Protein Choreography of the Molecular Compass. PhD in Biosciences. (BBSRC SWBio DTP) 4268

Birds, fruit flies and many other animals are equipped with the remarkable ability to sense the Earth's magnetic field by
means of a biochemical reaction in cryptochrome proteins. Surprisingly, this protein molecular compass utilises truly
quantum effects to respond to changes in the magnetic field as the animal navigates. The molecular basis of how these
proteins structurally reconfigure in response to planetary magnetic fields, transduced by quantum effects on single
electrons, is unknown. In migratory songbirds, such as the European robin, Cryptochrome 4 (Cry4) is the protein identified
to correlate with magnetosensation. Photoreduction of Cry4 has been shown to be sensitive to magnetic fields in vitro.
Yet, little is known about the structure of Cry4 and which conformational changes transduce the geomagnetic field.
Here, we will aim to decipher the inner workings of Cry4 protein as the molecular transducer of our planet's magnetic
field by migratory birds. You will learn a variety of cutting-edge and highly transferable biophysical and computational
tools and techniques. This studentship will provide a rare opportunity to become an expert in hydrogen/deuterium exchange mass spectrometry (HDX-MS), using novel prototype instrumentation developed by the Phillips lab at The Living
Systems Institute, Univ. Exeter. You will make millisecond time-resolved measurements of the protein structural dynamics
under magnetic stimulation. You will then use these experimental results to seed molecular dynamics simulations
(Mulholland Group, Univ. Bristol) and combine this with quantum mechanics calculations (Kattnig Group, Univ. Exeter).
As a result, you will produce an experimentally driven molecular movie of the process of Cry4 functional switching with
atomistic resolution.