VARIATION BETWEEN POPULATIONS AND LOCAL ADAPTATION IN ACANTHOCEPHALAN‐INDUCED PARASITE MANIPULATION

Many trophically transmitted parasites manipulate their intermediate host phenotype, resulting in higher transmission to the final host. However, it is not known if manipulation is a fixed adaptation of the parasite or a dynamic process upon which selection still acts. In particular, local adaptation has never been tested in manipulating parasites. In this study, using experimental infections between six populations of the acanthocephalan parasite Pomphorhynchus laevis and its amphipod host Gammarus pulex, we investigated whether a manipulative parasite may be locally adapted to its host. We compared adaptation patterns for infectivity and manipulative ability. We first found a negative effect of all parasite infections on host survival. Both parasite and host origins influenced infection success. We found a tendency for higher infectivity in sympatric versus allopatric combinations, but detailed analyses revealed significant differences for two populations only. Conversely, no pattern of local adaptation was found for behavioral manipulation, but manipulation ability varied among parasite origins. This suggests that parasites may adapt their investment in behavioral manipulation according to some of their host's characteristics. In addition, all naturally infected host populations were less sensitive to parasite manipulation compared to a naive host population, suggesting that hosts may evolve a general resistance to manipulation.     

Trypanosoma cruzi: Antibody-induced mobility of surface antigens

Antibody induces mobility of surface antigens of live blood forms of Trypanosoma cruzi when these cells are incubated with human or animal antisera. Parasites of one strain (Y) showed aggregation of surface antigens to form an anterior or more frequently a posterior cap. The proportion of cap forming trypomastigotes increased with time and was dependent on temperature and amount of antiserum. Cap formation was inhibited by sodium azide or iodoacetamide. Crosslinking of surface antigens by antibodies causing agglutination of trypomastigotes decreased antigenic mobility and capping. Capping was not affected by treatment of the parasites with colchicine or cytochalasin B. Antigen mobility was not related to the presence of antibodies against parasite and host tissue cross-reacting antigens. Aggregation of surface membrane antigens was also observed in parasites which survive after immune lysis. Results of light and electron microscopic studies suggested that at least part of the aggregated antigens was eliminated from the trypomastigote's surface. Cap formation was strain and stage dependent. It was not observed when Y-strain epimastigotes were used and it occurred less frequently in CL than in Y-strain trypomastigotes.     

Local adaptation of a holoparasitic plant,Cuscuta europaea: variation among populations

Locally adapted parasites have higher infectivity and/or fitness on sympatric than on allopatric hosts. We tested local adaptation of a holoparasitic plant, Cuscuta europaea, to its host plant, Urtica dioica. We infected hosts from five sites with holoparasites from the same five sites and measured local adaptation in terms of infectivity and parasite performance (biomass) in a reciprocal cross‐infection experiment. The virulence of the parasite did not differ between sympatric and allopatric hosts. Overall, parasites had higher infectivity on sympatric hosts but infectivity and parasite performance varied among populations. Parasites from one of the populations showed local adaptation in terms of performance, whereas parasites from one of the populations had higher infectivity on allopatric hosts compared with sympatric hosts. This among‐population variation may be explained by random variation in parasite adaptation to host populations or by time‐lagged co‐evolutionary oscillations that lead to fluctuations in the level of local adaptation.     

Female biased sex-ratio in Schistosoma mansoni after exposure to an allopatric intermediate host strain of Biomphalaria glabrata

For parasites that require multiple hosts to complete their development, the interaction with the intermediate host may have an impact on parasite transmission and development in the definitive host. The human parasite Schistosoma mansoni needs two different hosts to complete its life cycle: the freshwater snail Biomphalaria glabrata (in South America) as intermediate host and a human or rodents as final host. To investigate the influence of the host environment on life history traits in the absence of selection, we performed experimental infections of two B. glabrata strains of different geographic origin with the same clonal population of S. mansoni. One B. glabrata strain is the sympatric host and the other one the allopatric host. We measured prevalence in the snail, the cercarial infectivity, sex-ratio, immunopathology in the final host and microsatellite frequencies of individual larvae in three successive generations.     

