Solution of protein crystallographic structures by high-pressure cryocooling and noble-gas phasing

Room-pressure flash-cryocooling of protein crystals is the standard way to reduce radiation damage during data collection. Typically, it is necessary to find cryoprotection conditions by trial and error, a process that is not always successful. Recently, a new method, high-pressure cryocooling, was developed that does not require penetrative cryoprotectants and typically yields very high quality diffraction. Since this method involves helium gas as a pressurizing medium, it was of great interest to see whether the method could be extended to diffraction phasing by the incorporation of heavy noble gases such as krypton. A modified Kr–He high-pressure cyrocooling procedure is described wherein crystals are first pressurized with krypton gas to 10 MPa for 1 h. The krypton pressure is then released and the crystals are repressurized with helium over 150 MPa and cooled to liquid-nitrogen temperatures. Porcine pancreas elastase (PPE; 240 residues, 26 kDa) was selected as a test case for this study. Excellent diffraction was achieved by high-pressure cryocooling without penetrating cryoprotectants. A single 0.31 occupied krypton site in a PPE molecule [Bijvoet amplitude ratio (〈|ΔF|〉/〈F〉) of 0.53%] was successfully used for SAD phasing at 1.3 Å. This method has the potential to greatly simplify obtaining protein structures.