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| MINIREVIEW |
Maria Ilma Araujo,,
and Edward J. Pearce*
Department of Microbiology and Immunology, Cornell University, Ithaca, New York 14853-6401
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INTRODUCTION |
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 Top Introduction References |
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Many of the parasitic worms have complex multistage life cycles that involve several hosts. Within their mammalian hosts they often undergo extensive growth and differentiation with the ultimate goal of producing stages intended for transmission to the next intermediate host. Usually, the life stage responsible for infecting the mammalian host is the larva, and the larva must migrate within the host to its appropriate niche where it can grow and reproduce. Since the offspring are intended for transmission to another animal, they must necessarily be capable in some way of entering a site from which they can leave the host. How all this is accomplished varies from one helminth to another. Nevertheless, despite this extensive organismal complexity, in the majority of cases the immune responses of the hosts to worm infection are remarkably similar, being Th2-like with the production of significant quantities of interleukin-4 (IL-4), IL-5, IL-9, IL-10, and IL-13 and consequently the development of strong immunoglobulin E (IgE), eosinophil, and mast cell responses. This inherent ability of helminths to induce Th2 responses has led to interest in them from both the perspective of elucidation of the underlying mechanisms that lead to Th2 response development and in terms of understanding Th2 response function.
This review attempts to integrate data from experimental systems and human studies and to highlight developing areas of particular interest and importance.
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IMMUNOPATHOLOGY |
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) receptor (29). This result is consistent with findings in murine schistosomiasis where IFN- and the Th1 response can protect against severe fibrosis by preventing alternative macrophage activation and thereby limiting the fibrosis-enhancing effects of the Th2 response (51, 52). As a whole however, these findings remain to be integrated with the report by Mwatha et al. (83) that the immune responses of individuals suffering most-severe hepatosplenomegaly, usually considered to be indicative of severe fibrosis, were more Th1-like, whereas infected individuals with less-severe disease mounted Th2 responses. Perhaps hepatosplenomegaly is not always indicative of fibrosis during schistosomiasis? Filarial parasites cause significant pathology either through obstruction and damage of the lymphatic system by adult parasites, as is the case with Brugia spp. and Wuchereria bancrofti, or through cutaneous and ocular irritation by larval transmission stages (microfilariae) of Onchocerca volvulus. Clearly there is a physical component to this pathology caused by highly motile parasites living within the lymphatic system or actively migrating through the skin and conjunctiva, but more intriguing are the role of the immune response in the disease process (27, 31, 61, 73) and the growing possibility that the Wolbachia symbionts of filariae may be playing a role in the induction of destructive inflammatory reactions (for further discussion, see reference 100).
Not everyone infected with lymphatic filariae develops hydrocele or chronic lymphedema, and there is a general although incomplete association between the ability of an individual to clear microfilaremia (presumably by immunologically killing microfilariae or suppressing microfilarial production by adult parasites) and apparent clinical symptoms. In contrast, individuals who are microfilaremic have been considered pathology free, although ultrasound and lymphoscintigraphy have revealed that these individuals do experience subclinical pathologic changes (27). Whether Th1 responses play a pivotal role in the development of severe pathologic change has yet to be fully determined, although it is clear that the microfilaremic state is associated with a Th2 response. Of concern is the possibility that immune responses capable of preventing microfilaremia and/or killing adult parasites are also those that cause most pathology. Detailed experimental analysis has been hampered by the fact that neither Wuchereria nor Brugia will complete its full developmental cycle in mice.
Infection with O. volvulus leads to debilitating cutaneous inflammation and blindness. A mouse model has allowed detailed investigation of the immunopathologic changes that lead to loss of vision (90). When mice are sensitized to adult O. volvulus Ag by intraperitoneal injection and then challenged by injection with the same Ag into the corneal stroma, they develop ocular opacification and neovascularization, conditions that mimic the human disease. Dissection of this system has revealed that disease correlates with the development of a strong Ag-specific Th2 response and that both IL-4 and CD4 cells are necessary for the ocular pathology (90). The effector mechanism that leads to opacification and neovascularization is neutrophil mediated and CXC chemokine receptor 2, PECAM-1, and antibody dependent (48, 49, 56).
An important, and often underappreciated, point is that in addition to specific pathologic changes, there are less clear but nevertheless well-documented and very important effects of helminth infections on child growth and mental and sexual development (88, 99). The contribution of the immune system to these facets of disease is poorly understood, although interactions between the endocrine system and IL-6 in chronic cysticercosis due to Taenia crassiceps has been recently reported (81).
