Host–parasite interactions and vectors in the barn swallow in relation to climate change

Recent climate change has affected the phenology of numerous species, and such differential changes may affect host–parasite interactions. Using information on vectors (louseflies, mosquitoes, blackflies) and parasites (tropical fowl mite Ornithonyssus bursa, the lousefly Ornithomyia avicularia, a chewing louse Brueelia sp., two species of feather mites Trouessartia crucifera and Trouessartia appendiculata, and two species of blood parasites Leucozytozoon whitworthi and Haemoproteus prognei) of the barn swallow Hirundo rustica collected during 1971–2008, I analyzed temporal changes in emergence and abundance, relationships with climatic conditions, and changes in the fitness impact of parasites on their hosts. Temperature and rainfall during the summer breeding season of the host increased during the study. The intensity of infestation by mites decreased, but increased for the lousefly during 1982–2008. The prevalence of two species of blood parasites increased during 1988–2008. The timing of first mass emergence of mosquitoes and blackflies advanced. These temporal changes in phenology and abundance of parasites and vectors could be linked to changes in temperature, but less so to changes in precipitation. Parasites had fitness consequences for hosts because intensity of the mite and the chewing louse was significantly associated with delayed breeding of the host, while a greater abundance of feather mites was associated with earlier breeding. Reproductive success of the host decreased with increasing abundance of the chewing louse. The temporal decrease in mite abundance was associated with advanced breeding of the host, while the increase in abundance of the lousefly was associated with earlier breeding. Virulence by the tropical fowl mite decreased with increasing temperature, independent of confounding factors. These findings suggest that climate change affects parasite species differently, hence altering the composition of the parasite community, and that climate change causes changes in the virulence of parasites. Because the changing phenology of different species of parasites had both positive and negative effects on their hosts, and because the abundance of some parasites increased, while that of other decreased, there was no consistent temporal change in host fitness during 1971–2008.     

Dynamics of Hen Flea Ceratophyllus gallinae Subpopulations in Blue Tit Nests

The hen flea is a common parasite in bird nests, in particular, in tit species, and imposes considerable fitness costs for the host. These costs are expected to lead to selection for increased host defense, which in turn should select for better-adapted parasites. Our understanding of the coevolution of this host–parasite system is currently limited by the insufficient knowledge of both the timing of flea generations and their reproductive behavior within the nesting period of their hosts. In the present study we (1) followed the demography of experimental flea subpopulations during the host's breeding cycle, (2) assessed the importance of time–temperature effects in the nest by recording temperatures within the nest material, and (3) investigated the influence of variation in host timing and duration of the breeding period on flea development. We found the following. (1) Fleas completed either one or two generations within the birds' nesting cycle, leading to two well-defined periods of cocoon formation. (2) Within-nest temperatures during the warm period of the host breeding cycle—i.e., the incubation and nestling periods—depended on both outdoor temperatures and heat production from the breeding birds. Day-degree availability, a measure of physiological time, during the host incubation was significantly explained by the duration of incubation period and its timing in the season. Similarly, day-degrees during the warmer nestling period were significantly explained by its duration and its timing in the season. (3) The number of flea larvae found in the nests correlated with the host's timing and duration of the warm period available for their development; this was not the case, however, for the number of adult fleas. These results underline the importance of time–temperature effects as determinants of flea demography within the nests. The life-cycle and time–temperature effects are discussed in the light of potential host selection on parasite behavior and life histories.     

Reaction norms for age and size at maturity in response to temperature: a test of the compound interest hypothesis

