Project description:Although host-parasitoid interactions are becoming well characterized at the organismal and cellular levels, much remains to be understood of the molecular bases for the host immune response and the parasitoids’ ability to defeat this immune response. Leptopilina boulardi and L. heterotoma, two closely related, highly infectious natural parasitoids of Drosophila melanogaster, appear to use very different infection strategies at the cellular level. Here, we further characterize cellular level differences in the infection characteristics of these two wasp species using newly derived, virulent inbred strains, and then use whole genome microarrays to compare the transcriptional response of Drosophila to each. While flies attacked by the melanogaster group specialist Leptopilina boulardi (strain Lb17) up-regulate numerous genes encoding proteolytic enzymes, components of the Toll and JAK/STAT pathways, and the melanization cascade as part of a combined cellular and humoral innate immune response, flies attacked by the generalist L. heterotoma (strain Lh14) do not appear to initiate an immune transcriptional response at the time points post-infection we assayed, perhaps due to the rapid venom-mediated lysis of host hemocytes (blood cells). Thus, the specialist parasitoid appears to invoke a full-blown immune response in the host, but suppresses and/or evades downstream components of this response. Given that activation of the host immune response likely depletes the energetic resources of the host, the specialist’s infection strategy seems relatively disadvantageous. However, we uncover the mechanism for one potentially important fitness tradeoff of the generalist’s highly immune suppressive infection strategy. Experiment Overall Design: The parasitoid wasps L. boulardi and L. heterotoma were allowed to attack late second instar D. melanogaster larvae (72 hrs old at 22˚C) in the following manner. Nine petri dishes containing 60 fly larvae were each exposed to six experienced L. boulardi (strain Lb17) female wasps for 2 hrs, another nine plates were exposed to five L. heterotoma (strain Lh14) females, and nine control plates were left uninfected. For each of three time points post-infection (2-5 hrs, 9-12 hrs, 21-24 hrs), 40 larvae from three replicate plates were removed and frozen at -80˚C for RNA extraction and microarray analysis (3 treatments x 3 time points x 3 replicates = 27 samples total).

Project description:Parasitoid wasps inject venom containing complex bioactive compounds to regulate the immune response and development of host arthropods and sometime paralyze host arthropods. Although extensive studies have been conducted on the identification of venom proteins in larval parasitoids, relatively few studies have examined the pupal parasitoids. Hereby, proteomic method was used to identify putative venom proteins from P. vindemmiae, an ectoparasitoid of Drosophila.

Project description:Among the parasites of insects, endoparasitoids impose a costly challenge to host defenses because they use their host’s body for the development and maturation of their eggs or larvae, and ultimately kill the host. Tachinid flies are highly specialized acoustically-orienting parasitoids that release first instar mobile larvae which burrow into the host’s body to feed. We investigated the possibility that Teleogryllus oceanicus field crickets employ post-infestation strategies to maximize survival when infested with the larvae of the parasitoid fly Ormia ochracea. Using crickets from the Hawaiian island of Kauai, where the parasitoid is present, and crickets from the Cook Islands (Mangaia), where the parasitoid is absent, we evaluated fitness consequences of infestation by comparing feeding behavior, reproductive capacity, and survival of males experimentally infested with O. ochracea larvae. We also evaluated genetic mechanisms underlying host responses by comparing gene expression in crickets infested with fly larvae for different lengths of time with that of uninfested control crickets. We observe some differences in fitness (spermatophore production) and survival (total survival time post-infestation) between populations. However, for both traits significant population effects 1) were not associated with the slope of the response to different numbers of larvae and 2) only emerged from models containing body condition at one but not both time points evaluated. Gene expression patterns also revealed population differences in response to infestation. We did not find evidence for consistent differences in genes associated with immunity or stress response. Taken together, these results suggest that coevolution with the fly does not strongly select for either post-infestation resistance or tolerance of parasitoid larvae in male crickets.

Project description:Contrasting infection strategies in generalist and specialist wasp parasitoids of Drosophila melanogaster.

Project description:Smallpox has played an unparalleled role in human history and remains a significant potential threat to public health. Despite the historical significance of this disease, we know little about the underlying pathophysiology or the virulence mechanisms of the causative agent, variola virus. To improve our understanding of variola pathogenesis and variola-host interactions, we examined the molecular and cellular features of hemorrhagic smallpox in cynomolgus macaques. We used cDNA microarrays to analyze host gene expression patterns in sequential blood samples from each of 22 infected animals. Variola infection elicited striking and temporally coordinated patterns of gene expression in peripheral blood. Of particular interest were features that appear to represent an IFN response, cell proliferation, immunoglobulin gene expression, viral dose-dependent gene expression patterns, and viral modulation of the host immune response. The virtual absence of a tumor necrosis factor /NF-B-activated transcriptional program in the face of an overwhelming systemic infection suggests that variola gene products may ablate this response. These results provide a detailed picture of the host transcriptional response during smallpox infection, and may help guide the development of diagnostic, therapeutic, and prophylactic strategies.