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IMMUNOREGULATION |
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An additional facet of immunoregulation during filarial as well as schistosome infections is that the marked T-cell responsiveness that follows initial infection is, in the majority of patients, dampened as the infection becomes chronic (61, 84, 108). This diminution of responsiveness is believed to be in the best interest of the host, as it is not apparent in infected individuals exhibiting the most-severe forms of disease (73, 108). For example, peripheral blood mononuclear cells taken from microfilaremic individuals fail to proliferate to filarial antigen in vitro but are still able to respond in an Ag-specific manner as measured by cytokine production. Conversely, individuals with chronic lymphatic pathology, who rarely exhibit blood microfilaremia, generally mount stronger filarial-specific cellular proliferative responses. The underlying mechanisms behind down-regulation of cellular proliferative responses during helminth infections remain unknown, although recent studies have suggested that host macrophages may be alternatively activated by the parasite to effect suppression via a contact-dependent mechanism (69, 71), via the production of NO in response to parasite glycoconjugates (8), or through IL-10 production (72, 87). Indeed, it is clear that IL-10 plays a major role in the regulation of the intensity of both Th1 and Th2 responses during helminth infections and in so doing plays a principal role in minimizing immunpathology (40, 53, 62, 98) and in suppressing the expression of the allergic-like symptoms that might otherwise be expected in helminth-infected individuals who are producing large amounts of IgE (103). There is an important additional role for idiotypic regulation of immune responsiveness in disease severity in schistosomiasis (80).
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IMMUNE RESPONSES THAT PREVENT INFECTION WITH HELMINTHS |
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The immunological basis of resistance to reinfection with schistosomes has been examined by comparing the parasite-specific immune responses of older (resistant) versus younger (susceptible) individuals following treatment. This type of study has indicated that antiparasite IgE levels closely correlate with resistance (32, 46, 93), and segregation analysis of Brazilian pedigrees provides evidence for the effects of a major gene on the ability of individuals to resist infection (1, 28). Data from a genome-wide scan of individuals from informative families revealed linkage to a region on chromosome 5q31-q33 that contains several Th2 response genes, reinforcing considerably the view that Th2-mediated effector mechanisms play a pivotal role in resistance to schistosome infection (78). Experimental analysis of the role of Th2 responses in concomitant immunity in mice supports the view that this type of response is crucially important for naturally acquired resistance to S. mansoni. In contrast to infected wild-type animals, which are partially resistant to superinfection, infected IL-4-/- mice are incapable of mounting a strong Th2 response and exhibit no resistance (15).
Individuals infected with filarial parasites may also exhibit concomitant immunity against incoming infectious life forms (L3 larvae) of a secondary infection and against the transmission stage of the parasite (microfilariae, which are produced by the resident adult parasites). Additionally, some residents in areas of endemicity, the so-called "endemic normal" or putatively immune individuals, remain uninfected despite repeated exposure. Mechanisms responsible for these patterns of immunity in humans remain unclear and have been difficult to address experimentally due to the absence of a widely available experimental model. Recent rediscovery of the mouse filarial parasite Litosomoides sigmodontis as a viable organism for immunological studies (3) has opened the way for new developments in this important area
It has become apparent over the last 10 years that the ability of hosts to expel intestinal nematodes is closely linked to their ability to mount a Th2 response against the parasite. In the case of Trichuris muris, which is a natural infection of mice and a close relative of the human parasite Tritrichuris trichuria, a survey of different inbred mouse strains revealed that the majority of strains (analogous to the majority of individuals in an outbred population) are initially susceptible to infection but with varying kinetics expel the parasites (104). In contrast, a few strains are unable to expel the parasites (104). Comparison of the immune responses of different mouse strains following infection revealed that susceptibility correlated with the development of a Th1 response and that expulsion was associated with the ability to induce a Th2 response (36). Manipulations of the immune system to prevent the development of Th2 responses in expeller mice and of Th1 responses in resistant mice converted them to susceptible and resistant animals, respectively (35). Similarly important roles for Th2 responses in resistance and Th1 responses in susceptibility have been documented for the intestinal nematodes Heligmosomoides polygyrus and Nippostrongylus brasiliensis (38, 39), and it seems likely that the same will be true for intestinal trematode parasites (14). Current efforts are aimed at understanding the components of the immune system that are responsible for immune response skewing during these infections (an area that will be discussed below) and at identifying the effector functions that mediate worm expulsion. Interestingly, the latter studies have failed to clearly identify a universal protective effector mechanism, and it is fair to say that in most cases the nature of the response that ultimately expels the parasite is unknown (39). Moreover, it seems likely that despite similarities associated with being members of the same phylum, different nematode parasites will be expelled by different effector mechanisms. For example, while expulsion of both Trichinella spiralis and N. brasiliensis is dependent upon the ligation by IL-4 or IL-13 of the IL-4R
-containing receptor and activation of STAT6 via this receptor, expulsion of T. spiralis does not occur if mast cells are absent, whereas these cells are not necessary for N. brasiliensis rejection (102). Moreover, the injection of IL-4 alone into mice that lack T cells, B cells, or mast cells is sufficient to cause expulsion of N. brasiliensis, whereas T cells as well as mast cells are essential for exogenous IL-4-promoted rejection of T. spiralis (102). The implication of these findings and others showing that expulsion of H. polygyrus and T. muris is also dependent upon the signature Th2 cytokines IL-4 and IL-13, is that the mammalian host possesses an arsenal of effector mechanisms that can be blanket triggered by IL-4 and/or IL-13 and mediate protection against a panel of related pathogens (9, 38, 39, 75). Understanding these effector mechanisms is an area of considerable current interest.
