Influence of DNA template choice on transcription and inhibition of Escherichia coli RNA polymerase

Binding mode characterization of novel RNA polymerase inhibitors using a combined biochemical and NMR approach

Bacterial RNA polymerase (RNAP) represents a validated target for the development of broad-spectrum antibiotics. However, the medical value of RNAP inhibitors in clinical use is limited by the prevalence of resistant strains. To overcome this problem, we focused on the exploration of alternative target sites within the RNAP. Previously, we described the discovery of a novel RNAP inhibitor class containing an ureidothiophene-2-carboxylic acid core structure. Herein, we demonstrate that these compounds are potent against a set of methicillin-resistant Staphylococcus aureus (MRSA) strains (MIC 2-16 μg mL(-1)) and rifampicin-resistant Escherichia coli TolC strains (MIC 12.5-50 μg mL(-1)). Additionally, an abortive transcription assay revealed that these compounds inhibit the bacterial transcription process during the initiation phase. Furthermore, the binding mode of the ureidothiophene-2-carboxylic acids was characterized by mutagenesis studies and ligand-based NMR spectroscopy. Competition saturation transfer difference (STD) NMR experiments with the described RNAP inhibitor myxopyronin A (Myx) suggest that the ureidothiophene-2-carboxylic acids compete with Myx for the same binding site in the RNAP switch region. INPHARMA (interligand NOE for pharmacophore mapping) experiments and molecular docking simulations provided a binding model in which the ureidothiophene-2-carboxylic acids occupy the region of the Myx western chain binding site and slightly occlude that of the eastern chain. These results demonstrate that the ureidothiophene-2-carboxylic acids are a highly attractive new class of RNAP inhibitors that can avoid the problem of resistance.

Surface plasmon resonance – more than a screening technology: insights in the binding mode of σ70:core RNAP inhibitors

Aim: Antibiotic resistance has become a major health problem. The σ70:core interface of bacterial RNA polymerase is a promising drug target. Recently, the coiled-coil and lid-rudder-system of the β’ subunit has been identified as an inhibition hot spot. Materials & methods & Results: By using surface plasmon resonance-based assays, inhibitors of the protein–protein interaction were identified and competition with σ70 was shown. Effective inhibition was verified in an in vitro transcription and a σ70:core assembly assay. For one hit series, we found a correlation between activity and affinity. Mutant interaction studies suggest the inhibitors’ binding site. Conclusion: Surface plasmon resonance is a valuable technology in drug design, that has been used in this study to identify and evaluate σ70:core RNA polymerase inhibitors.

Benzamidobenzoic acids as potent PqsD inhibitors for the treatment of Pseudomonas aeruginosa infections

Targeting PqsD is a promising novel approach to disrupt bacterial cell-to-cell-communication in Pseudomonas aeruginosa. In search of selective PqsD inhibitors, two series of benzamidobenzoic acids - one published as RNAP inhibitors and the other as PqsD inhibitors - were investigated for inhibitory activity toward the respective other enzyme. Additionally, novel derivatives were synthesized and biologically evaluated. By this means, the structural features needed for benzamidobenzoic acids to be potent and, most notably, selective PqsD inhibitors were identified. The most interesting compound of this study was the 3-Cl substituted compound 5 which strongly inhibits PqsD (IC₅₀ 6.2 μM) while exhibiting no inhibition of RNAP.

Combining in silico and biophysical methods for the development of Pseudomonas aeruginosa quorum sensing inhibitors: an alternative approach for structure-based drug design

The present work deals with the optimization of an inhibitor of PqsD, an enzyme essential for Pseudomonas aeruginosa quorum sensing apparatus. Molecular docking studies, supported by biophysical methods (surface plasmon resonance, isothermal titration calorimetry, saturation transfer difference NMR), were used to illuminate the binding mode of the 5-aryl-ureidothiophene-2-carboxylic acids. Enabled to make profound predictions, structure-based optimization led to increased inhibitory potency. Finally a covalent inhibitor was obtained. Binding to the active site was confirmed by LC-ESI-MS and MALDI-TOF-MS experiments. Following this rational approach, potent PqsD inhibitors were efficiently developed within a short period of time. This example shows that a combination and careful application of in silico and biophysical methods represents a powerful complement to cocrystallography.

Novel small molecule inhibitors targeting the "switch region" of bacterial RNAP: structure-based optimization of a virtual screening hit

Rising resistance against current antibiotics necessitates the development of antibacterial agents with alternative targets. The "switch region" of RNA polymerase (RNAP), addressed by the myxopyronins, could be such a novel target site. Based on a hit candidate discovered by virtual screening, a small library of 5-phenyl-3-ureidothiophene-2-carboxylic acids was synthesized resulting in compounds with increased RNAP inhibition. Hansch analysis revealed π (lipophilicity constant) and σ (Hammet substituent constant) of the substituents at the 5-phenyl moiety to be crucial for activity. The binding mode was proven by the targeted introduction of a moiety mimicking the enecarbamate side chain of myxopyronin into the hit compound, accompanied by enhanced RNAP inhibitory potency. The new compounds displayed good antibacterial activities against Gram positive bacteria and Gram negative Escherichia coli TolC and a reduced resistance frequency compared to the established antibiotic rifampicin.

Peptide-based investigation of the Escherichia coli RNA polymerase σ(70):core interface as target site

The number of bacterial strains that are resistant against antibiotics increased dramatically during the past decades. This fact stresses the urgent need for the development of new antibacterial agents with novel modes of action targeting essential enzymes such as RNA polymerase (RNAP). Bacterial RNAP is a large multi-subunit complex consisting of a core enzyme (subunits: α(2)ββ'ω) and a dissociable sigma factor (σ(70); holo enzyme: α(2)ββ'ωσ(70)) that is responsible for promoter recognition and transcription initiation. The interface between core RNAP and σ(70) represents a promising binding site. Nevertheless, detailed studies investigating its druggability are rare. Compounds binding to this region could inhibit this protein-protein interaction and thus holo enzyme formation, resulting in inhibition of transcription initiation. Sixteen peptides covering different regions of the Escherichia coli σ(70):core interface were designed; some of them-all derived from σ(70) 2.2 region-led to a strong RNAP inhibition. Indeed, an ELISA-based experiment confirmed the most active peptide P07 to inhibit the σ(70):core interaction. Furthermore, an abortive transcription assay revealed that P07 impedes transcription initiation. In order to study the mechanism of action of P07 in more detail, molecular dynamics simulations and a rational amino acid replacement study were performed, leading to the conclusion that P07 binds to the coiled-coil region in β' and that its flexible N-terminus inhibits the enzyme by interaction with the β' lid-rudder-system (LRS). This work revisits the β' coiled-coil as a hot spot for the protein-protein interaction inhibition and expands it by introduction of the LRS as target site.