Trypanosoma cruzi specific antibody response in immunized C3H(He) mice during infection

C3H(He) mice previously immunized with live culture derived Corpus Christi strain T. cruzi are significantly protected (up to 100% survival) against challenge by Brazil strain blood trypanosomes. The antibody response, directed against the Brazil strain or the Corpus Christi strain, in these mice has been observed by comparing sera from mice immunized only, infected only, or immunized and infected. The anti- T. cruzi titers determined by both direct agglutination (DA) and indirect fluorescence (IFA) were routinely found to be highest for immunized and infected mice with immunized mice and infected mice following in decreasing order. The use of mercaptoethanol treatment of sera (DA) and isotope specific second antibody (IFA) showed that IgG is the major parasite specific immunoglobulin response through infection. Evidence of cross-reacting antigens on the two parasite strains was found. By both DA and IFA, 11 of 18 anti-Brazil strain monoclonal antibodies were found to react (IFA titers of 320 or greater) with both parasite strains. No evidence of localization of cross-reacting antigens (using mouse antisera) or antigenic determinants (using monoclonal antibodies) was found in that uniform fluorescence over the parasite was observed in all IFA tests.     

Haemonchus contortus and Trichostrongylus colubriformis did not adapt to long-term exposure to sheep that were genetically resistant or susceptible to nematode infections

We tested the hypothesis that Haemonchus contortus and Trichostrongylus colubriformis would adapt to long-term exposure to sheep that were either genetically resistant or susceptible to H. contortus. Sheep genotypes were from lines with 10 years prior selection for low (resistant, R) or high (susceptible, S) faecal worm egg count (WEC) following H. contortus infection. Long-term exposure of H. contortus and T.colubriformis to R or S genotypes was achieved using serial passage for up to 30 nematode generations. Thus, we generated four nematode strains; one strain of each species solely exposed to R sheep and one strain of each species solely exposed to S sheep. Considerable host genotype differences in mean WEC during serial passage confirmed adequate nematode selection pressure for both H. contortus (R 4900 eggs per gram (epg), S 19,900 epg) and T. colubriformis (R 5300 epg, S 13,500 epg). Adaptation of nematode strain to host genotype was tested using seven cross-classified tests for H. contortus, and two cross-classified and one outbred genotype test for T. colubriformis. In the cross-classified design, where each strain infects groups of R, S or randomly bred control sheep, parasite adaptation would be indicated by a significant host genotype by nematode strain interaction for traits indicating parasite reproductive success; specifically WEC and, for H. contortus strains, packed cell volume. We found no significant evidence of parasite adaptation to host genotype (P > 0.05) for either the H. contortus or T. colubriformis strains. Therefore, we argue that nematodes will not adapt quickly to sheep bred for nematode resistance, where selection is based on low WEC, although selecting sheep using a subset of immune functions may increase adaptation risk. Our results support the hypothesis that nematode resistance is determined by many genes each with relatively small effect. In conclusion, selection of sheep for nematode resistance using WEC should be sustainable in the medium to long-term.     

When parasites disagree: Evidence for parasite‐induced sabotage of host manipulation

Host manipulation is a common parasite strategy to alter host behavior in a manner to enhance parasite fitness usually by increasing the parasite's transmission to the next host. In nature, hosts often harbor multiple parasites with agreeing or conflicting interests over host manipulation. Natural selection might drive such parasites to cooperation, compromise, or sabotage. Sabotage would occur if one parasite suppresses the manipulation of another. Experimental studies on the effect of multi‐parasite interactions on host manipulation are scarce, clear experimental evidence for sabotage is elusive. We tested the effect of multiple infections on host manipulation using laboratory‐bred copepods experimentally infected with the trophically transmitted tapeworm Schistocephalus solidus. This parasite is known to manipulate its host depending on its own developmental stage. Coinfecting parasites with the same aim enhance each other's manipulation but only after reaching infectivity. If the coinfecting parasites disagree over host manipulation, the infective parasite wins this conflict: the noninfective one has no effect. The winning (i.e., infective) parasite suppresses the manipulation of its noninfective competitor. This presents conclusive experimental evidence for both cooperation in and sabotage of host manipulation and hence a proof of principal that one parasite can alter and even neutralize manipulation by another.     