In ectotherms, temperature induces similar developmental and evolutionary responses in body size, with larger individuals occurring or evolving in low temperature environments. Based on the occasional occurrence of opposite size clines, showing a decline in body size with increasing latitude, an interaction between generation time and growing season length was suggested to account for the patterns found. Accordingly, multivoltine species with short generation times should gain high compound interest benefits from reproducing early at high temperatures, indicating potential for extra generations, even at the expense of being smaller. This should not apply for obligatorily monovoltine populations. We explicitly test the prediction that monovoltine populations (no compound interest) should be selected for large body size to maximise adult fitness, and therefore size at maturity should respond only weakly to temperature. In two monovoltine populations (an Alpine and a Western German one) of the butterfly Lycaena hippothoe, increasing temperatures had no significant effect on pupal weight and caused a slight decrease in adult weight only. In contrast, two closely related, yet potentially multivoltine Lycaena populations showed a greater weight loss at increasing temperature (in protandrous males, but not in females) and smaller adult sizes throughout. Thus, the results do support our predictions indicating that the compound interest hypothesis may yield causal explanations for the relationship between temperature and insect size at maturity. At all temperatures, the alpine population had higher growth rates and concomitantly shorter development times (not accompanied by a reduction in size) than the other, presumably indicating local adaptations to different climates.     

Metazoan parasite communities of wild Leporinus friderici (Characiformes: Anostomidae) from Amazon River system in Brazil

This study compared the structure of metazoan parasite communities in two populations of Leporinus friderici from two rivers of the Amazon River system in Brazil. Jainus leporini, Urocleidoides paradoxus, Urocleidoides sp., Tereancistrum parvus, Tereancistrum sp., Clinostomum marginatum, Procamallanus (Spirocamallanus) inopinatus, Contracaecum sp., Octospiniferoides incognita and Ergasilus sp. were found in both hosts. There were differences in species richness of parasites, Shannon index and the evenness between both host populations, because the parasite community showed a similarity of only 33%. Parasites of both host populations had an aggregated dispersion. Host size also contributes to the differences between the populations of hosts investigated, and the feeding habit contributes to the occurrence of endoparasites in L. friderici, an intermediate host for these parasites. The existence of variation in infracommunity and community of parasites for the same host species from different localities indicates the presence of an uneven distribution in terms of species and density of parasites, which are intermediate hosts, and some of them constitute food items for L. friderici in the localities surveyed.     

Effectively vertical transmission of a Drosophila‐parasitic nematode: mechanism and consequences

1. Long‐term control of insects by parasites is possible only if the parasite populations persist. Because parasite transmission rate depends on host density, parasite populations may go extinct during periods of low host density. Vertical transmission of parasites, however, is independent of host density and may therefore provide a demographic bridge through times when their insect hosts are rare. 2. The nematode Howardula aoronymphium, which parasitises mycophagous species of Drosophila, can experience both horizontal and effectively vertical transmission, relative rates of which depend, in theory at least, on the density of hosts at breeding sites. 3. A nine‐generation experiment was carried out in which nematodes were transmitted either exclusively vertically or primarily horizontally. This experiment revealed that these parasites can persist and exhibit positive population growth even when there is only vertical transmission. 4. Assays at the end of the experiment revealed that the vertically transmitted nematodes had suffered no inbreeding depression and that they were similar to the horizontally transmitted nematodes in terms of virulence, infectivity, within‐host growth rate, and fecundity. Thus, vertical transmission of H. aoronymphium did not appear to compromise the ability of these parasites to control Drosophila populations.     

Consequences of divergent temperature optima in a host–parasite system

It was suggested that parasite infections become more severe with rising temperature, as expected during global warming. In ectothermic systems, the growth of a parasite and therefore its reproductive capacity is expected to increase with temperature. However, the outcome of the interaction depends on the temperature optima of both host and parasite. Here we used experimental infections of three‐spined stickleback fish Gasterosteus aculeatus with its specific tapeworm parasite Schistocephalus solidus to investigate in detail the temperature optima for both host and parasite. We analyzed the fitness consequences thereof, focusing on growth and immunity of the host, and growth and offspring production of the parasite as fitness correlates. We checked for potential differences among populations, using the offspring of hosts and parasites derived from four study sites in Iceland, Germany and Spain that differ in average annual temperature ranging between 4.8°C and 18.4°C. We found differences in temperature optima of host and parasites that were quite consistent across the populations: while sticklebacks grew faster and had higher immune activity at low temperatures, the parasites did not even grow fast enough to reach sexual maturity in these conditions. By contrast, with increasing temperatures, parasite growth, egg production and offspring hatching increased strongly while host immunity and growth were impaired. Our results show that divergent temperature optima of hosts and parasites can have drastic fitness consequences and support the expectation that some parasites will benefit from global warming.     

