Thrombomodulin (TM) is an endothelial anticoagulant cofactor that promotes thrombin-mediated formation of activated protein C (APC). We have found that the N-terminal lectin-like domain (D1) of TM has unique antiinflammatory properties. TM, via D1, binds high-mobility group-B1 DNA-binding protein (HMGB1), a factor closely associated with necrotic cell damage following its release from the nucleus, thereby preventing in vitro leukocyte activation, in vivo UV irradiation-induced cutaneous inflammation, and in vivo lipopolysaccharide-induced lethality. Our data also demonstrate antiinflammatory properties of a peptide spanning D1 of TM and suggest its therapeutic potential. These findings highlight a novel mechanism, i.e., sequestration of mediators, through which an endothelial cofactor, TM, suppresses inflammation quite distinctly from its anticoagulant cofactor activity, thereby preventing the interaction of these mediators with cell surface receptors on effector cells in the vasculature.
Thrombomodulin (TM) is an endothelial anticoagulant cofactor that promotes thrombin-mediated formation of activated protein C (APC). We have found that the N-terminal lectin-like domain (D1) of TM has unique antiinflammatory properties. TM, via D1, binds high-mobility group-B1 DNA-binding protein (HMGB1), a factor closely associated with necrotic cell damage following its release from the nucleus, thereby preventing in vitro leukocyte activation, in vivo UV irradiation-induced cutaneous inflammation, and in vivo lipopolysaccharide-induced lethality. Our data also demonstrate antiinflammatory properties of a peptide spanning D1 of TM and suggest its therapeutic potential. These findings highlight a novel mechanism, i.e., sequestration of mediators, through which an endothelial cofactor, TM, suppresses inflammation quite distinctly from its anticoagulant cofactor activity, thereby preventing the interaction of these mediators with cell surface receptors on effector cells in the vasculature.
The study shows constitutive activation of the Notch pathway in various types of malignancies. However, it remains unclear how the Notch pathway is involved in the pathogenesis of osteosarcoma. We investigated the expression of the Notch pathway molecules in osteosarcoma biopsy specimens and examined the effect of Notch pathway inhibition. Real-time PCR revealed overexpression of Notch2, Jagged1, HEY1, and HEY2. On the other hand, Notch1 and DLL1 were downregulated in biopsy specimens. Notch pathway inhibition using g-secretase inhibitor and CBF1 siRNA slowed the growth of osteosarcomas in vitro. In addition, g-secretase inhibitortreated xenograft models exhibited significantly slower osteosarcoma growth. Cell cycle analysis revealed that g-secretase inhibitor promoted G1 arrest. Real-time PCR and western blot revealed that g-secretase inhibitor reduced the expression of accelerators of the cell cycle, including cyclin D1, cyclin E1, E2, and SKP2. On the other hand, p21cip1 protein, a cell cycle suppressor, was upregulated by g-secretase inhibitor treatment. These findings suggest that inhibition of Notch pathway suppresses osteosarcoma growth by regulation of cell cycle regulator expression and that the inactivation of the Notch pathway may be a useful approach to the treatment of patients with osteosarcoma.
Objective. Tissue hypoxia is closely associated with arthritis pathogenesis, and extracellular high mobility group box chromosomal protein 1 (HMGB-1) released from injured cells also has a role in arthritis development. This study was thus undertaken to investigate the hypothesis that extracellular HMGB-1 may be a coupling factor between hypoxia and inflammation in arthritis.Methods. Concentrations of tumor necrosis factor ␣, interleukin-6, vascular endothelial growth factor, lactic acid, lactate dehydrogenase, and HMGB-1 were measured in synovial fluid (SF) samples from patients with inflammatory arthropathy (rheumatoid arthritis and pseudogout) and patients with noninflammatory arthropathy (osteoarthritis). The localization of tissue hypoxia and HMGB-1 was also examined in animal models of collagen-induced arthritis (CIA). In cellbased experiments, the effects of hypoxia on HMGB-1 release and its associated cellular events (i.e., protein distribution and cell viability) were studied.Results. In SF samples from patients with HMGB-1-associated inflammatory arthropathy (i.e., samples with HMGB-1 levels >2 SD above the mean level in samples from patients with noninflammatory arthropathy), concentrations of HMGB-1 were significantly correlated with those of lactic acid, a marker of tissue hypoxia. In CIA models in which the pathologic phenotype could be attenuated by HMGB-1 neutralization, colocalization of HMGB-1 with tissue hypoxia in arthritis lesions was also observed. In cell-based experiments, hypoxia induced significantly increased levels of extracellular HMGB-1 by the cellular processes of secretion and/or apoptosis-associated release, which was much more prominent than the protein release in necrotic cell injury potentiated by oxidative stress.Conclusion. These findings indicate that tissue hypoxia and its resultant extracellular HMGB-1 might play an important role in the development of arthritis.High mobility group box chromosomal protein 1 (HMGB-1) is a nuclear architectural protein that is released from necrotic cells (1) and/or secreted from activated macrophages (2,3). It has been identified as a mediator of endotoxin-induced lethality (2,4) and a causative factor in arthritis (3,5-7), acting, at least in part, as a proinflammatory cytokine (1-11). Engagement of the receptor for advanced glycation end products (RAGE) by extracellular HMGB-1 triggers activation of proinflammatory signaling pathways (10,11), such as those resulting in elaboration of reactive oxygen inter-
Purpose: XAGE-1 was originally identified by the search for PAGE/GAGE-related genes using expressed sequence tag database and was shown to exhibit characteristics of cancer/testis-like antigens. Four transcript variants XAGE-1a, XAGE-1b, XAGE-1c, and XAGE-1d have been identified thus far.We recently identified XAGE-1b as a dominant antigen recognized by sera from lung adenocarcinoma patients.We here investigated the mRNA expression of four XAGE-1variants and XAGE-1protein expression in non^small cell lung cancer (NSCLC). Humoral immune response to XAGE-1b was also evaluated in patients. Experimental Design: Forty-nine NSCLC specimens were analyzed for the expression of four XAGE-1 transcript variants by conventional 30-cycle and real-time reverse transcription-PCR and XAGE-1 protein expression by immunohistochemistry. Sera from 74 patients were analyzed for XAGE-1b antibody production by ELISA and Western blot. Results: XAGE-1b and XAGE-1d mRNA were detected in 15 and 6 of 49 lung cancer specimens, respectively. No XAGE-1a or XAGE-1c mRNA expression was observed. XAGE-1b mRNA expression was observed in 14 of 31 (45%) adenocarcinoma and 1 of 18 (6%) lung cancer with other histologic types. Immunohistochemical analysis using a XAGE-1 monoclonal antibody showed that 14 of 15 XAGE-1b mRNA-positive and 3 of 34 XAGE-1b mRNA-negative specimens expressed XAGE-1protein. Seropositivity was observed in 5 of 56 patients with adenocarcinoma, whereas none of 18 patients with other histologic types produced XAGE-1b antibody. Conclusion: XAGE-1b is highly and strongly expressed in lung adenocarcinoma and immunogenic in patients, suggesting that XAGE-1b is a promising antigen for immunotherapy against lung adenocarcinoma.
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