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Helminths: Pathogenesis and Defenses Derek Wakelin GENERAL CONCEPTS Classification Helminth is a general term for a parasitic worm. The helminths include the Platyhelminthes or flatworms (flukes and tapeworms) and the Nematoda or roundworms. Characteristics All helminths are relatively large (> 1 mm long); some are very large (> 1 m long). All have well-developed organ systems and most are active feeders. The body is either flattened and covered with plasma membrane (flatworms) or cylindrical and covered with cuticle (roundworms). Some helminths are hermaphrodites; others have separate sexes. Epidemiology Helminths are worldwide in distribution; infection is most common and most serious in poor countries. The distribution of these diseases is determined by climate, hygiene, diet, and exposure to vectors. Infection The mode of transmission varies with the type of worm; it may involve ingestion of eggs or larvae, penetration by larvae, bite of vectors, or ingestion of stages in the meat of intermediate hosts. Worms are often long-lived. Pathogenesis Many infections are asymptomatic; pathologic manifestations depend on the size, activity, and metabolism of the worms. Immune and inflammatory responses also cause pathology. Host Defenses Nonspecific defense mechanisms limit susceptibility. Antibody- and cell-mediated responses are important, as is inflammation. Parasites survive defenses through many evasion strategies. INTRODUCTION Helminths - worms - are some of the world's commonest parasites (see Ch. 86). They belong to two major groups of animals, the flatworms or Platyhelminthes (flukes and tapeworms) and the roundworms or Nematoda. All are relatively large and some are very large, exceeding one meter in length. Their bodies have well-developed organ systems, especially reproductive organs, and most helminths are active feeders. The bodies of flatworms are flattened and covered by a plasma membrane, whereas roundworms are cylindrical and covered by a tough cuticle. Flatworms are usually hermaphroditic whereas roundworms have separate sexes; both have an immense reproductive capacity. The most serious helminth infections are acquired in poor tropical and subtropical areas, but some also occur in the developed world; other, less serious, infections are worldwide in distribution. Exposure to infection is influenced by climate, hygiene, food preferences, and contact with vectors. Many potential infections are eliminated by host defenses; others become established and may persist for prolonged periods, even years. Although infections are often asymptomatic, severe pathology can occur. Because worms are large and often migrate through the body, they can damage the host's tissues directly by their activity or metabolism. Damage also occurs indirectly as a result of host defense mechanisms. Almost all organ systems can be affected. Host defense can act through nonspecific mechanisms of resistance and through specific immune responses. Antibody-mediated, cellular, and inflammatory mechanisms all contribute to resistance. However, many worms successfully avoid host defenses in a variety of ways, and can survive in the face of otherwise effective host responses. Infection Transmission of Infection Helminths are transmitted to humans in many different ways (Fig. 87-1). The simplest is by accidental ingestion of infective eggs (Ascaris, Echinococcus, Enterobius, Trichuris) or larvae (some hookworms). Other worms have larvae that actively penetrate the skin (hookworms, schistosomes, Strongyloides). In several cases, infection requires an intermediate host vector. In some cases the intermediate vector transmits infective stages when it bites the host to take a blood meal (the arthropod vectors of filarial worms); in other cases, the larvae are contained in the tissues of the intermediate host and are taken in when a human eats that host (Clonorchis in fish, tapeworms in meat and fish, Trichinella in meat). The levels of infection in humans therefore depend on standards of hygiene (as eggs and larvae are often passed in urine or feces), on the climate (which may favor survival of infective stages), on the ways in which food is prepared, and on the degree of exposure to insect vectors. FIGURE 87-1 Entry and localization of pathogenic helminths. Host Factors Influencing Susceptibility Human behavior is a major factor influencing susceptibility to infection. If the infective stages of helminths are present in the environment, then certain ways of behaving, particularly with regard to hygiene and food, will result in greater exposure. Because helminths, with few exceptions (Strongyloides, Trichinella, some tapeworm larvae), do not increase their numbers by replication within the same host, the level of infection is directly related to the number of infective stages encountered. Obviously, not every exposure results in the development of a mature infection. Many infective organisms are killed by the host's nonspecific defense mechanisms. Of those that do become established, many are destroyed or eliminated by specific defenses. The number of worms present at any one time therefore represents a dynamic balance between the rate of infection and the efficiency of defense. This balance (which reflects the host's overall susceptibility) is altered by changes in the host's behavior and ability to express forms of defense. Children are more susceptible to many helminths than are adults, and frequently are the most heavily infected members of a community. The waning of immune competence with age may also result in increased levels of infection. Individuals differ genetically in their ability to resist infection, and it is well known that in infected populations, some individuals are predisposed to heavier infections than others. Changes in diet may affect susceptibility, as do the hormonalimmune changes accompanying pregnancy and lactation. An important cause of increased susceptibility is the immune suppression that accompanies concurrent infections with some other pathogens and the development of certain tumors. Similarly, immunosuppressive therapies (irradiation, immunosuppressant drugs) may enhance susceptibility to helminth infection. A particular hazard in immunocompromised patients is the development of disseminated strongyloidiasis, in which large numbers of larvae develop in the body by autoinfection from relatively small numbers of adult Strongyloides stercoralis. It is interesting that the human immunodeficiency virus does not result in an overall increase in susceptibility to helminth infection. Parasite Factors Influencing Susceptibility The ability of hosts to control infection is offset by the ability of parasites to avoid the host's defenses and increase their survival. In addition to their ability to evade specific immune defenses (see below), many worms are unaffected by the host's attempts to limit their activities or to destroy them simply because they are large and mobile. Many important species measure several centimeters in length or diameter (Ascaris, hookworms, hydatid cysts, Trichuris) and others may exceed one meter in length (tapeworms). Size alone renders many defense mechanisms inoperative, as does the tough cuticle of adult roundworms. The ability of worms to move actively through tissues enables them to escape inflammatory foci. Many of the pathogenic consequences of worm infections are related to the size, movement and longevity of the parasites, as the host is exposed to long-term damage and immune stimulation, as well as to the sheer physical consequences of being inhabited by large foreign bodies. Pathogenesis Direct Damage from Worm Activity The most obvious forms of direct damage are those resulting from the blockage of internal organs or from the effects of pressure exerted by growing parasites (Fig. 87-2). Large Ascaris or tapeworms can physically block the intestine, and this may occur after some forms of chemotherapy; migrating Ascaris may also block the bile duct. Granulomas that form around schistosome eggs may block the flow of blood through the liver, and this may lead to pathological changes in that organ and elsewhere. Blockage of lymph flow, leading to elephantiasis, is associated with the presence of adult Wuchereria in lymphatics. Pressure atrophy is characteristic of larval tapeworm infections (hydatid cyst, the larva of Echinococcus granulosus) where the parasite grows as a large fluid-filled cyst in the liver, brain, lungs, or body cavity. The multilocular hydatid cysts caused by Echinococcus multilocularis have a different growth form, metastasizing within organs and causing necrosis. The larvae of Taenia solium, the pork tapeworm, frequently develop in the central nervous system (CNS) and eyes. Some of the neurological symptoms of the resulting condition, called cysticercosis, are caused by the pressure exerted by the cysts. FIGURE 87-2 Pathogenesis: direct damage caused by large helminths. Intestinal worms cause a variety of pathologic changes in the mucosa, some reflecting physical and chemical damage to the tissues, others resulting from immunopathologic responses. Hookworms (Ancylostoma and Necator) actively suck blood from mucosal capillaries. The anticoagulants secreted by the worms cause the wounds to bleed for prolonged periods, resulting in considerable blood loss. Heavy infections in malnourished hosts are associated with anemia and protein loss. Protein-losing enteropathies may also result from the inflammatory changes induced by other intestinal worms. Diversion of host nutrients by competition from worms is probably unimportant, but interference with normal digestion and absorption may well aggravate undernutrition. The tapeworm Diphyllobothrium latum can cause vitamin B12 deficiency through direct absorption of this factor. Many helminths undertake extensive migrations through body tissues, which both damage tissues directly and initiate hypersensitivity reactions. The skin, lungs, liver, and