Prevalence of malaria and related haemosporidian parasites in two shorebird species with different winter habitat distribution

Parasites can have strong effects on host life-history and behaviour, and result in changes in host population dynamics and community structure. We applied a PCR-based technique and examined prevalence of malaria and related haemosporidian parasites in two arctic breeding shorebird species: the Semipalmated Sandpiper (Calidris pusilla) and the Pectoral Sandpiper (C. melanotos). During the non-breeding season, Semipalmated Sandpipers inhabit coastal marine habitats, whereas Pectoral Sandpipers are found in inland areas. In accordance with the hypothesis that the risk of parasite infection is higher in a species wintering in freshwater areas, we found Plasmodium sp. infection during the breeding season only in Pectoral Sandpipers, whereas Semipalmated Sandpipers were parasite free. However, even in Pectoral Sandpipers sampled in the arctic, prevalence of malaria parasites was very low (<3% of individuals, n = 114). Overall, three different Plasmodium sp. lineages were found, one of which has never been described before.     

Temperature and multiple parasites combine to alter host community structure

Predicting the effects of climate change requires understanding complex interactions among multiple abiotic and biotic factors. By influencing key interactions among host species, parasites can affect community and ecosystem structuring. Yet, our understanding of how multiple parasites and abiotic factors interact to alter ecosystem structure remains limited. To empirically test the role of temperature variation and parasites in shaping communities, we used a multigenerational mesocosm experiment composed of four sympatric freshwater crustacean species (isopods and amphipods) that share up to four parasite species. Mesocosms were assigned to one of four different treatments with contrasting seasonal temperatures (normal and elevated) and parasite exposure levels (continuous and arrested (presence or absence of parasite larvae in mesocosm)). We found that parasite exposure and water temperature had interactive effects on the host community. Continuous exposure to parasites altered the community structure and differences in water temperature altered species abundance. The abundance of the amphipod Paracalliope fluviatilis decreased substantially when experiencing continuous parasite exposure and elevated water temperatures. Elevated temperatures also led to parasite-induced mortality in another amphipod host, Paracorophium excavatum. Contrastingly, isopod hosts were affected much less, suggesting increasing temperatures in conjunction with higher parasite exposure might increase their relative abundance in the community. Changes in invertebrate host populations have implications for other species such as fish and birds that consume crustaceans as well as having impacts on ecosystem processes, such as aquatic primary production and nutrient cycling. In light of climate change predictions, parasite exposure and rise in average temperatures may have substantial impacts on communities and ecosystems, altering ecosystem structure and dynamics.     

Parasitization of the cottony-cushion scale in relation to host size

Measurements of body length of cottony-cushion scales,Icerya purchasi Maskell, are presented. Although length increased markedly with developmental stage, the length distributions of successive stages were found to overlap, making length an imperfect indicator of stage andvice versa. The likelihood of parasitism by the fly,Cryptochaetum iceryae (Williston), was found to increase with increasing scale size when scales of different sizes were concurrently made available to the parasites under field conditions. Also, parasite loads (no. of parasites per parasitized host) were found to increase with host size. The size ofC. iceryae pupae was found to depend on the developmental stage of the scale host in which pupation took place — the more developed (larger) the host, the larger the pupa. This result suggests that parasite growth is food limited in the smaller hosts, and that therefore its apparent preference for larger hosts is to the parasite's advantage.      

Patterns of parasitism in monarch butterflies during the breeding season in eastern North America

