Presence of conspecifics triggers host searching behavior in an egg parasitoid wasp

Parasitoids and predators compete for host or prey species. The efficiency of obtaining prey or host items is reduced by intraspecific competition. As the optimal search behavior depends on the intensity of competition, it is important for the parasitoid or predator to obtain information on this intensity. Previous studies have shown that parasitoids can obtain information regarding competition from encounters with already parasitized hosts. They then change their host searching behavior accordingly. However, whether parasitoids obtain the information directly from observing the presence of conspecifics remains unclear. We used Tiphodytes gerriphagus (Marchal) (Hymenoptera: Scelionidae), the solitary egg parasitoid of water striders, for testing the effect of density of conspecifics on host searching behavior. Females of T. gerriphagus dive into the water to search for hosts and sometimes they dive without hosts present. Thus, we investigated whether T. gerriphagus changed underwater activities in response to the density of conspecifics in the absence of hosts. Four densities (1, 2, 4, and 8 female T. gerriphagus) were investigated. Females in competitive situations (groups of 2, 4, and 8 females) displayed host searching behavior, but the solitary females did not. This indicates that the presence of conspecifics triggers host searching behavior and that T. gerriphagus females obtain information on competition directly from conspecifics and use it for modifying their behavior.     

Costs of reproduction and geographic variation in the reproductive tactics of the mosquito Aedes triseriatus

Intraspecific host discrimination is widespread in solitary parasitoids whose adult females forage for and evaluate host suitability, whereas interspecific discrimination is less common. In some parasitoid species, mostly Diptera and Coleoptera, the larva performs the last step of host searching. It has been suggested that host discrimination will rarely occur in such host-seeking larvae because their low mobility results in a low host encounter rate. We determined the extent to which the larvae of Aleochara bilineata Gyllenhal (Coleoptera: Staphylinidae), a solitary parasitoid of aggregated Diptera pupae: (1) discriminated between unparasitized hosts and hosts parasitized by conspecifics; (2) used semiochemical cues to discriminate; (3) were influenced by life expectancy, presence of conspecifics and host availability in their host acceptance decision; and the extent to which (4) A. bilineata and A. bipustulata L., a species exploiting the same hosts and occurring sympatrically, showed interspecific host discrimination. A. bilineata larvae were able to discriminate between unparasitized hosts and hosts parasitized by conspecifics in a choice experiment. Such behavior has never previously been described for a coleopteran parasitoid or for a parasitoid species whose larvae perform host searching. Host discrimination in this species was not based on the presence of visual or tactile cues (e.g., entrance holes) but rather on chemical cues. The life expectancy of A. bilineata larvae was significantly shorter in the presence than in absence of hosts, and older larvae had lower parasitism success than young larvae in a 24-h experiment. However, the host acceptance decision of A. bilineata larvae was not influenced by larval age or the presence of conspecifics when the ratio of hosts per larva was greater than or equal to 1. When hosts were scarce, the degree of superparasitism increased significantly with the number of foraging conspecifics and the age of the larvae. Both species of Aleochara showed intra- and interspecific host discrimination in a choice experiment. In contrast to A. bipustulata, A. bilineata larvae more frequently parasitized hosts parasitized by A. bipustulata than those parasitized by conspecifics. We suggest that host discrimination will be frequent in solitary parasitoids with host-seeking larvae when hosts are aggregated. Received: 4 June 1998 / Accepted: 1 September 1998     

Strange limits of stability in host-parasitoid systems

The classical Nicholson-Bailey model for a two species host-parasitoid system with discrete generations assumes random distributions of both hosts and parasitoids, randomly searching parasitoids, and random encounters between the individuals of the two species. Although unstable, this model induced many investigations into more complex host-parasitoid systems. Local linearized stability analysis shows that equilibria of host parasitoid systems within the framework of a generalized Nicholson-Bailey model are generally unstable. Stability is only possible if host fertility does not exceede ⁴=54.5982 and if superparasitism is unsuccessful. This special situation has already been discovered by Hassell et al. (1983) in their study of the effects of variable sex ratios on host parasitoid dynamics. We discuss global behaviour of the Hassell-Waage-May model using KAM-theory and illustrate its sensitivity to small perturbations, which can give rise to radically different patterns of the population dynamics of interacting hosts and parasitoids.     

