Dam methylation and putative fimbriae in Klebsiella pneumoniae

Kuehn, Joanna Sue. Clegg, Steven.

January 2009

Thesis supervisor: Steven Clegg. Includes bibliographic references (p. 123-131).

Dam methylation and putative fimbriae in Klebsiella pneumoniae

Kuehn, Joanna Sue

01 December 2009

DNA adenine methyltransferase (Dam) plays an important role in different bacterial functions. It has been shown that Dam is required for regulation of bacterial replication initiation and is required for proofreading newly synthesized DNA through methylation directed mismatch repair. Dam is also involved in the regulation of different genes and is required for virulence in several different bacterial genera though its degree of importance depends on the specific bacteria being studied. During this work, a Dam-negative strain (JSM1) was constructed in Klebsiella pneumoniae strain 43816 to ascertain its importance for K. pneumoniae viability and virulence. To test JSM1 for expression of fimbrial virulence factors, agglutinations were used to detect the presence of type three and type one fimbriae, respectively. No differences between 43816 and JSM1 were discernable. Similarly, JSM1 production of capsular material appeared to be unaltered. K. pneumoniae JSM1 virulence in a murine model was examined following intranasal or intraperitoneal inoculation, and it was determined that JSM1 is partially attenuated. Quantitative analysis of 43816 and JSM1 biofilm growth revealed only slight decreases in JSM1 biofilm mass and thickness, but live/dead staining of developed biofilms showed decreased JSM1 biofilm viability over time compared to 43816 biofilms. JSM1 was also examined for alterations in the frequency of spontaneous antibiotic resistance mutations and tested for increased susceptibility to various DNA damaging agents, and statistically significant differences were found for some of the spontaneous antibiotic resistance mutation frequencies tested. Fimbriae in K. pneumoniae are important virulence factors which facilitate respiratory and urinary tract infections in vivo. They also contribute to formation of biofilms which are believed to cause chronic infections and increased antibiotic resistance. Searches for homologous regions within the Klebsiella chromosome using the chaperone and usher components of E. coli type 1 fimbriae revealed five putative fimbrial gene clusters on the Klebsiella chromosome which had not been characterized. Mutations created within select gene clusters did not yield detectable deficiencies in biofilm formation or murine respiratory virulence. However, based on the multiplicity of fimbrial expression observed in Salmonella enterica serovar Typhimurium, combinational mutations may be required prior to detection of a discernable phenotype.

Dam

DNA adenine methylase

DNA adenine methyltransferase

fimbriae

Klebsiella

Microbiology

Biochemical Characterization Of An Acid-Adaptive Type III DNA Methyltransferase From Helicobacter Pylori 26695 And Its Biological Significance

