The Tryptophan-Induced tnaC Ribosome Stalling Sequence Exposes High Amino Acid Cross-Talk That Can Be Mitigated by Removal of NusB for Higher Orthogonality.

A growing number of engineered synthetic circuits have employed biological parts coupling transcription and translation in bacterial systems to control downstream gene expression. One such example, the leader sequence of the tryptophanase (tna) operon, is a transcription-translation system commonly employed as an l-tryptophan inducible circuit controlled by ribosome stalling. While induction of the tna operon has been well-characterized in response to l-tryptophan, cross-talk of this modular component with other metabolites in the cell, such as other naturally occurring amino acids, has been less explored. In this study, we investigated the impact of natural metabolites and E. coli host factors on induction of the tna leader sequence. To do so, we constructed and biochemically validated an experimental assay using the tna operon leader sequence to assess differential regulation of transcription elongation and translation in response to l-tryptophan. Operon induction was then assessed following addition of each of the 20 naturally occurring amino acids to discover that several additional amino acids (e.g., l-alanine, l-cysteine, l-glycine, l-methionine, and l-threonine) also induce expression of the tna leader sequence. Following characterization of dose-dependent induction by l-cysteine relative to l-tryptophan, the effect on induction by single gene knockouts of protein factors associated with transcription and/or translation were interrogated. Our results implicate the endogenous cellular protein, NusB, as an important factor associated with induction of the operon by the alternative amino acids. As such, removal of the nusB gene from strains intended for tryptophan-sensing utilizing the tna leader region reduces amino acid cross-talk, resulting in enhanced orthogonal control of this commonly used synthetic system.

HPLC, quantitative NMR and HRMS spectroscopic data of nusbiarylins as a new class of antimicrobial agents.

Bacterial transcription is a valid but underutilized target for antimicrobial agent discovery [1]. Nusbiarylins are the first-in-class bacterial ribosomal RNA synthesis inhibitors that possess potent activity against various types of multidrug-resistant bacteria with a novel mode of action by targeting the interaction of bacterial transcription factors NusB and NusE [2]. To facilitate the characterization of nusbiarylin derivatives produced by other researchers, high-performance liquid chromatography (HPLC) profiles, quantitative nuclear magnetic resonance (qNMR) and high-resolution mass spectrometry (HRMS) spectroscopic data were presented for the quick determination of purity and characterization of 95 nusbiarylin compounds. The data presented in this article supplement the 1H and 13C NMR data provided previously [3,4], and assist the reproduction of nusbiarylins for chemical, biological and drug discovery research.

Nusbiarylins, a new class of antimicrobial agents: Rational design of bacterial transcription inhibitors targeting the interaction between the NusB and NusE proteins.

Discovery of antibiotics of a novel mode of action is highly required in the fierce battlefield with multi-drug resistant bacterial infections. Previously we have validated the protein-protein interaction between bacterial NusB and NusE proteins as an unprecedented antimicrobial target and reported the identification of a first-in-class inhibitor of bacterial ribosomal RNA synthesis with antimicrobial activities. In this paper, derivatives of the hit compound were rationally designed based on the pharmacophore model for chemical synthesis, followed by biological evaluations. Some of the derivatives demonstrated the improved antimicrobial activity with the minimum inhibitory concentration (MIC) at 1-2 µg/mL against clinically significant bacterial pathogens. Time-kill kinetics, confocal microscope, ATP production, cytotoxicity, hemolytic property and cell permeability using Caco-2 cells of a representative compound were also measured. This series of compounds were named "nusbiarylins" based on their target protein NusB and the biaryl structure and were expected to be further developed towards novel antimicrobial drug candidates in the near future.

Identification and validation of small molecule modulators of the NusB-NusE interaction.

Formation of highly possessive antitermination complexes is crucial for the efficient transcription of stable RNA in all bacteria. A key step in the formation of these complexes is the protein-protein interaction (PPI) between N-utilisation substances (Nus) B and E and thus this PPI offers a novel target for a new antibiotic class. A pharmacophore developed via a secondary structure epitope approach was utilised to perform an in silico screen of the mini-Maybridge library (56,000 compounds) which identified 25 hits of which five compounds were synthetically tractable leads. Here we report the synthesis of these five leads and their biological evaluation as potential inhibitors of the NusB-NusE PPI. Two chemically diverse scaffolds were identified to be low micro molar potent PPI inhibitors, with compound (4,6-bis(2',4',3.4 tetramethoxyphenyl))pyrimidine-2-sulphonamido-N-4-acetamide 1 and N,N'-[1,4-butanediylbis(oxy-4,1-phenylene)]bis(N-ethyl)urea 3 exhibiting IC50 values of 6.1µM and 19.8µM, respectively. These inhibitors were also shown to be moderate inhibitors of Gram-positive Bacillus subtilis and Gram-negative Escherichia coli growth.