The role of contact chemoreception in the host location process of an egg parasitoid

Taste allows insects to detect palatable or toxic foods, identify a mate, and select appropriate oviposition sites. The gustatory system strongly contributes to the survival and reproductive success of many species, yet it is rarely studied in insect parasitoids. In order to locate and assess a host in which they will lay their eggs, female wasps actively search for chemical cues using their sensory organs present mainly on the antennae. In this paper, we studied the role of antennal taste sensilla chaetica in the perception of contact semiochemicals in Trissolcus brochymenae (Hymenoptera: Platygastridae), an egg parasitoid of the brassicaceae pest Murgantia histrionica (Heteroptera: Pentatomidae). Methanolic extracts obtained from male and female hosts elicited action potentials in taste neurons housed in antennal sensilla chaetica, indicating that these sensilla are involved in the perception of non volatile host kairomones. In behavioural assays, wasp females displayed an intense searching behaviour in open arenas treated with host extracts, thus confirming that these kairomones are soluble in polar solvents. We further investigated the extracts by Gas Chromatography-Mass Spectrometry (GC-MS) and found that they contain several compounds which are good candidates for these contact kairomones. This study contributes to better understanding contact chemoreception in egg parasitoids and identifying gustatory receptor neurons involved in the host location process.     

Chemotaxis-induced spatio-temporal heterogeneity in multi-species host-parasitoid systems

When searching for hosts, parasitoids are observed to aggregate in response to chemical signalling cues emitted by plants during host feeding. In this paper we model aggregative parasitoid behaviour in a multi-species host-parasitoid community using a system of reaction-diffusion-chemotaxis equations. The stability properties of the steady-states of the model system are studied using linear stability analysis which highlights the possibility of interesting dynamical behaviour when the chemotactic response is above a certain threshold. We observe quasi-chaotic dynamic heterogeneous spatio-temporal patterns, quasi-stationary heterogeneous patterns and a destabilisation of the steady-states of the system. The generation of heterogeneous spatio-temporal patterns and destabilisation of the steady state are due to parasitoid chemotactic response to hosts. The dynamical behaviour of our system has both mathematical and ecological implications and the concepts of chemotaxis-driven instability and coexistence and ecological change are discussed. I. G. Pearce gratefully acknowledges the financial support of the NERC.     

Behavioral mechanisms of parasitic wasps for searching concealed insect hosts

Wood borers are important forest insect pests and difficult to be controlled owing to their concealed behavior. However, parasitic wasps can effectively ascertain and parasitize wood borers as well as other concealed pests by using special searching, finding and attacking mechanisms, which have been developed during the course of long-term coevolution with their hosts. The present paper summarizes the behavioral mechanisms of parasitic wasps involved in searching and locating their concealed hosts. Parasitic wasps can accurately find the location of their hidden hosts and then parasitize them, usually by using olfactory semiochemicals from hosts (lavare and adults), host frass and symbiotic microorganisms in host galleries; visual signals from color contrast of plant surface; contact stimuli from characters of host physical defense; substrate vibrations produced by host feeding and movement; infrared radiation from host activities and metabolizability. Some parasitic wasps may integrate the information of several stimuli from different sources to enhance the reliability and accuracy of host locations. In addition, the potentials for utilizing the host location signals of parasitoids in biological control are discussed.     

寄生蜂寻找隐蔽性寄主害虫的行为机制

林木蛀干类害虫具有高度的隐蔽性,是林业上的一类重要害虫,也是目前世界上最难防治的害虫类群之一.寄生蜂在与寄主长期的协同进化过程中,形成了搜索、发现和攻击寄主害虫的独特机制,能够有效地找到并寄生它们.总结了寄生性天敌寻找、发现并成功定位隐蔽性寄主害虫的行为学机制.寄生蜂可以利用来自嗅觉的化学信息物质(如寄主、寄主粪便、虫道共生菌的挥发性气味)、寄主成虫的化学通讯物质、来自视觉的植物表面色差信息、来自触觉的寄主保护物性状特征、来自寄主取食和运动所产生的介质振动信号以及来自寄主活动和代谢的红外辐射等多种途径有效地发现隐蔽性害虫的位置,从而完成寄生行为.有些寄生蜂还能综合利用来源不同的多种信息,从而提高寄主定位的可靠性和准确性.本文还对寄生蜂寻找寄主的这些线索在生物防治上可能的利用途径和前景进行了讨论.这对促进我国在该领域的研究,充分利用天敌昆虫,提高生物防治效率具有参考价值.     