1. Migratory behaviour can result in reduced prevalence of pathogens in host populations. Two hypotheses have been proposed to explain this relationship: (i) ‘migratory escape’, where migrants benefit from escaping pathogen accumulation in contaminated environments; and (ii) ‘migratory culling’, where the selective removal of infected individuals occurs during migration. 2. In the host–parasite system between the monarch butterfly (Danaus plexippus Linn.) and its obligate protozoan parasite Ophryocystis elektroscirrha (OE), there is evidence to support both hypotheses, particularly during the monarchs' autumn migration. However, these processes can operate simultaneously and could vary throughout the monarchs' annual migratory cycle. Assessing the relative strength for each hypothesis has not previously been done. 3. To evaluate both hypotheses, parasite infection prevalence was examined in monarchs sampled in eastern North America during April–September, and stable isotopes (δ²H, δ¹³C) were used to estimate natal origin and infer migration distance. There was stronger support for the migratory escape hypothesis, wherein infection prevalence increased over the breeding season and was higher at southern latitudes, where the breeding season tends to be longer compared with northern latitudes. Little support was found for the migratory culling hypothesis, as infection prevalence was similar whether monarchs travelled shorter or longer distances. 4. These results suggest that migration allows individuals to escape parasites not only during the autumn, as shown in previous work, but during the monarchs' spring and summer movements when they recolonise the breeding range. These results imply a potential fitness advantage to monarchs that migrate further north to exploit parasite‐free habitats.     

Intraseasonal variation in immune defence,body mass and hematocrit in adult house martins Delichon urbica

The intensity of parasite infections often increases during the reproductive season of the host as a result of parasite reproduction, increased parasite transmission and increased host susceptibility. We report within‐individual variation in immune parameters, hematocrit and body mass in adult house martins Delichon urbica rearing nestlings in nests experimentally infested with house martin bugs Oeciacus hirundinis and birds rearing nestlings in initially parasite‐free nests. From first to second broods body mass and hematocrit of breeding adult house martins decreased. In contrast leucocytes and immunoglobulins became more abundant. When their nests were infested with ectoparasites adults lost more weight compared with birds raising nestlings in nests treated with pyrethrin, whereas the decrease in hematocrit was more pronounced during infection with blood parasites. Neither experimental infestation with house martin bugs nor blood parasites had a significant effect on the amount of immune defences.     

Relative helminth size in crustacean hosts: in vivo determination, and effects of host gender and within-host competition in a copepod infected by a cestode

Crustaceans are important hosts for a number of helminth parasites, and they are increasingly used as models for studying the physiology, ecology and evolution of parasite-host interactions. In ecological studies, this interaction is commonly described only in terms of prevalence and number of larvae per infected host. However, the volume of helminth parasites can vary greatly, and this variation can potentially give important insights into the nature of a parasite-host relationship. It may influence and be influenced, for example, by within-host competition, host size, growth, and life history. Here we present a simple method that allows rapid approximation of the absolute and relative volumes of cestode larvae within copepod hosts of various developmental stages (nauplii, copepodites and adults). The measurements are taken in vivo without much disturbance of the animals, i.e. the technique allows study of growth and development of the parasites in relation to that of their hosts. The principles of this technique can be adopted to other helminth parasites and other crustacean hosts. Using this method in the copepod Macrocyclops albidus infected with the cestode Schistocephalus solidus, we found that the relative parasite size (= `parasite index') ranged from 0.5% to 6.5% of host size 14 days after infection. It was greater in male than in female hosts. With increasing number of parasites per host, the total parasite volume increased while the mean volume of the individual parasites decreased. The magnitude of the observed parasite indices, the large variation that was found within a sample of 46 infected adult copepods, and the observed correlates suggest that this new index can indeed be an important measure of parasite success and its pathogenecity.     

No evidence for long‐term effects of reproductive effort on parasite prevalence in great tits Parus major

Allocation of resources between the life history traits reproduction and parasite defence are expected because both are energetically costly. Experimental evidence for such allocation has been found in short‐term effects of reproduction on parasite prevalence or immune function. However, there is increasing evidence for long‐term negative effects of reproductive effort on individuals. This study investigates whether long‐term effects of reproductive effort on parasite prevalence exist. Brood sizes of great tits Parus major were experimentally altered in one breeding season and in the subsequent breeding season the prevalence of three parasites types (blood parasites, ticks and fleas) on the surviving parents were investigated. We detected no long‐term effects of brood size manipulation on the prevalence of parasites in the next year and therefore provide no evidence for inter‐seasonal effects of reproductive effort on parasite prevalence. The post hoc level of statistical power was reasonable for effects on blood parasite and flea prevalence, but low for effects on tick prevalence.     

