Analysis of non-typeable Haemophilous influenzae VapC1 mutations reveals structural features required for toxicity and flexibility in the active site.

Brooke Hamilton,Victoria Dimarco,Karyn Schmidt,J Scott Butler,Alexander Manzella,Manuela Helmer-Citterich

doi:10.1371/journal.pone.0112921

Brooke Hamilton, Victoria Dimarco + Show 4 more

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https://doi.org/10.1371/journal.pone.0112921

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Journal: PloS one	Publication Date: Nov 12, 2014
Citations: 9	License type: CC BY 4.0

Affiliation: University of Rochester Medical Center

Abstract

Bacteria have evolved mechanisms that allow them to survive in the face of a variety of stresses including nutrient deprivation, antibiotic challenge and engulfment by predator cells. A switch to dormancy represents one strategy that reduces energy utilization and can render cells resistant to compounds that kill growing bacteria. These persister cells pose a problem during treatment of infections with antibiotics, and dormancy mechanisms may contribute to latent infections. Many bacteria encode toxin-antitoxin (TA) gene pairs that play an important role in dormancy and the formation of persisters. VapBC gene pairs comprise the largest of the Type II TA systems in bacteria and they produce a VapC ribonuclease toxin whose activity is inhibited by the VapB antitoxin. Despite the importance of VapBC TA pairs in dormancy and persister formation, little information exists on the structural features of VapC proteins required for their toxic function in vivo. Studies reported here identified 17 single mutations that disrupt the function of VapC1 from non-typeable H. influenzae in vivo. 3-D modeling suggests that side chains affected by many of these mutations sit near the active site of the toxin protein. Phylogenetic comparisons and secondary mutagenesis indicate that VapC1 toxicity requires an alternative active site motif found in many proteobacteria. Expression of the antitoxin VapB1 counteracts the activity of VapC1 mutants partially defective for toxicity, indicating that the antitoxin binds these mutant proteins in vivo. These findings identify critical chemical features required for the biological function of VapC toxins and PIN-domain proteins.

Highlights

Type II toxin-antitoxin (TA) systems in bacteria first emerged as a mechanism of post-segregational killing caused by plasmid-borne TA operons [1,2]
Recent studies revealed the function of three members of this family as endonucleases that cleave initiator tRNAfMet in S. flexneri and S. typhimurium, or the sarcin-ricin loop of 23S rRNA in M. tuberculosis [15,21]
The findings presented here identify critical structural requirements for the biological function of VapC toxins and provide evidence for a conserved, alternative configuration of the active site in the VapC toxins of many bacteria

Summary

Introduction

Type II toxin-antitoxin (TA) systems in bacteria first emerged as a mechanism of post-segregational killing caused by plasmid-borne TA operons [1,2]. The discovery of chromosomally encoded TA systems led to the identification of several apparently distinct mechanisms of action for the encoded toxins [3,4]. These include ribonucleases that hydrolyze mRNA, rRNA and tRNA, DNA gyrase inhibitors and protein kinases that target translation. Stochastic fluctuations in toxin activity within populations of bacteria produce dormant cells resistant to many antibiotics [6,7]. These persisters can contribute to re-establishment of the bacterial population upon discontinuance of the drug. These characteristics make the elucidation of the mechanisms of TA function an important goal for molecular biologists

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