intestines are the organs most affected. Petechial hemorrhages, pneumonitis, eosinophilia, urticaria and pruritus, organomegaly, and granulomatous lesions are among the signs and symptoms produced during these migratory phases. Feeding by worms upon host tissues is an important cause of pathology, particularly when it induces hyperplastic and metaplastic changes in epithelia. For example, liver fluke infections lead to hyperplasia of the bile duct epithelium. Chronic inflammatory changes around parasites (for example, the granulomas around schistosome eggs in the bladder wall) have been linked with neoplasia, but the nature of the link is not known. The continuous release by living worms of excretory-secretory materials, many of which are known to have direct effects upon host cells and tissues, may also contribute to pathology. Indirect Damage from Host Response As with all infectious organisms, it is impossible to separate the pathogenic effects caused strictly by mechanical or chemical tissue damage from those caused by the immune response to the parasite. All helminths are "foreign bodies" not only in the sense of being large and invasive but also in the immunologic sense: they are antigenic and therefore stimulate immunity. An excellent illustration of this interrelation between direct and indirect damage is seen in the pathology associated with schistosome infections, especially with Schistosoma mansoni (Fig. 87-3). Hypersensitivity-based, granulomatous responses to eggs trapped in the liver cause a physical obstruction to blood flow, which leads to liver pathology. Hypersensitivity-based inflammatory changes probably also contribute to the lymphatic blockage associated with filarial infections (Brugia, Wuchereria). FIGURE 87-3 Pathogenesis: indirect damage caused by immunopathologic responses (for example, in Schistosomiasis). Immune-mediated inflammatory changes occur in the skin, lungs, liver, intestine, CNS, and eyes as worms migrate through these structures. Systemic changes such as eosinophilia, edema, and joint pain reflect local allergic responses to parasites. The pathologic consequences of immune-mediated inflammation are seen clearly in intestinal infections (especially Strongyloides and Trichinella infections). Structural changes, such as villous atrophy, develop. The permeability of the mucosa changes, fluid accumulates in the gut lumen, and intestinal transit time is reduced. Prolonged changes of this type may lead to a protein-losing enteropathy. The inflammatory changes that accompany the passage of schistosome eggs through the intestinal wall also cause severe intestinal pathology. Heavy infections with the whipworm Trichuris in the large bowel can lead to inflammatory changes, resulting in blood loss and rectal prolapse. The severity of these indirect changes is a result of the chronic nature of the infection. The fact that many worms are extremely long-lived means that many inflammatory changes become irreversible, producing functional changes in tissues. Three examples are the hyperplasia of bile ducts in long-term liver fluke infections, the extensive fibrosis associated with chronic schistosomiasis, and the skin atrophy associated with onchocerciasis. Severe pathology may also result when worms stray into abnormal body sites. Defenses Against Infection Nonspecific Resistance Infective stages attempting to enter via the mouth or through the skin are opposed by the same non-specific defenses that protect humans from invasion of other pathogens. Following oral ingestion, parasites must survive passage through the acid stomach to reach the small bowel. The natural parasites of humans are adapted to do this, but opportunistic parasites may be killed. Similarly, natural parasites are adapted to the environmental conditions of the bowel (and in many cases require them as cues for development), but accidental parasites may find them inappropriate. Penetration into the intestinal wall may trigger inflammatory responses that immobilize and kill the worm. This may itself lead to serious pathology (as in Anisakis infection). Worms entering through the skin must survive the skin secretions, penetrate the epidermal layers, and avoid inflammatory trapping in the dermis. Invasion of humans by the larvae of dog and cat hookworms (Ancylostoma spp.) results in dermatitis and "creeping eruption" as the worms become the focus of inflammatory reactions that form trails in the skin. Once in the tissues, worms need the correct sequence of environmental signals to mature. Absent or incomplete signals constitute a form of nonspecific resistance that may partially or completely prevent further development. The parasite may not die, however; indeed, prolonged survival at a larval stage may result in pathology from the continuing inflammatory response (e.g. Toxocara infection). Specific Acquired Immunity There is no doubt that specific immunity is responsible for the most effective forms of host defense, although the dividing line between nonspecific and specific mechanisms is difficult to draw with precision (Fig. 87-4). All helminths stimulate strong immune responses, which can easily be detected by measuring specific antibody or cellular immunity. Although these responses are useful for diagnosing infection, they frequently appear not to be protective. The high prevalence of helminth infection in endemic areas (sometimes approaching 100 per cent), and the fact that individuals may remain infected for many years and can easily be reinfected after they are cured by chemotherapy, suggest that protective immunity against helminths is weak or absent in humans. However, some degree of immunity does appear to operate, because the intensity of infection often declines with age, and many individuals in endemic areas remain parasitologically negative and/or clinically normal. Evidence from laboratory studies provides some clues as to the mechanisms involved. Antibodies that bind to surface antigens may focus complement- or cell-mediated effectors that can damage the worm. Macrophages and eosinophils are the prime cytotoxic effector cells, and IgM, IgG and IgE are the important immunoglobulins. Antibodies may also block enzymes released by the worm, thus interfering with its ability to penetrate tissues or to feed. Inflammatory changes may concentrate effector cells around worms, and the release of cellular mediators may then disable and kill the worm. Encapsulation of trapped worms by inflammatory cells may also result in the death of the worm, although this is not always the case. Intestinal worms can be dislodged by the structural and physiologic changes that occur in the intestine during acute inflammation. It has long been suspected that IgE-mediated hypersensitivity reactions, involving mast cells and basophils, contribute to this process, but the evidence is still circumstantial. Despite the abundance of IgA in the intestinal lumen, there is no conclusive evidence that it is involved in protective immunity in humans, although some field and laboratory data suggest it is. FIGURE 87-4 Host defense and parasite escape. A schematic diagram of the development and expression of acquired immunity to helminths and of the ways in which parasites escape the immune response. Avoidance of Host Defenses Despite their immunogenicity, many helminths survive for extended periods in the bodies of their hosts. Some of the reasons have already been mentioned (size, motility), but we now know that worms employ many sophisticated devices to render host defenses ineffective (Fig. 87-4). Some worms (schistosomes) disguise their outer surface by acquiring host molecules which reduce their antigenicity; intrinsic membrane changes also make these worms resistant to immune attack. Filarial nematodes acquire serum albumin on their cuticle, which may act as a disguise. Many worms release substances that depress lymphocyte function, inactivate macrophages, or digest antibodies. Larval cestodes appear to prolong their survival by producing anticomplement factors which protect their outer layers from lytic attack. Antigenic variation in the strict sense is not known to occur, but many species show a stage-specific change of antigens as they develop, and this phenomenon may delay the development of effective immune mechanisms. All helminths release relatively large amounts of antigenic materials, and this voluminous production may divert immune responses or even locally exhaust immune potential. Irrelevant antibodies produced by the host may block the activity of potentially protective antibodies, as has been shown to be the case in schistosome infections. It is striking that many helminth infections are associated with a degree of immune suppression, which may affect specific or general responsiveness. Many explanations have been proposed for this immune suppression, including antigen overload, antigenic competition, induction of suppressor cells, and production of lymphocyte-specific suppressor factors. Reduced immune responsiveness may not only prolong the survival of the original infecting worm species but increase the host's susceptibility to other pathogens. Epidemiologic evidence also raises the possibility that infections acquired early in life before or shortly after birth - may induce a form of immune tolerance, allowing heavy worm burdens to accumulate in the body. The subtlety with which parasitic worms manipulate the host's immune system not only increases their importance as pathogens but also creates formidable problems for their control and eradication. Protozoa: Pathogenesis and Defenses John Richard Seed General Concepts Resistance Resistance is the ability of a host to defend itself against a pathogen. Resistance to protozoan parasites involves three interrelated mechanisms: nonspecific factors, cellular immunity, and humoral immunity. Pathology Protozoal infection results in tissue damage leading to disease. In chronic infections the tissue damage is often due to an immune response to the