Phylogenetic relationships among the microgastroid wasps (Hymenoptera: braconidae): combined analysis of 16S and 28S rDNA genes and morphological data

Relationships among the microgastroid complex of braconid wasps were investigated using sequence data from the 16S mitochondrial rDNA and 28S (D2 expansion region) nuclear rDNA genes, as well as morphological data. Parsimony analysis of these gene fragments, both separately and combined, indicated that Neoneurus (Neoneurinae) and Ichneutes (Ichneutinae) were no more closely related to the microgastroids than were a range of helconoid taxa. Combined parsimony analysis of the microgastroids indicated the relationships ((Cardiochilinae + Microgastrinae) + Miracinae) + Cheloninae, with Adeliinae falling inside the Cheloninae. Bootstrap proportions for each of these nodes were greater than 70%. Character reweighting (sensu Farris), using the rescaled consistency index, also recovered these relationships. Mapping of lifestyle traits onto this relatively well supported phylogeny indicated that solitary endoparasitism is ancestral for the microgastroids, with a single origin for egg-larval endoparasitism in the Cheloninae + Adeliinae. Mapping of the radiation of the microgastroids into lepidopteran hosts was less clear, due to the specialized biology of the most basal microgastroid clade, the Cheloninae + Adeliinae. Our data are consistent with attack of concealed lepidopteran hosts as the plesiomorphic lifestyle, at least for the Miracinae + Cardiochilinae + Microgastrinae, with radiation into more exposed hosts in the Cardiochilinae + Microgastrinae.     

New insights into the population biology of endoparasitic Rafflesiaceae

Parasitic plants demonstrate a diversity of growth strategies, life histories, and developmental and physiological characteristics. Most research to date has focused on a narrow range of parasitic taxa, particularly in the Orobanchaceae, while the other independent origins of parasitism have largely gone unstudied. One type of parasite that has received relatively little attention are the endophytic parasites, which have a fascinating growth strategy where the parasite is embedded within the host tissue, with the flower the only externally visibly plant part. Endophytic growth makes it challenging to understand basic aspects of species biology, such as the size of a given parasite, the number of parasites per host, and the genetic diversity of populations. Recent studies by Barkman et al. (2017) and Pelser et al. (2017) have used microsatellite genotyping to investigate the population biology of endoparasitic Rafflesiaceae species in Asia. They show the potential for extensive parasite spread within a host vine and the strong partitioning of genetic diversity by host. These species are also shown to have an outcrossing mating system. However, these studies suggest different reproductive strategies, one supporting monoecy and one suggesting dioecy. Overall, these studies partly “lift the lid” on the cryptic biology of Rafflesia and the Rafflesiaceae and open the door for future comparative studies between endophytic and free-living parasitic plants.     

Postembryonic development of the sea spider Ammothella biunguiculata (Pycnogonida,Ammotheidae) endoparasitic to an actinian Entacmaea quadricolor (Anthozoa,Stichodactylidae) in Izu Peninsula,Japan

Postembryonic developmental stages of an endoparasitic pycnogonid, Ammothella biunguiculata in Izu Peninsula, Japan are described. Eleven stages were identified beginning with a protonymphon larva attached to the male oviger. We found endoparasitic individuals in the host actinian from the second to tenth instar, and forms in the ninth stage to adult were found free-living. This indicates a transition from being endoparasitic to free-living during the ninth to tenth instar stages. The first instar protonymphon attached to the adult male oviger has a gland duct on the anterior margin of each chelifore scape which completely disappears with the second instar. The disappearance of the chelifore gland duct coincides with the beginning of an endoparasitic stage in the development of this species. Although the larval morphology and the postembryonic development of pycnogonids have been summarized by several authors, the present study concludes that much remains to be learnt.     

Seed weevils living on the edge: pressures and conflicts over body size in the endoparasitic Curculio larvae

Abstract 1. Body size in parasitic insects can be subjected to contrasting selective pressures, especially if they complete their development within a single host. On the one hand, a larger body size is associated with a higher fitness. On the other hand, the host offers a discrete amount of resources, thus constraining the evolution of a disproportionate body size. 2. The present study used the weevil Curculio elephas as a study model. Larvae develop within a single acorn, feeding on its cotyledons, and larval body size is strongly related to individual fitness. 3. The relationship between larval and acorn size was negatively exponential. Larval growth was constrained in small acorns, which did not provide enough food for the weevils to attain their potential size. Larval size increased and levelled off in acorns over a certain size (inflexion point), in which cotyledons were rarely depleted. When there were more than one larva per acorn, a larger acorn was necessary to avoid food depletion. 4. The results show that C. elephas larvae are sometimes endoparasitic, living on the edge of host holding capacity. If they were smaller they could avoid food depletion more easily, but the fitness benefits linked to a larger size have probably promoted body size increase. The strong negative effects of conspecific competition may have possibly influenced female strategy of laying a single egg per seed. 5. Being larger and fitter, but always within the limits of the available host sizes, may be one main evolutionary dilemma in endoparasites.     

Immunological Detection of Hymenopteran Parasitism inHelicoverpa zeaandHeliothis virescens

We have developed a monoclonal antibody that recognizes the larval and adult stages ofMicroplitis croceipes(Cresson) (Hymenoptera: Braconidae) andCotesia marginiventris(Cresson) (Hymenoptera: Braconidae), two principal endoparasitoids of the polyphagous pestsHelicoverpa zea(Boddie) (Lepidoptera: Noctuidae) andHeliothis virescens(F.) (Lepidoptera: Noctuidae). The antibody has been incorporated into an indirect enzyme-linked immunosorbent assay that can be used to distinguish parasitized from unparasitized pests. The antibody cross-reacts with several different hymenopteran parasitoids, but not with any of the noctuid pests we have assayed. An immunoassay based on a broadly reactive antibody such as this one enables comprehensive detection of hymenopteran parasitism with a single antibody reagent.     