Adaptive self- and conspecific superparasitism in the solitary parasitoid Leptopilina heterotoma (Hymenoptera: Eucoilidae)

One of the foraging decisions facing parasitoids is whetherto accept (superparasitize) or reject hosts that have alreadybeen parasitized. An important distinction is whether the hosthas been parasitized by the female parasitoid herself or bya conspecific. In solitary parasitoids, the pay-off from anegg laid in the latter host type (conspecific superparasitism)is the probability that the second egg wins the competitionfor the host and results in an offspring. The pay-off from anegg laid in the former type (self-superparasitism) increaseswith an increasing probability that another female will superparasitizethe host in the near future. When this probability equals one,self-superparasitism and conspecific superparasitism have thesame payoff. However, conspecific superparasitism will generallyhave a higher pay-off than self-superparasitism. It will thereforebe beneficial for a female parasitoid to be able to distinguishbetween a host she parasitized and one parasitized by a conspecific.The degree of benefit depends on the probability of conspecificsuperparasitism in the near future. Using an optimal diet model,I show that when a parasitoid encounters a patch containinga mixture of unparasitized and already-parasitized hosts, afemale that can distinguish between the two types of parasitizedhosts gains more offspring than a female without this ability.However, when parasitoids search a patch together with conspecifics,it is adaptive to self-superparasitize, and the pay-off fromthis ability may be negligible. It is therefore predicted thatwhen a female parasitoid searches a partially depleted patchalone, it will reject the hosts parasitized by itself more frequentlythan hosts parasitized by conspecifics. In contrast, femaleparasitoids searching together are predicted to accept hoststhat they parasitized themselves much more often. The resultsshow that the solitary parasitoid Leptopilina heterotoma (Hymenoptera:Eucoilidae) is able to distinguish between hosts that it parasitizedand hosts parasitized by conspecifics. The predictions of themodel are met in a second experiment that shows that L. heterotomaself-superparasitizes when the probability of conspecific superparasitismis high.     

Putative Host Volatiles Used by <Emphasis Type="Italic">Habrobracon hebetor</Emphasis> (Hymenoptera: Braconidae) to Locate Larvae of <Emphasis Type="Italic">Plodia interpunctella</Emphasis> (Lepidoptera: Pyralidae)

Indianmeal moth, Plodia interpunctella (Hubner) (Lepidoptera: Pyralidae), is a post-harvest pest of grains, milled and processed food, processing plants, warehouses and bakeries. The parasitoid, Habrobracon hebetor (Say) is among the most important natural enemies of Pyralidae infesting stored grains and grain products. Many parasitoids use semiochemicals originating from their hosts, or host’s habitat as cues to locate hosts, hosts’ food or habitat. The authors used Y-tube and four-way olfactometers to assay responses to stimuli with the moth host and thereby understand the role of host-associated semiochemicals in host location by H. hebetor. Responses of mated parasitoid females were assayed to the following stimuli: P. interpunctella sex pheromone, female adults, larvae, or hexane extracts of residue of the rearing medium. Generally, host-related odor sources generated stimuli that elicited better responses than those to blank controls. Previous exposure to odor sources from the host shortened latency periods and response times compared to naïve females. Odors emanating from live moth larvae elicited the strongest responses. When responses from the four odor sources were compared in a four-way olfactometer, it was confirmed that volatiles from larval moths elicited the strongest attraction to the parasitoid. The involvement of host-specific chemical cues in both long and short range host location by female parasitoid is discussed.     

No evidence of strong host resource segregation by phorid parasitoids of leaf-cutting ants

