Project description:Porphyromonas gingivalis, the keystone pathogen responsible for dysbiosis in the oral microbiome, the development of periodontal diseases, and the contribution to systemic comorbidities, is a heme auxotroph. It encodes only four enzymes in the heme biosynthesis pathway, namely HemD, HemN, HemG, and HemH. HemH protein is a ferrochelatase involved in the final step of heme biosynthesis by inserting iron ions (Fe2+) into protoporphyrin IX. This study aimed to analyze the effect of hemH gene deletion on P. gingivalis gene expression, thereby verifying its importance for P. gingivalis.

Project description:Porphyromonas gingivalis is a keystone pathogen responsible for oral microbiome dysbiosis, the development of periodontal disease, and may be involved in the development of systemic comorbidities. As a heme auxotroph, P. gingivalis relies on host hemoproteins as its primary sources of heme and iron. Although heme acquisition in P. gingivalis is relatively well characterized, considerably less is known about its pathways for iron uptake and the regulation of iron and heme homeostasis. P. gingivalis encodes four enzymes associated with the heme biosynthesis pathway, namely HemD, HemN, HemG, and HemH. HemH is a ferrochelatase responsible for the final step of heme biosynthesis, catalyzing the insertion of ferrous iron (Fe²⁺) into protoporphyrin IX. In addition, P. gingivalis expresses the Iht system, which plays a role in iron/heme utilization. One of its components, IhtB, is a heme-binding protein homologous to CbiK cobaltochelatases. Based on this homology, IhtB is hypothesized to function as a reverse ferrochelatase, facilitating the removal of iron from heme and thereby contributing to iron acquisition. This study aimed to investigate the effect of ihtB and hemH gene deletions on P. gingivalis gene expression under heme- and iron-replete conditions, to elucidate the roles of IhtB and HemH chelatases in heme and iron homeostasis.

Project description:Porphyromonas gingivalis is a major pathogen associated with the microbial biofilm-mediated disease chronic periodontitis. P. gingivalis has an obligate requirement for iron and protoporphyrin IX which it satisfies by transporting heme and iron liberated from the human host. The level of cellular iron in P. gingivalis affects the expression of a distinct iron-associated regulon of 64 genes and low iron invokes an iron sparing response. Iron homeostasis is usually mediated in Gram-negative bacteria at the transcriptional level by the Ferric Uptake Regulator (Fur). There is a single predicted P. gingivalis Fur superfamily orthologue named Har (heme associated regulator) that lacks the conserved metal binding residues found in other Fur orthologues. We show that Har binds both heme and ferrous iron resulting in a conformational change in the protein. Har was unable to complement the Escherichia coli H1780 fur mutant and there was no change in cellular metal content in a P. gingivalis Har mutant compared with the wild-type. The Har regulon of 44 genes is not predicted to play a role in iron homeostasis. Together these data indicated that Har does not regulate iron homeostasis in P. gingivalis. However, Har was required for heme-responsive biofilm development and its regulon overlapped P. gingivalis regulons previously identified after growth in heme limitation or as a homotypic biofilm. P. gingivalis is unique as an iron-dependent Gram-negative bacterium with a single heme-binding Fur superfamily orthologue, Har, that does not regulate iron homeostasis.

