the interaction between helminth parasites and the hosts’ immune system, hence contributing to the understanding of the relevance of chemokine synthesis and biology in the immunological response to infection by parasitic helminths.     

Evidence for a cost of immunity when the crustacean Daphnia magna is exposed to the bacterial pathogen Pasteuria ramosa

The deployment of the immune system has the obvious potential to ameliorate infection outcomes, but immune responses can also harm hosts by either damaging host tissues or monopolizing resources, leading to enhanced mortality. To gain insight into such a 'cost of immunity' when the crustacean Daphnia magna is challenged with the bacterium Pasteuria ramosa, we measured survivorship among hosts that resisted infection following exposure to various strains and doses of the parasite. In the first of two experiments, these exposures were: single exposures with relatively non-aggressive strains, double exposures with non-aggressive strains, and exposure to aggressive strains. Mortality increased across this gradient of exposure. In a second experiment, we varied the dose of the most aggressive P. ramosa strain and found that resisting infection when a large dose was applied resulted in greater mortality than when a medium or low dose was applied. Assuming that resistance is accomplished with an immune response, and that more aggressive parasites and/or larger doses of parasites are more immunostimulatory, these data are compatible with a cost of immunity. Indeed, in terms of survival, resisting parasites can be more harmful than infection.     

Protozoan parasite-specific carbohydrate structures

The carbohydrate moieties displayed by pathogenic protozoan parasites exhibit many unusual structural features and their expression is often developmentally regulated. These unique structures suggest a specific relationship between such carbohydrates and parasite pathogenicity. Studies of infected humans indicate that immune responses to protozoan parasites are elicited by glycan determinants on cell-surface or secreted molecules. Infections by protozoa are a major worldwide health problem, and no vaccines or efficacious treatments exist to date. Recent progress has been made in elucidating the structure and function of carbohydrates displayed by major protozoan parasites that infect man. These structures can be used as prototypes for the chemical or combined chemo-enzymatic synthesis of new compounds for diagnosis and vaccine development, or as inhibitors specifically designed to target parasite glycan biosynthesis.     

Weshalb hemmen Würmer Allergien? Parasiten als Immunologen

Parasitic worms survive within their immunocompetent hosts by modulating their immune system and by inhibiting inflammatory responses directed against the parasites. This immunomodulation has a spill over effect and also inhibits inflammatory responses originating from other causes. For this reason, persons who are infected with certain species of worms show a lower rate of allergic diseases as compared to persons who are free of parasites. In the same line, studies in mouse models revealed that many inflammatory diseases can be treated by worm infections. This effect is among others owing to specific proteins that are released by the worms. Such secreted immunomodulators, shaped by co‐evolution between parasites and their hosts, could become lead compounds for the development of new therapies against allergic and inflammatory diseases.     

Living off a fish: a trade-off between parasites and the immune system

Research in fish immune system and parasite invasion mechanisms has advanced the knowledge of the mechanisms whereby parasites evade or cope with fish immune response. The main mechanisms of immune evasion employed by fish parasites are reviewed and considered under ten headings. 1) Parasite isolation: parasites develop in immuno-privileged host tissues, such as brain, gonads, or eyes, where host barriers prevent or limit the immune response. 2) Host isolation: the host cellular immune response isolates and encapsulates the parasites in a dormant stage without killing them. 3) Intracellular disguise: typical of intracellular microsporidians, coccidians and some myxosporeans. 4) Parasite migration, behavioural and environmental strategies: parasites migrate to host sites the immune response has not yet reached or where it is not strong enough to kill them, or they accommodate their life cycles to the season or the age in which the host immune system is down-regulated. 5) Antigen-based strategies such as mimicry or masking, variation and sharing of parasite antigens. 6) Anti-immune mechanisms: these allow parasites to resist innate humoral factors, to neutralize host antibodies or to scavenge reactive oxygen species within macrophages. 7) Immunodepression: parasites either suppress the fish immune systems by reducing the proliferative capacity of lymphocytes or the phagocytic activity of macrophages, or they induce apoptosis of host leucocytes. 8) Immunomodulation: parasites secrete or excrete substances which modulate the secretion of host immune factors, such as cytokines, to their own benefit. 9) Fast development: parasites proliferate faster than the ability of the host to mount a defence response. 10) Exploitation of the host immune reaction. Knowledge of the evasion strategies adopted by parasites will help us to understand host-parasite interactions and may therefore help in the discovery of novel immunotherapeutic agents or targeted vaccines, and permit the selection of host-resistant strains.     

Immune evasion by Babesia bovis and Plasmodium falciparum: cliff-dwellers of the parasite world

Erythrocyte-dwelling parasites, such as Babesia bovis and Plasmodium falciparum, are not accessible to the host immune system during most of their asexual reproductive cycle because they are intracellular. While intracellular, the host immune response must be directed toward the surface of the infected erythrocyte. Immune individuals mount protective antibody and cell-mediated responses which eliminate most of the parasites, yet some survive to establish chronic infections. In this review, David Allred discusses some of the mechanisms used by these parasites to evade individual immune mechanisms targeting the infected erythrocyte to survive in the hostile environment of an effective immune response.     

Seasonal changes in cell‐mediated immunocompetence and mass gain in nestling barn swallows: a parasite‐mediated effect?

