Publications by authors named "Y S Nim"
Article Synopsis
- Urease is a nickel enzyme crucial for bacteria colonizing the human stomach, but delivering toxic nickel ions safely to its active site is a challenge.
- Cells utilize metallochaperones, proteins that transport these ions specifically to protein complexes, to solve this problem.
- The study detailed the structures of UreFD/urease and UreD/urease complexes using cryo-electron microscopy, revealing a tunnel mechanism that facilitates nickel ion delivery to urease’s active site.
The ability of metallochaperones to allosterically regulate the binding/release of metal ions and to switch protein-binding partners along the metal delivery pathway is essential to the metallation of the metalloenzymes. Urease, catalyzing the hydrolysis of urea into ammonia and carbon dioxide, contains two nickel ions bound by a carbamylated lysine in its active site. Delivery of nickel ions for urease maturation is dependent on GTP hydrolysis and is assisted by four urease accessory proteins UreE, UreF, UreG, and UreH(UreD).
View Article and Find Full Text PDFHomology modeling allows the prediction of a protein structure based on sequence similarity to a known structure of homologous proteins. In this chapter, we use a plant-specific AtSar1a-Atsec23a pair of proteins as a case study to illustrate how to use homology modeling to understand the specificity of the pairwise interaction between AtSar1a and AtSec23a. The detailed procedures described here are also useful in structure prediction of other protein complexes.
View Article and Find Full Text PDF