Resource segregation by species is a cornerstone ecological concept that may result from several processes such as interspecific competition, and can help structuring communities, in particular parasitoid communities. Phorid parasitoid flies that use ants as hosts usually employ one host per individual parasitoid, and thus the pressure for segregating the host resource should be high. At a particular community, these parasitoids might segregate resources by temporal differences in activity patterns, using different host species or nests from those available. Even if parasitoid species coexist on the same nest, they can take advantage of worker polymorphism and task division, searching for ants performing different tasks at different microsites of the same nest. Here we evaluated the segregation of parasitoid species in these hypothesized axes using leaf-cutting ant phorid parasitoids as a model system. We analyzed temporal data collected at two localities with contrasting host species richness; and compared parasitoid co-occurrence at the different niche axis. For most of the hypothesized niche axes tested we found either no departures from random expectations or significantly more niche overlap than expected by chance, ruling out the existence of biologically relevant host resource segregation in this system. However, there was evidence of segregation for some species, since one parasitoid species was only found in winter and another species showed a negative correlation of its abundance over nests with other two species. Furthermore, we found that several species were flexible in host use; Atta phorids varied in average host sizes preferred, whereas Acromyrmex phorids that were generalists were able to use different host species or microsites for host location. From an applied perspective, these results are encouraging when selecting species for the control of leaf-cutting ants because parasitoids coexistence seems to be unaffected by their overlap in niche dimensions.     

Host Location of Hyssopus pallidus, a Larval Parasitoid of the Codling Moth, Cydia pomonella

The effectiveness of parasitoids as biological control agents depends largely on their host location behavior. In this study we describe the host-searching behavior of Hyssopus pallidus (Askew), a larval parasitoid of the codling moth Cydia pomonella L. We observed parasitoid behavior on mature apples (a potential host patch) and elucidated some of the stimuli which determine host location. Female wasps showed more complex and intensive searching on infested apples than on mechanically damaged or noninfested apples. Wasps were able to enter infested apples through the calyx or the tunnel made by the host larvae and parasitize them. Area-restricted searching was observed on infested apples, in particular on areas contaminated with host frass. In a further bioassay, we confirmed that host frass contains a host location kairomone. The kairomone appears to be produced by the host independently from its diet, even though frass produced by hosts fed on an apple are more attractive than frass produced by hosts fed on a fruit-devoid artificial diet. The capability of H. pallidus to locate its host inside apples makes the foraging strategy of this species potentially useful as a biological control agent.     

Diving Into The Water: Cues Related to the Decision‐Making by an Egg Parasitoid Attacking Underwater Hosts

Although adult parasitoids spend a majority of their lives above ground, females of several species must search for their host in the water or on the soil. Adult parasitoids above ground can use a variety of sensory cues to detect their hosts from a distance. However, their sensory cues can be impaired from volatile chemicals, and their visual stimuli can be decreased while submerging or burrowing in the water of soil during their search for their hosts. Searching underwater or underground would incur high foraging costs, that is, time and energy consumption and increase risk of drowning. Therefore, to reduce such costs and increase searching efficiency, the decision on where to start submerging or burrowing for attacking hosts is important for parasitoids. Furthermore, there are no studies that have examined the cues of submerging or burrowing parasitoids on their exploit for the decision to attack their hosts. We have examined the cues used by the egg parasitoid Tiphodytes gerriphagus attacking underwater hosts. We compared the searching behaviors of T. gerriphagus among four oviposition site conditions. The four sites investigated were oviposition site with both host adult chemical residues and presence of eggs, with only the presence of eggs, with only the host adult chemical residues, and without any cue. Our results indicated that T. gerriphagus more frequently contacted and submerged at oviposition sites with the adult residues rather than at oviposition sites without them. Nonetheless, the presence of underwater host eggs did not affect the host‐searching behavior. This suggests that T. gerriphagus decided to submerge at the oviposition site in response to the adult residues. Furthermore, our observation also suggested that T. gerriphagus has already detected that the adult residues might be volatile before contacting the oviposition site. Finally, we will discuss the exploitation patterns of host‐searching cue by parasitoids that need to submerge from the context of its reliability and detectability problems.     

Infochemical use and dietary specialization in parasitoids: a meta‐analysis

Many parasitoid species use olfactory cues to locate their hosts. In tritrophic systems, parasitoids of herbivores can exploit the chemical blends emitted by plants in reaction to herbivore‐induced damage, known as herbivore‐induced plant volatiles (HIPVs). In this study, we explored the specificity and innateness of parasitoid responses to HIPVs using a meta‐analysis of data from the literature. Based on the concept of dietary specialization and infochemical use, we hypothesized that (i) specialist parasitoids (i.e., with narrow host ranges) should be attracted to specific HIPV signals, whereas generalist parasitoids (i.e., with broad host ranges) should be attracted to more generic HIPV signals and (ii) specialist parasitoids should innately respond to HIPVs, whereas generalist parasitoids should have to learn to associate HIPVs with host presence. We characterized the responses of 66 parasitoid species based on published studies of parasitoid behavior. Our meta‐analysis showed that (i) as predicted, specialist parasitoids were attracted to more specific signals than were generalist parasitoids but, (ii) contrary to expectations, response innateness depended on a parasitoid's target host life stage rather than on its degree of host specialization: parasitoids of larvae were more likely to show an innate response to HIPVs than were parasitoids of adults. This result changes our understanding of dietary specialization and highlights the need for further theoretical research that will help clarify infochemical use by parasitoids.     