Evolutionary expansion of the Monogenea

The evolutionary expansion of the monogeneans has taken place in parallel with the diversification of the fish-like vertebrates. In this article the main trends in monogenean evolution are traced from a hypothetical skin-parasitic ancestor on early vertebrates. Special consideration is given to the following topics: early divergence between skin feeders and blood feeders; diversification and specialization of the haptor for attachment to skin; transfer from host to host, viviparity and the success of the gyrodactylids; predation on skin parasites and camouflage; colonization of the buccal and branchial cavities; diversification and specialization of the haptor for attachment to the gills; phoresy in gill parasites; the development of endoparasitism and the origin of the cestodes; the success of dactylogyroidean gill parasites; the uniqueness of the polyopisthocotyleans; ovoviviparity and the colonization of the tetrapods. Host specificity has been the guiding force of coevolution between monogeneans and their vertebrate hosts, but the establishment of monogeneans on unrelated hosts sharing the same environment (host-switching) may have been underestimated. Host-switching has provided significant opportunities for evolutionary change of direction and is probably responsible for the establishment of monogeneans on cephalopod molluscs, on the hippopotamus and possibly on chelonians. There are indications that host-switching may be more common in monogeneans that spread by direct transfer of adults/juveniles from host to host. A limitation on the further expansion of monogeneans is the need for water for the dispersal of the infective larva (oncomiracidium).     

Bionomics and morphological and molecular characterization of Elasmus schmitti and Baryscapus elasmi (Hymenoptera: Chalcidoidea, Eulophidae), parasitoids associated with a paper wasp, Polistes dominulus (Vespoidea, Vespidae)

Elasmus schmitti and Baryscapus elasmi have been recorded in southern Ukraine as gregarious parasitoids in the nests of the paper wasps Polistes dominulus and Polistes nimphus. Polistes dominulus nests infested with E. schmitti were less productive than uninfested nests in only one year (2004) of the three years of the present study, when an increase in the host population size occurred. Females of E. schmitti are synovigenic, and they lay their eggs on the skins of P. dominulus last instar larvae, without paralyzing the host. Rather, the parasitoid larvae feed on young host pupae. The pupae of E. schmitti are isolated from the host remnants by a thin fecal partition as in Elasmus polistis and Elasmus japonicus, other paper wasp parasitoids. Baryscapus elasmi is a pupal endoparasitoid of E. schmitti. The females of B. elasmi emerge without mature eggs in their ovaries and mate with males. They penetrate the paper wasp’s cells with their ovipositor and feed on the extracted hemolymph exudate. Pupation of B. elasmi occurs inside or outside the pupa of the host, E. schmitti. If inside, then the cranial end of the pupa and the adult emergence hole of B. elasmi are situated in the caudal ends of the pupae of their hosts. Comparative notes and illustrations on the morphology of adults are provided, and DNA sequences of three genes (nuclear 28S D2 rDNA, mitochondrial cytochrome oxidase subunit I, and mitochondrial cytochrome b) were obtained for both parasitoid species. The similarity of the 28S D2 sequences of E. schmitti and E. polistis relative to other available Elasmus sequences suggests a single origin of parasitism on paper wasps in this genus.     

Sperm transfer mechanisms: some correlates and consequences

Abstract

The methods by which the Metazoa bring their gametes into juxtaposition as a preliminary to fertilisation are reviewed. The method of sperm transfer employed by a particular organism or group of organisms is commonly more directly related to habitat than to phylogeny. This appears in part to be a consequence of certain methods of sperm transfer facilitating the exploitation of particular habitats. Non-exposure of sperm to hostile influences such as fresh water, digestive enzymes, antibodies, or the desiccating effects of air may have been important in the colonisation of fresh waters by animals with body fluids of high osmolarity, in the establishment of the endoparasitic habit, and in the colonisation of dry land. Mutual exchange of sperm with equal sharing of the reproductive burden by means of hermaphroditism, coupled with internal fertilisation, is seen as an important adaptation to very small body size, especially as associated with life in interstitial habitats. Efficient transfer of sperm, usually in conjunction with internal fertilisation, is seen as a prerequisite for the development of yolky eggs with fairly direct development of the young. It is also a prerequisite for establishing maternal nourishment of the young in viviparity and a consequent reduction or suppression of free larval stages. Yolky eggs confer freedom from the vicissitudes of fluctuation in larval food supplies, and eggs which contain all or most of the mineral salts required for development seem necessary for colonisation of fresh waters. Amongst freshwater fishes and anurans, close pairing of male and female minimises the effects of rapid destruction of sperm in species which do not copulate or use spermatophores.     

Ultrastructure of the haustorium of Trenomyces histophthorus and adjacent host cells

The haustorium of Trenomyces histophthorus (Ascomycetes, Laboulbeniales) appears to be enucleate and aseptate; its bulbs, isthmuses, and tubules contain abundant mitochondria and are often vacuolate. Although host cells around some bulbs appear to be unaffected, most host cells in contact with the haustorial tubules are in various stages of degeneration. In some instances deterioration of the tissues of the mallophagan host apparently occurs in advance of the haustorial tips.