Functional Genomics of Aphid Adaptation to Plant Species
Lead Research Organisation:
John Innes Centre
Department Name: UNLISTED
Abstract
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Technical Summary
The green peach aphid (GPA) Myzus persicae is an agronomically important pest worldwide. This aphid colonizes over 400 different plant species from more than 50 plant families and has developed resistance to all insecticides that are currently in use. Remarkably, a single GPA clone (consisting of genetically identical individuals) can colonize diverse plant species of several plant families, whilst the specialist pea aphid Acyrthosiphon pisum (for which the genome sequence is available) consists of genetically distinct races each of which colonizes different plant species of the family Fabaceae (or Leguminosae).
The objective of this project is to identify mechanisms that have given GPA its impressive phenotypic plasticity.
We will test the hypothesis that some gene families have adaptively expanded, offering GPA better protection to phytochemicals and insecticides. Given that genetically identical clones can exploit distinct host plants, we hypothesise that epigenetic regulation affects gene expression levels, and that certain gene members within these gene families are differentially up or down-regulated depending on exposure to host species and insecticides.
This project tests an exiting new idea that adaptive gene duplication and expansion of certain gene families has provided GPA with a versatile “genetic toolbox” allowing for a phenotypically plastic response through epigenetic regulation, thereby equipping this parasite with a vast evolutionary potential that could threaten future food security. We will use state-of-the-art genomics tools to compare aphid genomes and assess gene expression and DNA methylation profiles of GPA reared on diverse plant species and exposed to insecticides with different chemistries. We will then knock down the expression of specific GPA genes to study their effect on GPA adaptation to plants and insecticides.
This project includes a translational component that will be taken forward in collaboration with Syngenta.
The objective of this project is to identify mechanisms that have given GPA its impressive phenotypic plasticity.
We will test the hypothesis that some gene families have adaptively expanded, offering GPA better protection to phytochemicals and insecticides. Given that genetically identical clones can exploit distinct host plants, we hypothesise that epigenetic regulation affects gene expression levels, and that certain gene members within these gene families are differentially up or down-regulated depending on exposure to host species and insecticides.
This project tests an exiting new idea that adaptive gene duplication and expansion of certain gene families has provided GPA with a versatile “genetic toolbox” allowing for a phenotypically plastic response through epigenetic regulation, thereby equipping this parasite with a vast evolutionary potential that could threaten future food security. We will use state-of-the-art genomics tools to compare aphid genomes and assess gene expression and DNA methylation profiles of GPA reared on diverse plant species and exposed to insecticides with different chemistries. We will then knock down the expression of specific GPA genes to study their effect on GPA adaptation to plants and insecticides.
This project includes a translational component that will be taken forward in collaboration with Syngenta.
Planned Impact
unavailable