Killing of helminths by eosinophils via antibody-dependent cellular cytotoxicity (ADCC) is an attractive and widely cited mechanism for resistance to parasitic worms. Although this mechanism was initially based on in vitro assays in which eosinophils were shown capable of killing a wide variety of Ab and/or C-opsonized helminths, and on immunoepidemiological data (17), it has nevertheless been difficult to show a widely important role for eosinophils in protection against helminths. However, important recent reports have established a role for the Th2 cytokine IL-5, the central regulator of eosinophilia, in resistance to the nematodes Strongyloides stercoralis and L. sigmodontis, (50, 66) and have strongly implicated the eosinophil as a killer cell against the tissue-traversing larval stages of this type of parasite (12) and surprisingly as helper cells for protective Ab production (12, 50). In most other settings, despite clear and decisive evidence that eosinophils can kill helminths (17, 44), their importance for resistance to infection against most helminths remains to be proven.
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VACCINE DEVELOPMENT |
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Intriguingly, the application of antihelminth vaccines is more advanced in veterinary medicine than in human medicine, with a history of the use of attenuated vaccines against certain nematode parasites and more recently the development of recombinant protein and DNA vaccines against the sheep tapeworm Taenia ovis (30, 55, 67). This probably reflects a combination of factors including the greater commercial potential of veterinary vaccines that can be sold in the developed world and the less stringent safety requirements for products intended for veterinary versus human use.
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IMMUNE RESPONSE EVASION |
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COINFECTION, AUTOIMMUNITY, AND ALLERGY |
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Another important issue is that of how the presence of ongoing helminth infection affects the likelihood of the development of immunological disorders, such as autoimmunity and allergy. Data from studies addressing the issue of autoimmunity are still descriptive but nevertheless tantalizing. Weinstock and colleagues have argued that a failure to acquire helminthic parasites predisposes one to Crohn's disease and have correlated increased hygiene in westernized countries with the decreased prevalence of helminthiases and the increased prevalence of autoimmune intestinal diseases and other forms of autoimmunity (34). The relationship between immune responsiveness to allergens and/or allergic symptoms and helminth infections is fascinating and has puzzled immunologists for decades. Helminth infections induce strong IgE responses, which in combination with high Ag levels would be expected to lead to allergic symptoms and possibly anaphylaxis (63). However, helminth-infected individuals rarely have allergic reactions to these parasites and, moreover, appear to suffer less from allergic disorders in general than do helminth-free individuals (e.g., see reference 7). There are several possible explanations for this paradox, including the production of IgG antibodies that block access of allergenic Ag to specific IgE (61, 109), but in an exciting recent development, studies have correlated increased IL-10 levels resulting from chronic schistosomiasis hematobium with reduced expression of house mite allergy in African children (103, 109).
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TH2 RESPONSE INDUCTION |
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An alternative view of Th2 response development, probably with more support, is that autocrine IL-4, derived from the naïve Th cell itself, is of central importance (20, 21, 85). The circumstances under which Th cells are activated to make and/or retain responsiveness to IL-4 are not completely clear, and there is a growing interest in the role of dendritic cells, the initiators of immune responses, in this process. Clearly, these cells play a central role in Th1 response induction by producing IL-12 following recognition of certain microbial pathogens (92, 97). However, recent reports indicate that dendritic cells are not activated by helminth Ag to make either IL-4 or IL-12, or to undergo any of the phenotypic changes that occur following exposure to Th1-inducing pathogens, and yet acquire the ability to induce strong Th2 responses (70, 105). Helminths can also inhibit dendritic cell migration (6) and prevent their activation by Ag that normally would promote IL-12 production (95).
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SUMMARY |
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ACKNOWLEDGMENTS |
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FOOTNOTES |
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Present address: Department of Pathobiology, School of Veterinary Medicine, University of Pennsylvania, Philadelphia, PA 19104-6008.
Permanent address: Servico de Imunologia, Hospital Universitario Professor Edgard Santos, Universidade Federal da Bahia, Bahia, Brazil.
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