Project description:Prostate cancer is the second leading cause of male cancer deaths in the United States and Europe. Current evidence implicates an inflammatory mechanism as a cause of prostate carcinogenesis. Here we show that the bacterium Propionibacterium acnes (P. acnes) is prevalent in prostate glandular tissues: 70% of benign hyperplasia and 81% of cancer tissue samples tested positive for the bacterium. Live P. acnes bacteria were isolated from cancerous prostates and co-cultured with epithelial prostate cells to confirm they were cell invasive. Transcriptome and ELISA studies revealed that P. acnes induced a strong inflammatory response in prostate cells, resulting in the secretion of cytokines and chemokines such as interleukin (IL)-6 and IL-8. In addition, P. acnes triggered the COX prostaglandin and the plasminogen-matrix metalloproteinase (MMP) pathways. Strikingly, long-term exposure of non-tumorigenic prostate cells to P. acnes resulted in loss of E-cadherin, altered betacatenin levels and localization, increased cellular migration, and conferred anchorage- independent growth. Our work adds to the growing body of work highlighting the presence of viruses and bacteria in cancerous prostate tissues and strongly suggests that P. acnes infection could lead to malignant transformation of prostate cells.

Project description:Prostate cancer is the second leading cause of male cancer deaths in the United States and Europe. Current evidence implicates an inflammatory mechanism as a cause of prostate carcinogenesis. Here we show that the bacterium Propionibacterium acnes (P. acnes) is prevalent in prostate glandular tissues: 70% of benign hyperplasia and 81% of cancer tissue samples tested positive for the bacterium. Live P. acnes bacteria were isolated from cancerous prostates and co-cultured with epithelial prostate cells to confirm they were cell invasive. Transcriptome and ELISA studies revealed that P. acnes induced a strong inflammatory response in prostate cells, resulting in the secretion of cytokines and chemokines such as interleukin (IL)-6 and IL-8. In addition, P. acnes triggered the COX prostaglandin and the plasminogen-matrix metalloproteinase (MMP) pathways. Strikingly, long-term exposure of non-tumorigenic prostate cells to P. acnes resulted in loss of E-cadherin, altered betacatenin levels and localization, increased cellular migration, and conferred anchorage- independent growth. Our work adds to the growing body of work highlighting the presence of viruses and bacteria in cancerous prostate tissues and strongly suggests that P. acnes infection could lead to malignant transformation of prostate cells. Microarray experiments were performed as dual-color hybridizations. To compensate for dye-specific effects, a dye-reversal color-swap was applied. Ratio profiles comprising color-swap hybridizations were combined in an error-weighted fashion to create ratio experiments. A 1.5–fold change expression cut-off for ratio experiments was applied together with anti-correlation of color-swap ratio profiles rendering the microarray analysis highly significant (P-value > 0.01), robust and reproducible.

Project description:Proprionibacterium acnes is a Gram positive bacterium found ubiquitously on human skin, where it is typically considered to assume a commensal relationship with its host. However, it is also closely associated with the skin condition acne vulgaris. More controversially, it has a postulated involvement in infections of implanted prosthetic devices and has been isolated from malignant prostate tissues. The role of P. acnes in these pathologies remains undetermined, although both bacterial and host factors are implicated. By microarray analysis, we have identified fundamental differences in the global transcriptional profiles of keratinocyte and prostate cells to P. acnes infection. Notably, P. acnes infection of the keratinocyte cell line, HaCaT, elicited a robust, but acute inflammatory response. By contrast, the inflammatory response of the prostate cell line, RWPE1, was delayed and persisted for longer times. Immunofluorescence and electron microscopy revealed higher numbers of internalized P. acnes bacteria in RWPE1 cells, which could still be detected intracellularly three weeks post infection. This contrasted with HaCaT cells, which P. acnes largely failed to invade. Moreover, P. acnes induced a delayed, sustained activation of NFκB in RWPE1 cells, which was absent in HaCaT cells. Further characterization of the host-cell response to infection revealed that the intermediate filament protein, vimentin, was a key determinant of P. acnes invasion, persistence and inflammatory profile in RWPE1 cells. siRNA mediated knock down of vimentin in RWPE1 cells attenuated bacterial invasion and the inflammatory response to infection; similarly, overexpression of vimentin in HaCaT cells increased bacterial invasion. We conclude that vimentin-dependent host-tissue tropism, in part, determines P. acnes invasion and inflammatory capacity. This could contribute to P. acnes pathology at non-skin infection sites.