Mathematical modelling of host-parasitoid systems: effects of chemically mediated parasitoid foraging strategies on within- and between-generation spatio-temporal dynamics.

In this paper we develop a novel discrete, individual-based mathematical model to investigate the effect of parasitoid foraging strategies on the spatial and temporal dynamics of host-parasitoid systems. The model is used to compare na?ve or random search strategies with search strategies that depend on experience and sensitivity to semiochemicals in the environment. It focuses on simple mechanistic interactions between individual hosts, parasitoids, and an underlying field of a volatile semiochemical (emitted by the hosts during feeding) which acts as a chemoattractant for the parasitoids. The model addresses movement at different spatial scales, where scale of movement also depends on the internal state of an individual. Individual interactions between hosts and parasitoids are modelled at a discrete (micro-scale) level using probabilistic rules. The resulting within-generation dynamics produced by these interactions are then used to generate the population levels for successive generations. The model simulations examine the effect of various key parameters of the model on (i) the spatio-temporal patterns of hosts and parasitoids within generations; (ii) the population levels of the hosts and parasitoids between generations. Key results of the model simulations show that the following model parameters have an important effect on either the development of patchiness within generations or the stability/instability of the population levels between generations: (i) the rate of diffusion of the kairomones; (ii) the specific search strategy adopted by the parasitoids; (iii) the rate of host increase between successive generations. Finally, evolutionary aspects concerning competition between several parasitoid subpopulations adopting different search strategies are also examined.     

Host‐searching responses to herbivory‐associated chemical information and patch use depend on mating status of female solitary parasitoid wasps

1. In a tritrophic interaction system consisting of plants, herbivores, and their parasitoids, chemicals released from plants after herbivory are known to play important roles for many female parasitoids to find their hosts efficiently. On the plant side, chemical information associated with herbivory can act as an indirect defence by attracting the natural enemies of the host herbivores. 2. However, mated and virgin females of haplodiploid parasitoids might not necessarily respond to such chemical cues in the same way. Since virgin females can produce only sons, they might refrain from searching for hosts to invest eggs until copulation, in order to produce both sexes. 3. Here, we investigated differential host‐searching behaviours shown by mated and virgin females in the solitary parasitoid wasp, Cotesia vestalis, in response to herbivory‐associated chemical information from cruciferous plants infested by their host larvae, Plutella xylostella. 4. Mated females showed a significantly higher flight preference for host‐infested plants over intact plants, while no preference was observed with virgin females. Mated females also showed more intensive antennal searching and ovipositor probing behaviours to leaf squares with wounds caused by hosts than did virgin females. Furthermore, mated females stayed longer in host patches with higher parasitism rates than virgin females. 5. These results indicate that mating status of C. vestalis females clearly influences their host‐searching behaviour in response to herbivory‐associated chemical information and patch exploitation. Female parasitoids seem to forage for hosts depending on their own physiological condition in a tritrophic system.     

Aggregation and the Coexistence of Competing Parasitoid Species

In nature, many insect species are attacked by more than one specialized species of parasitoid. We examine whether parasitoid aggregation among patches containing hosts can promote the coexistence of specialized parasitoids on the same host species. We construct models to analyze the effects of three types of parasitoid aggregation: direct density-dependent, inverse density-dependent, and density-independent aggregation. All three types of aggregation may facilitate coexistence, provided the parasitoid species show behavioral differences that produce different patterns of aggregation. By deriving general conditions of coexistence of parasitoids, we show that all three types of aggregation act to facilitate coexistence in the same way—by increasing the covariance between the distributions of susceptible hosts and the least common parasitoid. Although they act in the same way, in general the effect of density-independent aggregation in facilitating coexistence is greater than either direct or inverse density-dependent aggregation. This suggests that density-independent aggregation may have the greatest potential to facilitate the coexistence of specialize parasitoids using the same host.     

