Competence in Streptococcus pneumoniae Is a Response to an Increasing Mutational Burden

Alyssa L Gagne,Kathleen E Stevens,Diana J Chang,Michael E Sebert,Amit Pujari,Marco Cassone,Olufunke E Abiola

doi:10.1371/journal.pone.0072613

Alyssa L Gagne, Kathleen E Stevens + Show 5 more

Open Access

https://doi.org/10.1371/journal.pone.0072613

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Abstract

Competence for genetic transformation in Streptococcus pneumoniae has previously been described as a quorum-sensing trait regulated by a secreted peptide pheromone. Recently we demonstrated that competence is also activated by reduction in the accuracy of protein biosynthesis. We have now investigated whether errors upstream of translation in the form of random genomic mutations can provide a similar stimulus. Here we show that generation of a mutator phenotype in S. pneumoniae through deletions of mutX, hexA or hexB enhanced the expression of competence. Similarly, chemical mutagenesis with the nucleotide analog dPTP promoted development of competence. To investigate the relationship between mutational load and the activation of competence, replicate lineages of the mutX strain were serially passaged under conditions of relaxed selection allowing random accumulation of secondary mutations. Competence increased with propagation in these lineages but not in control lineages having wild-type mutX. Resequencing of these derived strains revealed between 1 and 9 single nucleotide polymorphisms (SNPs) per lineage, which were broadly distributed across the genome and did not involve known regulators of competence. Notably, the frequency of competence development among the sequenced strains correlated significantly with the number of nonsynonymous mutations that had been acquired. Together, these observations provide support for the hypothesis that competence in S. pneumoniae is regulated in response to the accumulated burden of coding mutations in the bacterial genome. In contrast to previously described DNA damage response systems that are activated by physical lesions in the chromosome, this pneumococcal pathway may represent a unique stress response system that monitors the coding integrity of the genome.

Highlights

Natural competence for genetic transformation is a widespread phenomenon found in diverse groups of bacteria, but the primary function of this trait has remained uncertain [1,2]
To test whether the induction of competence by dPTP required the established peptide pheromone signaling pathway, we evaluated the impact of the mutagen in the context of a comA deletion, which prevents the export of competence-stimulating peptide (CSP) [9]
Evidence has recently been developing that genetic competence in S. pneumoniae represents a type of bacterial stress response [10,11]

Summary

Introduction

Natural competence for genetic transformation is a widespread phenomenon found in diverse groups of bacteria, but the primary function of this trait has remained uncertain [1,2]. The observation that DNA damage does not induce competence in either Haemophilus influenzae or Bacillus subtilis has been seen as additional evidence against a primary repair function for competence in these organisms [4]. Competence in the respiratory tract pathogen S. pneumoniae (aka the pneumococcus) is accompanied by a behavior described as fratricide wherein competent cells lyse other pneumococci [8]. This process of active bacterial predation has the potential to circumvent the problem of poor quality DNA in the extracellular pool and may thereby improve the ability of transformation to increase fitness

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