Abstract
Aminoglycosides are a well known antibiotic family used to treat bacterial infections in humans and animals, but which can be toxic. By binding to the decoding site of helix44 of the small subunit RNA of the bacterial ribosome, the aminoglycoside antibiotics inhibit protein synthesis, cause misreading, or obstruct peptidyl-tRNA translocation. Although aminoglycosides bind helix69 of the bacterial large subunit RNA as well, little is known about their interaction with the homologous human helix69. To probe the role this binding event plays in toxicity, changes to thermal stability, base stacking, and conformation upon aminoglycoside binding to the human cytoplasmic helix69 were compared with those of the human mitochondrial and Escherichia coli helix69. Surprisingly, binding of gentamicin and kanamycin A to the chemically synthesized terminal hairpins of the human cytoplasmic, human mitochondrial, and E. coli helix69 revealed similar dissociation constants (1.3-1.7 and 4.0-5.4 μM, respectively). In addition, aminoglycoside binding enhanced conformational stability of the human mitochondrial helix69 by increasing base stacking. Proton one-dimensional and two-dimensional NMR suggested significant and specific conformational changes of human mitochondrial and E. coli helix69 upon aminoglycoside binding, as compared with human cytoplasmic helix69. The conformational changes and similar aminoglycoside binding affinities observed for human mitochondrial helix69 and E. coli helix69, as well as the increase in structural stability shown for the former, suggest that this binding event is important to understanding aminoglycoside toxicity.
Highlights
The conformational changes and similar aminoglycoside binding affinities observed for human mitochondrial helix69 and E. coli helix69, as well as the increase in structural stability shown for the former, suggest that this binding event is important to understanding aminoglycoside toxicity
All H69 rRNAs have a wobble pair G1⁄7U located at the penultimate position of the stem (Fig. 2). hmt69 has a loop of six nucleosides, whereas the hcyt69 and E. coli H69 hairpins have loops of seven nucleosides each (Fig. 2)
Structural Effects of Kanamycin A Binding to hmt44 and E. coli H44 Observed by CD Analysis—Given the understanding that the prokaryotic H44 is the primary target of aminoglycosides, we investigated the conformational effects of kanamycin A binding to E. coli H44 and hmt44 using CD, as we did for H69
Summary
By binding to the decoding site of helix of the small subunit RNA of the bacterial ribosome, the aminoglycoside antibiotics inhibit protein synthesis, cause misreading, or obstruct peptidyl-tRNA translocation. The conformational changes and similar aminoglycoside binding affinities observed for human mitochondrial helix and E. coli helix, as well as the increase in structural stability shown for the former, suggest that this binding event is important to understanding aminoglycoside toxicity. Aminoglycosides prevent bacterial protein synthesis by binding to prokaryotic ribosomes with greater affinity than to eukaryotic ribosomes [1, 2] They inhibit ribosomal function through an interaction with an internal loop in helix (H44) of the small ribosomal subunit decoding site [3,4,5].
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