Abstract
Synthetic oligonucleotides targeting functional regions of the prokaryotic rRNA could be promising antimicrobial agents. Indeed, such oligonucleotides were proven to inhibit bacterial growth. 2’-O-methylated (2’-O-Me) oligoribonucleotides with a sequence complementary to the decoding site in 16S rRNA were reported as inhibitors of bacterial translation. However, the binding mode and structures of the formed complexes, as well as the level of selectivity of the oligonucleotides between the prokaryotic and eukaryotic target, were not determined. We have analyzed three 2’-O-Me oligoribonucleotides designed to hybridize with the models of the prokaryotic rRNA containing two neighboring aminoglycoside binding pockets. One pocket is the paromomycin/kanamycin binding site corresponding to the decoding site in the small ribosomal subunit and the other one is the close-by hygromycin B binding site whose dynamics has not been previously reported. Molecular dynamics (MD) simulations, as well as isothermal titration calorimetry, gel electrophoresis and spectroscopic studies have shown that the eukaryotic rRNA model is less conformationally stable (in terms of hydrogen bonds and stacking interactions) than the corresponding prokaryotic one. In MD simulations of the eukaryotic construct, the nucleotide U1498, which plays an important role in correct positioning of mRNA during translation, is flexible and spontaneously flips out into the solvent. In solution studies, the 2’-O-Me oligoribonucleotides did not interact with the double stranded rRNA models but all formed stable complexes with the single-stranded prokaryotic target. 2’-O-Me oligoribonucleotides with one and two mismatches bound less tightly to the eukaryotic target. This shows that at least three mismatches between the 2’-O-Me oligoribonucleotide and eukaryotic rRNA are required to ensure target selectivity. The results also suggest that, in the ribosome environment, the strand invasion is the preferred binding mode of 2’-O-Me oligoribonucleotides targeting the aminoglycoside binding sites in 16S rRNA.
Highlights
The ribosomes, composed of rRNA and proteins, catalyze polypeptide synthesis in living cells
We examined if there is any relation between the flexibility of the aminoacyl-tRNA binding site (A-site) models determined from Molecular dynamics (MD) simulations and melting temperatures determined in solution studies of these constructs
The model of the prokaryotic rRNA used in this study (PDB ID: 3LOA [6]) contains two overlapping aminoglycoside binding sites [16]: (i) the 4’-5’ and 4’-6’-2-DOS aminoglycoside binding site with nucleotides: C1407, A1408, G1491, A1492, A1493, G1494, U1495, and (ii) hygromycin B binding site composed of: C1403, C1404, 1405, G1494, U1495, C1496, G1497, U1498 (Fig 2)
Summary
The ribosomes, composed of rRNA and proteins, catalyze polypeptide synthesis in living cells They are built up of two subunits, small and large, which in prokaryotic ribosomes are called 30S and 50S. They are in a slightly energetically preferred intra-helical conformation [3] and the non-cognate tRNA cannot be accepted in the A-site [4]. This functionally important region of 16S rRNA overlaps with the inter-subunit contact, termed the B2a bridge, which is formed between the penultimate stem of helix h44 of 16S rRNA and helix 69 of 23S rRNA of the large subunit [5]
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