Electron Cryo-microscopy

Thyroglobulin, the protein precursor to the thyroid hormones T3 and T4, is the only molecule in the human body that is modified by iodine, and the modification directly leads to the formation of the thyroid hormones in the thyroid gland. But the exact process has been sparsely understood.

Our DNA contains all of the information required to tell a cell what it needs to do, but it is constantly being damaged. This damage can cause severe problems, making repair processes hugely important. One common type of DNA damage, known as crosslinking, involves links forming inappropriately between two nucleotide letters. Although the specific repair pathway that fixes DNA crosslinks, and the complex at the heart of it, have been known about for decades, a full mechanistic understanding has been missing. Lori Passmore’s group, in the LMB’s Structural Studies Division, has now revealed the structure of the complex at the heart of this repair pathway for the first time.

Is it possible to improve imaging of purified biological specimens in electron cryo-microscopy (cryo-EM) while also reducing its cost? The latest proof-of-principle paper from Chris Russo’s group says yes, and indicates that the answer lies in reducing the electron energy in the cryo-EM from the current standard of 300 or 200 kiloelectron volts (keV) to 100 keV. Recent measurements of radiation damage to biological specimens by high-energy electrons have shown that at lower energies there is an increased amount of information available per unit damage. The authors of the paper foresee that future cryo-microscopes designed for ultimate single-particle resolution will be designed to maximise this information. This will then make true atomic resolution (~1 Å) more accessible and affordable.