Methionyl-tRNA synthetase synthetic and proofreading activities are determinants of antibiotic persistence.

Bacterial antibiotic persistence is a phenomenon where bacteria are exposed to an antibiotic and the majority of the population dies while a small subset enters a low metabolic, persistent, state and are able to survive. Once the antibiotic is removed the persistent population can resuscitate and continue growing. Several different molecular mechanisms and pathways have been implicated in this phenomenon.

Deacylated tRNA Accumulation Is a Trigger for Bacterial Antibiotic Persistence Independent of the Stringent Response.

Bacterial antibiotic persistence occurs when bacteria are treated with an antibiotic and the majority of the population rapidly dies off, but a small subpopulation enters into a dormant, persistent state and evades death. Diverse pathways leading to nucleoside triphosphate (NTP) depletion and restricted translation have been implicated in persistence, suggesting alternative redundant routes may exist to initiate persister formation. To investigate the molecular mechanism of one such pathway, functional variants of an essential component of translation (phenylalanyl-tRNA synthetase [PheRS]) were used to study the effects of quality control on antibiotic persistence.

Did Amino Acid Side Chain Reactivity Dictate the Composition and Timing of Aminoacyl-tRNA Synthetase Evolution?

The twenty amino acids in the standard genetic code were fixed prior to the last universal common ancestor (LUCA). Factors that guided this selection included establishment of pathways for their metabolic synthesis and the concomitant fixation of substrate specificities in the emerging aminoacyl-tRNA synthetases (aaRSs). In this conceptual paper, we propose that the chemical reactivity of some amino acid side chains (e.

Indirect tRNA aminoacylation during accurate translation and phenotypic mistranslation.

The fact that most bacteria do not contain a full set of aminoacyl-tRNA synthetases (aaRS) is often underappreciated. In the absence of asparaginyl-tRNA and/or glutaminyl-tRNA synthetase (AsnRS and GlnRS), Asn-tRNA and/or Gln-tRNA are produced by an indirect tRNA aminoacylation pathway that relies on misacylation of these two tRNAs by two different misacylating aaRSs, followed by transamidation by an amidotransferase (GatCAB in bacteria). This review highlights the central importance of indirect tRNA aminoacylation to accurate protein translation, mechanistic peculiarities that appear to be unique to this system, and the newly recognized connection between indirect tRNA aminoacylation and mistranslation as a strategy used by bacteria to respond to environmental stressors like antibiotics.

Enhancing yields of low and single copy number plasmid DNAs from Escherichia coli cells.

Many plasmids used for gene cloning and heterologous protein expression in Escherichia coli cells are low copy number or single copy number plasmids. The extraction of these types of plasmids from small bacterial cell cultures produces low DNA yields. In this study, we have quantitated yields of low copy and single copy number plasmid DNAs after growth of cells in four widely used broths (SB, SOC, TB, and 2xYT) and compared results to those obtained with LB, the most common E.

Characterization of tunnel mutants reveals a catalytic step in ammonia delivery by an aminoacyl-tRNA amidotransferase.

The Helicobacter pylori Asp-tRNA(A) (sn) /Glu-tRNA(G) (ln) amidotransferase (GatCAB) utilizes an uncommonly hydrophilic, ~ 40 Å ammonia tunnel for ammonia/ammonium transport between isolated active sites. Hydrophilicity of this tunnel requires a distinct ammonia transport mechanism, which hypothetically occurs through a series of deprotonation and protonation steps. To explore the initiation of this relay mechanism, the highly conserved tunnel residue D185 (in the GatA subunit) was enzymatically and computationally investigated by comparing D185A, D185N, and D185E mutant enzymes to wild-type GatCAB.

Enhancement of plasmid DNA transformation efficiencies in early stationary-phase yeast cell cultures.

Chemical-based methods have been developed for transformation of DNA into log-phase cells of the budding yeast Saccharomyces cerevisiae with high efficiency. Transformation of early stationary-phase cells, e.g.