Plasmodium gallinaceum: Selective immunosuppression by cyclophosphamide in preerythrocytic malaria

When chicks are injected with the immunosuppressant cyclophosphamide (Cy) on days 1 and 2 after hatching and then injected with sporozoites from infected mosquitoes on day 4, the normal susceptibility of only one host cell type to the sequential invasive stages of the preerythrocytic forms of avian malaria (Plasmodium gallinaceum) is increased. Thus, only endothelial cells lining capillaries showed an increased susceptibility to invasion or development of second generation preerythrocytic parasites. There is some indication that such an increased susceptibility also occurs after X-irradiation of chicks but not after treatment with endotoxin. Neither the infectivity or development of sporozoites within macrophages nor the invasion of erythrocytes by parasites released from the tissues was apparently affected by Cy-treatment of chicks. Neither suppression of natural anti-sporozoite humoral antibody nor the possibility of suppression of acquired immunity to preerythrocytic stages of the parasite was shown to be responsible for the observed increased parasitemia of Cy-treated chicks. The apparent specificity of the immunosuppression of a natural immunity was ascertained by inoculation of a selected preerythrocytic stage into Cy-treated and control birds, and, in addition, by observing the increased tissue parasite levels of spleens and brains of similarly treated birds after sporozoite inoculation when compared to controls.     

Specialization and local adaptation of a fungal parasite on two host plant species as revealed by two fitness traits

We investigate the geographic pattern of adaptation of a fungal parasite, Colletotrichum lindemuthianum, on two host species, Phaseolus vulgaris and P. coccineus for two parasite fitness traits: infectivity (ability to attack a host individual) and aggressivity (degree of sporulation and leaf surface damage). Using a cross-inoculation experiment, we show specialization of the fungus on its host species of origin for both traits even when fungi, which originated from hosts growing in sympatry, were tested on sympatric host populations. Within the two host species, we compared infectivity and aggressivity on local versus allopatric plant-fungus combinations. We found evidence for local adaptation for the two traits on P. vulgaris but not on P. coccineus. There was no significant correlation between the degrees of local adaptation for infectivity and aggressivity, indicating that the genetic basis and the effect of selection may differ between these two traits. For the two fitness traits, a positive correlation between the degree of specialization and the degree of local adaptation was found, suggesting that specialization can be reinforced by local adaptation.     

Plasmodium berghei: Osmotic fragility of malaria parasites and mouse host erythrocytes

The osmotic properties of intraerythrocytic and ultrasonically liberated malaria parasites (Plasmodium berghei) were analyzed and compared with those of mouse host erythrocytes utilizing a multiple tube fragility test. Cells were incubated in phosphate buffered saline solutions of varying osmolalities ranging from 20–4000 mOsm. Changes in cell ultrastructure and parasite infectivity were used as indicators of osmotic damage. Intraerythrocytic and host cell-free plasmodia showed similar patterns of cell alteration and changes in infectivity following osmotic stress. The various developmental forms within each of the preparations responded somewhat differently to hypo-osmotic stress, however. The majority of merozoites seemed to be more sensitive than many trophozoites, schizonts, and segmenters. Small trophozoites were, on the average, more resistant than other developmental forms. Incubation of parasite populations in hypotonic salt solutions with osmolalities slightly greater than the infectivity threshold of 100 mOsm lysed the majority of the merozoites, whereas many small trophozoites were still intact. While normal erythrocytes were more resistant to hypo-osmotic stress than were either intracellular or free parasites, the majority of parasitized erythrocytes was less resistant than normal erythrocytes. The predominant alteration induced by hyperosmotic stress appears in the parasite's nuclear region with myelination of the nuclear membranes and chromatin clumping. The infectivity threshold in the hypertonic range was found to be approximately 2500 mOsm. Results indicate that these obligate intracellular parasites have a wide range of osmotic sensitivities and that they are capable of existing for short periods in various osmotic environments ranging from 100–2500 mOsm without complete loss of infectivity. This suggests that these parasites have osmotic regulatory capabilities at least comparable to those of host cells.     

