Effects of parasitism by Asobara tabida (Hymenoptera: Braconidae) on the development,survival and activity of Drosophila melanogaster larvae

The impact of parasitism by Asobara tabida on Drosophila melanogaster larval development, survival features and larval activity has been investigated using two strains of the parasitoid. The successful parasitism rate of the A1 strain was four times greater than that of the WOPV strain. Both strains induced equivalent mortality rates but hosts parasitized by A1 predominantly died as pupae. The time necessary for the host pupariation and emergence, and the larval weight at 72, 96 and 120 h post-parasitization were measured. Parasitized larvae exhibited longer periods of development and lower weights than controls, especially when parasitized by A1. These results suggest that hosts underwent physiological costs varying with respect to the outcome of the parasitic relationship. Of the parasitoid factors possibly responsible for these costs, we examined venoms for their impact on host mortality. Artificial injections of WOPV venoms induced higher mortality rates than did A1 venoms. Venoms were also found responsible for the induction of a transient paralysis, naturally occuring after parasitization. Again, the strongest effect was observed after parasitization by WOPV or injections of its venoms. This study gives new insights into the intriguing features of A. tabida and constitutes the first report of the paralysing properties of the venoms.     

Geographic variation in reproductive success of the parasitoid Asobara tabida in larvae of several Drosophila species

Abstract.

• 1 Asobara tabida is a parasitoid of Drosophila larvae in fermenting substrates. Because it is a widespread species, it may encounter different biotic and abiotic circumstances in various parts of its range.
• 2 The species composition of the host population varies over the parasitoid's range: D.obscura-group species (especially D.subobscura) are the main hosts for northwestern and central European parasitoids; D.melanogaster is the main host for southern European parasitoids.
• 3 D.melanogaster larvae can defend themselves against A.tabida by encapsulating the parasitoid egg, and survival in D.melanogaster is always lower than in D.subobscura.
• 4 Parasitoids from southern European populations are much better able to survive in D.melanogaster than their northwestern and central European conspecifics; parasitoids from different populations are equally well able to survive in D.subobscura.
• 5 The lower survival in D.melanogaster may be partly compensated for by the larger size of parasitoids emerging from this host species compared to parasitoids emerging from D.subobscura.
• 6 Within population groups, larger A.tabida females have more eggs in their ovarioles. Additionally, southern European females have more eggs and less fat than northern and western/central European females. The relationship between size and longevity is ambiguous.
• 7 It is concluded that parasitoids from different populations are adapted to region-specific circumstances.

     

Geographical variation in encapsulation ability ofDrosophila melanogaster larvae and evidence for parasitoid-specific components

Summary The ability ofDrosophila melanogaster larvae in Europe to encapsulate the eggs of their most important parasitoids,Asobara tabida andLeptopilina boulardi, shows a large amount of geographical variation. Interestingly, encapsulation ability againstA. tabida is not correlated with encapsulation ability againstL. boulardi. This indicates that the encapsulation system ofD. melanogaster larvae has parasitoid-specific components. The variation in encapsulation ability can only partly be explained by the incidence of parasitism on the larvae. This means that factors other than the two parasitoid species must be selection pressures on the encapsulation ability ofD. melanogaster larvae.     

Kleptoparasitism as an explanation for paradoxical oviposition decisions of the parasitoid Asobara tabida

It is known that the braconid Asobara tabida, a parasitoid of Drosophila larvae, takes oviposition decisions in accordance with survival probabilities in several host species. Nevertheless, larvae of D. simulans, in which the survival probability is virtually zero, are readily accepted for oviposition by searching females. This even happens when they are offered together with D. melanogaster larvae, in which the parasitoid can develop. Here I show that A. tabida can act as a kleptoparasitoid in D. simulans larvae: it can develop in D. simulans larvae, once these larvae are parasitized by another parasitoid, the eucoilid Leptopilina boulardi. Analysis with an optimal foraging model suggests that the increase in survival probability and the occurrence of L. boulardi in the field are high enough to make this kleptoparasitic behaviour of A. tabida pay.     

