Flagellar sensilla in male and female European beewolves, Philanthus triangulum F. (Hymenoptera: Sphecidae)

We investigated the morphology of the antennal sensilla of a sphecid wasp, the European beewolf Philanthus triangulum, to provide an inventory for the species and to compare the sensillar equipment between the sexes. The density of sensilla increased from the base to the tip of the antennae. We distinguished nine different types of sensilla. One type has not yet been described in Hymenoptera. The large sensilla basiconica occurred only on the antennae of female beewolves. We discuss the functional significance of the difference between the sexes and compare our results with data from other sphecids and the honeybee Apis mellifera

Sexual selection and the evolution of male pheromone glands in philanthine wasps (Hymenoptera, Crabronidae)

Background: Sexual selection is thought to promote evolutionary changes and diversification. However, the impact of sexual selection in relation to other selective forces is difficult to evaluate. Male digger wasps of the tribe Philanthini (Hymenoptera, Philanthinae) scent mark territories to attract receptive females. Consequently, the organs for production and storage of the marking secretion, the mandibular gland (MG) and the postpharyngeal gland (PPG), are subject to sexual selection. In female Philanthini, these glands are most likely solely subject to natural selection and show very little morphological diversity. According to the hypothesis that sexual selection drives interspecific diversity, we predicted that the MG and PPG show higher interspecific variation in males than in females. Using histological methods, 3D-reconstructions, and multivariate statistical analysis of morphological characters, we conducted a comparative analysis of the MG and the PPG in males of 30 species of Philanthini and three species of the Cercerini and Aphilanthopsini, two related tribes within the Philanthinae. Results: We found substantial interspecific diversity in gland morphology with regard to gland incidence, size, shape and the type of associated secretory cells. Overall there was a phylogenetic trend: Ensuing from the large MGs and small PPGs of male Cercerini and Aphilanthopsini, the size and complexity of the MG was reduced in male Philanthini, while their PPG became considerably enlarged, substantially more complex, and associated with an apparently novel type of secretory cells. In some clades of the Philanthini the MG was even lost and entirely replaced by the PPG. However, several species showed reversals of and exceptions from this trend. Head gland morphology was significantly more diverse among male than among female Philanthinae. Conclusion: Our results show considerable variation in male head glands including the loss of an entire gland system and the evolution of a novel kind of secretory cells, confirming the prediction that interspecific diversity in head gland morphology is higher in male than in female Philanthini. We discuss possible causes for the remarkable evolutionary changes in males and we conclude that this high diversity has been caused by sexual selection

A cuckoo in wolves' clothing? Chemical mimicry in a specialized cuckoo wasp of the European beewolf (Hymenoptera, Chrysididae and Crabronidae)