Crowding and disease: effects of host density on response to infection in a butterfly–parasite interaction

Abstract. 1. Hosts experiencing frequent variation in density are thought to benefit from allocating more resources to parasite defence when density is high (‘density‐dependent prophylaxis’). However, high density conditions can increase intra‐specific competition and induce physiological stress, hence increasing host susceptibility to infection (‘crowding‐stress hypothesis’). 2. We studied monarch butterflies (Danaus plexippus) and quantified the effects of larval rearing density on susceptibility to the protozoan parasite Ophryocystis elektroscirrha. Larvae were inoculated with parasite spores and reared at three density treatments: low, moderate, and high. We examined the effects of larval density on parasite loads, host survival, development rates, body size, and wing melanism. 3. Results showed an increase in infection probability with greater larval density. Monarchs in the moderate and high density treatments also suffered the greatest negative effects of parasite infection on body size, development rate, and adult longevity. 4. We observed greater body sizes and shorter development times for monarchs reared at moderate densities, and this was true for both unparasitised and parasite‐treated monarchs. We hypothesise that this effect could result from greater larval feeding rates at moderate densities, combined with greater physiological stress at the highest densities. 5. Although monarch larvae are assumed to occur at very low densities in the wild, an analysis of continent‐wide monarch larval abundance data showed that larval densities can reach high levels in year‐round resident populations and during the late phase of the breeding season. Treatment levels used in our experiment captured ecologically‐relevant variation in larval density observed in the wild.     

Development of the red algal parasite Vertebrata aterrimophila sp. nov. (Rhodomelaceae,Ceramiales) from New Zealand

Parasitic red algae grow only on other red algae and have over 120 described species. Developmental studies in red algal parasites are few, although they have shown that secondary pit connections formed between parasite and host and proposed that this was an important process in successful parasitism. Furthermore, it was recorded that the transfer of parasite nuclei by these secondary pit connections led to different host cell effects. We used developmental studies to reconstruct early stages and any host cell effects of a parasite on Vertebrata aterrima. A mitochondrial marker (cox1) and morphological observations (light and fluorescence microscopy) were used to describe this new red algal parasite as Vertebrata aterrimophila sp. nov. Early developmental stages show that a parasite spore connects via secondary pit connections with a pericentral host cell after cuticle penetration. Developmental observations revealed a unique connection cell that grows into a ‘trunk-like’ structure. Host cell transformation after infection by the parasite included apparent increases in both carbohydrate concentrations and nuclear size, as well as structural changes. Analyses of molecular phylogenies and reproductive structures indicated that the closest relative of V. aterrimophila is its host, V. aterrima. Our study shows a novel developmental parasite stage (‘trunk-like’ cell) and highlights the need for further developmental studies to investigate the range of developmental patterns and host effects in parasitic red algae.     

Life in the fast lane: Temperature,density and host species impact survival and growth of the fish ectoparasite Argulus foliaceus

With expanding human populations, the food sector has faced constant pressure to sustainably expand and meet global production demands. In aquaculture this frequently manifests in an animal welfare crisis, with fish increasingly farmed under high production, high stress conditions. These intense environments can result in fish stocks having a high susceptibility to infection, with parasites and associated disease one of the main factors limiting industry growth. Prediction of infection dynamics is key to preventative treatment and mitigation. Considering the climatic and technology driven changes facing aquaculture, an understanding of how parasites react across a spectrum of conditions is required. Here we assessed the impact of temperature, infection density and host species on the life history traits of Argulus foliaceus, a common palearctic fish louse, representative of a parasite group problematic in freshwater aquaculture and fisheries worldwide. Temperature significantly affected development, growth and survival; parasites hatched and developed faster at higher temperatures, but also experienced shorter lifespans when maintained off the host. At high temperatures, these parasites will likely experience a short generation time as their life history traits are completed more rapidly. A. foliaceus additionally grew faster on natural hosts and at lower infection densities. Ultimately such results contribute to prediction of population dynamics, aiding development of effective control to improve animal welfare and reduce industry loss.     

