Coming to the end of my Biology degree there were many things I envisaged I would be doing in 10 years’ time.
Helping rid the world of a disease? Saving the odd panda bear? Emergency centre forward for Liverpool Football Club? At 32 I’m still banking on the latter.
Attaching tiny flies to strands of human hair, however, did not really enter this thought process. But here I am, evident by the superglue on my fingers and clothes, as well as some rather disturbed and sticky flies sat, or should I say welded, onto the lab bench.
Why on earth am I doing this? It’s a fair question.
I am a member of the Insect Migration and Spatial Ecology Group at Rothamsted Research. Every year billions of insects migrate vast distances (up to a thousand kilometres in some cases) to cope with the changing seasons and to find suitable habitats in which to breed. Many of these are our most important crop pests and it is migration that allows them to flourish.
Now there is no TripAdvisor or A to Z guidebook instructing each insect how to navigate, power and fuel these remarkable journeys. The ability to migrate is ‘in the genes’. What these genes are and how they manifest in migratory behaviour is largely unknown. Discovering and understanding these ‘migration genes’ in super pests, the global and invasive cotton bollworm moth in my case, is the goal of my research.
But how do you study this? Bringing me nicely back to superglue and flies.
In our lab we measure flight as a proxy for migration. To do this we tether insects, either housed in our insectaries or those collected straight from the field, to flight mill chambers that allow us to determine the speed, duration and distance of each flight. We can then compare the DNA of insects (by sequencing their genomes) showing the greatest flight propensity (long-haulers) with those that don’t fly far at all (more budget airline).
Using this approach, we have found that genes involved in metabolism, flight muscles and hormonal control are associated with flight, and hence, migratory potential. These are early but promising findings. So what’s next?
Well March marks the start of my BBSRC Future Leader Fellowship. The fellowship is a three-year competitive scheme designed as a stepping stone for early career biologists to start their own research lab.
Right now, and for someone with superglue on their trousers, the tag ‘future leader’ is slightly disconcerting. As my Dad succinctly put it on hearing the news: “Future leader? You?! Future idiot more like”. Thanks Dad.
Nevertheless, this is an exciting time and the fellowship gives me the chance to expand this area of science called ‘migratory genomics’.
The application process itself has been a steep learning curve in how to write a grant. It has been a lesson in: selling your research; selling yourself (bordering on arrogance); getting to the point; asking as many of your peers and colleagues for advice; listening to criticism; failure; and perseverance.
If I can take one thing away from the process it is the last one; perseverance. One reviewer in a previously unsuccessful application of mine described the research proposal as “boring”. That’s fine, it is their opinion, but if I’d have listened to this feedback then I might as well have packed up my desk, gone home and watched daytime TV - I hear Bargain Hunt and Come Dine with Me are very good!
It’s a good job I didn’t listen because now I am fortunate to be able to perform some ‘not so boring’ research and hopefully come back in a few years’ time with pertinent findings on what drives the movement and migrations of our most economically damaging insect pests.
More specifically, the fellowship will allow me to answer some fundamental questions:
How do environmental cues that signify deteriorating conditions in the field interact with the genes that trigger migratory behaviour?
What impact does removing, or ‘knocking out’, genes associated with migration inside the insect have on flight performance?
Can we use our knowledge of migration associated genes to predict insect movement?
And just how do you remove superglue from a pair of trousers?
Let's have a chat!
Do you have any questions about a day in my life? On Monday 9th May, I will be doing a Reddit Science AMA (ask me anything) session. To find out about how you can get involved in this digital event please see: http://www.rothamsted.ac.uk/events/genetics-high-flying-migrating-insect...
In the meantime, you are welcome to ask me anything about my research, my experience with the fellowship application, or any other insect migration questions you may have! Just use the discussion box below.
Chris Jones gained a BSc in Biology at Durham University in 2005 and an MSc on the Biology and Control of Disease Vectors at the London School of Tropical Medicine in 2006. He then joined Rothamsted for his PhD working on the genetics of insecticide resistance in agricultural pests. In 2010 he moved to Professor Hilary Ranson’s group at the Liverpool School of Tropical Medicine to continue insecticide resistance research on African malaria mosquitoes combining both field and molecular approaches. Using this experience, he re-joined Rothamsted in 2013 to start a new project investigating the genetic basis of migratory behaviour in insect pests. Little is known about the genes that contribute to the fascinating, long and arduous journeys undertaken by insect migrants and recently Chris was awarded a BBSRC Future Leader Fellowship to tackle this fundamental behaviour in important global insect pests.