parasite and/or to host antigens as well as to changes in cytokine profiles. Alternatively, it may be due to toxic protozoal products and/or to mechanical damage. Escape Mechanisms Escape mechanisms are strategies by which parasites avoid the killing effect of the immune system in an immunocompetent host. Escape mechanisms used by protozoal parasites include the following. Antigenic Masking: Antigenic masking is the ability of a parasite to escape immune detection by covering itself with host antigens. Blocking of Serum Factors: Some parasites acquire a coating of antigen-antibody complexes or noncytotoxic antibodies that sterically blocks the binding of specific antibody or lymphocytes to the parasite surface antigens. Intracellular Location: The intracellular habitat of some protozoan parasites protects them from the direct effects of the host's immune response. By concealing the parasite antigens, this strategy also delays detection by the immune system. Antigenic Variation: Some protozoan parasites change their surface antigens during the course of an infection. Parasites carrying the new antigens escape the immune response to the original antigens. Immunosuppression: Parasitic protozoan infections generally produce some degree of host immunosuppression. This reduced immune response may delay detection of antigenic variants. It may also reduce the ability of the immune system to inhibit the growth of and/or to kill the parasites. INTRODUCTION Resistance to parasitic protozoa appears to be similar to resistance against other infectious agents, although the mechanisms of resistance in protozoan infections are not yet as well understood. Resistance can be divided into two main groups of mechanisms: (1) nonspecific mechanism(s) or factor(s) such as the presence of a nonspecific serum component that is lethal to the parasite; and (2) specific mechanism(s) involving the immune system (Fig. 78-1). Probably the best studied nonspecific mechanisms involved in parasite resistance are the ones that control the susceptibility of red blood cells to invasion or growth of plasmodia, the agents of malaria. Individuals who are heterozygous or homozygous for the sickle cell hemoglobin trait are considerably more resistant to Plasmodium falciparum than are individuals with normal hemoglobin. Similarly, individuals who lack the Duffy factor on their red blood cells are not susceptible to P vivax. Possibly both the sickle cell trait and absence of the Duffy factor have become established in malaria-endemic populations as a result of selective pressure exerted by malaria. Epidemiologic evidence suggests that other inherited red blood cell abnormalities, such as thalassanemia and glucose-6-phosphate dehydrogenase deficiency, may contribute to survival of individuals in various malaria-endemic geographical regions. A second welldocumented example of a nonspecific factor involved in resistance is the presence in the serum of humans of a trypanolytic factor that confers resistance against Trypanosoma brucei brucei, an agent of trypanosomiasis (sleeping sickness) in animals. There is evidence that other nonspecific factors, such as fever and the sex of the host, may also contribute to the host's resistance to various protozoan parasites. Although nonspecific factors can play a key role in resistance, usually they work in conjunction with the host's immune system (Fig. 78-1). FIGURE 78-1 Some interrelationships between host factors involved in resistance to protozoan infections. Different parasites elicit different humoral and/or cellular immune responses. In malaria and trypanosome infections, antibody appears to play a major role in immunity. In both T cruzi and T brucei gambiense infections, antibody-dependent cytotoxic reactions against the parasite have been reported. Although antibody has been shown to be responsible for clearing the African trypanosomes from the blood of infected animals, recent evidence suggests that the survival time of infected mice does not necessarily correlate with the ability of the animal to produce trypanosome-specific antibody. In other words, resistance as measured by survival time may not solely involve the specific humoral immune system. Recent data suggest that cellular immunity is required for resistance to malaria. for example, vaccine trials with a sporozoite antigen indicated that both an active cellular response and sporozoite-specific antibody may be needed for successful immunization. Cellular immunity is believed to be the single most important defense mechanism in leishmaniasis and toxoplasmosis. In animals infected with Toxoplasma, the activated macrophage has been shown to play an important role in resistance. Accordingly, resistance to the protozoan parasites most likely involves nonspecific factors as well as specific humoral and/or cellular mechanisms. Cytokines are involved in the control of both the immune response and pathology. It has become apparent that there are subsets of both helper (h) and cytotoxic (c) T-cells that produce different profiles of cytokines. For example, the Th-1 subset produces gamma interferon (IFN-), and interleukin-2 (IL-2) and is involved in cell-mediated immunity. In contrast the Th-2 subset produces IL-4 and IL-6, and is responsible for antibody-mediated immunity. The induction of a particular T-cell subset is key to recovery and resistance. The Th-1 subset and increased IFN- are important in resistance to Leishmania, T cruzi and Toxoplasma infections, whereas the Th-2 response is more important in parasitic infections in which antibody is a key factor. It is important to recognize that the cytokines produced by one T-cell subset can up or downregulate the response of other T-cell subsets. IL-4 will downregulate Th-1 cells and exacerbate infection and/or susceptibility of mice to Leishmania. The cytokines produced by T and other cell types do not act directly on the parasites but influence other host cell types. The response of cells to cytokines includes a variety of physiological changes, such as changes in glucose, fatty acid and protein metabolism. For example, IL-1 and tumor necrosis factor will increase gluconeogenesis, and glucose oxidation. It should be noted that cytokines influence the metabolism not only of T-cells, but also a variety of other cell types and organ systems. Cytokines can also stimulate cell division and, therefore, clonal expansion of T and B-cell subsets. This can lead to increased antibody production and/or cytotoxic T-cell numbers. The list of cytokines and their functions is growing rapidly, and it would appear that these chemical messages influence all phases of the immune response. they are also clearly involved in the multitude of physiological responses (fever, decreased food intake, etc.) observed in an animal's response to a pathogen, and in the pathology that results. Unlike most viral and bacterial infections, protozoan diseases are often chronic, lasting months or years. When associated with a strong host immune response, this type of chronic infection is apt to result in a high incidence of immunopathology. The question also arises of how these parasites survive in an immunocompetent animal. The remainder of this chapter treats the mechanisms responsible for pathology, particularly immunopathology, in protozoan disease, and the mechanisms by which parasites evade the immune responses of the host. Finally, because of the very rapid advances in our knowledge of the host-parasite relationship (due primarily to the development of techniques in molecular biology), it is necessary to briefly mention the potential for developing vaccines to the pathogenic protozoa. PATHOLOGY The protozoa can elicit humoral responses in which antigen-antibody complexes in the region of antibody excess activate Hageman blood coagulation factor (Factor XII), which in turn activates the coagulation, fibrinolytic, kinin and complement systems. It has been suggested that this type of immediate hypersensitivity is responsible for various clinical syndromes in African trypanosomiasis, including blood hyperviscosity, edema, and hypotension. Similar disease mechanisms would be expected in other infections by protozoa involving a strong humoral immune response (Table 78-1). Immune complexes have been found circulating in serum and deposited in the kidneys and other tissues of humans and animals infected with protozoans. These parasite antigenantibody complexes, plus complement, have been eluted from kidney tissue in cases of malaria and African trypanosomiasis. Antigen and antibody have been directly visualized in the glomeruli of infected animals by light and electron microscopy. Inflammatory cell infiltrates accompany these deposits, and signs of glomerulonephritis are usually seen. African trypanosomes and presumably their antigens are also found in a variety of extravascular locations. Immune complexes, cellular infiltrates, and tissue damage have been detected in these tissues. Another important form of antibody-mediated pathology is autoimmunity. Autoantibodies to a number of different host antigens (for example, red blood cells, laminin, collagen, and DNA) have been demonstrated. These autoantibodies may play a role in the pathology of parasitic diseases in two ways. First the antibodies may exert a direct cytotoxic effect on the host cells; for example, autoantibodies that coat red blood cells produce hemolytic anemia. Alternatively, autoantibodies may be pathogenic through a buildup of antigen-antibody complexes in the kidneys or other tissues, leading to glomerulonephritis or other forms of immediate hypersensitivity. A particularly good example of a protozoan infection in which autoimmunity appears to be an important contributor to pathogenesis is T cruzi infection. In this case, there is substantial evidence that host and parasite share cross-reacting antigens. Antibodies and cytotoxic lymphocytes to these antigens appear to be harmful to host tissue. This type of experimental data, combined with the fact