Excision-reintegration at a pneumococcal phase-variable restriction-modification locus drives within- and between-strain epigenetic differentiation and inhibits gene acquisition.

Phase-variation of Type I restriction-modification systems can rapidly alter the sequence motifs they target, diversifying both the epigenetic patterns and endonuclease activity within clonally descended populations. Here, we characterize the Streptococcus pneumoniae SpnIV phase-variable Type I RMS, encoded by the translocating variable restriction (tvr) locus, to identify its target motifs, mechanism and regulation of phase variation, and effects on exchange of sequence through transformation. The specificity-determining hsdS genes were shuffled through a recombinase-mediated excision-reintegration mechanism involving circular intermediate molecules, guided by two types of direct repeat. The rate of rearrangements was limited by an attenuator and toxin-antitoxin system homologs that inhibited recombinase gene transcription. Target motifs for both the SpnIV, and multiple Type II, MTases were identified through methylation-sensitive sequencing of a panel of recombinase-null mutants. This demonstrated the species-wide diversity observed at the tvr locus can likely specify nine different methylation patterns. This will reduce sequence exchange in this diverse species, as the native form of the SpnIV RMS was demonstrated to inhibit the acquisition of genomic islands by transformation. Hence the tvr locus can drive variation in genome methylation both within and between strains, and limits the genomic plasticity of S. pneumoniae

Recombination of the phase variable spnIII locus is independent of all known pneumococcal site-specific recombinases.

Streptococcus pneumoniae is one of the world's leading bacterial pathogens, causing pneumonia, septicaemia and meningitis. In recent years it has been shown that genetic rearrangements in a type I restriction-modification system (SpnIII) can impact colony morphology and gene expression. By generating a large panel of mutant strains, we have confirmed a previously reported result that the CreX (also known as IvrR and PsrA) recombinase found within the locus is not essential for hsdS inversions. In addition, mutants of homologous recombination pathways also undergo hsdS inversions. In this work we have shown that these genetic rearrangements, which result in different patterns of genome methylation, occur across a wide variety of serotypes and sequence types including two strains (a 19F and a 6B strain) naturally lacking CreX. Our gene expression analysis, by RNAseq, confirm that the level of creX expression is impacted by these genomic rearrangements. In addition, we have shown that the frequency of hsdS recombination is temperature dependent. Most importantly we have demonstrated that the other known pneumococcal site-specific recombinases XerD, XerS and SPD_0921 are not involved in spnIII recombination, suggesting a currently unknown mechanism is responsible for the recombination of these phase variable type I systems.ImportanceStreptococcus pneumoniae is a leading cause of pneumonia, septicaemia and meningitis. The discovery that genetic rearrangements in a type I restriction modification locus can impact gene regulation and colony morphology have led to a new understanding of how this pathogen switches from harmless coloniser to invasive pathogen. These rearrangements, which alter the DNA specificity of the type I restriction modification enzyme, occur across many different pneumococcal serotypes and sequence types, and in the absence of all known pneumococcal site-specific recombinases. This finding suggests that this is a truly global mechanism of pneumococcal gene regulation and the need for further investigation of mechanisms of site specific recombination

Methylation warfare: interaction of pneumococcal bacteriophages with their host.

Virus-host interactions are regulated by complex co-evolutionary dynamics. In S. pneumoniae phase-variable Type I restriction modification (R-M) systems are part of the core genome. We hypothesised that the ability of the R-M systems to switch between six target DNA specificities also has a key role in preventing the spread of bacteriophages. Using the streptococcal temperate bacteriophage SpSL1, we showed that the variants of both the SpnIII and SpnIV R-M system were able to restrict invading bacteriophage proportional to the number of target sites in the bacteriophage genome. In addition to restriction of lytic replication SpnIII also led to abortive infection in the majority of host cells. During lytic infection, transcriptional analysis found evidence of phage-host interaction through the strong upregulation of the nrdR nucleotide biosynthesis regulon. During lysogeny, the phage had less effect on host gene regulation. This research demonstrates a novel combined bacteriophage restriction and abortive infection mechanism, highlighting the importance that the phase-variable Type I R-M systems have in the multi-functional defence against bacteriophage infection in the respiratory pathogen S. pneumoniae.Importance With antimicrobial drug resistance becoming an increasing burden on human health, much attention has been focussed on the potential use of bacteriophages and their enzymes as therapeutics. However, the investigations into the physiology of the complex interactions of bacteriophages with their hosts has attracted far less attention in comparison. This work describes the molecular characterisation of the infectious cycle of a bacteriophage of the important human pathogen Streptococcus pneumoniae and explores the intricate relationship between phase variable host defence mechanisms and the virus. This is the first report showing how a phase variable type I restriction modification system is involved in bacteriophage restriction, whilst also providing an additional level of infection control through abortive infection