Natural Bond Orbital Analysis to Rationalize Transfer RNA Anticodon Stability
Rachel N. Witts
Dr. Maria Nagan and Dr. Eric V. Patterson, Faculty Mentors
Transfer RNA (tRNA) plays an essential role in the process of manufacturing proteins. Specifically, the anticodon stem loop (ASL) region of tRNA is the portion that is coded for by messenger RNA (mRNA) to carry the proper amino acid to the growing polypeptide chain. The anticodon, positions 34-36 of the tRNA strand, exhibits a stair-stepped conformation of its bases. Modified bases, thought to increase the stability of the stacking interaction, occur naturally in positions 34 and 37. The interactions within the anticodon were studied using quantum mechanical calculations, specifically the M06-2X level of theory with the 6-31+G(d,p) basis set and natural bond orbital (NBO) theory. In addition, these calculations were performed with solvation effects taken into account by the use of the SMD solvation model. This study provided insight into the effects of the solvent on the anticodon and the roles played by the modified bases in the 37th position.
Keywords: Transfer RNA, Computational, Anticodon, Modified Bases
Topic(s):Chemistry
Presentation Type: Oral Paper
Session: 43-1
Location: MG 1000
Time: 2:45