Friendly food for fitter flies? – Influence of dietary microbial species on food choice and parasitoid resistance in Drosophila

Nutrition fuels any activity performed by an organism and has been shown to affect its ability to withstand pathogens and parasites. Furthermore, animals over a wide range of taxa have been shown to exhibit a choice of foods and nutrients that are beneficial to their fitness. Saprophagous animals most often feed on microorganisms growing on dead organic matter rather than the organic matter itself. Various yeast species play an important role in both larval and adult nutrition of saprophagous Drosophila melanogaster. We hypothesised the dietary microbial species to affect life‐history traits of D. melanogaster, including the ability to fend offparasitoids, and larvae to prefer to devour those yeast species beneficial to their development and immunocompetence. Particular yeast species known to be associated with D. melanogaster could be shown to have a substantial influence on various larval and adult fitness traits including the ability to encapsulate eggs of the parasitoid wasp Asobara tabida. It also turned out that larvae chose to devour those yeast species which supported their ability to encapsulate parasitoid eggs. Which yeast species was preferred and had a beneficial impact on encapsulation ability, was subject to inter‐individual variability within the investigated population, hinting at the existence of an adaptive heritable variability regarding individual choice and salubriousness of food. The results suggest that the dietary microbial species of saprophagous insects may influence the resistance against parasitoid attacks and thus the outcome of the interaction between a saprophagous host and its parasitoids.     

Is parasitoid virulence against multiple hosts adaptive or constrained by phylogeny? A study of Leptopilina spp. (Hymenoptera: Figitidae)/Drosophila (Diptera: Drosophilidae) interactions

Summary. Some insects can develop immune resistance to koinobiont parasitoids. Reciprocally, adaptation to host immunology is critical for parasitoid success. Phylogenetic inertia and correlations between virulence against different hosts can act as constraints preventing these adaptations. Insights on these constraints may be obtained from the analysis of patterns of variations in the interactions at the species or genus level. Multivariate phylogenetic comparative methods were applied to virulence traits of 13 parasitoid strains of Leptopilina spp. (Hymenoptera: Figitidae) on five host strains of the Drosophila melanogaster species subgroup (Diptera Drosophilidae). Independent contrasts of virulence were calculated and principal component analysis (PCA) was performed on the independent contrasts to estimate the dimensionality of the interactions. Most of the variation of virulence was associated with the first component of the PCA (62.2%). But a significant proportion was explained by the second and third components, suggesting specific interactions. Strain–strain reciprocal specificity was observed in several pairs of host–parasitoid species. Significant phylogenetic inertia was observed on parasitoid virulence, but only at the genus level and only against hosts of intermediate resistance (phylogenetic R² between 0.62 and 0.85). Some parts of the interaction matrix exhibited specific interactions and others were fixed due to ancestral non-specific virulence (or avirulence). The results were interpreted viewing virulence as a threshold trait determined by underlying liability. When liability is far from the threshold, virulence is fixed. When liability is close to the threshold, virulence varies specifically and reciprocal adaptations can take place. These phylogenetic constraints may lead to a scenario of escape and radiation coevolution in the host–parasitoid system.     

<Emphasis Type="Italic">Rhodococcus fascians</Emphasis>: Shoot Proliferation without Elevated Cytokinins?

In order to determine whether the disease symptoms caused by virulent strains of Rhodococcus fascians are due to increased cytokinin activity in infected tissues, germinating peas (Pisum sativum cv Novella) were inoculated with either a virulent strain or a nonvirulent strain of Rhodococcus fascians. The nonvirulent strain lacked both the ipt gene and the putative cytokinin oxidase/dehydrogenase homologue, fas5. Control peas were not inoculated. Twelve cytokinins were isolated from pea shoots 3, 6 and 9 days post-inoculation. Within 6 days of inoculation the levels of cytokinin free bases, ribosides, O-glucosides and nucleotides were decreased in shoots inoculated with the virulent strain, and were increased in shoots inoculated with the nonvirulent strain relative to the uninoculated control. The results are discussed with respect to the classic Skoog and Miller (1965) model of organogenesis and to the possible involvement of the plant cytokinin oxidase/dehydrogenase during infection by virulent strains of R. fascians.     

Variation in diapause and sex ratio in the parasitoidAsobara tabida

Asobara tabida Nees (Hymenoptera: Braconidae) is a widespread parasitoid, attacking larvae ofDrosophila (Diptera: Drosophilidae) species in fermenting substrates. In this species, geographic variation is found in the percentage of parasitoids entering diapause and in the sex ratio of emerging parasitoids. Percentage diapause appears to be influenced by host species (more parasitoids enter diapause inD. melanogaster Meigen than inD. subobscura Collin) and temperature. It is not correlated with any of the abiotic factors investigated, but is correlated with survival probability inD. melanogaster larvae and with the time of year in which the experiment was conducted (even though none of the parasitoids experienced natural day light). Sex ratio was only found to correlate with percentage diapause, suggesting that males enter diapause more frequently than females. It is concluded thatA. tabida uses diapause to survive both unfavourable abiotic and biotic circumstances.     

