Side chain dynamics of carboxyl and carbonyl groups in the catalytic function of Escherichia coli ribonuclease H. Academic Article

abstract

• Many proteins use Asx and Glx (x = n, p, or u) side chains as key functional groups in enzymatic catalysis and molecular recognition. In this study, NMR spin relaxation experiments and molecular dynamics simulations are used to measure the dynamics of the side chain amide and carboxyl groups, (13)C(/), in Escherichia coli ribonuclease HI (RNase H). Model-free analysis shows that the catalytic residues in RNase H are preorganized on ps-ns time scales via a network of electrostatic interactions. However, chemical exchange line broadening shows that these residues display significant conformational dynamics on s-ms time scales upon binding of Mg(2+) ions. Two groups of catalytic residues exhibit differential line broadening, implicating distinct reorganizational processes upon binding of metal ions. These results support the "mobile metal ion" hypothesis, which was inferred from structural studies of RNase H.

authors

• Cho, Jae

published proceedings

• J Am Chem Soc

altmetric score

• 1

author list (cited authors)

• Stafford, K. A., Ferrage, F., Cho, J., & Palmer, A. G.

citation count

• 13

complete list of authors

• Stafford, Kate A||Ferrage, Fabien||Cho, Jae-Hyun||Palmer, Arthur G

publication date

• January 2013

publisher

• American Chemical Society (ACS)  Publisher

published in

• Journal of the American Chemical Society  Journal

keywords

• Binding Sites
• Cations, Divalent
• Escherichia Coli
• Magnesium
• Molecular Dynamics Simulation
• Protein Conformation
• Ribonuclease H

PubMed Central ID

• 24219366

Digital Object Identifier (DOI)

• 10.1021/ja409479y

start page

• 18024

end page

• 18027

volume

• 135

issue

• 48

URL

• http%3A%2F%2Fdx.doi.org%2F10.1021%2Fja409479y