Project description:Goal: Natural populations of Drosophila melanogaster vary widely in their capacity to resist infection by the parasitic wasp Leptopilina boulardi. To date, little is known about the genetic, cellular and molecular basis underpinning the variation in susceptibility to parasitic wasps. In D.melanogaster populations artificially selected for parasitoid resistance, an increase in the number of circulating hemocytes (blood cells) is observed. One possibility is that this is accompanied by changes in hemocyte activation state, resulting in a successful defence response when exposed to parasitic wasps. We tested this possibility by generating populations that are highly resistant and highly susceptible to the parasitic wasps. We generated these populations after 26 generations of experimental evolution, starting from a single interbred wild caught population. Here, we study how selection for resistance to the parasitic wasp L. boulardi changes the number and type of circulating hemocytes in D. melanogaster larvae using scRNA-seq. Methods: Wild caught D. melanogaster females were collected from Cambridge, UK, to establish an outbreed population. From this, three replicated populations were selected for resistance to L. boulardi strain NSRef for 26 generations (Selection). Another three populations were maintained in the laboratory for 26 generations without being exposed to parasitoid-associated selection pressures (No Selection). At generation 26, second instar D. melanogaster larvae (48-63 hours after fertilization) from each population were infected with L. boulardi for three hours (Infection) or maintained without infection (No infection). 48 hours after, circulating hemocytes from third instar D. melanogaster larvae (96-111 hours after fertilization) from each population were collected in PBS and cleaned in OptiPrep solution (1.09g/ml). 10X Single Cell GEX v2 libraries were prepared and sequenced. CellRanger v2 was used to generate sample cell count matrices. Seurat v3 was used to integrate, normalise and cluster the cell types. Results: We identified novel plasmatocyte cell types, immature and mature lamellocytes and crystal cells. We identify a single lineage of cellular differentiation starting from a self-cycling plasmatocyte population, enriched for genes involved in extracellular matrix organisation, and ending in a mature lamellocyte population that has enriched expression of genes involved in signalling, hemostasis and gluconeogenesis. Immature lamellocytes were overrepresented in populations selected for resistance to parasitoids. Infection with parasitoid resulted in an increase in both immature and mature lamellocytes in circulation. Conclusions: Selection for resistance to the parasitic wasps resulted in the constitutive activation of the D. melanogaster immune system, where plasmatocytes differentiate into immature lamellocytes even where they are not exposed to parasitic wasps. We speculate these constitutive changes assist in mounting a successful defence response when exposed to parasitic wasps.

Project description:Multinucleated giant hemocytes (MGHs) represent a novel type of blood cell in insects that participate in a highly efficient immune response against parasitoid wasps involving isolation and killing of the parasite. Previously we showed that circulating MGHs have high motility and interaction with the parasitoid rapidly triggers encapsulation, structural and molecular mechanisms behind these processes remained elusive. Here, we use detailed ultrastructural analysis of MGHs and also live cell imaging to study encapsulation in Drosophila ananassae after parasitoid wasp infection. We found dynamic structural changes, mainly driven by the formation of diverse vesicular systems and a large variety of newly developed intracytoplasmic membrane organizations, moreover abundant generation of giant cell exosomes (GCE) in the MGHs. Moreover, we used RNA sequencing to study the transcriptomic profile of MGHs and the activated plasmatocytes 72 hours after infection, as well as the uninduced blood cells. This reveals that differentiation of MGHs is accompanied by broad changes in gene expression. Consistent with the observed structural changes, transcripts mainly related to vesicular function, cytoskeletal organization and adhesion were enriched in MGHs. In addition, transmembrane receptors were upregulated, which may be important for parasitoid recognition. Our results reveal coordinated molecular and structural changes in the course of MGH differentiation and parasitoid encapsulation, providing a mechanistic model for a powerful innate immune response.

Project description:Smallpox has played an unparalleled role in human history and remains a significant potential threat to public health. Despite the historical significance of this disease, we know little about the underlying pathophysiology or the virulence mechanisms of the causative agent, variola virus. To improve our understanding of variola pathogenesis and variola-host interactions, we examined the molecular and cellular features of hemorrhagic smallpox in cynomolgus macaques. We used cDNA microarrays to analyze host gene expression patterns in sequential blood samples from each of 22 infected animals. Variola infection elicited striking and temporally coordinated patterns of gene expression in peripheral blood. Of particular interest were features that appear to represent an IFN response, cell proliferation, immunoglobulin gene expression, viral dose-dependent gene expression patterns, and viral modulation of the host immune response. The virtual absence of a tumor necrosis factor /NF-B-activated transcriptional program in the face of an overwhelming systemic infection suggests that variola gene products may ablate this response. These results provide a detailed picture of the host transcriptional response during smallpox infection, and may help guide the development of diagnostic, therapeutic, and prophylactic strategies. Groups of assays that are related as part of a time series. Keywords: time_series_design Using regression correlation

Project description:Mitochondria participate in various cellular processes including energy metabolism, apoptosis, autophagy, ROS production, stress responses, inflammation and immunity. We investigated the effects of immune tissue specific mitochondrial perturbations on immune responses at the organismal level. Drosophila melanogaster model was utilized to knockdown genes from oxidative phosphorylation (OXPHOS) complexes cI-V, by targeting the two main immune tissues of Drosophila, the fat body and the immune cells (hemocytes). While fat body targeted OXPHOS perturbations caused detrimental effects on the viability and immunity, hemocyte specific perturbations led to enhanced immunocompetence of the host. This was accompanied by the formation of melanized hemocyte aggregates (melanotic nodules), a sign of activated cell-mediated innate immunity. Furthermore, hemocyte specific OXPHOS perturbations caused proliferation and immune activation of the hemocytes, resulting to a similar hemocyte profile as seen upon infection, and the animals ultimately had an enhanced immune response when infected with a parasitoid. Our data shows that hemocyte targeted OXPHOS perturbations cause mitochondrial membrane depolarization and upregulation of genes associated with mitochondrial unfolded protein response, including aerobic glycolysis and reactive oxygen species. Overall, we show that while the effects of mitochondrial perturbations on immune responses are highly tissue specific, mild mitochondrial dysfunction can be beneficial in immune-challenged individuals and is causing variation in infection outcomes between individuals.

Project description:Parasitoid wasps inject venom to regulate the immune response and development of host arthropods and sometime paralyze host arthropods. Hereby, proteomic method was used to identify putative venom proteins from Theocolax elegans, ectoparasitoids of storage insect pests.