CROSS-RESISTANCE FOLLOWING ARTIFICIAL SELECTION FOR INCREASED DEFENSE AGAINST PARASITOIDS IN DROSOPHILA MELANOGASTER

An increase in resistance to one natural enemy may result in no correlated change, a positive correlated change, or a negative correlated change in the ability of the host or prey to resist other natural enemies. The type of specificity is important in understanding the evolutionary response to natural enemies and was studied here in a Drosophila-paxasitoid system. Drosophila melanogaster lines selected for increased larval resistance to the endoparasitoid wasps Asobara tabida or Leptopilina boulardi were exposed to attack by A. tabida, L. boulardi and Leptopilina heterotoma at 15°C, 20°C, and 25°C. In general, encapsulation ability increased with temperature, with the exception of the lines selected against L. boulardi, which showed the opposite trend. Lines selected against L. boulardi showed large increases in resistance against all three parasitoid species, and showed similar levels of defense against A. tabida to the lines selected against that parasitoid. In contrast, lines selected against A. tabida showed a large increase in resistance to A. tabida and generally to L. heterotoma, but displayed only a small change in their ability to survive attack by L. boulardi. Such asymmetries in correlated responses to selection for increased resistance to natural enemies may influence host-parasitoid community structure.     

Foraging behavior and encapsulation ability ofDrosophila melanogaster larvae: Correlated polymorphisms? (Diptera: Drosophilidae)

Larvae ofDrosophila melanogaster are polymorphic with respect to their foraging behavior. Rovers move around, while sitters stay more in one place. This difference in movements while foraging may result in differences in the rate at which these larvae are attacked by hymenopteran parasitoids, especially by those that locate their hosts by reacting to the vibrations they make. From previous work it is known thatD. melanogaster larvae show intra- and interpopulation variation in their ability to destroy parasitoid eggs by encapsulation. If rovers have a higher probability to be attacked by a parasitoid, they may have a higher developed encapsulation system as compensation for this higher attack probability. Experiments show that rovers are indeed more often attacked byAsobara tabida, a vibrotactic (=reacting to vibrations) parasitoid, than sitters. However, foraging behavior and encapsulation ability appear to be independent of each other inD. melanogaster. This shows that the large variation between populations in encapsulation ability is not a reflection of the relative proportion of rovers and sitters in the populations. It also shows that parasitoids can be an important factor in the maintenance of the foraging behavior polymorphism, because a higher encapsulation ability is not a compensation for a higher attack probability.     

THE GENETICS OF ADAPTATION: THE GENETIC BASIS OF RESISTANCE TO WASP PARASITISM IN DROSOPHILA MELANOGASTER

There have been very few genetic analyses of “natural” adaptations, that is, those not involving artificial selection or responses to human disturbance. Here we analyze the genetic basis of geographic variation in Drosophila melanogaster's resistance to parasitism by a wasp, Asobara tabida. Our results suggest that population differences in ability to encapsulate parasitoid eggs have a fairly simple genetic basis: 60% of the D. melanogaster genome plays no role in differences between resistant and susceptible populations. Instead, resistance gene(s) are restricted to chromosome two, and may be further restricted to the centromeric region of this chromosome. This finding suggests that natural adaptations—like many responses to artificial selection and human disturbance—sometimes have a simple genetic basis.     

Oviposition behavior ofDrosophila subobscura and its parasitoidAsobara tabida in the laboratory

At 18°C, adultAsobara tabida emerge 21 days after oviposition within the host;Drosophila subobscura emerges 18 days after oviposition. The relatively short pre-oviposition period of adultA. tabida (4 days), compared to that ofD. subobscura (4–8 days) results in the generation times of both host and parasitoid being approximately similar. A yeast source is necessary forD. subobscura females to mature their eggs; female flies will not oviposit on patches without a yeast source. While surface roughness is an important characteristic for maximumD. subobscura oviposition,A. tabida oviposition, and consequent levels of parasitism, is enhanced by coating patches with askin of active yeast. When presented with a multi-patch environment, experienced and inexperienced female wasps showed no significant difference in their level of attack.     

Costs of secondary parasitism in the facultative hyperparasitoid Pachycrepoideus dubius: does host size matter?

