Project description:Identification of Corynebacterium diphtheriae manganese and MntR regulated genes

Project description:We assessed changes in gene expression in response to zinc availability for the human pathogen Corynebacterium diphtheriae. Expression profiles of wild-type C. diphtheriae strain 1737 grown in semi-defined metal-poor media (mPGT) without and with 5 µM zinc chloride supplementation were compared; the expression profile of wild-type C. diphtheriae strain 1737 in zinc-replete conditions was also compared against an isogenic Δzur mutant grown in zinc-replete conditions. Three biological replicates were prepared by isolating total RNA from mid-logarithmic growth cultures and eleven genes (dip0013, dip0093, dip0173, dip0438, dip1087, dip1486, dip1724, dip2114, dip2128, dip2162, and dip2325) were assessed by real-time PCR to validate the array results. (Abstract) Corynebacterium diphtheriae is a Gram-positive bacterial pathogen and the causative agent of diphtheria, a severe disease of the upper respiratory tract of humans. Factors required for C. diphtheriae to survive in the human host are not well defined, but likely include the acquisition of essential metals such as zinc. In C. diphtheriae, zinc-responsive global gene regulation is controlled by the Zinc Uptake Regulator (Zur), a member of the Fur-family of transcriptional regulators. In this study, we use transcriptomics to identify zinc-regulated genes in C. diphtheriae by comparing gene expression of a wild-type strain grown without and with zinc supplementation. Zur-regulated genes were identified by comparing wild-type gene expression with that of an isogenic zur mutant. We observed zinc repression of several putative surface proteins, the heme efflux system hrtBA, various ABC transporters, and the non-ribosomal peptide synthetase/polyketide synthase cluster sidAB. Furthermore, increased gene expression in response to zinc was observed for the alcohol dehydrogenase, adhA. Zinc and Zur regulation were confirmed for several genes by complementing the zur deletion and subsequent qPCR analysis. We used MEME to predict Zur binding sites within the promoter regions of zinc- and Zur-regulated genes, and verified Zur binding by electrophoretic mobility shift assays. Additionally, we characterized cztA (dip1101), which encodes a putative cobalt/zinc/cadmium efflux family protein. Deletion of cztA results in increased sensitivity to zinc, but not to cobalt or cadmium. This study advances our knowledge of changes to Zur-dependent global gene expression in response to zinc in C. diphtheriae. The identification of zinc-regulated ABC transporters herein will facilitate future studies to characterize zinc transport in C. diphtheriae.

Project description:ICP-MS analysis of Streptococcus pneumoniae D39 reveals a high cell-associated manganese (Mn(II)) concentration that is comparable to that of zinc (Zn(II)). Stressing these cells with 100-200 µM Zn(II) leads to a slow-growth phenotype and a reduction in total Mn(II) concentration, with no decrease in the concentrations of other metal ions. Supplementation of the growth media with as little as 10 µM Mn(II) fully restores wildtype growth patterns and normal levels of cell-associated Mn(II). DNA microarray analysis reveals that zinc stress induces the expected upregulation of czcD (encoding a zinc effluxer), but also a pleiotropic transcriptional response suggestive of mild cell wall stress. Genes encoding a nitric oxide detoxification system (nmlR) and the Mn(II) uptake system (psaABC) are also induced. We conclude that Zn(II) toxicity results in a cytoplasmic Mn(II) deficiency, possibly caused by competition at the Mn(II) uptake transporter protein PsaA.

Project description:Pmr1 is a cis-Golgi Mn/Ca transporter with a key role in protein glycosylation and manganese detoxification. We used microarray analysis to analyze the impact of CaCl2 supplementation on gene expression in pmr1∆ mutants and found that extracellular CaCl2 suppresses transcriptional misregulation in pmr∆ mutants.

Project description:Escherichia coli possesses >65 small proteins of <50 amino acids, many of which are uncharacterized. We have identified a new small protein, MntS, involved in manganese homeostasis. Manganese is a critical micronutrient, serving as an enzyme cofactor and protecting against oxidative stress. Yet manganese is toxic in excess and little is known about its function in cells. Bacteria carefully control intracellular manganese levels using the transcription regulator MntR. Before this work, mntH, which encodes a manganese importer, was the only gene known to respond to manganese via MntR repression in E. coli K12. We demonstrated that mntS is another member of the MntR manganese regulon. We also identified yebN, which encodes a putative manganese efflux pump, as the first gene positively regulated by MntR in Enterobacteria. Since MntS is expressed when manganese levels are low, causes manganese sensitivity when overexpressed, and binds manganese, we propose that MntS may be a manganese chaperone. This study reveals new factors involved in manganese regulation and metabolism and expands our knowledge of how small proteins function.

Project description:Escherichia coli possesses >65 small proteins of <50 amino acids, many of which are uncharacterized. We have identified a new small protein, MntS, involved in manganese homeostasis. Manganese is a critical micronutrient, serving as an enzyme cofactor and protecting against oxidative stress. Yet manganese is toxic in excess and little is known about its function in cells. Bacteria carefully control intracellular manganese levels using the transcription regulator MntR. Before this work, mntH, which encodes a manganese importer, was the only gene known to respond to manganese via MntR repression in E. coli K12. We demonstrated that mntS is another member of the MntR manganese regulon. We also identified yebN, which encodes a putative manganese efflux pump, as the first gene positively regulated by MntR in Enterobacteria. Since MntS is expressed when manganese levels are low, causes manganese sensitivity when overexpressed, and binds manganese, we propose that MntS may be a manganese chaperone. This study reveals new factors involved in manganese regulation and metabolism and expands our knowledge of how small proteins function. Two E. coli strains, MG1655 (wild type) and GSO458 (Delta-mntR) were grown to OD600 ~ 0.5 in M9 glucose media at 37 M-BM-:C and treated with 10 microM MnCl2. In the first experiment, this incubation with 10 microM MnCl2 was for 60 min and in the second experiment, it was for 10 min. RNA was extracted using the hot phenol method and cDNA prepared and hybridized according the manufacturer's instructions (Affymetrix).