that the parasite itself seems not to cause the tissue pathology, lead one to conclude that autoimmunity may play a key role in pathogenesis. Cellular hypersensitivity is also observed in protozoan diseases (Table 78-1). For example, in leishmaniasis (caused by Leishmania tropica), the lesions appear to be caused by a cellmediated immune response and have many, if not all, of the characteristics of granulomas observed in tuberculosis or schistosomiasis. In these lesions, a continuing immune response to pathogens that are able to escape the host's defense mechanisms causes further influx of inflammatory cells, which leads to sustained reactions and continued pathology at the sites of antigen deposition. During a parasitic infection, various host cell products (cytokines, lymphokines, etc.) are released from activated cells of the immune system. These mediators influence the action of other cells and may be directly involved in pathogenesis. An example is tumor necrosis factor (TNF), which is released by lymphocytes. TNF may be involved in the muscle wasting observed in the chronic stages of African trypanosomiasis. TNF has also been implicated in the cachexia and wasting in Leishmania donovani infection, cerebral malaria in P falciparum in children and decreased survival in T cruziinfected mice. It is apparent that mediators involved in resistance to protozoan parasites may also lead to pathology during a chronic infection (Fig. 78-1). There appears to be a delicate balance between the factors involved in resistance to infectious agents and those which ultimately produce pathology and clinical disease. Numerous authors have suggested that toxic products produced by parasitic protozoa are responsible for at least some aspects of pathology (Table 78-1). For example, the glycoproteins on the surface of trypanosomes have been found to fix complement. This activation of complement presumably results in the production of biologically active and toxic complement fragments. In addition, trypanosomes are known to release proteases and phospholipases when they lyse. These enzymes can produce host cell destruction, inflammatory responses, and gross tissue pathology. Furthermore, it has been hypothesized that the trypanosomes contain a B-cell mitogen that may alter the immune response of the host by eliciting a polyclonal B-cell response that leads to immunosuppression. Finally it has recently been shown that the African trypanosomes also contain an endotoxin which is presumably released during antibody- mediated lysis. Parasitic protozoa have also been reported to synthesize (or contain) low-molecular-weight toxins. For example, the trypanosomes produce several indole catabolites; at pharmacologic doses, some of these catabolites can produce pathologic effects, such as fever, lethargy, and even immunosuppression. Similarly, enzymes, B-cell mitogen, etc., are presumably released by many if not all of the other parasitic protozoa. There has been limited work on the role of these protozoal products in pathogenesis. However, parasitic protozoa are generally not known to produce toxins with potencies comparable to those of the classic bacterial toxins (such as the toxins responsible for anthrax and botulism). One possible exception is the African trypanosomes which are suggested to contain an endotoxin. IMMUNE ESCAPE Parasite escape mechanisms may include a number of different phenomena (Table 78-2). In antigenic masking, the parasite becomes coated with host components and so fails to be recognized as foreign. In blocking, noncytotoxic antibody combines with parasite antigens and inhibits the binding of cytotoxic antibodies or cells. The parasite may pass part of its life cycle in an intracellular location, for example, in erythrocytes or macrophages, in which it is sheltered from intracellular digestion and from the cytotoxic action of antibody and/ or lymphocytes. Some parasites practice antigenic variation, altering their surface antigens during the course of an infection and thus evading the host's immune responses. Finally, the parasite may cause immunosuppression, reducing the host's immune response either to the parasite specifically or to foreign antigens in general. These strategies are discussed in more detail below. Masking and Mimicry Various species of trypanosomes have host immunoglobulins associated with their cell surfaces. There are several reports that these antibodies are not bound to the trypanosomes through their variable regions, but presumably through the Fc portion of their molecule. These antibodies may mask the parasite-that is, prevent immune recognition by the host. However, no evidence other than the presence of immunoglobulins on the surface of the trypanosomes supports this hypothesis. Mimicry, in which the parasite has the genetic information to synthesize antigens identical to those of its host, has not been demonstrated in parasitic protozoa. Blocking It has been hypothesized that in some cases antigen-antibody complexes in serum of infected animals bind to the parasite's surface, mechanically blocking the actions of cytotoxic antibodies or lymphocytes and directly inhibiting the actions of lymphocytes. This type of immune escape mechanism has been proposed for tumor cells and for the parasitic helminths. Because the trypanosomes carry immunoglobulins on their cell surfaces, they may use a similar mechanism; however, no direct evidence has yet been reported. Intracellular location Many protozoan parasites grow and divide within host cells. For example, Plasmodium parasites grow first in hepatocytes and then in red blood cells. Leishmania and Toxoplasma organisms are capable of growing in macrophages; one genus of parasitic protozoa, Theilera, not only multiplies in lymphocytes but appears even to stimulate the multiplication of the infected lymphocytes. Although some parasites, such as Plasmodium, are restricted to a limited number of host cell types, others, such as T cruzi and Toxoplasma, appear to be able to grow and divide in a variety of different host cells. An intracellular refuge may protect a parasite from the harmful or lethal effects of antibody or cellular defense mechanisms. For example, Plasmodium may be susceptible to the actions of antibody only during the brief extracellular phases of its life cycle (the sporozoite and merozoite stages). It should be remembered that Plasmodium actually resides in a membrane-bound vacuole in the host cell. Thus, plasmodia are shielded from the external environment by at least two host membranes (the outer cell membrane and an inner vacuole membrane). Although intracellular plasmodia are very well protected from the host's immune response early in their growth, this strategy does create physiologic problems for the parasite. For example, the parasite must obtain its nutrients for growth through three membranes (two host and one parasite), and must eliminate its waste products through the same three membranes. Plasmodia solve this problem by appropriately modifying the host cell membranes. Parasitic proteins are incorporated into the red blood cell outer membrane. The host eventually responds to these antigens, and this response ultimately leads to the increased removal of infected host cells. The existence of extracellular phases in the malaria life cycle is important, since immunization against these stages is the rationale for the development of our current vaccine candidates. The protective antigens on these extracellular stages have been purified as potential antigens for a vaccine. However, this approach has problems. For example, the sporozoite stage is exposed to protective antibody for only a brief period, and even a single sporozoite that escapes immune elimination will lead to an infection. Second, the antigenic variability of different isolates and the ability of different strains to undergo antigenic variation are not fully known. Therefore, the effectiveness of the vaccine candidates must still be demonstrated. However a large synthetic peptide containing antigenic sequences from 3 different proteins of P falciparum has been shown to reduce the clinical incidence of malaria by 31% in field trials. There is therefore optimism that a vaccine against P falciparum may be available in the near future. A number of parasitic protozoa reside in macrophages. Although these organisms are protected from external immune threats, they must still evade digestion by the macrophage. Three strategies have been suggested. First, the parasite may prevent the fusion of lysosomes with the phagocytic vacuole. The actual mechanism responsible for this inhibition is not yet understood, but it has been shown to occur in cells infected with Toxoplasma. A second mechanism is represented by the ability of T cruzi to escape from the phagocytic vacuole into the cytoplasm of the macrophage. Finally, it is possible that some parasites can survive in the presence of lysosomal enzymes, as can the leprosy bacillus. One of the best-studied examples of a protozoan parasite able to survive in the phagolysosome is Leishmania. It has been suggested that the resistance of this parasite to the host's hydrolytic enzymes is due to surface components that inhibit the host's enzymes and/or to the presence of parasitic enzymes that hydrolyze the host's enzymes. As previously noted, at least one protozoan parasite, Theilera, is capable of growing directly in lymphocytes. Therefore, this parasite may escape the host's immune response by growing inside the very cells required for the response. Antigenic Variation Three major groups of parasitic protozoa are known to be able to change the antigenic properties of their surface coat. The African trypanosomes can completely replace the antigens in their glycocalyx each time the host exhibits a new humoral response. These alterations in serotype are one important way in which the African trypanosomes escape their host's defense mechanism. Although less well-characterized, similar changes are reported to