Although hyperparasitism frequently occur in parasitic insects, many aspects of this strategy remain unknown. We investigated possible fitness costs of hyperparasitism as influenced by host size. Our study was conducted with the facultative hyperparasitoid Pachycrepoideus dubius Ashmead (Hymenoptera: Pteromalidae), which parasitizes host species differing greatly in size. We compared some fitness traits (level of successful parasitism, development time, sex ratio and offspring size) of P. dubius developing on large secondary/primary (Delia radicum L. (Diptera: Anthomyiidae)/Trybliographa rapae Westwood (Hymenoptera: Figitidae)) or small secondary/primary host species (Drosophila melanogaster L./Asobara tabida Nees (Hymenoptera: Braconidae)). In no-choice and choice experiments, P. dubius was able to develop on different stages of T. rapae (L2 (endophagous), L4 (ectophagous), and pupae) but that it preferred to parasitize unparasitized D. radicum pupae over pupae parasitized by T. rapae. Furthermore, in P. dubius, hyperparasitism was associated with fitness costs (lower level of successful parasitism, smaller adult size) and these costs were greater on the smallest host complex. We hypothesize that the size of D. melanogaster pupae parasitized by A. tabida may be close to the suboptimal host size for P. dubius beneath which the costs of hyperparasitism make this strategy nonadaptive. Hyperparasitism in terms of trade-offs between host quality and abundance of competitors is discussed.     

Relationship between oviposition,virulence gene expression and parasitism success in <Emphasis Type="Italic">Cotesia typhae</Emphasis> nov. sp. parasitoid strains

Studying mechanisms that drive host adaptation in parasitoids is crucial for the efficient use of parasitoids in biocontrol programs. Cotesia typhae nov. sp. (Fernández-Triana) (Hymenoptera: Braconidae) is a newly described parasitoid of the Mediterranean corn borer Sesamia nonagrioides (Lefebvre) (Lepidoptera: Noctuidae). Braconidae are known for their domesticated bracovirus, which is injected with eggs in the host larva to overcome its resistance. In this context, we compared reproductive success traits of four Kenyan strains of C. typhae on a French and a Kenyan populations of its host. Differences were found between the four strains and the two most contrasted ones were studied more thoroughly on the French host population. Parasitoid offspring size was correlated with parasitism success and the expression of bracovirus virulence genes (CrV1 and Cystatin) in the host larva after parasitism. Hybrids between these two parasitoid strains showed phenotype and gene expression profiles similar to the most successful parental strain, suggesting the involvement of dominant alleles in the reproductive traits. Ovary dissections revealed that the most successful strain injected more eggs in a single host larva than the less successful one, despite an equal initial ovocyte number in ovaries. It can be expected that the amount of viral particles increase with the number of eggs injected. The ability to bypass the resistance of the allopatric host may in consequence be related to the oviposition behaviour (eggs allocation). The influence of the number of injected eggs on parasitism success and on virulence gene expression was evaluated by oviposition interruption experiments.     

Host-feeding and egg maturation byPachycrepoideus vindemiae

Pachycrepoideus vindemiae Rondani (Hymenoptera: Pteromalidae) is a facultative hyperparasitoid ofDrosophila parasitoids in Europe. FemaleP. vindemiae host-feed from the same hosts into which they lay eggs and this enables them to mature additional eggs.P. vindemiae females were allowed to host-feed from puparia containingDrosophila melanogaster Meigen (Diptera: Drosophilidae) pupae or pupae ofAsobara tabida Nees (Hymenoptera: Braconidae). Wasps which had host-fed carried significantly more eggs; the species of host which was fed from had no significant effect on the number of mature eggs in the ovaries. Host-feeding caused no significant reduction in the size of the emerging offspring.P. vindemiae were allowed to forage over patches containing different frequencies of the two host species. No significant oviposition preference was found but there were marked host-feeding preferences which were affected by the age of the host pupae. It is suggested that these preferences were due to the physical nature of the hosts which were fed from.     

Reciprocal influences and costs of parasitism on the development of Corcyra cephalonica and its endoparasitoid Venturia canescens

Many endoparasitoids develop successfully within a range of host instars. Parasitoid survival is highest when parasitism is initiated in earlier host instars, due to age-related changes in internal (physiological) host defences. Most studies examining fitness-related costs associated with differences in host instar have concentrated on the parasitoid, ignoring the effects of parasitism on the development of surviving hosts that have encapsulated parasitoid eggs. A laboratory experiment was undertaken examining fitness-related costs associated with encapsulation of Venturia canescens (Hymenoptera: Ichneumonidae) eggs by fifth (L5) instar larvae of Corcyra cephalonica (Lepidoptera: Pyralidae). Growth and development of both host and parasitoid were monitored in C. cephalonica larvae containing 0, 1, 2, or 4 parasitoid eggs. Adult size and fecundity of C. cephalonica did not vary with the number of eggs per host. However, there was a distinct increase in host mortality with egg number, although most parasitoids emerged from hosts containing a single egg. The most dramatic effect on the host was a highly significant increase in development time from parasitism to adult eclosion, with hosts containing 4 parasitoid eggs taking over 2.5 days longer to complete development than unparasitized larvae. The egg-to-adult development time and size of adult V. canescens did not vary with egg number per host, as demonstrated in a previous experiment using a different host (Plodia interpunctella). The results described here show that there are fitness-related costs to the host associated with resistance to parasitism.     