<p>Abstract</p> <p>Background</p> <p>Host-parasite interactions are among the most important biotic relationships. Host species should evolve mechanisms to detect their enemies and employ appropriate counterstrategies. Parasites, in turn, should evolve mechanisms to evade detection and thus maximize their success. Females of the European beewolf (<it>Philanthus triangulum</it>, Hymenoptera, Crabronidae) hunt exclusively honeybee workers as food for their progeny. The brood cells containing the paralyzed bees are severely threatened by a highly specialized cuckoo wasp (<it>Hedychrum rutilans</it>, Hymenoptera, Chrysididae). Female cuckoo wasps enter beewolf nests to oviposit on paralyzed bees that are temporarily couched in the nest burrow. The cuckoo wasp larva kills the beewolf larva and feeds on it and the bees. Here, we investigated whether <it>H. rutilans </it>evades detection by its host. Since chemical senses are most important in the dark nest, we hypothesized that the cuckoo wasp might employ chemical camouflage.</p> <p>Results</p> <p>Field observations suggest that cuckoo wasps are attacked by beewolves in front of their nest, most probably after being recognized visually. In contrast, beewolves seem not to detect signs of the presence of these parasitoids neither when these had visited the nest nor when directly encountered in the dark nest burrow.</p> <p>In a recognition bioassay in observation cages, beewolf females responded significantly less frequently to filter paper discs treated with a cuticular extract from <it>H. rutilans </it>females, than to filter paper discs treated with an extract from another cuckoo wasp species (<it>Chrysis viridula</it>). The behavior to paper discs treated with a cuticular extract from <it>H. rutilans </it>females did not differ significantly from the behavior towards filter paper discs treated with the solvent only.</p> <p>We hypothesized that cuckoo wasps either mimic the chemistry of their beewolf host or their host's prey. We tested this hypothesis using GC-MS analyses of the cuticles of male and female beewolves, cuckoo wasps, and honeybee workers. Cuticle extracts of <it>Hedychrum nobile </it>(Hymenoptera: Chrysididae) and <it>Cerceris arenaria </it>(Hymenoptera: Crabronidae) were used as outgroups. There was little congruence with regard to cuticular compounds between <it>H. rutilans </it>females and honeybees as well as females of <it>C. arenaria </it>and <it>H. nobile</it>. However, there was a considerable similarity between beewolf females and <it>H. rutilans </it>females. Beewolf females show a striking dimorphism regarding their cuticular hydrocarbons with one morph having (<it>Z</it>)-9-C25:1 and the other morph having (<it>Z</it>)-9-C27:1 as the major component. <it>H. rutilans</it> females were more similar to the morph having (Z)-9-C27:1 as the main component.</p> <p>Conclusion</p> <p>We conclude that <it>H. rutilans </it>females closely mimic the composition of cuticular compounds of their host species <it>P. triangulum</it>. The occurrence of isomeric forms of certain compounds on the cuticles of the cuckoo wasps but their absence on beewolf females suggests that cuckoo wasps synthesize the cuticular compounds rather than sequester them from their host. Thus, the behavioral data and the chemical analysis provide evidence that a specialized cuckoo wasp exhibits chemical mimicry of the odor of its host. This probably allows the cuckoo wasp to enter the nest with a reduced risk of being detected by olfaction and without leaving traitorous chemical traces.</p

Nitric oxide radicals are emitted by wasp eggs to kill mold fungi

Detrimental microbes caused the evolution of a great diversity of antimicrobial defenses in plants and animals. Insects developing underground seem particularly threatened. Here we show that the eggs of a solitary digger wasp, the European beewolf Philanthus triangulum, emit large amounts of gaseous nitric oxide (NO center dot) to protect themselves and their provisions, paralyzed honeybees, against mold fungi. We provide evidence that a NO-synthase (NOS) is involved in the generation of the extraordinary concentrations of nitrogen radicals in brood cells (similar to 1500 ppm NO center dot and its oxidation product NO2 center dot). Sequencing of the beewolf NOS gene revealed no conspicuous differences to related species. However, due to alternative splicing, the NOS-mRNA in beewolf eggs lacks an exon near the regulatory domain. This preventive external application of high doses of NO center dot by wasp eggs represents an evolutionary key innovation that adds a remarkable novel facet to the array of functions of the important biological effector NO center dot

The Chemistry of the Postpharyngeal Gland of Female European Beewolves

Females of the European beewolf, Philanthus triangulum, possess a large glove-shaped gland in the head, the postpharyngeal gland (PPG). They apply the content of the PPG to their prey, paralyzed honeybees, where it delays fungal infestation. Here, we describe the chemical composition of the gland by using combined GC-MS, GC-FTIR, and derivatization. The PPG of beewolves contains mainly long-chain unsaturated hydrocarbons (C23–C33), lower amounts of saturated hydrocarbons (C14–C33), and minor amounts of methyl-branched hydrocarbons (C17–C31). Additionally, the hexane-soluble gland content is comprised of small amounts of an unsaturated C25 alcohol, an unknown sesquiterpene, an octadecenylmethylester, and several long-chain saturated (C25, C27) and unsaturated (C23–C27) ketones, some of which have not yet been reported as natural products. Surprisingly, we found a dimorphism with regard to the major component of the PPG with some females having (Z)-9-pentacosene, whereas others have (Z)-9-heptacosene as their predominant component. The biological relevance of the compounds for the prevention of fungal growth on the prey and the significance of the chemical dimorphism are discussed