Genetic structure and host–parasite co‐divergence: evidence for trait‐specific local adaptation

Host–parasite co‐evolution can lead to genetic differentiation among isolated host–parasite populations and local adaptation between parasites and their hosts. However, tests of local adaptation rarely consider multiple fitness‐related traits although focus on a single component of fitness can be misleading. Here, we concomitantly examined genetic structure and co‐divergence patterns of the trematode Coitocaecum parvum and its crustacean host Paracalliope fluviatilis among isolated populations using the mitochondrial cytochrome oxidase I gene (COI). We then performed experimental cross‐infections between two genetically divergent host–parasite populations. Both hosts and parasites displayed genetic differentiation among populations, although genetic structure was less pronounced in the parasite. Data also supported a co‐divergence scenario between C. parvum and P. fluviatilis potentially related to local co‐adaptation. Results from cross‐infections indicated that some parasite lineages seemed to be locally adapted to their sympatric (home) hosts in which they achieved higher infection and survival rates than in allopatric (away) amphipods. However, local, intrinsic host and parasite characteristics (host behavioural or immunological resistance to infections, parasite infectivity or growth rate) also influenced patterns of host–parasite interactions. For example, overall host vulnerability to C. parvum varied between populations, regardless of parasite origin (local vs. foreign), potentially swamping apparent local co‐adaptation effects. Furthermore, local adaptation effects seemed trait specific; different components of parasite fitness (infection and survival rates, growth) responded differently to cross‐infections. Overall, data show that genetic differentiation is not inevitably coupled with local adaptation, and that the latter must be interpreted with caution in a multi‐trait context.     

Population diversity and multiplicity of infection in Theileria annulata

The tick-borne apicomplexan parasite Theileria annulata is endemic in many sub-tropical countries and causes the bovine disease tropical theileriosis. Although the parasite is known to be highly diverse, detailed information is lacking on the genetic structure of natural populations and levels of multiplicity of infection in the cattle host. With the widespread deployment of live attenuated vaccines and the emergence of drug-resistant parasites in the field, it is vital to appreciate the factors which shape genetic diversity of the parasite both within individual hosts and in the wider population. This study addresses these issues and represents an extensive genetic analysis of T. annulata populations in two endemic countries utilising a high-throughput adaptation of a micro- and mini-satellite genotyping system. Parasite material was collected from infected cattle in defined regions of Turkey and Tunisia to allow a variety of analyses to be conducted. All animals (n = 305) were found to harbour multiple parasite genotypes and only two isolates shared an identical predominant multi-locus profile. A modelling approach was used to demonstrate that host age, location and vaccination status play a measurable role in determining multiplicity of infection in an individual animal. Age was shown to positively correlate with multiplicity of infection and while positive vaccination status exerted a similar effect, it was shown to be due not simply to the presence of the immunising genotype. Importantly, no direct evidence was found for the immunising genotype spreading or recombining within the local parasite community. Genetic analysis confirmed the tentative conclusion of a previous study that the parasite population appears to be, in general, panmictic. Nevertheless, evidence supporting linkage disequilibrium and a departure from panmixia was uncovered in some localities and a number of explanations for these findings are advanced.     

Male hosts are responsible for the transmission of a trophically transmitted parasite, Pterygodermatites peromysci, to the intermediate host in the absence of sex-biased infection

Field studies have identified that male-biased infection can lead to increased rates of transmission, so we examined the relative importance of host sex on the transmission of a trophically transmitted parasite (Pterygodermatites peromysci) where there is no sex-biased infection. We experimentally reduced infection levels in either male or female white-footed mice (Peromyscus leucopus) on independent trapping grids with an anthelmintic and recorded subsequent infection levels in the intermediate host, the camel cricket (Ceuthophilus pallidipes). We found that anthelmintic treatment significantly reduced the prevalence of infection among crickets in both treatment groups compared with the control, and at a rate proportional to the number of mice de-wormed, indicating prevalence was not affected by the sex of the shedding definitive host. In contrast, parasite abundance in crickets was higher on the grids where females were treated compared with the grids where males were treated. These findings indicate that male hosts contribute disproportionately more infective stages to the environment and may therefore be responsible for the majority of parasite transmission even when there is no discernable sex-biased infection. We also investigated whether variation in nematode length between male and female hosts could account for this male-biased infectivity, but found no evidence to support that hypothesis.     