Coping with multiple enemies – the evolution of resistance and host-parasitoid community structure

Recent work has shown that the evolution of Drosophila melanogaster resistance to attack by the parasitoid Asobara tabida is constrained by a trade-off with larval competitive ability. However, there are two very important questions that need to be answered. First, is this a general cost, or is it parasitoid specific? Second, does a selected increase in immune response against one parasitoid species result in a correlated change in resistance to other parasitoid species? The answers to both questions will influence the coevolutionary dynamics of these species, and also may have a previously unconsidered, yet important, influence on community structure.     

A model for the coevolution of resistance and virulence in coupled host—parasitoid interactions

A coevolutionary model is developed of the interaction between a host and an internal parasitoid, where the outcome of parasitism depends upon the extent to which individual hosts invest in resistance mechanisms and individual parasitoids in countermeasures (virulence). The host and parasitoid are assumed to have coupled population dynamics (of Nicholson–Bailey form) and to be composed of a series of asexual clones with different levels of resistance and virulence. Investment in resistance and virulence mechanisms is assumed to be costly. The model has two main outcomes. First, if resistance is relatively costly compared to virulence, the host may be selected not to invest in resistance mechanisms despite parasitoid investment in virulence, in effect trading off the risks of parasitism against the savings in costs. A number of cases which appear to correspond to this result have been reported. Second, for most other feasible parameter values, an arms race occurs between host and parasitoid, until effective resistance becomes so costly that the host abandons defence. This abandonment is followed by a reduction in parasitoid virulence and the cycle begins again. These cycles may explain reports of persistent additive genetic variation in resistance and virulence, and may also contribute towards population dynamic stability.     

Virulent and nonvirulent Flavobacterium columnare colony morphologies: characterization of chondroitin AC lyase activity and adhesion to polystyrene

Aims: Colony morphology variants of fish pathogenic Flavobacterium columnare were studied to clarify the role of colony morphology change in the virulence of the bacterium. Typical rhizoid colony (Rz) variants are virulent and moderately adherent, nonrhizoid rough (R) colony variants are nonvirulent and highly adherent, and soft colony (S) variants are nonvirulent and poorly adherent. Methods and Results: Chondroitin AC lyase activity, adhesion to polystyrene at different temperatures and after modification of bacterial surface, and lipopolysaccharide (LPS) profiles of the variants were studied. The chondroitinase activity was significantly higher in the virulent, rhizoid variants than in the rough variants of the same strain. Temperature significantly increased the adhesion of rhizoid variants up to 20°C. Modification of bacterial surface suggested that adhesion molecules contain both carbohydrates and proteins. LPS did not differ between the variants of the same strain. Conclusions: The results suggest that in Fl. columnare both rhizoid colony morphology and high chondroitinase activity are needed for virulence and that temperature may promote the adhesion of the virulent variants to surfaces at fish farms. Significance and Impact of the Study: New information is produced on the virulence mechanisms of Fl. columnare and the reasons behind the survival of the bacterium at fish farms.     

沙门菌噬菌体抗性菌的筛选鉴定及致病力研究

【目的】筛选鉴定沙门菌噬菌体侵染裂解过程中的抗性菌株,研究抗性菌株的生物学特性及致病力的差异,为解决噬菌体治疗应用中的抗性菌问题提供理论依据。【方法】本研究通过次级感染法和双层平板法筛选沙门菌噬菌体抗性菌,通过生物学特性和毒力基因检测比较宿主菌ATCC 13076及其噬菌体抗性菌株R3之间的差异,并通过小鼠攻毒实验和细胞粘附实验比较致病力强弱。【结果】噬菌体抗性菌株R3的生长速度较宿主菌略慢;生化及毒力基因检测均表明抗性菌株与宿主菌无差异;与宿主菌相比,抗性菌R3的LD50增加了74.8%(P>0.05);对MODE-K细胞粘附能力稍弱,但是差异不显著。【结论】该研究表明,与噬菌体宿主菌相比,噬菌体抗性菌株的生物学特性和毒力基因并没有改变,对小鼠致病力减弱,但是对MODE-K细胞粘附能力差异不显著。