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Phase variable methyltransferases and their role in gene regulation in pathogenic bacteria

Previous work carried out in our laboratory has identified that phase variation of type III R-M systems found in Haemophilus influenzae, Neisseria meningitidis and N. gonorrhoeae is reversible, and occurs at high frequency, as seen both through mod::lacZ fusions, and by measuring changes in repeat tract length. In addition, phase variation of the methyltransferases results in coordinated switching of expression of a distinct group of genes in each of the strains studied so far. WE have termed this phenomenon the PHASEVARION, for phase variable regulon, to identify the set of genes whose expression is affected by moe phase variation. Many of the genes found to be regulated by mod phase variation are known virulence factors and even include some genes investigated as candidates for vaccine development (Srikhanta et al., 2005 and 2009. The aims of this project was to further the investigation of how these R-M systems regulated the expression of genes which hitherto had not been predicted to phase vary. The first step in the process of investigating how phase variable R-M systems influence expression of unrelated genes is to identify the DNA sequences methylated by the methyltransferases of interest. As discussed in Chapter 3, elucidation of the ModA1 methylation target site was in part facilitated by predictions that the phase variable methyltransferase found in H. influenzae strain Rd methylated the same sequence as did HinfIII, isolated from H. influenzae strain Rf. This hypothesis was confirmed by methylation dependent inhibition of digestion, revealing that ModA1 methylates the second A in its recognition sequence, 5’-CGAAT-3’. Once confirmed, the genes found to be regulated by modA1 phase variation in the initial phasevarion study could be investigated for the presence of ModA1 methylation sites within their promoters or upstream of their transcriptional regulators. Two such methylation target sites were located just upstream of the dnaK ORF. Transcriptional start site analysis of the dnaK gene revealed three transcripiotnal start sites, one of which is unduced by heat shock. Exactly 10 nucleotides upstream of this heat shock induced transcriptional start site lies one of these ModA1 methylation target sequences. Ongoing invetigations are looking into the importance of this ModA1 site located within the dnaK promoter, and whether this is the site responsible for ModA1 dependent variations in dnaK expression. Although numerous methods were investigated for their potential to identify all sites methylated by the different modA alleles, the only method which resulted in identification of any methylation target sites was methylation dependent inhibition of restriction. This method allowed us to confirm the ModA1 recongition sequence, and to discover the methylation sequence, and adenine targeted by the modA13 allele, which is found in many clinically relevant N. gonorrhoeae strains. As will be discussed in Chapter 5, ModA13 dependent inhibition of restriction was first observed when the Neisserial plasmid pCmGFP was extracted from modA13 ON and modA13::kan cells, and further investigated and confirmed using a Southern blot approach to determine whether ModA13 dependent inhibtion could be detected as differential methylation of the chromosome. It was found that ModA13 recognised the sequence 5’-AGAAA-3’, with methylation occurring on the second last A. This sequence was mapped not only to the genes found to be regulated by modA13 phase variation, but also to the entire FA1090 chromosome, and this information will be used in future studies to investigate the direct molecular mechanisms by which modA13 phase variation results in subpopulations with different phenotypes in relation to antimicrobial resistance and biofilm/cell invasion.

Identiferoai:union.ndltd.org:ADTP/279173
CreatorsStefanie Dowideit
Source SetsAustraliasian Digital Theses Program
Detected LanguageEnglish

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