Banerjee, Arun

07 1900

Enzyme DNA methylation is an important biochemical process that imprints DNA with additional information. DNA methylation is catalyzed by S-adenosyl-L-methionine (AdoMet)-dependent methyltraferases (MTases). Prokaryotic DNA MTases are usually components of restriction-modification(R-M) systems that enable cells to resist propagation of foreign genomes that would otherwise kill them. Based on the position methyl group transfer on the bases in DNA, MTases are classified into two groups-exocyclic or amino MTases and endocyclic or ring MTases. The amino MTases methylate exocyclic amino nitrogen to form either N6-methyladenine or n4-methycytosine. N6-methyaladenine is mostly found in the genomes of bacteria, archaea protists and fungi. Helicobacter pylori is a gram-negative, flagellated, fastidious bacterium that colonizes the highly acidic environment of the gastric mucosa. Frequently and persistence of H.paylori infection in humans make it attractive model for studying the host- pathogen interaction mechanisms. Analysis of the genome sequence of H.pylori strains 26695, J99.HPAGI, and G27 revealed an abundance of restriction-modification (R-M) systems. Most of the R-M system genes are either conserved among the strains or specific to each strain. Strain specific genes are responsible for different phenotypes in several host adapted pathogens such as H.pylori. Many of the R-M gene homologues exhibit different usages of condon bias and lower G+C content from the average genes suggesting horizontal transfer of the R-M system genes in H. Pylori. Genome analysis of strain 26695 showed the presence of three putative type III R-M systems and hp0592-hp0593 constitutes one such type III R-M system. Based on the conserved motif arrangements, HP0593 MTases belongs to the subgroups of MTases. The amino acid sequence of HP0593 MTases has 38% sequence identity to Ecop11 MTases and EcoP151 MTase, both of which belongs to type IIIR-M systems therefore, it was important to study in detail previously unexplored role of this putative type III DNA MTase (HP0593) in H. Pylori. Investigation of methyltransferease activity and sequence specifically of putative DNA adenine MTase (HP0593) HP0593 (N6-adenine) - DNA MTase is a member of a type III R-M system in H. pylori strain 26695. HP0593 MTase has been cloned, over expressed and purified heterologously in Escherichia coli. Matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) was carried out with purified HP0593 and profile showed a single peak with expected molecular mass of 70.6kDa. The protein was determined as-5.8. HP0593 MTase exits predominantly as monomer and a small fraction as dimer in solution as determined by size exclusion chromatography and glutaraldehyde cross-linking studies. The recognition sequence of the purified MTase was determined as 5’GCAG-3’ and the target base of methylation is adenine. Dot-blot assay using antibodies that reacted specifically with DNA containing m6A modification confirmed that HP0593 MTase is an adenine specific MTase. Exocyclic MTase have a conserved catalytic motif (D/N/S/SPPY/F/W). Most interestingly, the amino acid sequence analysis of HP0593 MTase revealed the presence of a PCQ-like motif, which is the catalytic motif for C5-cytosine MTase in addition to DPPY motif. In order to check the role of both these MTase by glycine. HP0593 –Y107G and C54G mutant proteins were purified to near homogeneity. It was found that the Y107G mutant protein was catalytically inactive as compared to wild-type HP0593 MTase. On the other hand the C54G mutant protein was found to be as active as the wild-type HP0593 MTase indicating that HP0593 MTase is an adenine MTase and not a C5- cytosine MTase. Kinetic and catalytic properties of HP0593 DNA adenine methyltransferase DNA binding studies were carried out by electrophoretic mobility shift assay using DNA having cognate site and either in absence or presence of AdoHcy or sinefungin. In all the three cases two different DNA-protein complexes were observed-a fast running complex I and a slow running complex 2. It can be surmised that the fast running complex could be HP0593 monomer-DNA and the slow running complex could be a HP0593 dimer-DNA complex. With non specific DNA (lacking 5’-GCAG-3’ sequences) no complexes were formed even in the presence of cofactors. Based on the above observations it is suggested that a specific interactions of HP0593 MTase with DNA occurs on cognate recognition site. The activity of HP0593 MTase is optional at pH 5.5. This is a unique property in context of natural adaptation of H. pylori in its acidic niche. When initial velocities were plotted against varying concentrations of duplex DNA having a single 5’GCAG-3’ site a rectangular hyperbola was obtained confirming that HP0593 MTase obeys michaelis menten kinetics. From non-linear regression analysis of the plot of initial velocity versus DNA concentration Km (DNA) and kcat were calculated. Analysis of initial velocity with AdoMet as a substrate showed that two molecules of AdoMet bind to HP0593 MTase. The nonlinear dependence of methylation activity on enzyme concentration indicated that more than one molecule of methylation activity on enzyme concentration indicated that more than one molecule of enzyme is required for its activity. Metal ion cofactors such as CO 2, Mn2+ and Mg2+ stimulated the HP09593 MTase activity. As Mn2+ showed maximum stimulation of methyaltion activity compared to other metal ions, surface plasmon resonance spectroscopy was used to determine the kinetics of DNA binding by HP0593 MTase in the absence and presence of Mn2+. In the presence of Mn2+, HP0593 MTase showed~1000-fold increase in affinity to duplex DNA. DNA MTase bind substrates in random or sequential order. Preincubation study demonstrated that the preformed enzyme-DNA complex is competent than the preformed enzyme-AdoMet complex. This suggests that MTase binds to DNA first followed by AdoMet. Isotope partitioning analysis indicated that HP0593 MTase shows a distributive mechanism of methylation DNA having more than one recognition site. Effects of inactivation of HP0593 DNA MTase in Helicobacter pylori 26695 strain and its functional role. DNA dot-blot assay using hp0593 gene specific primer showed that this gene is present in 25.15% of the clinical strains checked suggesting that hp0593 is strain-specific gene. Strain-specific genes in many host-adapted pathogene impart strain specific phenotype. Wild-type 26695 strain grew slightly faster at the initial phase of growth in PH 4.5 compared to pH 7.4. A~5-fold enhanced level of hp0593 mRNA expression was growth under acidic condition HP0593 MTase could play an important role in H. pylori physiology through methylation. To elucidate the possible role(s) played by the MTase in H.pylori physiology, an hp0593 knock-out in 26695 strain was generated by chloramphenecol cassette mediated insertional gene inactivation. Growth kinetic study was carried out with both wild-type and hp0593 knock-out strain at pH7.4, the growth of the hp0593 strain. At pH 4.5 no major differences were observed in the growth compared to the wild-type hp0593 knock-out strain. To further investigate the effect of the knock-out, cell-morphology study was carried out after growing the strains at pH 7.4 till mid-exponential phase. Transmission electron microscopy studies reveled changes in cell shape, presence of sheathed structure and production of outer membrane vesicles (OMVs) in the hp0593 knock out strain. OMVs contain effectors molecules during infection helps in pathogenicity caused by H.pylori.This is the first report where inactivation of DNA MTase causes shedding of vesicles. OMVs are also known to modulate the production of IL-8 by gastic epitheial cells. To check weather H.pylori strains could produce IL-8, both wild-type and hp0593 knock-out strains were co-cultured with AGS cell infected with the hp0593 knock out strain. This was further confirmed by semi-quantitative RT-PCR analysis. To analyze the different phenotypes observed in the hp0593 knock-out strain, transcriptome profile were compared by microarray and RT-PCR analysis. In thehp0593 knock-out strain peptidologlycan and murein synthesis genes like pbp2, murC and neu4 showed upregulation which could be responsible for the changes in cell shape presence of sheathed structure and OMVs production. The RT-PCR data showed ~9-fold down-regulation of dank chaperone which might play a key role in slow growth phenotype in the hp0593 knock-out strain. Considering the occurrence of GCAG sequence in the potential promoter regions of physiologically important genes such as dank, neuA, murC, fliH, filP and cag5, the results presented in this study provide impetus for exploring the role of HP0593 DNA MTase in the cellular processes of H.pylori. However, R-M systems are not absolutely essential, but different methylation patterns may contribute to strain-specific epigenetic gene regulation and may contribute to variability among the strains.

DNA Methyltransferase - Biochemistry

Helicobacter pylori 26695

DNA Adenine Methyltransferase

HP0593 Gene

H. pylori

Adenine Methyltransferase

DNA Adenine MTase

Type III R-M Systems

Bacteriology