Die Evolution des Pheromonkommunikationssystems des Europäischen Bienenwolfs Philanthus triangulum F. (Hymenoptera: Crabronidae)

Darwin’s theory of sexual selection explains the evolution of flamboyant male traits through female choice. It does not, however, address the question why males typically court and females choose. This asymmetry is now thought to be the result of the dichotomy in reproductive expenditures: Females invest primarily in parental care and males invest predominantly in mate attraction or competition. Based on this view, several hypotheses for the origin and maintenance of female preferences have been proposed. They include the classical sexual selection models, i.e. female choice for direct and indirect benefits as well as the more recent concepts of female choice for genetic compatibility and receiver bias models. The complementary choice scenario assumes that females choose mates with regard to genetic compatibility. The receiver bias concept views male traits and female preferences within the framework of communication theory and encompasses various more or less distinct models, two of which are sensory exploitation and sensory trap. Both models postulate that male signals evolved in response to pre-existing perceptual biases of females. The sensory trap hypothesis additionally emphasizes that pre-existing female preferences for certain cues evolved in non-sexual contexts, like e.g. foraging. Males that mimic these cues and elicit a favourable out-of-context response by females may increase their reproductive success. This thesis examines the evolution of the pheromone communication in the European Beewolf Philanthus triangulum. Beewolf females are specialized hunters of honeybees and provision their progeny with paralyzed prey. Male beewolves establish and scent mark territories with a pheromone from a head gland to court females. The concordant occurrence of the otherwise rare alcohol (Z)-11-eicosen-1-ol in the male pheromone and in the alarm pheromone of honeybees, the exclusive prey of the females, suggests a sensory trap process as an explanation for the evolution of the male pheromone in P. triangulum. According to this hypothesis, we tested three predictions: First, foraging honeybees should emit eicosenol. Via chemical analysis we could show that honeybee workers in fact smell of eicosenol during foraging. The occurrence of eicosenol on the cuticle and in the headspace of honeybees is a new finding. Second, beewolf females should use eicosenol as a cue for prey detection or identification. Using behavioural assays, we demonstrated that prey recognition in beewolf females is accomplished by olfactory cues and that eicosenol is an essential cue in this process. The sensory sensitivity of beewolf females to eicosenol must be extremely high, since they perceive the trace amounts present in the head space of honeybees. This sensitivity may be due to specialized olfactory receptors on the antennae of beewolf females. An inventory of the flagellar sensilla of both sexes showed that females carry one type of sensillum that is missing in males, the large sensillum basiconicum. This chemo-sensitive sensillum most likely plays a role in prey recognition. The third prediction is that beewolf males incorporate bee-like substances, including eicosenol, into their pheromone, and possibly catch females in a sensory trap. A reanalysis of the male pheromone revealed, among others, eicosenol and several alkanes and alkenes as pheromonal compounds. Our own analyses of the chemical profiles of honeybee workers and beewolf pheromone disclosed a surprisingly strong resemblance between the two. Eight of the eleven substances of the male pheromone are also present on the cuticle and in the headspace of honeybees. Notwithstanding this similarity, the male pheromone does not function as a sensory trap for females. Nevertheless, the extensive congruence between the odour bouquets of the females’ prey and the male pheromone strongly suggests that the male signal evolved to exploit a pre-existing female sensory bias towards bee odour, and, thus represents a case of sensory exploitation. In addition to the above described scenario concerning mostly the ‘design’ of the male pheromone, we addressed possible indirect benefits female beewolves may gain by basing their mating decisions on signal ‘content’. We show that the pheromone of male beewolves varies between families and may, thus, contain information about the degree of relatedness between the female and a potential mate. Females could use this information to choose genetically complementary males to avoid inbreeding and the production of infertile diploid sons. Collectively, our results provide strong evidence for a receiver bias process in the evolution of the male pheromone of P. triangulum. They further indicate that the pheromone composition may subsequently have been influenced by other natural or sexual selection pressures, like e.g. complementary