occur in Plasmodium, Babesia, and Giardia. It has been estimated that African trypanosomes have approximately 1,000 different genes coding for surface antigens. These genes are located on various chromosomes; however, to be expressed, the gene must be located at the end of a chromosome (telomeric site). The rate at which variation occurs in a tsetse-fly-transmitted population appears quite high. It has been shown that 1 in 10 cells appears to be capable of switching its surface antigen. The order in which the surface coat genes are expressed is not predictable. Much information is available on the nucleotide sequence of the genes coding the coat proteins; however, neither the factor(s) that induces a cell to switch its surface antigens nor the specific genetic mechanisms) involved in the switch are fully understood. The antibody response does not induce the genetic switch, but merely selects variants with new surface antigens out of the original population. Considerably less information is available on the phenomenon of antigenic variation in malaria or babesiosis. However, antigen variation could be a major problem in reference to the development of a blood stage (merozoite) vaccine for malaria. Finally, antigenic variation has been observed in Giardia lamblia. A number of different gene families coding for surface proteins in Giardia have been identified. Antigenic variation has been suggested to assist Giardia in escaping the host's immune response. Immunosuppression Immunosuppression of the host has been observed with almost every parasitic organism carefully examined to date. In some cases the suppression is specific, involving only the host's response to the parasite. In other cases the suppression is much more general, involving the response to various heterologous and nonparasite antigens. It has not yet been proven that this immunosuppression allows the parasites to survive in a normally immunocompetent host. However, one can postulate that immunosuppression could permit a small number of parasites to escape immune surveillance, thus favoring establishment of a chronic infection. This mechanism might be particularly effective in parasites thai undergo antigenic variation, since it could allow the small number of parasites with new surface antigens to go undetected initially. Immunosuppression experimentally induced by various extraneous agents has certainly been shown to produce higher parasitemias, higher infection rates, or both. Therefore, the hypothesis that parasite-induced immmosuppression increases the chance for a parasite to complete its life cycle makes sense. It should be noted that immunosuppression can be pathogenic itself. A reduced response to heterologous antigens could favor secondary infections. Humans suffering from malaria or trypanosomiasis have been shown to be immunosuppressed to a variety of heterologous antigens. Secondary infections may often be involved in death from African trypanosomiasis. A variety of mechanisms have been suggested to explain the immunosuppression observed in protozoan infections. The most common mechanisms proposed are (1) the presence in the infected host of parasite or host substances that nonspecifically stimulate the growth of antibody-producing B cells, rather than stimulating the proliferation of specific antiparasite B-cells; (2) proliferation of suppressor T-celis and/or macrophages that inhibit the immune system by excretion of regulatory cytokines; and (3) production by the parasite of specific immune suppressor substances. Non-specific Host Defenses: Non-specific host defenses are those that do not rely on antigen-antibody reactions and which operate (more or less) without regard to the pathogen involved. Antibody mediated defenses on the other hand are quite specific to certain pathogens, and even to certain specific molecules associated with specific pathogens. We will consider the immune systen (antibody defenses) in the next unit. Non-specific defense mechanisms include a variety of physical, chemical, and biological barriers to infection. Physical defenses: epithelial surfaces - intact (undamaged) skin and mucous membranes present a formidible barrier that few organisms can penetrate. The larvae of hookworms and the cercaria of the blood flukes represent a few of the rare exceptions. Cross-sections of human skin (Credit: National Institutes of Health) mucus - creates a sticky layer on tissue surfaces that entraps potential invading organisms. the "ciliary escalator" - this refers to the system of ciliated epithelial surfaces of the upper respiratory tract. The beating of the cilia moves the thin sheet of mucus associated with it upward (or downward from the nose and sinuses) towards an accumulation point in the throat where it triggers a cough reflex that causes the accumulation of mucus and the dust and bacteria trapped in it to be expectorated or swallowed. Respiratory epithelium: 1-cilia; 2-mucus cell Scanning EM of respiratory cilia Image: Linkpublishing flushing action - the flow of tears, sweat, and urine all serve to flush bacteria away. coughing and sneezing - serve to flush (with air rather than water) invading organisms away. Chemical defenses: Acidic pH - of skin (due to fatty acids in sebum); of the stomach (due to gastric hydrochloric acid); of the vagina (due to the normal flora of lactobacilli that produce lactic acid); and the slightly acidic pH of urine all serve to suppress the growth of most bacteria or even kill them outright in the case of the stomach where the pH is extremly low (acidic). Osmotic pressure - The salt left behind on skin as sweat evaporates creates high osmotic pressure which suppresses the growth of most bacteria. Lysozymes are smallish enzymes that are widely distributed throughout the biological world. They attack the polysacharide polymers of the bacterial cell wall and render the cell subject to osmotic lysis. Lysozyme is found in egg white, and in human blood, mucus, tears, sweat, and saliva. It is also produced by phagocytic white blood cells (neutrophils and monocytes) and by some bacteriophages. Like penicillin, it was discovered by Alexander Fleming. Egg white lysozyme was the first enzyme to have its structure fully determined. Interferons are a family of low molecular weight proteins that protect cells from viral attack (among other functions). There are 3 groups of human interferons (alpha, beta, and gamma interferon). Interferons are produced by virus-infected cells and also by macrophages and some lymphocytes, which are stimulated to produce interferon via activation by antigens. The effect of interferon on healthy cells is to stimulate them to produce antiviral proteins (AVP) which protects them from viral infection. Bile salts in bile suppress the growth of gram positive bacteria. Bile salts are steroids with detergent properties. Bile salts conjugated to certain amino acids have recently been shown to have antiviral activity, including anti-HIV activity. Digestive enzymes in the small intestine create a very harsh chemical environment that is hostile to most bacterial cells. Complement - a complex series of proteins in body fluids that cause damage to the bacterial plasma membrane. In humans, complement is produced by the liver. Complement may also serve as an opsonin- a substance that coats invading cells and prepares them for destruction by phagocytes (see below). Many antibody-antigen reactions require the participation of complement as well. The complement system consists of about thirty plasma proteins (designated C1 through C9 with a number of sub-types) that function either as enzymes or as binding proteins. It plays an important role in host defence against pathogens and also participates in the process of inflammation. In addition to the protein components, the system also includes specific receptors on the surfaces of immune system cells to which the complement proteins (or their fragments) bind. There are also several regulatory proteins that protect the host's cells from accidental attack by its own complement. The complement system can be activated by either of two different pathways: the classical pathway and the alternative pathway. The classical pathway is activated by the binding of certain antibody molecules to an antigen and is therefore antibody-dependent. The alternative pathway is activated by the invading pathogens themselves and does not require antibody. Complement activation by either of the two pathways initiates a cascade reaction in which each protein initiates the production of the next protein in the cascade sequence, and ultimately produces a complex of proteins called the membrane attack complex (MAC). The MAC produces a large hole in the membrane of the invading microorganism. With its membrane integrity destroyed the invader loses the ability to regulate its intracellular chemical environment and is killed by osmotic lysis. Complement mediated lysis occurs in bacteria, enveloped (animal) viruses, and other cells such as tumor cells, lymphocytes, platelets, and erythrocytes (red blood cells). The destruction of red blood cells in transfusion reactions is an example of complement mediated lysis. During the course of the reaction cascade, other molecular products are produced that have other effects including the release of histamine and other inducers of the inflammatory response. These chemicals are released by basophils and mast cells (tissue basophils). Other effects inclkude the stimulation and attraction of neutrophils, and the coating of invading cells to mark them for destruction by phagocyles (opsonization). Some complement components also appear to play a role in the body's elimination of large and insoluble immune complexes (proteinaceous aggregates of antigen, antibody, and complement). Receptors for C3B(a complement protein) on red blood cells allow these cells to transport immune complexes to the liver where they are destroyed. Complement cascade resulting in the formation of membrane hole in invading cell (credit: Nat. Cancer Inst. ) Biological (cellular) defenses: Phagocytosis: certain white blood cells (polymorphonuclear neutrophils and monocytes) and other cells called macrophages (tissue cells derived from monocytes) are able to engulf and destroy bacteria and some other invading organisms. Phagocytosis is actually a rather complex process involving at least 5 steps: 1. locating the cell to be destroyed. This is usually accomplished by some form of chemotaxis , which involves attraction of the phagocyte by a chemical substance produced either by the microorganism itself or by other cells of the immune system.. 