Project description:Porphyromonas gingivalis is a major pathogen associated with the microbial biofilm-mediated disease chronic periodontitis. P. gingivalis has an obligate requirement for iron and protoporphyrin IX which it satisfies by transporting heme and iron liberated from the human host. The level of cellular iron in P. gingivalis affects the expression of a distinct iron-associated regulon of 64 genes and low iron invokes an iron sparing response. Iron homeostasis is usually mediated in Gram-negative bacteria at the transcriptional level by the Ferric Uptake Regulator (Fur). There is a single predicted P. gingivalis Fur superfamily orthologue named Har (heme associated regulator) that lacks the conserved metal binding residues found in other Fur orthologues. We show that Har binds both heme and ferrous iron resulting in a conformational change in the protein. Har was unable to complement the Escherichia coli H1780 fur mutant and there was no change in cellular metal content in a P. gingivalis Har mutant compared with the wild-type. The Har regulon of 44 genes is not predicted to play a role in iron homeostasis. Together these data indicated that Har does not regulate iron homeostasis in P. gingivalis. However, Har was required for heme-responsive biofilm development and its regulon overlapped P. gingivalis regulons previously identified after growth in heme limitation or as a homotypic biofilm. P. gingivalis is unique as an iron-dependent Gram-negative bacterium with a single heme-binding Fur superfamily orthologue, Har, that does not regulate iron homeostasis. Paired samples were compared on the same microarray using a two-colour system. A total of 6 paired microarray hybridizations were performed representing 6 biological replicates, where a balanced dye design was used, with the overall analysis including three microarrays where P. gingivalis 33277 samples were labeled with Cy3 and the paired ECR455 samples were labeled with Cy5 and three other microarrays where samples were labeled with the opposite combination of fluorophores.

Project description:Porphyromonas gingivalis is one of the main etiological agents responsible for initiating and progressing periodontal diseases in humans. P. gingivalis does not synthesize heme, and it uses host hemoproteins as a source of this molecule. The main heme uptake mechanism utilized by P. gingivalis is the Hmu system composed of six proteins where HmuY (hemophore-like protein) and HmuR (TonB-dependant outer membrane heme receptor) play a crucial role in heme supply. The second heme uptake mechanism is the Hus system composed of four proteins, with HusA (hemophore-like protein) and HusB (TonB-dependant outer membrane receptor) supporting heme uptake. Heme and iron starvation influence the P. gingivalis phenotype, therefore the aim was to determine the influence of deletion of HmuY and HmuR (ΔhmuYR strain) or HusA and HusB (ΔhusAB strain) encoding genes on P. gingivalis gene expression.

Project description:The aim of this study is to assess the transcriptome for genes that are differentially expresed in liver tissues with high or low liver copper concentration in sheep. Therefore, 12 liver samples high and low liver copper were selected and grouped equally into high liver copper and low liver copper groups.

Project description:Porphyromonas gingivalis is one of the main etiological agents responsible for initiating and progressing periodontal diseases in humans. P. gingivalis does not synthesize heme, and it uses host hemoproteins as a source of this molecule. The main heme uptake mechanism utilized by P. gingivalis is the Hmu system composed of six proteins where HmuY (hemophore-like protein) and HmuR (TonB-dependant outer membrane heme receptor) play a crucial role in heme supply. The second heme uptake mechanism is the Hus system composed of four proteins, with HusA (hemophore-like protein) and HusB (TonB-dependant outer membrane receptor), having a supporting role in heme uptake. Heme and iron starvation influence the P. gingivalis phenotype, therefore the aim was to determine the influence of deletion of HmuY and HmuR (ΔhmuYR strain) or HusA and HusB (ΔhusAB strain) encoding genes on P. gingivalis phenotype including the impact on protein production in response to the analyzed deletion. The mutant strains were constructed in wild-type A7436 P. gingivalis strain. Bacteria were grown in basal medium (BM) supplemented with 7.7 µM heme. After analysis of bacteria lysates with SDS-PAGE and CBB G-250 staining, in ΔhmuYR a protein (~45 kDa) was detected produced in higher amounts, than in the wild-type and the ΔhusAB strains. The gel band of interest, as well as its corresponding sections in the WT lanes were excised for bottom-up LC-MS analysis, and the protein was identified as FimA.

Project description:Transcriptional profiling of the wild-type and its htrA mutant. Identification of genes that are affected by the htrA mutation in P. gingivalis Keywords: Genetic modification Two-condition experiment, W83 vs. htrA mutant late-log growth phase. Biological replicates: 4 control, 4 mutant, independently grown. One replicate per array.