female choice.Darwins Theorie der Sexuellen Selektion deutet die Evolution übersteigerter Männchenmerkmale als Ergebnis der Weibchenwahl. Sie erklärt jedoch nicht, warum Männchen in der Regel um Weibchen werben und Weibchen unter den werbenden Männchen wählen. Man glaubt heute, daß dies auf eine Asymmetrie im reproduktiven Aufwand zwischen den Geschlechtern zurückzuführen ist: Weibchen investieren überwiegend in elterliche Fürsorge, Männchen v.a. in Balzsignale. Hierauf basierend wurden mehrere Hypothesen zur Evolution von Präferenzen bei weiblicher Partnerwahl vorgeschlagen. Dazu gehören die klassischen Modelle der Sexuellen Selektion, wie ‚direct’ und ‚indirect benefit’ sowie die neueren Konzepte der Weibchenwahl aufgrund genetischer Kompatibilität und die 'Receiver Bias' Modelle. Letztere betrachten Männchenmerkmale und Weibchenpräferenzen im Rahmen der Kommunikationstheorie und umfassen mehrere ähnliche Modelle wie z.B. 'Sensory Exploitation' und 'Sensory Trap'. Sie postulieren, daß das Design von Männchensignalen in Anpassung an existierende Präferenzen der Weibchen entsteht. Die 'Sensory Trap' Hypothese betont zudem, daß diese sensorischen Präferenzen der Weibchen für bestimmte Signale in einem der natürlichen Selektion unterliegenden (nicht sexuellen) Kontext entstanden, so z.B. zum Auffinden von Nahrung. Männchen imitieren diese Signale um vorteilhafte Reaktionen der Weibchen auszulösen und so ihren Reproduktionserfolg zu erhöhen. Die vorliegende Dissertation untersucht die Evolution der Pheromonkommunikation des Europäischen Bienenwolfs. Bienenwolfweibchen sind spezialisierte Jäger der Honigbiene und versorgen ihre Nachkommen mit gelähmter Beute. Bienenwolfmännchen etablieren Reviere und markieren diese mit einem Pheromon um Weibchen anzulocken. Das übereinstimmende Vorkommen des sonst sehr seltenen Alkohols (Z)-11-Eicosen-1-ol sowohl im Pheromon der Männchen als auch im Alarmpheromon der Honigbienen, der ausschließlichen Beute der Weibchen, deutete darauf hin, daß es sich bei dem Pheromon um eine 'Sensory Trap' für Weibchen handeln könnte. Entsprechend dieser Hypothese testeten wir drei Vorhersagen: Erstens, furagierende Honigbienen sollten nach Eicosenol riechen. Mit Hilfe chemischer Analysen konnten wir erstmals zeigen, daß Honigbienensammlerinnen nach Eicosenol riechen. Zweitens sollten Bienenwolfweibchen Eicosenol für die Identifikation ihrer Beute nutzen. Wie wir in unseren Verhaltenstests zeigen konnten, verlassen sich die Weibchen für die Beuteerkennung auf Duftsignale. Hierbei ist Eicosenol eine notwendige Komponente für die Identifizierung der Honigbienen. Die sensorische Empfindlichkeit der Weibchen für Eicosenol scheint extrem hoch zu sein, da sie diese nur in Spuren im Luftraum um Honigbienen vorhandene Substanz, wahrnehmen können. Die hohe sensorische Empfindlichkeit der Weibchen könnte durch spezialisierte olfaktorische Rezeptoren bedingt sein. Die Analyse der antennalen Sensillen zeigte, daß Weibchen einen Sensillentyp besitzen, der bei Männchen nicht vorkommt: die großen Sensilla basiconica. Diese chemosensitiven Sensillen könnten eine entscheidende Rolle bei der Beuteerkennung spielen. Die dritte Vorhersage ist, daß Bienenwolfmännchen die für Honigbienen typischen Substanzen, darunter auch Eicosenol, in ihr Pheromon integrieren, um Weibchen in einer 'Sensory Trap' zu fangen. Eine Neuanalyse des Männchenpheromons zeigte, u.a. Eicosenol und einige Alkane und Alkene als Pheromonbestandteile. Unsere Analysen zeigten eine überraschende Übereinstimmung der chemischen Profile von Honigbienen und Bienenwolfmännchen. Acht der elf Substanzen des Pheromons finden sich auch im Duft der Honigbiene. Trotz dieser erstaunlichen Ähnlichkeit fungiert das Männchenpheromon nicht als 'Sensory Trap' für Weibchen. Die ausgeprägte Kongruenz der Düfte von Weibchenbeute und Männchenpheromon deutet aber darauf hin, daß bei der Evolution des Männchenpheromons vermutlich eine bereits existierende sensorische Präferenz der Weibchen für Bienenduft ausgenutzt wurde, d.h. daß es sich dabei um 'Sensory Exploitation' handelt. Das oben beschriebene Szenario für die Evolution des Männchenpheromons betrifft hauptsächlich das Design des Männchensignals. Darüber hinaus haben wir den möglichen Informationsgehalt des Pheromons untersucht. Das Pheromonmuster variiert beim Europäischen Bienewolf mit der Familienzugehörigkeit. Das Pheromon könnte somit Information über den Verwandtschaftsgrad zwischen einem Weibchen und einem potentiellen Paarungspartner enthalten. Weibchen könnten diese Information nutzen um sich nur mit genetisch kompatiblen Männchen zu paaren und auf diese Weise Inzucht zu vermeiden. Die vorliegenden Ergebnisse liefern starke Evidenzen für einen 'Receiver Bias' Prozess bei der Evolution des Pheromons von P. triangulum. Sie deuten außerdem darauf hin, daß die Zusammensetzung des Pheromons in der Folge durch weitere Selektionsdrücke, wie z.B. Weibchenwahl für genetische Kompatibilität, beeinflusst wurde