Project description:Proprionibacterium acnes is a Gram positive bacterium found ubiquitously on human skin, where it is typically considered to assume a commensal relationship with its host. However, it is also closely associated with the skin condition acne vulgaris. More controversially, it has a postulated involvement in infections of implanted prosthetic devices and has been isolated from malignant prostate tissues. The role of P. acnes in these pathologies remains undetermined, although both bacterial and host factors are implicated. By microarray analysis, we have identified fundamental differences in the global transcriptional profiles of keratinocyte and prostate cells to P. acnes infection. Notably, P. acnes infection of the keratinocyte cell line, HaCaT, elicited a robust, but acute inflammatory response. By contrast, the inflammatory response of the prostate cell line, RWPE1, was delayed and persisted for longer times. Immunofluorescence and electron microscopy revealed higher numbers of internalized P. acnes bacteria in RWPE1 cells, which could still be detected intracellularly three weeks post infection. This contrasted with HaCaT cells, which P. acnes largely failed to invade. Moreover, P. acnes induced a delayed, sustained activation of NFM-NM-:B in RWPE1 cells, which was absent in HaCaT cells. Further characterization of the host-cell response to infection revealed that the intermediate filament protein, vimentin, was a key determinant of P. acnes invasion, persistence and inflammatory profile in RWPE1 cells. siRNA mediated knock down of vimentin in RWPE1 cells attenuated bacterial invasion and the inflammatory response to infection; similarly, overexpression of vimentin in HaCaT cells increased bacterial invasion. We conclude that vimentin-dependent host-tissue tropism, in part, determines P. acnes invasion and inflammatory capacity. This could contribute to P. acnes pathology at non-skin infection sites. Microarray experiments were performed as dual-color hybridizations. In order to compensate specific effects of the dyes and to ensure statistically relevant data analysis, a color-swap dye-reversal was performed.

Project description:The anaerobic Gram-positive bacterium Propionibacterium acnes is a human skin commensal, but is occasionally associated with inflammatory diseases. Recent work has indicated that evolutionary distinct lineages of P. acnes play etiologic roles in disease while others are associated with health. To shed light on the molecular basis for differential strain properties, we carried out genomic and transcriptomic analysis of distinct P. acnes strains. We sequenced the genome of the P. acnes strain 266, a type I-1a sequence type (ST) 18 strain. Comparative genome analysis of strain 266 and four other P. acnes strains revealed that overall genome plasticity is relatively low; however, a number of island-like genomic regions, encoding a variety of putative virulence-associated and fitness traits, differ between phylotypes. Comparative transcriptome analysis revealed that 225 genes of strain KPA171202 (type I-2, ST34) were differentially transcribed in strain 266 during exponential growth. 47% of these genes belong to the strain-specific gene content of strain KPA171202, indicating that strain-specific functions are utilized. Next, we studied differential expression during exponential and stationary growth phases. Genes encoding components of the energy-conserving respiratory chain as well as secreted and virulence-associated factors were transcribed during the exponential phase, while the stationary growth phase was characterized by up-regulation of genes involved in the stress response and amino acid metabolism. Taken together, our data highlight the genomic basis for strain diversity and identify, for the first time, the transcribed part of the genome, underling the important role active growth plays in the inflammatory activity of P. acnes. We argue that the disease-causing potential of different P. acnes strains is not only determined by variable genome content but also, and to a greater degree, by variable transcriptomes.