Developmental interactions between the tobacco hornworm Manduca sexta and its braconid parasite Apanteles congregatus

After newly hatched Manduca sexta larvae were parasitized by Apanteles congregatus, the wasps emerged from third, fourth, fifth, or supernumerary sixth stage host larvae. The number of parasites present within a host determined the time required for Apanteles development and the final host instar. In addition, the percent of parasites within a host which successfully completed their development and emerged was determined by the parasite load. Parasitized larvae gained weight more slowly and attained lower final weights than did unparasitized control larvae; this was attributed to reduced food consumption by the parasitized larvae. Following parasitization of freshly ecdysed fifth-instar Manduca larvae, the rate of Apanteles development was accelerated with respect to that observed when young larvae served as hosts. Parasitism also induced developmental changes in Manduca larvae which encapsulated Apanteles and from which no parasites emerged. Our findings suggest that such larvae retain high juvenile titers late in larval life, preventing normal metamorphosis.

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Zusammenfassung Nachdem frischgeschlüpfte Manduca sexta Raupen durch Apanteles congregatus parasitiert worden waren, schlüpften Wespen aus dem dritten, vierten, fünften oder aus einem überzähligen sechsten Raupenstadium des Wirts. Die Zahl der Parasiten in einem Wirt bestimmte die für die Entwicklung von Apanteles erforderliche Zeit und das Endraupenstadium des Wirts. Zudem wurde der Prozentsatz der Parasiten, die in einem Wirt erfolgreich ihre Entwicklung abschlossen und schlüpften, durch die Parasitenzahl bestimmt. Parasitierte Raupen nahmen langsamer an Gewicht zu und erreichten ein geringeres Endgewicht als nichtparasitierte Vergleichsraupen; dies wurde auf geringere Futteraufnahme der parasitierten Raupen zurückgeführt. Nach der Parasitierung von Manduca Raupen direkt nach der fünften Hautung war die Entwicklungsgeschwindigkeit von Apanteles beschleunigt im Vergleich zu derjenigen in parasitierten Jungraupen. Die Parasitierung verursachte auch Entwicklungsänderungen in Manduca-Raupen, die Apanteles einkapselten und aus denen keine Parasiten schlüpften. Unsere Beobachtungen deuten an, dass solche Raupen einen hohen Juveniltiter bis spät in der Raupenentwicklung behalten, was eine normale Metamorphose verhindert.

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Presented in part at the American Society of Zoologists Meeting, New Orleans, in June 1976.     

Simulated climate change,epidemic size,and host evolution across host–parasite populations

Climate change is causing warmer and more variable temperatures as well as physical flux in natural populations, which will affect the ecology and evolution of infectious disease epidemics. Using replicate seminatural populations of a coevolving freshwater invertebrate‐parasite system (host: Daphnia magna, parasite: Pasteuria ramosa), we quantified the effects of ambient temperature and population mixing (physical flux within populations) on epidemic size and population health. Each population was seeded with an identical suite of host genotypes and dose of parasite transmission spores. Biologically reasonable increases in environmental temperature caused larger epidemics, and population mixing reduced overall epidemic size. Mixing also had a detrimental effect on host populations independent of disease. Epidemics drove parasite‐mediated selection, leading to a loss of host genetic diversity, and mixed populations experienced greater evolution due to genetic drift over the season. These findings further our understanding of how diversity loss will reduce the host populations’ capacity to respond to changes in selection, therefore stymying adaptation to further environmental change.     

Growth and development of the endoparasitic wasp Apanteles congregatus: dependence on host nutritional status and parasite load

ABSTRACT. Previously we have shown that the number of Apanteles congregatus Say (Hymenoptera, Braconidae) larvae developing in Manduca sexta (L.) (Lepidoptera, Sphingidae) larvae that are parasitized in the first instar determines the timing of emergence of the parasites from the host. Here we show that the first larval ecdysis of the wasps occurs after the host ecdyses to the terminal stage, regardless of whether that stage is the host's fourth, fifth or supernumerary sixth instar. Starvation of newly ecdysed terminal stage host larvae prevents emergence of the parasites. When starvation is begun at progressively later times, then an increasing proportion of the hosts have parasites that emerge, suggesting a period of indispensable host nutrition exists during which the host must feed to satisfy the developmental requirements of the parasites. In hosts fed ad libitum , the weight of the host plus its parasites at the time of emergence is positively correlated with the number of parasites developing in the host. When the weight of the parasites alone is subtracted from the weight of the host—parasite complex, the data show that heavily parasitized hosts have a larger host mass than lightly parasitized larvae. In contrast, the wasp larvae, and the adult males and females that develop from them, have lower individual weights after development in heavily parasitized hosts.     