2. attachment to the invading cell is facilitated by antibodies, complement, and specific binding sites on the surface of the phagocyte. 3. ingestion of the invading cell by internalizing it within the phagocyte by a process of endocytosis. A membranous phagosome (food vacuole) is thus formed around the invading cell. 4. killing the invading cell with chemical substances which may include various enzymes, hydrogen peroxide, superoxide anion, and hypochlorite ion. Lysosomes (containing up to 60 different digestive enzymes) fuse with and discharge their contents into the phagosome to form a phagolysosome. 5. digestion of invading cell by hydrolytic (digestive) lysosomal enzymes. For an animation of the process of phagocytosis, press HERE. (Graphic: Community College of Baltimore Co.) Human white blood cells (wbc's or leucocytes): There are typically 5,000 to 10,000 of these per cubic millimeter of human blood ( 5-10 billion per liter ). The white cell count typically increases in response to infection. Leucocytes play a role in both specific (antibody-based) and non-specific host defense mechanisms. Stained Human Blood Cells (RBC= red blood Scanning EM of Human Blood Cells (Image: cells) NIH) There are two broad types of white cells: granulocytes (neutrophils, eosinophils, and basophils) and agranulocytes (lymphocytes and monocytes). The 5 basic types of leukocytes are: Polymorphonuclear neutrophils (PMNs) - about 55-70% of circulating wbc's are PMNs. These are phagocytic cells that play an important role in the defense against bacterial pathogens. (Image) Eosinophils represent about 5 % of circulating wbc's. These are capable of phagocytosis under some conditions, but are more directly concerned with the extracellular destruction of invading organisms, particularly parasites such as helminths. High eosinophil numbers are typically associated with helminth infections. (Image) Basophils - constitute 1% or less of circulating wbc's. Basophils produce a variety of biologically active chemicals including histamine (involved in allergic response) and heparin (an anticoagulant). (Image) Lymphocytes - about 20% of circulating wbc's are lymphocytes. These cells are largely responsible for both humoral and cellular immunity. There are two general types of lymphocytes, B cells (plasma cells) that produce soluble (humoral) antibodies, and T cells which are responsible for cellular immunity. There are 5 different types of T-cells, each with its own set of functions (discussed later): (Image) Helper cells (Th) Suppressor cells (Ts) Delayed hypersensitivity cells (Td) Cytoxic [killer] cells (Tc) Natural killer cells (Nk) - destroy tumor cells, transplanted tissue, and cells infected with intracellular bacteria such as the Rickettsia and Chlamydias. Both Tc and Nk cells produce a protein called perforin which bores a hole in the membrane of the attacked cell, much like the membrane attack complex( MAC) of complement. While lymphocytes are generally considered to be part of the "specific" immunity system (involving antigens and antibodies), the Nk cells do not require an antigen to activate them, and so are perhaps best considered to be part of the body's non-specific defense system. Monocytes constitute about 5-8 % of circulating wbc's. Like, PMNs, these cells are capable of phagocytosis. In the tissues, these cells can be transformed into macrophages which phagocytize invading cells and process and "present" antigens to B-lymphocytes, stimulating them to produce antibodies. (Image) inflamation - a complex interwoven series of processes that increase the blood supply to an infected site. The symptoms of inflamation: swelling, warming, reddening, and pain are all the result of the increased blood supply brought about by capillary dilation. A series of chemical mediators including histamine and the prostaglandins are also involved in inflamatory processes. fever - elevated body temperature protects the body from infection in several ways: creates an unfavorable thermal environment for bacteria whose thermal optimum is 37o C. speeds-up chemical reactions that are part of the chemical defense mechanism(s) Nonspecific Defenses Ferdinando Dianzani Samuel Baron General Concepts Most viral infections are limited by defenses that are antigen nonspecific and/or specific. Nonspecific defenses act sooner than specific defenses. Some are always in place (anatomic barriers, nonspecific inhibitors, and phagocytic cells); others are evoked by the infection (fever, inflammation, and interferon). Anatomic Barriers Anatomic barriers are located at body surfaces (skin and mucosa) or within the body (endothelial cells and basement membranes). They are partly effective in preventing virus spread but may be breached by large numbers of virus, by trauma, by increased permeability, by replication of virus in endothelial cells, or by transportation of virus in leukocytes. Nonspecific Inhibitors Body fluids and tissues normally contain soluble viral inhibitors. Most prevent viral attachment, some directly inactivate viruses, and others act intracellularly. These inhibitors may be overwhelmed by sufficient virus. Phagocytosis Viruses may be phagocytosed to different degrees by polymorphonuclear leukocytes and macrophages. The effect of phagocytosis may be virus inactivation, persistence, or multiplication; consequently, the result may be clearance of virus, transportation to distant sites, or enhanced infection. Fever Replication of most viruses is reduced by even a modest rise in temperature. During viral infection, fever can be initiated by several endogenous pyrogens, such as interleukins-1 and -6, interferon, prostaglandin E2, and tumor necrosis factor. Inflammation Inflammation inhibits viral replication through (1) elevated local temperature, (2) reduced oxygen tension, (3) metabolic alterations, and (4) acid production. The effects of these mechanisms are often additive. Viral Interference and Interferon Viral interference occurs when infection by one virus renders cells resistant to the same or other superinfecting viruses. Interference is usually mediated by newly induced host cell proteins designated as the interferon systems. Secreted interferon binds to cells and induces them to block various stages of viral replication. Interferon also (1) inhibits growth of some normal and tumor cells and of many intracellular parasites, such as rickettsiae and protozoa; (2) modulates the immune response; and (3) affects cell differentiation. There are three main types of interferon, alpha, beta, and gamma interferons. Alpha interferon is produced mainly by certain leukocytes (dendritic cells, macrophages and B cells), beta interferon by epithelial cells and fibroblasts, and gamma interferon by T and natural killer cells. Two other interferon types are related to alpha interferon. Omega interferons share about seventy percent identity with alpha interferons. Tau interferons also are related structurally to alpha interferons but are unusual by (a) being produced for only a few days by normal placental trophoblasts and (b) not being inducible by viruses. INTRODUCTION Most viral infections are limited by nonspecific defenses, which (1) restrict initial virus multiplication to manageable levels, (2) initiate recovery from established infections that is then completed by a combination of these early nonspecific and subsequent antigenspecific immune defenses, and (3) enable the host to cope with the peak numbers of virus that, if presented as the infecting dose, could be lethal. Although immune and nonimmune (nonspecific) defenses operate together to control viral infections, this chapter considers only nonspecific defenses. Some nonspecific defenses exist independently of infection (e.g., genetic factors, anatomic barriers, nonspecific inhibitors in body fluids, and phagocytosis). Others (e.g., fever, inflammation, and interferon) are produced by the host in response to infection. All nonspecific defenses begin to act before the specific defense responses develop and can potentiate some of the established immune effector mechanisms. The fact that viruses replicate intracellularly and the ability of some viruses to spread by inducing cell fusion partly protect viruses against such extracellular defenses as neutralizing antibody, phagocytosis, and nonspecific inhibitors. However, because they replicate within the cell, viruses are vulnerable to intracellular alterations caused by host responses to infection. Nonspecific responses that alter the intracellular environment include fever, inflammation, and interferon. These multiple defenses function with great complexity because of their interactions with one another. This complexity is compounded by the varying effectiveness of the defenses that results from the diversity of viruses, hosts, and sites and stages of infection. Defense Mechanisms that Precede Infection Anatomic Barriers Anatomic barriers to viruses exist at the body surfaces and within the body. At the body surfaces, the dead cells of the epidermis and any live cells that may lack viral receptors resist virus penetration and do not permit virus replication. However, this barrier is easily breached, for example, by animal bites (rabies virus), insect bites (togaviruses), and minor traumas (wart virus). At mucosal surfaces, only the mucus layer stands between invading virus and live cells. The mucus layer forms a physical