Effect of Mutations on the Binding of Kanamycin‑B to RNA Hairpins Derived from the Mycobacterium tuberculosis Ribosomal A‑Site

July 28, 2017

Title

Effect of Mutations on the Binding of Kanamycin‑B to RNA Hairpins Derived from the Mycobacterium tuberculosis Ribosomal A‑Site

Author

Amber R. Truitt, Bok-Eum Choi, Jenny Li, Ana Maria Soto

Year

2015

Journal

Biochemistry

Abstract

Kanamycin is an aminoglycoside antibiotic used in the treatment of drug-resistant tuberculosis. Mutations at the rRNA A-site have been associated with kanamycin resistance in Mycobacterium tuberculosis clinical isolates. Understanding the effect of these mutations on the conformation of the M. tuberculosis A-site is critical for understanding the mechanisms of antibiotic resistance inM. tuberculosis. In this work, we have studied RNA hairpins derived from the M. tuberculosis A-site, the wild type and three mutants at the following positions (M. tuberculosis/Escherichia colinumbering): A1400/1408 → G, C1401/1409 → U, and the double mutant G1483/1491 C1401/1409 → UA. Specifically, we used circular dichroism, ultraviolet spectroscopy, and fluorescence spectroscopy to characterize the conformation, stability, and binding affinity of kanamycin-B and other aminoglycoside antibiotics for these RNA hairpins. Our results show that the mutations affect the conformation of the decoding site, with the mutations at position 1401/1409 resulting in significant destabilizations. Interestingly, the mutants bind paromomycin with weaker affinity than the wild type, but they bind kanamycin-B with similar affinity than the wild type. The results suggest that the presence of mutations does not prevent kanamycin-B from binding. Instead, kanamycin may promote different interactions with a third partner in the mutants compared to the wild type. Furthermore, our results with longer and shorter hairpins suggest that the region of the A-site that varies among organisms may have modulating effects on the binding and interactions of the A-site.

Instrument

J-815

Keywords

Circular dichroism, Ligand binding, Protein folding, Biochemistry