PHYSIOLOGISCHE WECHSELBEZIEHUNGEN ZWISCHEN PIERIS BRASSICAE UND DEM ENDOPARASITEN APANTELES GLOMERATUS. DER EINFLUß DER PARASITIERUNG AUF WACHSTUM UND KÖRPERGEWICHT DES WIRTES1

Zusammenfassung Der Parasitismus von Apanteles glomeratus (L.) bewirkt bei den Larven seines Wirtes, Pieris brassicae. L., eine Blockierung des Gewebewachstums und der Reservestoffspeicherung, sobald sich die Parasitenlarven zum 2. Stadium gehäutet haben. Das Ausmaß der durch diese Blockierung bedingten Wachstumshemmung der Wirtsraupe ist von der Anzahl der in ihr vorhandenen Parasitenlarven unabhängig; es scheint jedoch vom Häutungstermin derselben bestimmt zu werden. Gemessen am durchschnittlichen Trockengewicht erwachsener Pieris-Raupen beträgt der Hemmungseffekt zwischen 60% und 80%. Die Stoffwechselkapazität der Wirtsraupen wird trotz der Blockierung nicht eingeschränkt, sondern steht den Entwicklungsbedürfnissen der Parasitenlarven zur Verfügung, wobei der Grad ihrer Inanspruchnahme von der Individuenzahl der Parasitenlarven abhängt.

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Summary Apanteles glomeratus and Pieris brassicae served as models to investigate the parasitic effect on growth and body weight of the host. Three kinds of host larvae were used in the experiments: Aunparasitized larvae, B-larvae being parasitized on the first day after hatching from the egg, and C-larvae parasitized on the sixth day after hatching. Parasitism by A. glomeratus blocks the growth of the host body independently of the number of parasite larvae living in a host, when the dry weight of the host tissues has reached about 20% (in B-larvae) or 40% (in C-larvae) of the final dry weight of the unparasitized host larva. This blocking occurs on the first and about the third day of the host's fifth instar, respectively. Further growth of the host-parasite-system comes from the development of the parasite larvae only, and depends on the number of them present in the host body. In this way slightly parasitized Pieris-larvae remain abnormally small, whereas heavily parasitized ones grow up to a final body weight higher than unparasitized larvae. This effect is apparent in the maximum and the final live weight as well as in the final dry weight of the total system.The blocking effect seems to be induced by the parasite's second-instar larvae, because growth of the host tissues ceases immediately after the moulting of the parasites. At this moment the host larva seems to loose most of its metabolic autonomy and becomes governed by the parasite larvae. The blocking effect, the physiological mechanism of which is not yet understood, is absolute. It preserves about 80% of the host's spatial and nutritional capacity for the development of the parasite larvae. This reserve of space and metabolic potency is completely exhausted only when the number of parasites exceeds 60 or 80 per host larva in B- and C-larvae, respectively; smaller parasite numbers use only a part of this reserve.It is concluded that the Apanteles larvae, being unable to feed on or to destroy solid host tissues, prevent their synthesis by a blocking effect, thereby eliminating the competition of the host body for nutrients absorbed by the host's gut. Because of the varying number of parasite larvae in the range of 1 to 160 the expected nutritional requirement of the parasite larvae present is uncertain in their early stages of development. Preserving about 80% of the host's physiological capacity independently of the number of the moulting parasite larvae, A. glomeratus guarantees conditions sufficient for the development of even an extraordinarily numerous progeny.

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Gefördert durch die Deutsche Forschungsgemeinschaft