Leveraging genomics and artificial intelligence to develop predictive pesticide risk assessment frameworks for wild bees (Ref 4559)
Lead Research Organisation:
UNIVERSITY OF EXETER
Department Name: Biosciences
Abstract
Project Outline:
Protecting wild bees from pesticides:
Are you interested in making fundamental discoveries into the molecular systems that determine the sensitivity of bee pollinators to toxins such as pesticides, while also generating knowledge and tools that can be used to protect bees and the vital ecosystem services they provide? This exciting project will use a range of cutting-edge computational and experimental approaches to address the challenge of controlling damaging crop pests while protecting 'innocent bystander' species such as bees.
Bees are among the world's most environmentally and economically important group of insects, pollinating a remarkable diversity of flowering plants and playing a key role in the production of a wide range of food and commodity crops. However, while carrying out this ecosystem service bees can be exposed to a variety of potentially harmful toxins such as pesticides used in agriculture. Current bee pollinator pesticide risk assessment relies on experimental data collected for a handful of 'model' managed bee species such as the western honeybee. However, bees are a highly diverse group of insects comprising more than 20,000 known species. Thus, there is an urgent need to find ways to move beyond the use of data derived from a few managed model bee species as a proxy for wild bees in pesticide risk assessment.
This project will leverage the dramatic increase in genomic information available for bees, in combination with recent advances in three-dimensional modelling of enzyme structures and enzyme expression, to develop new tools and predictive pipelines for bee pesticide risk assessment. The supervisory team have a strong track record of working and publishing on the topic of bee-pesticide interactions and include an industrial partner who will provide additional funding for the project, and an excellent route to ensure the fundamental knowledge generated results in applied impact in terms of protecting bee pollinators.
You will be trained in a variety of state-of-the-art approaches that are highly sought-after by employers in academia and industry. These will include bioinformatics (analysis of genome sequences) three-dimensional modelling of enzyme structures, insect (bee and Drosophila) bioassays, molecular biology (gene cloning and expression) and biochemistry (enzyme assays).
Protecting wild bees from pesticides:
Are you interested in making fundamental discoveries into the molecular systems that determine the sensitivity of bee pollinators to toxins such as pesticides, while also generating knowledge and tools that can be used to protect bees and the vital ecosystem services they provide? This exciting project will use a range of cutting-edge computational and experimental approaches to address the challenge of controlling damaging crop pests while protecting 'innocent bystander' species such as bees.
Bees are among the world's most environmentally and economically important group of insects, pollinating a remarkable diversity of flowering plants and playing a key role in the production of a wide range of food and commodity crops. However, while carrying out this ecosystem service bees can be exposed to a variety of potentially harmful toxins such as pesticides used in agriculture. Current bee pollinator pesticide risk assessment relies on experimental data collected for a handful of 'model' managed bee species such as the western honeybee. However, bees are a highly diverse group of insects comprising more than 20,000 known species. Thus, there is an urgent need to find ways to move beyond the use of data derived from a few managed model bee species as a proxy for wild bees in pesticide risk assessment.
This project will leverage the dramatic increase in genomic information available for bees, in combination with recent advances in three-dimensional modelling of enzyme structures and enzyme expression, to develop new tools and predictive pipelines for bee pesticide risk assessment. The supervisory team have a strong track record of working and publishing on the topic of bee-pesticide interactions and include an industrial partner who will provide additional funding for the project, and an excellent route to ensure the fundamental knowledge generated results in applied impact in terms of protecting bee pollinators.
You will be trained in a variety of state-of-the-art approaches that are highly sought-after by employers in academia and industry. These will include bioinformatics (analysis of genome sequences) three-dimensional modelling of enzyme structures, insect (bee and Drosophila) bioassays, molecular biology (gene cloning and expression) and biochemistry (enzyme assays).
People |
ORCID iD |
| Christopher Bass (Primary Supervisor) |
Studentship Projects
| Project Reference | Relationship | Related To | Start | End | Student Name |
|---|---|---|---|---|---|
| NE/V013041/1 | 01/10/2021 | 30/09/2027 | |||
| 2866086 | Studentship | NE/V013041/1 | 01/10/2023 | 31/07/2027 |