Project Details
Description
The rapid warming of the Earth caused by anthropogenic factors has profound long-term implications for preventing pests and controlling vector-borne diseases. Put simply, Arthropods, ectotherms animals, do better in a warmer world. One of the advantages of a more hospitable environment is spreading geographically to establish new niches. However, appropriate communication within and between individuals is crucial for successful niche realization, and one of the most ancient ways of communication occurs via chemicals and chemoreception. As biological models, this project will examine chemosensory adaptations to specialized lifestyles in two arthropods. First, Ixodes ricinus (Chelicerata) is a vector for multiple tick-borne diseases common in Europe and, as a result, has a significant impact on public health. Despite their epidemiological importance, there is still limited knowledge of the chemosensory system of this species, and thus a poor understanding of host-seeking behavior and chemical ecology. Through comprehensive phylogenetic analysis and comparative genomics approaches, we will investigate how the chemosensory receptor genes are conserved or diversified in seven tick species from five significant genera in the hard ticks (Ixodidae).
On the other hand, this project will annotate the chemosensory gene families in the ambrosia beetle Trypodendron lineatum, the second biological model. The T. lineatum genome will be globally annotated using automated annotation pipelines, and gene family expansions will be analyzed for comparisons with available bark beetle genomes (Ips typographus and Dendroctonus ponderosa) to seek genomic signatures of the specialized lifestyle of ambrosia beetles as fungal farmers and eusocial insects.
On the other hand, this project will annotate the chemosensory gene families in the ambrosia beetle Trypodendron lineatum, the second biological model. The T. lineatum genome will be globally annotated using automated annotation pipelines, and gene family expansions will be analyzed for comparisons with available bark beetle genomes (Ips typographus and Dendroctonus ponderosa) to seek genomic signatures of the specialized lifestyle of ambrosia beetles as fungal farmers and eusocial insects.
Status | Active |
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Effective start/end date | 2022/09/08 → … |
Collaborative partners
- Lund University (lead)
- Max Planck Center Next Generation Insect Chemical Ecology
UKÄ subject classification
- Natural Sciences
- Bioinformatics (Computational Biology)
- Behavioral Sciences Biology