Porphyromonas gingivalis HSP60 peptides have distinct roles in the development of atherosclerosis.

Different epitope peptides of bacterial heat shock proteins may function as effector or regulatory molecules in autoimmune responses in infection-triggered atherosclerosis. We investigated the mechanisms for the distinct roles of two epitope peptides from Porphyromonas gingivalis heat shock protein 60 (HSP60) in atherogenesis with regard to peptide-specific T cell polarization relevant to (1) phenotype and cytokine profiles, (2) expression of transcription factors, and (3) role of antigen presenting dendritic cell subsets.Apolipoprotein E-knockout (ApoE KO) mice were immunized with peptide 14 or peptide 19 from P. gingivalis HSP60 prior to induction of atherosclerosis by infection with P. gingivalis plus a Western diet. Significant reductions in plaque/lipid droplet area and plasma cholesterol levels were observed in mice immunized with peptide 14, whereas the opposite phenomenon was evident in mice immunized with peptide 19. CD4+ T-cells polarized to the regulatory T-cell type in peptide 14-immunized group, whereas they polarized to the Th1 cells in peptide 19-immunized group; this observation was supported by the cytokine profiles characteristic to each T-cell phenotype.Significantly higher expression of Nr4a1 and Nr4a2 mRNA, transcriptional factors for regulatory T-cell type, were observed in peptide 14-immunized group. In contrast, the expression level of IFN-γ and T-bet mRNA, signaling molecules for Th1 cells, was higher in peptide 19-immunized group than in PBS-immunized group.In non-immunized wild mice, BMDC-derived CD11c+ dendritic cells have shown to stimulate Tregs significantly in antigen-nonspecific manner. However, each peptide antigen demonstrated a unique mode of preferential adoption of dendritic cell subsets.In conclusion, peptide 14 or peptide 19 from P. gingivalis HSP60, respectively, may play either an anti- or pro-atherogenic role in the ApoE KO mouse model of infection-triggered atherosclerosis through distinct mechanisms operating in the polarization of T cells.

Human CD103(+) dendritic cells promote the differentiation of Porphyromonas gingivalis heat shock protein peptide-specific regulatory T cells.

PURPOSE: Regulatory T cells (Tregs), expressing CD4 and CD25 as well as Foxp3, are known to play a pivotal role in immunoregulatory function in autoimmune diseases, cancers, and graft rejection. Dendritic cells (DCs) are considered the major antigen-presenting cells (APCs) for initiating these T-cell immune responses, of which CD103(+) DCs are derived from precursor human peripheral blood mononuclear cells (PBMCs). The aim of the present study was to evaluate the capacity of these PBMC-derived CD103(+) DCs to promote the differentiation of antigen-specific Tregs. METHODS: Monocyte-derived DCs were induced from CD14(+) monocytes from the PBMCs of 10 healthy subjects. Once the CD103(+) DCs were purified, the cell population was enriched by adding retinoic acid (RA). Peptide numbers 14 and 19 of Porphyromonas gingivalis heat shock protein 60 (HSP60) were synthesized to pulse CD103(+) DCs as a tool for presenting the peptide antigens to stimulate CD3(+) T cells that were isolated from human PBMC. Exogenous interleukin 2 was added as a coculture supplement. The antigen-specific T-cell lines established were phenotypically identified for their expression of CD4, CD25, or Foxp3. RESULTS: When PBMCs were used as APCs, they demonstrated only a marginal capacity to stimulate peptide-specific Tregs, whereas CD103(+) DCs showed a potent antigen presenting capability to promote the peptide-specific Tregs, especially for peptide 14. RA enhanced the conversion of CD103(+) DCs, which paralleled the antigen-specific Treg-stimulating effect, though the differences failed to reach statistical significance. CONCLUSIONS: We demonstrated that CD103(+) DCs can promote antigen-specific Tregs from naive T cells, when used as APCs for an epitope peptide from P. gingivalis HSP60. RA was an effective reagent that induces mature DCs with the typical phenotypic expression of CD103 that demonstrated the functional capability to promote antigen-specific Tregs.

Implication of necrosis-linked p53 aggregation in acquired apoptotic resistance to 5-FU in MCF-7 multicellular tumour spheroids.

Three-dimensional (3D) multicellular tumour spheroids (MTS) have been used as an in vitro model of solid tumours for drug resistance studies because they mimic the growth characteristics of in vivo tumours more closely than in vitro two-dimensional (2D) culture of cancer cell lines. As observed in solid tumours, MTS exhibits a proliferation gradient with outer regions consisting of proliferating cells that surround inner quiescent cells. The innermost cells in core regions undergo cell death mostly by necrosis to form necrotic core due to insufficient supply of oxygen and nutrient such as glucose with increasing size of spheroids. Tumour necrosis is thought to indicate a poor prognosis and to contribute to acquisition of chemoresistance in solid tumours; however, the mechanism underlying necrosis-mediated chemoresistance remains unclear. In this study, we examined the chemoresistance to 5-Fluorouracil (5-FU) using MCF-7 breast cancer MTS. 5-FU (400 microM) induced apoptosis in MCF-7 cell monolayer as determined by HO/PI staining, PARP cleavage, p53 induction, Bax induction, and Bcl-2 down-regulation. When MCF-7 breast tumour spheroids were cultured on agarose for 8 days, they reached approximately 700 microm in diameter, with a necrotic core. We found that 5-FU-induced apoptosis is markedly reduced in spheroids that were cultured for 9 days and had necrotic core, compared with MCF-7 monolayer cells and spheroids that were cultured for 6 days and had no necrotic core, indicating that the formation of necrotic core may be linked to acquisition of chemoresistance to 5-FU. We also found that a specific set of cellular proteins including p53 was aggregated into a RIPA-insoluble form during MTS culture. Furthermore, most of p53 induced by 5-FU was aggregated in MTS with necrotic core. Our results suggest that necrosis-linked p53 aggregation may contribute to acquired apoptotic resistance to 5-FU in MTS model system.