Project description:The anaerobic Gram-positive bacterium Propionibacterium acnes is a human skin commensal, but is occasionally associated with inflammatory diseases. Recent work has indicated that evolutionary distinct lineages of P. acnes play etiologic roles in disease while others are associated with health. To shed light on the molecular basis for differential strain properties, we carried out genomic and transcriptomic analysis of distinct P. acnes strains. We sequenced the genome of the P. acnes strain 266, a type I-1a sequence type (ST) 18 strain. Comparative genome analysis of strain 266 and four other P. acnes strains revealed that overall genome plasticity is relatively low; however, a number of island-like genomic regions, encoding a variety of putative virulence-associated and fitness traits, differ between phylotypes. Comparative transcriptome analysis revealed that 225 genes of strain KPA171202 (type I-2, ST34) were differentially transcribed in strain 266 during exponential growth. 47% of these genes belong to the strain-specific gene content of strain KPA171202, indicating that strain-specific functions are utilized. Next, we studied differential expression during exponential and stationary growth phases. Genes encoding components of the energy-conserving respiratory chain as well as secreted and virulence-associated factors were transcribed during the exponential phase, while the stationary growth phase was characterized by up-regulation of genes involved in the stress response and amino acid metabolism. Taken together, our data highlight the genomic basis for strain diversity and identify, for the first time, the transcribed part of the genome, underling the important role active growth plays in the inflammatory activity of P. acnes. We argue that the disease-causing potential of different P. acnes strains is not only determined by variable genome content but also, and to a greater degree, by variable transcriptomes. Microarray experiments were performed as dual-color hybridizations. In order to compensate specific effects of the dyes and to ensure statistically relevant data analysis, a color-swap dye-reversal was performed. Two different labeling methods were applied. RNA labeling was performed with the two color Quick Amp Labeling Kit (Agilent Technologies) using FullSpectrum MultiStart Primer for T7 IVT RNA Amplification (BioCat GmbH, Heidelberg, Germany) as random T7 labeling. Alternatively, the total RNA samples were amplified with the TransPlex Whole Transcriptome Amplification Kit (Sigma-Aldrich, Munich, Germany) and labeled with BioPrime Plus Array CGH Indirect Genomic Labeling System (Invitrogen, Karlsruhe, Germany) as WTA BioPrime indirect. Both methods were compared and combined for final data analysis.

Project description:In the present study, we investigated the effect of Cutibacterium acnes on lifespan and susceptibility to infection with Staphylococcus aureus using Caenorhabditis elegans as a model animal. When adult C. elegans were fed C. acnes strains, the lifespan of the animals fed pathogenic C. acnes strain (HM-122) was significantly shorter than that of animals fed OP50 (control). In contrast, the lifespan of the animals fed commensal C. acnes strain (HM-555) was not significantly different from that of animals in the control group. Moreover, the worms fed the commensal C. acnes strain were more resistant to infection with S. aureus. Transcriptional profiling comparing HM-122-, HM-555- and control-fed animals suggested that genes related to “cuticle development involved in collagen and cuticulin-based cuticle molting cycle” were regulated by HM-122, and genes related to “defense response to gram-positive bacterium” were regulated by HM-555.

Project description:Individual acne comedones can undergo spontaneous remission in association with shrunken sebaceous glands (SGs) containing undifferentiated cells under unknown mechanisms. It is also still controversial whether sebum-induced follicular Propionibacterium acnes（P. acnes）interacts with the SGs. We explored the effects of P. acnes and peptidoglycan (PGN) on the aryl hydrocarbon receptor (AhR) activation, lipogenesis and differentiation in cultured human SZ95 sebocytes in vitro. Both formaldehyde-inactivated P. acnes and PGN upregulated mRNA levels of AhR charachteristic downstream genes CYP1A1, CYP1B1, CYP1A2, as well as significantly induced translocation of AhR protein from cytoplasm into nucleus. GSEA revealed pathways of downregulated lipogenesis and upregulated keratinization. In addition, P.acnes and PGN inhibited linoleic acid(LA)-induced neutral lipid synthesis and expressions of Keratin 7 and Mucin1/EMA (sebocyte markers) and increased the expression of Keratin 10 and involucrin (keratinocyte markers), which were abolished after AhR gene silencing. Moreover, inhibited expressions of lipogenesis-related genes such as SREBP1 were observed. In conclusion, we provide evidence that P. acnes can switch sebocytes into a keratinocyte-like differentiation with reduced lipogenesis via AhR, indicating that follicular P. acnes should not only be considered as acnegenic but also as a factor promoting acne remission through feedback regulation of sebum production.

Project description:Recently the membrane vesicles (MVs) production has been observed in Gram-positive bacterium, Cutibacterium acnes (C. acnes). In order to explore the mechanism of antibiotic resistance and the virulent components within the C. acnes-derived MVs, we isolated MVs from the clinical C. acnes, which were sensitive or resistant to antibiotics erythromycin and clindamycin. With the LC-MS/MS method, we detected several lipases, virulent factors and cell division protein differentially expressed between the sensitive and the resistant C. acnes-derived MVs.

Project description:Propionibacterium acnes HKGB1 Genome sequencing and assembly