Morphology and ultrastructure of the allomone and sex-pheromone producing mandibular gland of the parasitoid wasp Leptopilina heterotoma (Hymenoptera: Figitidae)

Chemical communication by the parasitoid wasp Leptopilina heterotoma is based largely on (-)-iridomyrmecin. The female wasps use (-)-iridomyrmecin as a defensive allomone, a chemical cue to avoid competition with con- and heterospecific females, and as a major component of their sex pheromone to attract males. Males of L heterotoma produce (+)-isoiridomyrmecin, which is also used for chemical defense. In this study we show that females and males of L. heterotoma produce the iridomyrmecins in a pair of mandibular glands. Each gland consists of a secretory part composed of class 3 gland cells and their accompanying duct cells, as well as a reservoir bordered by a thin intima. The gland discharges between the mandible base and the clypeus. Males have considerably smaller glands than females, which corresponds to the lower amount of iridomyrmecins produced by males. Chemical analyses of the mandibular gland contents showed that the gland of females contained mainly (-)-iridomyrmecin, as well as low amounts of the other previously described iridoid pheromone compounds, while the glands of males contained only (+)-isoiridomyrmecin. The morphology and sizes of the mandibular glands of males and females of L. heterotoma have evolved to the multi-functional use of iridomyrmecin. (C) 2016 Elsevier Ltd. All rights reserved

Multifaceted Defense against Antagonistic Microbes in Developing Offspring of the Parasitoid Wasp Ampulex compressa (Hymenoptera, Ampulicidae)

