SUMMARY
We demonstrate that the antibiotic amicoumacin A (AMI) whose cellular target was unknown, is a potent inhibitor of protein synthesis. Resistance mutations in helix 24 of the 16S rRNA mapped the AMI binding site to the small ribosomal subunit. The crystal structure of bacterial ribosome in complex with AMI solved at 2.4 Å resolution revealed that the antibiotic makes contacts with universally conserved nucleotides of 16S rRNA in the E site and the mRNA backbone. Simultaneous interactions of AMI with 16S rRNA and mRNA and the in vivo experimental evidence suggest that it may inhibit the progression of the ribosome along mRNA. Consistent with this proposal, binding of AMI interferes with translocation in vitro. The inhibitory action of AMI can be partly compensated by mutations in the translation elongation factor G.
e In order to accelerate drug discovery, a simple, reliable, and cost-effective system for high-throughput identification of a potential antibiotic mechanism of action is required. To facilitate such screening of new antibiotics, we created a double-reporter system for not only antimicrobial activity detection but also simultaneous sorting of potential antimicrobials into those that cause ribosome stalling and those that induce the SOS response due to DNA damage. In this reporter system, the red fluorescent protein gene rfp was placed under the control of the SOS-inducible sulA promoter. The gene of the far-red fluorescent protein, katushka2S, was inserted downstream of the tryptophan attenuator in which two tryptophan codons were replaced by alanine codons, with simultaneous replacement of the complementary part of the attenuator to preserve the ability to form secondary structures that influence transcription termination. This genetically modified attenuator makes possible Katushka2S expression only upon exposure to ribosome-stalling compounds. The application of red and far-red fluorescent proteins provides a high signal-to-background ratio without any need of enzymatic substrates for detection of the reporter activity. This reporter was shown to be efficient in high-throughput screening of both synthetic and natural chemicals.T he spread of antibiotic resistance genes among pathogenic bacteria is leading to a gradual decrease in the efficiency of known antibiotics. Substantial efforts have been invested in platforms for new antibiotic development (1). High-throughput screening (HTS) is a major method for the discovery of new chemical scaffolds for drug discovery. However, in the search for new antibiotics, HTS demonstrated low efficiency (for a discussion, see references 2 and 3). Acceleration of the antibiotic development pipeline demands increased efficiency in the identification of mechanisms of action with both HTS of chemical libraries and screening of natural compounds. Ideally, the mechanism of action should be determined while screening for antibacterial activity. One of the major challenges in high-throughput screening is the development of a cost-effective procedure that could maximize information output while concomitantly minimizing the number of pipetting steps and the reagent costs.The most efficient way to reveal the mechanism of action is the application of reporter strains (for a recent review, see reference 4). However, the majority of the reporter strains developed thus far aim to identify a narrow group of chemically related compounds, such as tetracyclines (5), macrolides (6, 7), or -lactams (8). Broader-spectrum reporters based on stress response promoters are also available (9-11). A combination of several reporter strains could help to classify more mechanisms of action, but that would require multiple experiments for a single substance being tested.The majority of antibiotics currently in clinical use target the cell wall, DNA, or protein biosynthesis. For the latter two mechanisms ...
Silver nanoparticles stabilized by a well-known antibacterial surfactant benzyldimethyl[3-(myristoylamino)propyl]ammonium chloride (Myramistin(®)) were produced for the first time by borohydride reduction of silver chloride sol in water. Stable aqueous dispersions of silver nanoparticles without evident precipitation for several months could be obtained. In vitro bactericidal tests showed that Myramistin(®) capped silver NPs exhibited notable activity against six different microorganisms-gram-positive and gram-negative bacteria, yeasts and fungi. The activity was up to 20 times higher (against E. coli) compared to Myramistin(®) at the same concentrations and on average 2 times higher if compared with citrate-stabilized NPs.
A reporter construct was created on the basis of the transcription attenuator region of the Escherichia coli tryptophan operon. Dual-fluorescent-protein genes for red fluorescent protein and cerulean fluorescent protein were used as a sensor and internal control of gene expression. The sequence of the attenuator was modified to avoid tryptophan sensitivity while preserving sensitivity to ribosome stalling. Antimicrobial compounds which cause translation arrest at the stage of elongation induce the reporter both in liquid culture and on an agar plate. This reporter could be used for high-throughput screening of translation inhibitors.
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