barrier that entraps foreign particles and carries them out of the body; it also contains nonspecific inhibitors (see following section). The mucus barrier is not absolute, however, since sufficient quantities of many viruses can overwhelm it and infect by this route. In fact, most viruses use mucous surfaces as the portal of entry and initial replication site. Within the body, anatomic barriers to virus spread are formed by the layer of endothelial cells that separates blood from tissues (e.g., the bloodbrain barrier). Under normal conditions, these barriers have a low permeability for viruses unless the virus can penetrate them by replicating in the capillary endothelial cells or in circulating leukocytes. These internal barriers may explain, in part, the high level of viremia required to infect organs such as the brain, placenta, and lungs. Nonspecific Inhibitors A number of viral inhibitors occur naturally in most body fluids and tissues. They vary chemically (lipids, polysaccharides, proteins, lipoproteins, and glycoproteins) and in the degree of viral inhibition and types of viruses affected. Some inhibitors are related to the viral receptors of the cell surface, but most are of unknown origin. Many inhibitors act by preventing virus from attaching to cells, others by directly inactivating virus, and a few by inhibiting virus replication. In the gastrointestinal tract, some susceptible viruses are inactivated by acid, bile salts, and enzymes. Whereas most inhibitors block only one or a few viruses, some have a broad antiviral spectrum. Although the effectiveness of the inhibitors has not been fully established in vivo, their importance as host defenses is suggested by their antiviral activity in tissue culture and in vivo and by the direct correlation between the degree of virulence of some viruses and their degree of resistance to certain inhibitors. Examples are the serum and mucus inhibitors of influenza viruses during experimental infections. However, even sensitive viruses may overwhelm these inhibitors when the infecting dose of virus is sufficiently high. Therefore, the presence of these inhibitors may explain the relatively high dose of virus required to initiate infection in vivo, compared with the dose needed in cell cultures. Phagocytosis The limited information available suggests that phagocytosis is less effective against viral infections than against bacterial infections. However, few of the factors that control uptake of virions or infected cells by phagocytes and their digestion by lysosomal enzymes have been studied systemically. Different viruses are affected differently by the various phagocytic cells. Some viruses are not engulfed, whereas others are engulfed but may not be inactivated. In fact, some viruses, such as human immunodeficiency virus (HIV), may even multiply in the phagocytes (e.g., macrophages), which may serve as a persistent reservoir of virus (Fig. 49-1). The virulence of several strains of HIV and herpesviruses correlates with their ability to multiply in macrophages. Infected macrophages may carry virus across the blood-brain barrier. Interestingly, cytomegalovirus has been reported to replicate in granulocytes. Macrophages seem to be more effective against viruses than are granulocytes, and some viruses seem to be more susceptible to phagocytosis than others. Macrophages and polymorphonuclear leukocytes can afford important protection by markedly reducing the viremia caused by virus strains susceptible to phagocytosis. FIGURE 49-1 Possible outcomes of phagocytosis of a virus. Viruses may stimulate macrophages to produce monokines, which can reduce viral multiplication. For example, macrophage-produced alpha interferon (IFN-a) inhibits viral multiplication both directly and also indirectly by activating natural killer cells. Interleukin 1 (IL-1), produced by macrophages, can interfere with viral multiplication in a number of ways: (1) by inducing T lymphocytes to produce interleukin-2, which in turn induces gamma interferon (IFN-g), which can induce alpha and beta interferons; (2) by inducing the production of beta interferon (IFN-b) by fibroblasts and epithelial cells; (3) by inducing fever, which inhibits viral replication; (4) by enhancing macrophage-mediated cytolysis of infected cells; and (5) by inducing production of tumor necrosis factor (TNF), which inhibits virus multiplication both directly and indirectly by inducing interferon and other cytokines and augmenting inflammation, phagocytosis and cytotoxic activity. Therefore, depending on the situation, macrophages acting as phagocytes may reduce the number of viruses, help spread the infection, augment or depress immune defenses, or have little effect. Defense Mechanisms Evoked by Infection Fever Viral replication is influenced strongly by temperature. Fever can be induced during viral infection by at least three independent endogenous pyrogens: interleukins-1 and 6, interferon, prostaglandin E2, and tumor necrosis factor. Even a modest increase can cause strong inhibition: a temperature rise from 37°C to 38°C drastically decreases the yield of many viruses. This phenomenon has been observed in tissue culture as well as in many experimental (including primate) and natural infections. Artificial induction of fever reduces mortality in mice infected with viruses (Fig. 49-2). Artificial lowering of the temperature during infection may increase mortality, as in suckling mice infected with coxsackieviruses and taken away from the warmth of their mother's nest. Fever also augments the generation of cytotoxic T lymphocytes. FIGURE 49-2 Protection of mice by elevated temperature or antibody administered before or after intracerebral infection with the picornavirus EMC type. Several observations suggest strongly that fever reduces virus multiplication during human viral infections. Retrospective studies have shown that the incidence and severity of paralysis among children infected with polioviruses were significantly greater in patients treated with antipyretic drugs (e.g., aspirin) than in untreated children. Also consistent with these findings is the observation that virus strains that replicate best at fever temperature are usually virulent, whereas virus strains that replicate poorly at fever temperature are usually low in virulence and therefore often are used as live virus vaccines. Temperatures as low as 33°C are normal at body surfaces exposed to air; viruses that infect these sites and replicate optimally at these temperatures establish only local infections that do not spread to deeper tissues, where the body temperature is higher. For example, rhinoviruses that cause common colds replicate optimally at 33°C to 34°C (found in normally ventilated nasal passages); however, they are inhibited at 37°C (found when swelling of the edematous mucosa and secretions interrupt air flow). An interesting question is whether this temperature increase is important for recovery from coryza. The same general considerations of temperature probably apply to other human viral infections such as measles, rubella, and mumps, although, unfortunately, suitable and controlled studies have not been conducted. Nevertheless, available information suggests that antipyretic drugs be used conservatively. Inflammation Several antiviral mechanisms are generated by the local inflammatory response to virusinduced cell damage or to virus-stimulated mediators such as activated complement. The major components of the inflammatory process are circulatory alterations, edema, leukocyte accumulation and perhaps prostaglandins A and J. The resulting phenomena are elevated local temperature, reduced oxygen tension in the involved tissues, altered cell metabolism, and increased levels of CO2 and organic acids. All of these alterations, which occur in a cascading and interrelated fashion, drastically reduce the replication of many viruses. For instance, the altered energy metabolism of the infected and surrounding cells, as well as the accumulating lymphocytes, can generate local hyperthermia. At superficial sites where the temperature is normally lower, hyperthermia can also be generated by hyperemia during the early stages of inflammation. As inflammation progresses, hyperemia becomes passive, thereby greatly reducing blood flow and decreasing oxygen tension. Two factors account for this decrease in oxygen tension: limited influx of erythrocytes, and lower diffusion of oxygen through edema fluid. In turn, the decreased oxygen tension causes less ATP production, thus reducing the energy available for viral synthesis and increasing anaerobic glycolysis, which increases the accumulation of CO2 and organic acids in the tissues. These acid catabolites may decrease the local pH to levels that inhibit the replication of many viruses. Local acidity also may increase by accumulation and subsequent degradation of the leukocytes in the affected area. It is possible that other less well-defined factors are also significant . Therefore, the local inflammation resulting from viral infection clearly activates several metabolic, physicochemical, and physiologic changes; acting individually or together, these changes interfere with virus multiplication. Although further animal and human studies are required, this interpretation is supported by the finding that anti-inflammatory drugs (corticosteroids) often increase the severity of infection in animals. Therefore, these drugs should be used with caution in treating viral diseases. Viral Interference and Interferon Viral Interference Generally, infection by one virus renders host cells resistant to other, superinfecting viruses. This phenomenon, called viral interference, occurs frequently in cell cultures and in animals (including humans). Although interference occurs between most viruses, it may be limited to homologous viruses under certain conditions. Some types of interference are caused by competition among different viruses for critical replicative pathways (extracellular