The in vitro activity of the aminoglycoside 6=-N-acetyltransferase type Ib [AAC(6=)-Ib] was inhibited by CuCl 2 with a 50% inhibitory concentration (IC 50 ) of 2.8 M. The growth of an amikacin-resistant Klebsiella pneumoniae strain isolated from a neonate with meningitis was inhibited when amikacin was supplemented by the addition of Zn 2؉ or Cu 2؉ in complex with the ionophore pyrithione. Coordination complexes between cations and ionophores could be developed for their use, in combination with aminoglycosides, to treat resistant infections.
External guide sequences (EGSs) are short antisense oligoribonucleotides that elicit RNase P-mediated cleavage of a target mRNA, which results in inhibition of gene expression. EGS technology is used to inhibit expression of a wide variety of genes, a strategy that may lead to development of novel treatments of numerous diseases, including multidrug-resistant bacterial and viral infections. Successful development of EGS technology depends on finding nucleotide analogs that resist degradation by nucleases present in biological fluids and the environment but still elicit RNase P-mediated degradation when forming a duplex with a target mRNA. Previous results suggested that locked nucleic acids (LNA)/DNA chimeric oligomers have these properties. LNA are now considered the first generation of compounds collectively known as bridged nucleic acids (BNAs) – modified ribonucleotides that contain a bridge at the 2ʹ,4ʹ-position of the ribose. LNA and the second-generation BNA, known as BNANC, differ in the chemical nature of the bridge. Chimeric oligomers containing LNA or BNANC and deoxynucleotide monomers in different configurations are nuclease resistant and could be excellent EGS compounds. However, not all configurations may be equally active as EGSs. RNase P cleavage assays comparing LNA/DNA and BNANC/DNA chimeric oligonucleotides that share identical nucleotide sequence but with different configurations were carried out using as target the amikacin resistance aac(6ʹ)-Ib mRNA. LNA/DNA gapmers with 5 and 3/4 LNA residues at the 5ʹ- and 3ʹ-ends, respectively, were the most efficient EGSs while all BNANC/DNA gapmers showed very poor activity. When the most efficient LNA/DNA gapmer was covalently bound to a cell-penetrating peptide, the hybrid compound conserved the EGS activity as determined by RNase P cleavage assays and reduced the levels of resistance to amikacin when added to Acinetobacter baumannii cells in culture, an indication of cellular uptake and biological activity.
RNase P is a ribozyme consisting of a catalytic RNA molecule and, depending on the organism, one or more cofactor proteins. It was initially identified as the enzyme that mediates cleavage of precursor tRNAs at the 5'-end termini to generate the mature tRNAs. An important characteristic of RNase P is that its specificity depends on the structure rather than the sequence of the RNA substrate. Any RNA species that interacts with an antisense molecule (called external guide sequence, EGS) and forms the appropriate structure can be cleaved by RNase P. This property is the basis for EGS technology, an antisense methodology for inhibiting gene expression by eliciting RNase P-mediated cleavage of a target mRNA molecule. EGS technology is being developed to design therapies against a large variety of diseases. An essential milestone in developing EGSs as therapies is the assessment of the efficiency of antisense molecules to induce cleavage of the target mRNA and evaluate their effect in vivo. Here, we describe simple protocols to test the ability of EGSs to induce cleavage of a target mRNA in vitro and to induce a phenotypic change in growing cells.
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