Expression of genes in gastrointestinal and lymphatic tissues during parasite infection in sheep genetically resistant or susceptible to Trichostrongylus colubriformis and Haemonchus contortus

Resistance to an acute gastrointestinal nematode (GIN) infection is dependent on the ability of the host to recognise the parasite and mount a protective Th2 response. It is hypothesised that lambs which are genetically susceptible to GIN will differentially up-regulate Th1-type genes and therefore remain susceptible to chronic parasitism compared with genetically resistant lambs which will differentially up-regulate Th2-type genes and clear the parasite infection. Two selection flocks, in which lines of Merino sheep produced lambs genetically resistant or susceptible to GIN, were acutely challenged once or thrice with either Haemonchus contortus or Trichostrongylus colubriformis. Faecal-egg counts (FECs), and plasma and tissue anti-parasite (H. contortus or T. colubriformis) antibody isotype responses showed that resistant animals challenged three times with T. colubriformis established a protective Th2 response (negligible FEC, IgG1 and IgE) whereas susceptible animals required multiple challenges to establish a significant IgG1 response despite FECs remaining high. Trichostrongylus colubriformis elicited a more pronounced host response than H. contortus. RNA extracted from tissues at the site of each parasite infection and associated lymph nodes were interrogated by microarray and quantitative PCR analyses to correlate host gene expression to FECs and antibody responses. The IFN-γ inducible gene cxcl10 was up-regulated in the susceptible line of the Trichostrongylus selection flock sheep after a tertiary challenge with the parasites H. contortus and T. colubriformis. However, a uniform pattern of genes was not up-regulated in resistant animals from both selection flocks during both parasite infections, suggesting that the mode of host resistance to these parasites is different, although some similarities in host susceptibility were apparent.     

Variation and covariation in infectivity,virulence and immunodepression in the host–parasite association Gammarus pulex–Pomphorhynchus laevis

Parasites often manipulate host immunity for their own benefit, either by exacerbating or suppressing the immune response and this may directly affect the expression of parasite virulence. However, genetic variation in immunodepression, which is a prerequisite to its evolution, and the relationship between immunodepression and virulence, have rarely been studied. Here, we investigated the variation among sibships of the acanthocephalan parasite, Pomphorhynchus laevis, in infecting and in immunodepressing its amphipod host, Gammarus pulex. We also assessed the covariation between infectivity, parasite-induced immune depression and host mortality (parasite virulence). We found that infectivity, the intensity of immunodepression and virulence were variable among parasite sibships. Infectivity and the level of immunodepression were not correlated across parasite sibships. Whereas infectivity was unrelated to host mortality, we found that gammarids that were exposed to the parasite sibships that immunodepressed their hosts the most survived better. This positive covariation between host survival and immunodepression suggests that gammarids exposed to the less immunodepressive parasites could suffer from damage imposed by a higher activity of the phenoloxidase.     

In vivo and in vitro studies of the effects of immune rat serum on Fasciola hepatica

Significant protection against infection with 10 or 30 metacercariae of Fasciola hepatica was conferred on naive rats by the passive transfer of serum derived from rats which had been exposed to primary and challenge infections with 5 or 10 and 30 or 20 metacercariae respectively. Immune serum did not have a pronounced effect on the mortality of metacercariae in vitro. However, its presence was associated with the formation of a precipitate on the tegument of each metacercaria and in the culture medium. The precipitate contained rat antibody and other components, presumably parasite antigens, which elicited the formation of antibody when the precipitate was injected into rats. Viability of metacercariae cultured in immune and normal sera as well as freshly excysted specimens was tested in rats by intraperitoneal infection. Metacercariae cultured in immune serum did not develop. By comparison with the viability of freshly excysted metacercariae, that of some metacercariae cultured in normal serum was impaired; this was attributed to inadequacies in the culture technique. A relationship between precipitate formation in vitro and impaired viability of metacercariae in vivo has yet to be established.     