competition for cell surface receptors, intracellular competition for biosynthetic machinery and genetic control). Similar interference may result from competition between defective (nonmultiplying) and infective viruses that may be produced concurrently. Another type of interferencethe most important type in natural infectionsis directed by the host cells themselves. These infected cells may respond to viral infection by producing interferon proteins, which can react with uninfected cells to render them resistant to infection by a wide variety of viruses. Interferon The important role played by interferon as a defense mechanism is clearly documented by three types of experimental and clinical observations: (1) for many viral infections, a strong correlation has been established between interferon production and natural recovery; (2) inhibition of interferon production or action enhances the severity of infection; and (3) treatment with interferon protects against infection. In addition, the interferon system is one of the earliest appearing of known host defenses, becoming operative within hours of infection. Figure 49-3 compares the early production of interferon with the level of antibody during experimental infection of humans with influenza virus. Clinical studies of interferon and its inducers have shown protection against certain viruses, including hepatitis B and C viruses, papovaviruses, rhinoviruses, and herpes simplex virus. FIGURE 49-3 Production of virus, interferon, and antibody during experimental infection of humans with influenza wild-type virus. Nonspecific defenses include anatomic barriers, inhibitors, phagocytosis, fever, inflammation, and IFN. Specific defenses include antibody and cell-mediated immunity. Data from a study by B. Murphy et al, National Institutes of Health (personal communication). Although interferon was first recognized as an extraordinarily potent antiviral agent, it was found subsequently to affect other vital cell and body functions. For example, it may enhance killing by granulocytes, macrophages, natural killer (NK) cells, and cytotoxic lymphocytes and affect the humoral immune response and the expression of cell membrane antigens and receptors. It may also lyse or inhibit the division of certain cells, influence cell differentiation, and cross-activate hormone functions such as those of epinephrine and adrenocorticotropin (ACTH). The effect of these modulations may influence many viral infections. Interferon Production and Types Interferon is produced de novo by cellular protein synthesis. The three types (alpha, beta, and gamma) differ both structurally and antigenically and have molecular weights ranging from 16,000 to 45,000. Interferons are secreted by the cell into the extracellular fluids (Fig. 49-4). Usually, virus-induced interferon is produced at about the same time as the viral progeny are released by the infected cell, thus protecting neighboring cells from the spreading virus. FIGURE 49-4 Induction of beta interferon, alpha interferon, and gamma interferon, respectively, by foreign nucleic acids, foreign cells, and foreign antigens. The three known types of interferon are induced by different stimuli. Beta interferon is induced by viral and other foreign nucleic acids in most body cells (fibroblasts, epithelial cells, and macrophages). This induction mechanism is illustrated in Figure 49-4 and the top portion of Figure 49-5. FIGURE 49-5 Cellular events of the induction, production, and action of interferon. Inducers of interferon react with cells to depress the interferon gene(s) (A). This leads to the production of mRNA for interferon (B). The mRNA is translated into the interferon protein (C), which is secreted into the extracellular fluid(D), where it reacts with the membrane receptors of cells (E). The interferon-stimulated cells derepress genes (F) for effector proteins (AVP) that establish antiviral resistance and other cell changes. The activated cells also stimulate contacted cells (G) to produce AVP by a still unknown mechanism. Alpha interferon can be induced by foreign cells, virus-infected cells, tumor cells, bacterial cells, and viral envelopes that stimulate mostly circulating dendritic cells and to a lesser degree monocytes and B lymphocytes to produce it (Fig. 49-4, middle). Gamma interferon is produced (along with other lymphokines) by T lymphocytes induced by foreign antigens to which the T lymphocytes have been presensitized (Fig. 49-4). Mitogens for T cells may mimic this induction. Gamma interferon has several unusual properties: (1 ) it exerts greater immunomodulatory activity, including activation of macrophages, than the other interferons; (2) it exerts greater lytic effects than the other interferons; (3) it potentiates the actions of other interferons; (4) it activates cells by a mechanism significantly different from that of the other interferons; and (5) it inhibits intracellular microorganisms other than viruses (e.g., rickettsia). The 24 genes that code for interferons alpha and the single gene for beta in humans, are located in adjacent positions on chromosome 9. The only gene for interferon gamma is found on chromosome 12. The genes for interferons alpha and beta exhibit significant homology but not with interferon gamma. Genes for interferon alpha may be differentiated into two distinct clusters on the basis of the degree of homology. As a consequence, interferon alpha comprises two families of proteins, at least 14 of which belong to the alpha-1 type and two to the alpha-2 type (omega and tau). Also, interferon occurs without apparent stimulation in the plasma of patients with autoimmune diseases (such as rheumatoid arthritis, disseminated lupus erythematosus and pemphigus) and in patients with advanced HIV infection. In these cases, an interferon antigenically identical to interferon alpha is present but which, unlike the latter, is partially inactivated at pH 2 (acid-labile interferon alpha). This interferon is a synergistic combination of interferons alpha (acid stable) and gamma (acid labile). Consequently, acid treatment reduces the interferon activity by inactivating the synergistic interferon gamma. Mechanism of Action Interferon does not inactivate viruses directly. Instead, it prevents viral replication in surrounding cells by reacting with specific receptors on the cell membranes to derepress cellular genes that encode intracellular effector antiviral proteins, which must be synthesized before virus replication can be inhibited (Figs. 49-5 and 49-6). Alpha and beta interferons both bind to the same type of membrane receptor; gamma interferon binds to a different receptor. The antiviral proteins probably inhibit viral multiplication by inhibiting the synthesis of essential viral proteins, but alternative or additional inhibitory mechanisms (e.g, inhibition of transcription and viral release) also occur. Viral protein synthesis may be inhibited by several biochemical alterations of cells, which may, in theory, inhibit viral replication at the different steps shown in Figure 49-6. FIGURE 49-6 Molecular mechanisms of interferon antiviral actions. It has been shown that the antiviral state may be transferred from interferon-treated cells to adjacent untreated cells without the continued presence of interferon (Fig. 49-4); this transfer mechanism may further amplify and spread the activity of the interferon system. The interferon system is nonspecific in two ways: (1) various viral stimuli induce the same type of interferon, and (2) the same type of interferon inhibits various viruses. On the other hand, the interferon molecule is mostly specific in its action for the animal species in which it was induced: interferon produced by animals or humans generally stimulates antiviral activity only in cells of the same or closely related families (e.g., human interferon protects human and monkey cells, but not chicken cells). Interferon During Natural Infection The importance of interferon in the response to certain natural virus infections varies. Much depends on the effectiveness of the virus in stimulating interferon production and on its susceptibility to the antiviral action of interferon. Interferon protects solid tissues during virus infection; it is also disseminated through the bloodstream during viremia, thereby protecting distant organs against the spreading infection. Cells protected against viral replication may eliminate virus by degrading the virus genome (Fig. 49-7). FIGURE 49-7 Nonspecific elimination of viruses by cells. Medical Applications Interferons have been approved in several nations for treatment of viral infections (papillomas and condylomata, herpes simplex, and hepatitis B and C) and cancers (hairy cell leukemia, chronic myelogenous leukemia, non-Hodgkin's lymphomas, and Kaposi's sarcoma in AIDS patients). Clinical trials also have shown effectiveness against cryoglobulinemia and thrombocytosis and maintenance of remission in multiple myeloma. Interferon beta has received governmental approval for treatment of relapsing multiple sclerosis and interferon gamma for chronic granulomatous disease. Studies of effectiveness in other viral infections and cancers are continuing, as are studies with substances capable of inducing endogenous interferon. Conclusion In conclusion, individual defense mechanisms assume roles of varying importance during different viral infections; in most cases, the recovery process is probably carried out by the simultaneous or sequential action of several mechanisms. The presence of multiple defenses helps explain why suppression of one or several mechanisms does not entirely abrogate host resistance to viral infections; however, impairment of host defenses by medications used for symptomatic relief of viral infections may lead to more severe illness. For example, aspirin and corticosteroids reduce the nonspecific defenses. Therefore, the well-established principle of the ancient physician"primum non nocere" (primarily do not harm)is still valid.