Reproduction in seasonal environments is usually timed so peak demand for food by offspring coincides with peak availability. Hence, late breeders will encounter a scarcity of food. Since parasite populations grow during the reproductive season of their hosts, late reproducing animals will also face an increasing challenge by parasites. We hypothesised that seasonal decrease in food availability and seasonal increase in parasite abundance will cause a trade-off between growth and immune function. This prediction was tested in nestling barn swallows ( Hirundo rustica ) from first and second broods. Nestlings from second broods mounted stronger T cell mediated immune responses to a challenge with a novel antigen, but had lower rates of mass gain, than nestlings from first broods, consistent with the prediction. Broods in which at least one nestling died had lower levels of T cell mediated immune response, but not lower rates of mass gain, than broods without mortality, suggesting that brood reduction is mediated through an inability of offspring to defend themselves against parasites rather than an inability to grow. Possible mechanisms include scarcity of specific nutrients needed for immune responses, and/or parasites being concentrated on a single or few nestlings.     

Fc receptors and immunity to parasites

Fc receptors (FcRs) are crucial in the immune system; they mediate a plethora of biological functions as diverse as antigen presentation, phagocytosis, cytotoxicity, induction of inflammatory cascades and modulation of immune responses. Parasites, in order to survive in the immunocompetent host, have devised ingenious methods to subvert this important aspect of the immune response. This article discusses the current thinking on FcRs, their role in immunity to parasites, and immune evasion strategies employed by parasites in their attempt to neutralize the important immune defense mechanisms mediated by these molecules.     

HOST IMMUNE STATUS DETERMINES SEXUALITY IN A PARASITIC NEMATODE

We examine the hypothesis that sexual reproduction by parasites is an adaptation to counter the somatic evolution of vertebrate immune responses. This is analogous to the idea that antagonistic coevolution between hosts and their parasites maintains sexual reproduction in host populations. Strongyloides ratti is a parasitic nematode of rats. It can have a direct life cycle, with clonal larvae of the wholly parthenogenetic parasites becoming infective, or an indirect life cycle, with clonal larvae developing into free-living dioecious adults. These free-living adults produce infective larvae by conventional meiosis and syngamy. The occurrence of the sexual cycle is determined by both environmental and genetic factors. By experimentally manipulating host immune status using hypothymic mutants, corticosteroids, whole-body γ-irradiation and previous exposure to S. ratti, we show that larvae from hosts that have acquired immune protection are more likely to develop into sexual adults. This effect is independent of the method of manipulation, larval density, and the number of days postinfection. This immune-determined sexuality is consistent with the idea that sexual reproduction by parasites is adaptive in the face of specific immunity, an idea which, if true, has clinical and epidemiological consequences.     

The ecology of host immune responses to chronic avian haemosporidian infection

Host responses to parasitism in the wild are often studied in the context of single host–parasite systems, which provide little insight into the ecological dynamics of host–parasite interactions within a community. Here we characterized immune system responses to mostly low-intensity, chronic infection by haemosporidian parasites in a sample of 424 individuals of 22 avian host species from the same local assemblage in the Missouri Ozarks. Two types of white blood cells (heterophils and lymphocytes) were elevated in infected individuals across species, as was the acute-phase protein haptoglobin, which is associated with inflammatory immune responses. Linear discriminant analysis indicated that individuals infected by haemosporidians occupied a subset of the overall white blood cell multivariate space that was also occupied by uninfected individuals, suggesting that these latter individuals might have harbored other pathogens or that parasites more readily infect individuals with a specific white blood cell profile. DNA sequence-defined lineages of haemosporidian parasites were sparsely distributed across the assemblage of hosts. In one well-sampled host species, the red-eyed vireo (Vireo olivaceus), heterophils were significantly elevated in individuals infected with one but not another of two common parasite lineages. Another well-sampled host, the yellow-breasted chat (Icteria virens), exhibited no differences in immune response to different haemosporidian lineages. Our results indicate that while immune responses to infection may be generalized across host species, parasite-specific immune responses may also occur.     

Designing blood-stage vaccines against Babesia bovis and B. bigemina.

The tick-transmitted apicomplexan parasites Babesia bovis and B. bigemina cause significant disease in cattle in many tropical and temperate areas of the world. These parasites present a challenge for vaccine development, and yet provide a system for studying the pathogenesis, mechanisms of protective immunity and regulation of host immune responses associated with intraerythrocytic protozoan parasites in a non-rodent species. In this article, Wendy Brown and Guy Palmer review strategies for identifying candidate vaccine antigens of B. bovis and B. bigemina and for priming immune responses to evoke strain crossprotective immunity.     

Immune stress and facultative sex in a parasitic nematode

It has been suggested that sexual reproduction in parasites may be advantageous because it helps evade genotype‐specific host immune responses. Indirect support for this hypothesis has recently come from work on Strongyloides ratti, a parasitic nematode of rats that develops and reproduces sexually or asexually. In this species, host immune responses against S. ratti lead to a higher proportion of individuals reproducing sexually. However, an alternative explanation for these results is that sex is favoured by general environmental stress, including host responses against antigen sources other than S. ratti. Here we test this hypothesis, by determining how host immunity against two other parasitic nematode species (Nippostrongylus brasiliensis & Strongyloides venezuelensis) and commonly used mammalian antigens (sheep red blood cells) affects the likelihood of S. ratti larvae developing sexually. Our results show that increased levels of sex occur in response to immune responses generated against these other species, and not just host immunity elicited by S. ratti. This is consistent with the idea that sex is favoured under stressful conditions, and does not support the immune evasion hypothesis.     

Diversity and dialogue in immunity to helminths

The vertebrate immune system has evolved in concert with a broad range of infectious agents, including ubiquitous helminth (worm) parasites. The constant pressure of helminth infections has been a powerful force in shaping not only how immunity is initiated and maintained, but also how the body self-regulates and controls untoward immune responses to minimize overall harm. In this Review, we discuss recent advances in defining the immune cell types and molecules that are mobilized in response to helminth infection. Finally, we more broadly consider how these immunological players are blended and regulated in order to accommodate persistent infection or to mount a vigorous protective response and achieve sterile immunity.