Antigenic Analysis of Virulent and Avirulent Strains of Trichomonas gallinae by Gel Diffusion Methods*

SYNOPSIS. Antigenic constitution of 5 Trichomonas gallinae strains and substrains was analyzed by gel diffusion technics. Fresh isolates of the very virulent JB and of an avirulent SG strain as well as avirulent substrains JBC and SGC, derived from JB and SG respectively by prolonged in vitro cultivation, were used in the experiments. An originally avirulent AG strain that was attenuated still further and lost its infectivity for pigeons during many years of serial transfers in nonliving media also was analyzed. Two major groups of antigens, A and B, were differentiated on the basis of precipitin line patterns formed in gel diffusion reactions involving the 5 strains and substrains and antisera prepared in rabbits against each of these trichomonad stocks. Group A was subdivided further into subgroups [A] and (A). JB, JBC, AG, and SGC trichomonads appeared to share all or nearly all antigens of both these subgroups, but AG strain contained some unique [A] and (A) antigens in addition to those which it had in common with the remaining 4 strains and substrains. Group B antigens were divided into 5 subgroups, B₁ to B₅. The complete B₁ antigenic complex was found in JB and JBC trichomonads and part of this complex was present also in SG strain and SGC substrain. In all instances, subgroup B₁ antigens stimulated production of specific antibodies in rabbits and combined with these antibodies present in immune sera. The complete B₂ antigenic complex was found only in JBC substrain. Some subgroup B₂ antigens were present also in JB trichomonads. Very few of these, however, were capable of stimulating antibody production in rabbits. The more numerous B₂ elements of JB strain that did not stimulate immunologic responses in rabbits, might be in the form of incomplete hapten-like antigens. All subgroup B₂ antigens found in JB strain represented only a portion of the B₂ complex associated with JBC substrain. Subgroup B₂ was characteristic of SG and SGC trichomonads, the latter substrain differing from the parental SG strain in the levels of both B₂ and B₁ antigens; these differences, however, were purely quantitative. JB strain reacted with some of subgroup B₃ antibodies present in SG and SGC antisera, but failed to stimulate antibody formation against any of these antigens in rabbits. The B₃ elements of JB trichomonads might be incomplete antigens. AG strain was characterized by having B₄ and B₅ antigenic complexes. The very small part of subgroup B₄, represented by a weak precipitin line in reactions between JB strain or JBC substrain and anti-AG serum, suggested the presence of some incomplete B₄ antigens in these trichomonads. Irrespective of whether freshly isolated avirulent strains or substrains attenuated by prolonged in vitro cultivation are examined by gel diffusion, such organisms are found richer in subgroup B antigens than the fully virulent JB trichomonads. All the results suggest that there may be a direct relationship between antigenic constitution and virulence of T. gallinae strains.     

Human immune responses against sexual stages of malaria parasites: considerations for malaria vaccines

Studies on the natural immune responses to the sexual stages of malaria parasites have been reviewed in the context of human malaria transmission-blocking vaccines. Antibodies against the sexual stages of the malaria parasite, gametocytes and gametes, are readily evoked by natural malaria infections. These antibodies that suppress infectivity at high concentrations can, at low concentrations, enhance the development of the parasite in the mosquito; however, because enhancing antibodies are prevalent during natural malaria infections, it is likely that a vaccine would rapidly boost these antibodies to blocking levels. The immunogenicity of sexual stage antigens appears to be constrained in the human host, probably due to T epitope polymorphism and MHC restriction in humans. These constraints apply mainly to those antigens that are sensitive targets of host immunity such as the gamete surface antigens and not to internal gamete antigens, indicating that antigenic polymorphism may have evolved in response to immune selection pressure. Evidence for immunosuppression of the host by exposure to endemic malaria is presented and its consequences on vaccine development are discussed.     

Identification of a human immunodominant B-cell epitope within the GRA1 antigen of Toxoplasma gondii by phage display of cDNA libraries

Excreted secreted antigens of the protozoan parasite Toxoplasma gondii play a key role in stimulating the host immune system during acute and chronic infection. With the aim of identifying the immunodominant epitopes of T. gondii antigens involved in the human B-cell response against the parasite, we employed a novel immunological approach. A library of cDNA fragments from T. gondii tachyzoites was displayed as fusion proteins to the amino-terminus of lambda bacteriophage capsid protein D. The lambdaD-tachyzoite library was then affinity-selected by using a panel of sera of pregnant women, all infected with the parasite. Some of the clones identified through this procedure matched the sequence of the dense granule GRA1 protein (p24), allowing us to identify its antigenic regions. In particular, the analysis of human antibody response against the recombinant GRA1 antigen fragments revealed the existence of an immunodominant epitope (epi-24 peptide).