Project description:The natural histories of various parasite-host interactions that involve adaptive manipulation of host behavior describe a time-of-day synchronization of certain events. One example is the manipulated biting behavior observed in Carpenter ants infected with Ophiocordyceps unilateralis sensu lato. Field observations in Thailand demonstrated that manipulated biting takes place around solar noon. Laboratory work with species from South Carolina, demonstrated a shift of this synchronized biting event to the early morning. We therefore hypothesize that biological clocks play an important role in these and other parasite-host interactions. To set the stage for our future research into this, we, here, aimed to explore if fungal species of the complex O. unilateralis s.l. have a functional molecular clock. We, therefore, performed RNA-Seq on time course samples of the recently sequenced species Ophiocordyceps kimflemingiae. Fungal blastospores grown in liquid media were harvested under cycling light-dark and continuous darkness conditions. Rhythmic mRNA levels were assessed with JTK_CYCLE. We found that O. kimflemingiae is not hugely rhythmic under our sampling conditions, but rhythmicity can be observed. Moreover, we identified functional homologs of known clock genes. In addition, our data indicated that regulation of transcription appears to take place during the light phase (day time). In contrast, the expression levels of a significant number of secreted enzymes, proteases, toxins and small bioactive compounds peaked during the dark phase (night time). This suggests that this fungal parasite might indeed rely on biological clocks for the precise daily timing of certain events and additionally validates further research into this.

Project description:Gene expression during biting behavior in zombie ants reflects the complexity of fungal pathogenic manipulation of ants

Project description:This experiment was performed to investigate the effect of the manipulation of social rank on gene expression. Fire ants newly mated queens were paired and placed in nesting chambers. After emergence of workers, queensM-^R behavior was monitored. Once the behavioral observation revealed the social rank of the two cofoundresses (winners and losers), queens were weighed again and re-paired with a different partner. We created the following three groups of queens: a) winner + winner (similar weight), b) loser + loser (similar weight), and c) winner + loser (different weights). Again, we monitored the behavior until the social rank of the newly coupled specimens was evident and we collected 4 new behavioral phenotypes in the same way as above: a) winners switched into losers (win/los), b) losers switched into winners (los/win), c) continuing winners (win/win) and d) continuing losers (los/los).

Project description:The transition to parasitism is a drastic shift in lifestyle, involving rapid changes in gene structure, function, and expression. Evolutionarily 'young' parasites are ideal models for the elucidation of the early steps of this transition. After the establishment of an antagonistic relationship, parasite and host co-evolve through reciprocal adaptations resulting in an evolutionary arms-race. Repeated evolution of social parasitism and slavery among Temnothorax ants allows us to examine gene expression patterns characterizing slavemaker raiding and reciprocal host defensive behavior. Previous studies of Temnothorax provide evidence for co-evolving adaptations between parasites and hosts, as well as diverging raiding strategies between slavemakers. However, under parasite pressure, host defense portfolios shift similarly, suggesting diverging evolution of defensive traits. Through comparative gene expression analyses, we find that slavemaker raiding behavior is characterized by a down-regulation of numerous genes relative to their non-raiding state. Moreover, only a small number of genes shared expression between slavemaking species. In contrast, hosts possess a higher ratio of commonly-to-privately over-expressed genes and metabolic pathways during raids, suggesting that genes of similar function control defensive behavior. Additionally, a number of candidate genes were identified, each potentially playing a major role in shaping slavemaker- and host-specific behaviors. Finally, in two slavemaking species, functional enrichment analyses indicate that genes over-expressed during raiding behavior are associated with ribosomal structure, oxidation-reduction, and metabolic processes. Overall, our analysis revealed evidence for divergent evolution among closely-related ant species, where species-specific gene expression characterize raiding and defensive behavior.

Project description:Primary endosymbiont of carpenter ants

Project description:The goal of this study was to assay the extent of variation in chromatin organization between 3 ant castes (major and minor female workers and males) in one colony of Camponotus floridanus carpenter ant using ChIPseq. 45 samples total: 30 ChIP samples and 3 inputs for total histone H3, 7 histone H3 PTMs and RNA Pol II in major, minor, and male ants; CBP in major and minor ants; the major H3K27ac sample was replicated. 4 ChIP samples for H3 and H3K27ac in brains of majors and minors, and 2 inputs. 2 RNAseq samples for major and minor ants head+thorax; 4 RNAseq samples for brain (majors and minors with 2 replicates each).

Project description:This SuperSeries is composed of the following subset Series: GSE22678: Transcriptome sequencing and analysis of two ants: Camponotus floridanus and Harpegnathos saltator GSE22679: Small RNA sequencing and analysis of two ants: Camponotus floridanus and Harpegnathos saltator Refer to individual Series

Project description:Mass spectrometry imaging is a powerful analytical technique for detecting and determining spatial distributions of molecules within a sample. Typically, mass spectrometry imaging is limited to the analysis of thin tissue sections taken from the middle of a sample. In this work, we present a mass spectrometry imaging method for the detection of compounds produced by bacteria on the outside surface of ant exoskeletons in response to pathogen exposure. Fungus-growing ants have a specialized mutualism with Pseudonocardia, a bacterium that lives on the ants’ exoskeletons and helps protect their fungal garden food source from harmful pathogens. The developed method allows for visualization of bacterial-derived compounds on the ant exoskeleton. This method demonstrates the capability to detect compounds that are specifically localized to the bacterial patch on ant exoskeletons, shows good reproducibility across individual ants, and achieves accurate mass measurements within 5 ppm error when using a high-resolution, accurate-mass mass spectrometer.

Project description:Simulium damnosum sensu lato (s.l.) blackflies transmit Onchocerca volvulus, a filarial nematode that causes human onchocerciasis. Human landing catches (HLCs) is currently the sole method used to estimate blackfly biting rates but is labour-intensive and questionable on ethical grounds. A potential alternative is to measure host antibodies to vector saliva deposited during bloodfeeding. In this study, the salivary proteome of S. damnosum s.l. was investigated. Blackflies were collected in Ghana by HLCs and dissected to extract their salivary glands. Salivary proteins were separated by gel-electrophoresis, and antigenic proteins visualized by immunoblot. Liquid chromatography mass spectrometry (LC–MS/MS) was performed to characterize the proteome of S. damnosum s.l. salivary glands. Several antigenic proteins were recognized, with the major ones located around 15 and 40 kDa. LC–MS/MS identified the presence of antigen 5-related protein, apyrase/nucleotidase, and hyaluronidase.

Project description:Deep BS-Seq of two Ants: Camponotus floridanus and Harpegnathos saltator.