Reducing ppGpp Level Rescues an Extreme Growth Defect Caused by Mutant EF-Tu

Jessica M Bergman,Diarmaid Hughes,Disa L Hammarlöf,Eric Jan

doi:10.1371/journal.pone.0090486

Jessica M Bergman, Diarmaid Hughes + Show 2 more

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https://doi.org/10.1371/journal.pone.0090486

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Journal: PloS one	Publication Date: Feb 28, 2014
Citations: 48	License type: CC BY 4.0

Affiliation: Uppsala University

Abstract

Transcription and translation of mRNA's are coordinated processes in bacteria. We have previously shown that a mutant form of EF-Tu (Gln125Arg) in Salmonella Typhimurium with a reduced affinity for aa-tRNA, causes ribosome pausing, resulting in an increased rate of RNase E-mediated mRNA cleavage, causing extremely slow growth, even on rich medium. The slow growth phenotype is reversed by mutations that reduce RNase E activity. Here we asked whether the slow growth phenotype could be reversed by overexpression of a wild-type gene. We identified spoT (encoding ppGpp synthetase/hydrolase) as a gene that partially reversed the slow growth rate when overexpressed. We found that the slow-growing mutant had an abnormally high basal level of ppGpp that was reduced when spoT was overexpressed. Inactivating relA (encoding the ribosome-associated ppGpp synthetase) also reduced ppGpp levels and significantly increased growth rate. Because RelA responds specifically to deacylated tRNA in the ribosomal A-site this suggested that the tuf mutant had an increased level of deacylated tRNA relative to the wild-type. To test this hypothesis we measured the relative acylation levels of 4 families of tRNAs and found that proline isoacceptors were acylated at a lower level in the mutant strain relative to the wild-type. In addition, the level of the proS tRNA synthetase mRNA was significantly lower in the mutant strain. We suggest that an increased level of deacylated tRNA in the mutant strain stimulates RelA-mediated ppGpp production, causing changes in transcription pattern that are inappropriate for rich media conditions, and contributing to slow growth rate. Reducing ppGpp levels, by altering the activity of either SpoT or RelA, removes one cause of the slow growth and reveals the interconnectedness of intracellular regulatory mechanisms.

Highlights

Translation Elongation Factor Tu (EF-Tu) plays a crucial role in protein synthesis [1], forming a complex with each aminoacylated tRNA and carrying it to the decoding site on translating ribosomes
Strains in which one tuf gene is inactivated produce approximately 66% of the wild-type amount of EF-Tu and have a maximum growth rate in rich medium (Luria broth, LB) that is reduced to a similar degree [2,3,6]
Free-living bacteria constantly adjust their rates and patterns of macromolecular synthesis in response to the nutritional status of their environment [24,25]. This ability to make appropriate adjustments is key to their survival in natural environments and understanding the details of these processes may be key to manipulating or controlling bacterial growth and persistence in clinical settings

Summary

Introduction

Translation Elongation Factor Tu (EF-Tu) plays a crucial role in protein synthesis [1], forming a complex with each aminoacylated tRNA and carrying it to the decoding site on translating ribosomes. The degree of saturation of elongating ribosomes by ternary complex (EF-Tu?GTP?aa-tRNA) is a major determinant of the maximum growth rate of bacteria [2]. Typhimurium) EF-Tu is encoded by two widely separated genes, tufA and tufB, that encode identical proteins [3,4]. Strains in which one tuf gene is inactivated produce approximately 66% of the wild-type amount of EF-Tu and have a maximum growth rate in rich medium (Luria broth, LB) that is reduced to a similar degree [2,3,6]. Strains in which only one tuf gene is present (or active) facilitate the study of the phenotypes associated with mutant variants of EF-Tu

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