Effective antimicrobial strategies are essential adaptations of insects to protect themselves, their offspring, and their foods from microbial pathogens and decomposers. Larvae of the emerald cockroach wasp, Ampulex compressa, sanitize their cockroach hosts, Periplaneta americana, with a cocktail of nine antimicrobials comprising mainly (R)-(-)-mellein and micromolide. The blend of these antimicrobials has broad-spectrum antimicrobial activity. Here we explore the spatiotemporal pattern of deployment of antimicrobials during the development from egg to adult as well as their physicochemical properties to assess how these aspects may contribute to the success of the antimicrobial strategy. Using gas chromatography/mass spectrometry (GC/MS) we show that larvae start sanitizing their food as soon as they have entered their host to feed on its tissue. Subsequently, they impregnate the cockroach carcass with antimicrobials to create a hygienic substrate for cocoon spinning inside the host. Finally, the antimicrobials are incorporated into the cocoon. The antimicrobial profiles on cockroach and wasp cocoon differed markedly. While micromolide persisted on the cockroaches until emergence of the wasps, solid-phase microextraction sampling and GC/MS analysis revealed that (R)-(-)-mellein vaporized from the cockroaches and accumulated in the enclosed nest. In microbial challenge assays (R)-(-)-mellein in the headspace of parasitized cockroaches inhibited growth of entomopathogenic and opportunistic microbes (Serratia marcescens, Aspergillus sydowii, Metarhizium brunneum). We conclude that, in addition to food sanitation, A. compressa larvae enclose themselves in two defensive walls by impregnating the cocoon and the cockroach cuticle with antimicrobials. On top of that, they use vaporous (R)-(-)-mellein to sanitize the nest by fumigation. This multifaceted antimicrobial defense strategy involving the spatially and temporally coordinated deployment of several antimicrobials in solution and vapor form has apparently evolved to reliably protect the larvae themselves and their food against a broad range of antagonistic microbes

Comparative morphology of the postpharyngeal gland in the Philanthinae (Hymenoptera, Crabronidae) and the evolution of anantimicrobial brood protection mechanism

Background Hymenoptera that mass-provision their offspring have evolved elaborate antimicrobial strategies to ward off fungal infestation of the highly nutritive larval food. Females of the Afro-European Philanthus triangulum and the South American Trachypus elongatus (Crabronidae, Philanthinae) embalm their prey, paralyzed bees, with a secretion from a complex postpharyngeal gland (PPG). This coating consists of mainly unsaturated hydrocarbons and reduces water accumulation on the prey’s surface, thus rendering it unfavorable for fungal growth. Here we (1) investigated whether a North American Philanthus species also employs prey embalming and (2) assessed the occurrence and morphology of a PPG among females of the subfamily Philanthinae in order to elucidate the evolution of prey embalming as an antimicrobial strategy. Results We provide clear evidence that females of the North American Philanthus gibbosus possess large PPGs and embalm their prey. The comparative analyses of 26 species from six genera of the Philanthinae, using histological methods and 3D-reconstructions, revealed pronounced differences in gland morphology within the subfamily. A formal statistical analysis based on defined characters of the glands confirmed that while all members of the derived tribe Philanthini have large and complex PPGs, species of the two more basal tribes, Cercerini and Aphilanthopsini, possess simple and comparatively small glands. According to an ancestral state reconstruction, the complex PPG most likely evolved in the last common ancestor of the Philanthini, thus representing an autapomorphy of this tribe. Conclusion Prey embalming, as described for P. triangulum and T. elongatus, and now also for P. gibbosus, most probably requires a complex PPG. Hence, the morphology and size of the PPG may allow for inferences about the origin and distribution of the prey embalming behavior within the Philanthinae. Based on our results, we suggest that prey embalming has evolved as an antimicrobial strategy in and is restricted to the tribe Philanthini, which seems to face exceptional threats with regard to fungal infestations of their larval provisions