Project description:Polyphosphate (polyP) is a ubiquitous and abundant compound found in bacteria, fungi, algae, plant, and animals. Among roles of intracellular polyP in bacteria are resistance and survival in the stationary phase of the growth against stress and stringent condition. Therefore, intracellular polyP is considered as a virulence factor of bacteria. In contrast, exogenous polyP has an antimicrobial activity against a variety of microorganisms. To date, much has been numerous studies of antibacterial effect of polyP against gram positive bacteria and fungi while relatively little reports have been published concerning gram negative bacteria. Here we describe bactericidal effect of polyP against gram negative periodontopathic bacterium, Porphyromonas gingivalis, and the transcriptional change by polyP in this bacterium. The bacterial growth was inhibited by polyP (chain length of P3~P75) at concentration of 0.02~0.03%, but not by Pi and PPi at the concentrations. polyP75 was chosen for further experiments, which suppressed the further growth of P. gingivalis as low as 0.03%. polyP75 completely killed the bacterial cells at the concentration of 0.035%. Microarray analysis was employed to identify genes that showed a greater than 1.5-fold difference in the expression by polyP75 at the concentration of 0.03%. It was found that 155 genes were up-regulated and 173 were down-regulated. Down-regulated genes include groups of energy metabolism-related genes, cell envelope-related genes, and genes in relation to biosynthesis of cofactors, prosthetic groups and carriers. Among the down-regulated genes were several involved in DNA replication, cell division protein, and biosynthesis of purines, pyrimidines, nucleosides and nucleotides. In contrast, a large number of ribosomal proteins, transciptional regulators and transposases were up-regulated. Oxidative stress-related genes and iron storage proteins also appeared to be increased in the expression. Real-time PCR confirmed up- and down-regulation of some selected genes. The overall results suggest that polyP has a bactericidal activity against P. gingivalis, interfering with translation, energy metabolism, DNA replication, cell division, and biosynthesis of purines, pyrimidines, nucleoside and nucleotides. polyP may be used as an agent for prevention and treatment of periodontal infections. Polyp-treated vs. untreated intensity ratio data linked below as a supplementary file. Keywords: agent response Twenty μg of each total RNA sample was used in separate hybridization experiments on identical arrays. The whole genome of 1,909 genes of P. gingivalis W83 (GenBank accession no. NC_002950) was submitted to NimbleGen System Inc. (Madison, WI) for microarray design and manufacture using maskless, digital micromirror technology. Five replicates of the genome were included per chip. An average of 19 different 60-base oligonucleotides (60-mer probes) represented each gene in the genome. Sixty-mer probes were selected such that each probe had at least three mismatches compared to all other 60-mers in the target genome. A quality control check (hybridization) was performed for each array, which contained on-chip control oligonucleotides. The arrays were analyzed using an Axon GenePix 4000B microarray scanner with associated software (Molecular Devices Corp., Sunnyvale, CA). Gene expression levels were calculated with NimbleScan Version 2.3 (NimbleGen). Relative signal intensities for each gene were generated using the Robust Multi-Array Average algorithm. The data were processed based on quantile normalization method using the R package. This normalization method aims to make the distribution of intensities for each array in a set of arrays the same. The background-adjusted, normalized, and log transformed intensity values were then analyzed using GeneSpring GX 7.3.1 (Silicon Genetics, Palo Alto, CA).

Project description:Here we show that the phytochrome-less chlorophyte Chlamydomonas reinhardtii retains a functional pathway to synthesize the linear tetrapyrrole (bilin) precursor of the phytochrome chromophore. Reverse genetic, metabolic inactivation and bilin rescue experiments establish that this pathway is needed for heme iron acquisition and for the diurnal transition to phototrophic growth. RNA-Seq measurements reveal a bilin-dependent signaling network that is necessary for the heterotrophic to phototrophic transition. These results imply the presence of a novel bilin sensor pathway that may be widely distributed amongst oxygenic photosynthetic organisms. We isolated RNA from heterotrophic suspension cultures of 4A+ WT and the hmox1 mutant grown in the presence or absence of 0.1 mM BV IXM-NM-1 before and after transfer to low light.