Investigating the Effectiveness of mqsR-Peptide Nucleic Acid as a Novel Solution for the Eradication of Persister Cells in Clinical Isolates of Escherichia coli.

BACKGROUND: Bacterial persisters are non- or slow-growing phenotypic variants that may be responsible for recalcitrance and relapse of persistent infections and antibiotic failure. In Escherichia coli, mqsRA is a well-known type II toxin-antitoxin system associated with persister cell formation. This study aimed to investigate the efficiency of an antisense peptide nucleic acid (PNA) targeting mqsRA in eliminating E. coli persisters. METHODS: The study included 600 non-duplicated urine samples from adult patients with suspected urinary tract infections. The isolates were subjected to antimicrobial susceptibility testing and bacterial persister cells assay. The presence of mqsRA in the isolates was evaluated by polymerase chain reaction. Finally, expression of the mqsR and mqsA genes was assessed after exposure to normal conditions, stress, and different concentrations of mqsR-PNA (1 - 35 µM). RESULTS: The mqsR gene was significantly overexpressed under stress conditions, which was compensated by the PNA treatment. Complete inhibition of E. coli persister cells was achieved after overnight treatment with the anti-mqsR-PNA at concentrations ≥ 15 µM. CONCLUSIONS: The growth of E. coli persister cells can be inhibited by the anti-mqsR-PNA. Further studies are required to evaluate the effectiveness of this antisense PNA in both preclinical and clinical settings.

Application of meta- and para-Phenylenediamine as Enhanced Oxime Ligation Catalysts for Protein Labeling, PEGylation, Immobilization, and Release.

Meta- and para-phenylenediamines have recently been shown to catalyze oxime and hydrazone ligation reactions at rates much faster than aniline, a commonly used catalyst. Here, we demonstrate how these new catalysts can be used in a generally applicable procedure for fluorescent labeling, PEGylation, immobilization, and release of aldehyde- and ketone- functionalized proteins. The chemical orthogonality of phenylenediamine-catalyzed oxime ligation versus copper-catalyzed click reaction has also been harnessed for simultaneous dual labeling of bifunctional proteins containing both aldehyde and alkyne groups in high yield.

Chemoenzymatic site-specific reversible immobilization and labeling of proteins from crude cellular extract without prior purification using oxime and hydrazine ligation.

In a facile and potentially general method for protein modification at the C-terminus, aldehyde-modified proteins, obtained from enzymatic protein prenylation, react rapidly with hydrazide and aminooxy surfaces and fluorophores at neutral pH and in micromolar concentration ranges of reagents. This strategy was used for fluorescent labeling of eGFP-CVIA, as a model protein, with aminooxy and hydrazide fluorophores or PEGs, and immobilization onto and subsequent release of the protein from hydrazide-functionalized agarose beads using hydrazone-oxime exchange. This method is described in detail here and provides site-specifically PEGylated or fluorescently labeled proteins starting from crude cellular extract in three steps: prenylation, capture, and release.

A highly efficient catalyst for oxime ligation and hydrazone-oxime exchange suitable for bioconjugation.

Imine-based reactions are useful for a wide range of bioconjugation applications. Although aniline is known to catalyze the oxime ligation reaction under physiological conditions, it suffers from slow reaction kinetics, specifically when a ketone is being used or when hydrazone-oxime exchange is performed. Here, we report on the discovery of a new catalyst that is up to 15 times more efficient than aniline. That catalyst, m-phenylenediamine (mPDA), was initially used to analyze the kinetics of oxime ligation on aldehyde- and ketone-containing small molecules. While mPDA is only modestly more effective than aniline when used in equal concentrations (~2-fold), its much greater aqueous solubility relative to aniline allows it to be used at higher concentrations, resulting in significantly more efficient catalysis. In the context of protein labeling, it was first used to site-specifically label an aldehyde-functionalized protein through oxime ligation, and its kinetics were compared to reaction with aniline. Next, a protein was labeled with an aldehyde-containing substrate in crude cell lysate, captured with hydrazide-functionalized beads and then the kinetics of immobilized protein release via hydrazone-oxime exchange were analyzed. Our results show that mPDA can release and label 15 times more protein than aniline can in 3 h. Then, using the new catalyst, ciliary neurotrophic factor, a protein with therapeutic potential, was successfully labeled with a fluorophore in only 5 min. Finally, a protein containing the unnatural amino acid, p-acetyl phenylalanine, a ketone-containing residue, was prepared and PEGylated efficiently via oxime ligation using mPDA. This new catalyst should have a significant impact on the field of bioconjugation, where oxime ligation and hydrazone-oxime exchange are commonly employed.