Innate Host Habitat Preference in the Parasitoid Diachasmimorpha longicaudata: Functional Significance and Modifications through Learning

Parasitoids searching for polyphagous herbivores can find their hosts in a variety of habitats. Under this scenario, chemical cues from the host habitat (not related to the host) represent poor indicators of host location. Hence, it is unlikely that naïve females show a strong response to host habitat cues, which would become important only if the parasitoids learn to associate such cues to the host presence. This concept does not consider that habitats can vary in profitability or host nutritional quality, which according to the optimal foraging theory and the preference-performance hypothesis (respectively) could shape the way in which parasitoids make use of chemical cues from the host habitat. We assessed innate preference in the fruit fly parasitoid Diachasmimorpha longicaudata among chemical cues from four host habitats (apple, fig, orange and peach) using a Y-tube olfactometer. Contrary to what was predicted, we found a hierarchic pattern of preference. The parasitism rate realized on these fruit species and the weight of the host correlates positively, to some extent, with the preference pattern, whereas preference did not correlate with survival and fecundity of the progeny. As expected for a parasitoid foraging for generalist hosts, habitat preference changed markedly depending on their previous experience and the abundance of hosts. These findings suggest that the pattern of preference for host habitats is attributable to differences in encounter rate and host quality. Host habitat preference seems to be, however, quite plastic and easily modified according to the information obtained during foraging.     

Behavioral responses of the parasitoid Psyllaephagus pistaciae (Hymenoptera: Encyrtidae) to host plant volatiles and honeydew

The behavioral responses of the parasitoid Psyllaephagus pistaciae, the major biocontrol agent of the common pistachio psylla, Agonoscena pistaciae, to volatiles emanating from its host plant and host honeydew, were examined using a four‐arm airflow olfactometer. In addition, the arrestment behavior of this parasitoid on clean and honeydew‐treated leaves of the pistachio, Pistacia vera, was monitored. The infested pistachio leaves were the most favored source of the volatile attracting the parasitoids. The parasitoid clearly distinguished and responded to infochemicals emitted by psyllid honeydew but at a lower level than to the volatiles from infested host plants. However, the searching time, locomotory behavior, antennal drumming and ovipositor probing were all affected when they encountered honeydew‐contaminated zones on pistachio leaves. These findings suggest that the psyllid honeydew releases kairomones that stimulate the parasitoids to greater searching activity, as well as providing a directional cue. The intensive searching activities in the presence of the volatiles tested were very similar to responses by the parasitoid females when encountering patches treated with psyllid honeydew. Such behavior could retain the parasitoid in a favorable area, thereby increasing the probability of additional host encounters.     

Searching for Food or Hosts: The Influence of Parasitoids Behavior on Host–Parasitoid Dynamics

A host–parasitoid system with overlapping generations is considered. The dynamics of the system is described by differential equations with a control parameter describing the behavior of the parasitoids. The control parameter models how the parasitoids split their time between searching for hosts and searching for non-host food. The choice of the control parameter is based on the assumption that each parasitoid maximizes the instantaneous growth rate of the number of copies of its genotype. It is shown that optimal individual behavior of parasitoids, with respect to time sharing between hosts and food searching, may have a stabilizing effect on the host–parasitoid dynamics.     

Exploitation of the Host's Chemical Communication in a Parasitoid Searching for Concealed Host Larvae

We found empirical evidence for the exploitation of the host's chemical communication in a parasitic wasp foraging for a concealed host. Female Halticoptera laevigata wasps (Hym., Pteromalidae) searched longer and probed more frequently on honeysuckle fruit that carried fresh marking pheromone or harbored a first instar larva of its host, the tephritid fruit fly, Myoleja lucida . They further increased their searching efforts on fruits that provided both host-related cues. While the exploitation of host marking pheromones for host location had previously been shown in two parasitoid species attacking the eggs of their tephritid hosts, this is the first evidence for the exploitation of a host's marking pheromone in a parasitoid attacking the larvae of an herbivorous host. Taking into account the time interval between application of host marking pheromones and parasitoid attack plus the fact that these pheromones are generally water soluble and thus might be washed off by rains, we discuss the reliability-detectability problem for the exploitation of those cues for host location in parasitoids attacking a larval host.