Project description:Transcriptional profiling of SirR and manganese regulated expression of genes in Mycobacterium tuberculosis strains comparing high manganese vs. low manganese in Rv (wild type Mycobacterium tuberculosis) and ST70 (mntR mutant strain of Mycobacterium tuberculosis) Two strains each with two conditions experiment, Rv (Mycobacterium tuberculosis wild type strain) high manganese vs. low manganese and ST70 (mntR mutant strain of Mycobacterium tuberculosis) high manganese vs. low manganese. Number of biological replicates is 3 for each condition for each strain.

Project description:We assessed changes in gene expression in response to iron availability for the human pathogen Corynebacterium diphtheriae. Expression profiles of wild-type C. diphtheriae strain 1737 grown in semi-defined metal-poor media (mPGT) in iron-limiting (0.5 µM iron chloride supplementation) and iron-replete (10 µM supplementation) conditions were compared; the expression profiles of wild-type C. diphtheriae strain 1737 during growth in iron-replete conditions was also compared against an isogenic ΔdtxR mutant grown in iron-replete conditions. Three biological replicates were prepared by isolating total RNA from mid-logarithmic growth cultures and ten genes (dip0169, dip0415, dip1061, dip1062, dip2330, dip1486, dip0173, dip1252, dip1866, and dip0281) were quantified by real-time PCR to validate the array results. Corynebacterium diphtheriae is the causative agent of the severe respiratory disease, diphtheria. Diphtheria Toxin (DT), encoded by the tox gene, is the potent exotoxin secreted by C. diphtheriae responsible for much of the morbidity and mortality of diphtheria. Expression of the tox gene is regulated by the Diphtheria Toxin Repressor (DtxR) and iron. In addition to the regulation of toxin expression, DtxR functions as a global iron-dependent regulatory factor that mediates iron homeostasis in C. diphtheriae. While numerous genes regulated by DtxR and iron are known, a genome-wide study of both the iron and DtxR regulons is lacking in C. diphtheriae. Here, we report novel iron- and DtxR-regulated genes revealed by a comprehensive transcriptomic analysis. Not all identified genes appear to be repressed by iron and DtxR; some genes were found to be induced by iron in a DtxR-dependent manner, a mechanism of regulation not previously described in C. diphtheriae. Using a prediction algorithm (MEME) and electrophoretic mobility shift assays, we verified DtxR binding to sequences upstream of several newly identified genes. Furthermore, we characterized expression of ferritin (ftn) and catalase (cat), which are both induced by iron, but differentially affected by DtxR. We identified three DtxR binding sites in the ftn promoter, while analysis of the cat promoter establishes a role for DtxR in cat expression and suggests complex regulation by additional regulators. Collectively, these results expand our knowledge on the function of DtxR and the diverse roles of this regulatory protein in controlling gene expression.

Project description:Transcriptional profiling of SirR and manganese regulated expression of genes in Mycobacterium tuberculosis strains comparing high manganese vs. low manganese in Rv (wild type Mycobacterium tuberculosis) and ST70 (mntR mutant strain of Mycobacterium tuberculosis)

Project description:Iron (Fe) and Manganese (Mn) are essential for bacterial survival and virulence as they are involved in catalysis, infection and biofilm formation. The basal metabolism of pathogenic bacteria would be disturbed by the deficiency of metal ions in the host environment. In this study, we found that Streptococcus pneumoniae (S. pneumoniae) can still grow slowly in the medium without manganese ions. Further ICP-MS determination showed that the iron concentration in the bacterium was increased when the manganese content was decreased. The supplement of iron in the manganese deficient culture medium (MDCM) can recovery the bacterial growth. The quantitative proteome using stable-isotope dimethyl labeling was performed to investigate the adaptive growth mechanism of S. pneumoniae in Mn-deficiency condition. Compared with the bacteria cultured in the normal medium, 25 proteins were down-regulated and 54 proteins were up-expressed with more than 1.2-fold alteration (P < 0.05) in S. pneumoniae cultured with MDCM. A large number of depressed proteins are participated in cell energy metabolism, amino acid synthesis process and oxidation products reduction process. The subsequent detection indicated that both intracellar and extracellular hydrogen peroxide levels of in cells were significantly elevated, and the intracellular ATP levels of were evidently decreased in cells cultured in the absence of manganese, meaning that Mn-deficiency can cause multiple metabolic disorders. More importantly, several iron ABC transporters, such as PiuA/PiaA/PitA/SPD_1609, etc, were over-expressed to uptake more iron from the medium. These results suggest that lacking of manganese only disturbed multiple metabolic processes of S. pneumoniae, but also caused the compensatory effect of iron for manganese Mn which is beneficial to the survival of bacteria in extreme environments.