Browsing by Author "Liao, Chung-Ping"
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Item Contributions of inflammation and tumor microenvironment to neurofibroma tumorigenesis(American Society for Clinical Investigation, 2018-07-02) Liao, Chung-Ping; Booker, Reid C.; Brosseau, Jean-Philippe; Chen, Zhiguo; Mo, Juan; Tchegnon, Edem; Wang, Yong; Clapp, D. Wade; Le, Lu Q.; Pediatrics, School of MedicineNeurofibromatosis type 1 associates with multiple neoplasms, and the Schwann cell tumor neurofibroma is the most prevalent. A hallmark feature of neurofibroma is mast cell infiltration, which is recruited by chemoattractant stem cell factor (SCF) and has been suggested to sustain neurofibroma tumorigenesis. In the present study, we use new, genetically engineered Scf mice to decipher the contributions of tumor-derived SCF and mast cells to neurofibroma development. We demonstrate that mast cell infiltration is dependent on SCF from tumor Schwann cells. However, removal of mast cells by depleting the main SCF source only slightly affects neurofibroma progression. Other inflammation signatures show that all neurofibromas are associated with high levels of macrophages regardless of Scf status. These findings suggest an active inflammation in neurofibromas and partly explain why mast cell removal alone is not sufficient to relieve tumor burden in this experimental neurofibroma model. Furthermore, we show that plexiform neurofibromas are highly associated with injury-prone spinal nerves that are close to flexible vertebras. In summary, our study details the role of inflammation in neurofibromagenesis. Our data indicate that prevention of inflammation and possibly also nerve injury at the observed tumor locations are therapeutic approaches for neurofibroma prophylaxis and that such treatment should be explored.Item Microarray studies on effects of Pneumocystis carinii infection on global gene expression in alveolar macrophages(BMC, 2010-04-08) Cheng, Bi-Hua; Liu, Yunlong; Xuei, Xiaoling; Liao, Chung-Ping; Lu, Debao; Lasbury, Mark E.; Durant, Pamela J.; Lee, Chao-Hung; Medicine, School of MedicinePneumocystis pneumonia is a common opportunistic disease in AIDS patients. The alveolar macrophage is an important effector cell in the clearance of Pneumocystis organisms by phagocytosis. However, both the number and phagocytic activity of alveolar macrophages are decreased in Pneumocystis infected hosts. To understand how Pneumocystis inactivates alveolar macrophages, Affymetrix GeneChip® RG-U34A DNA microarrays were used to study the difference in global gene expression in alveolar macrophages from uninfected and Pneumocystis carinii-infected Sprague-Dawley rats. Results Analyses of genes that were affected by Pneumocystis infection showed that many functions in the cells were affected. Antigen presentation, cell-mediated immune response, humoral immune response, and inflammatory response were most severely affected, followed by cellular movement, immune cell trafficking, immunological disease, cell-to-cell signaling and interaction, cell death, organ injury and abnormality, cell signaling, infectious disease, small molecular biochemistry, antimicrobial response, and free radical scavenging. Since rats must be immunosuppressed in order to develop Pneumocystis infection, alveolar macrophages from four rats of the same sex and age that were treated with dexamethasone for the entire eight weeks of the study period were also examined. With a filter of false-discovery rate less than 0.1 and fold change greater than 1.5, 200 genes were found to be up-regulated, and 144 genes were down-regulated by dexamethasone treatment. During Pneumocystis pneumonia, 115 genes were found to be up- and 137 were down-regulated with the same filtering criteria. The top ten genes up-regulated by Pneumocystis infection were Cxcl10, Spp1, S100A9, Rsad2, S100A8, Nos2, RT1-Bb, Lcn2, RT1-Db1, and Srgn with fold changes ranging between 12.33 and 5.34; and the top ten down-regulated ones were Lgals1, Psat1, Tbc1d23, Gsta1, Car5b, Xrcc5, Pdlim1, Alcam, Cidea, and Pkib with fold changes ranging between -4.24 and -2.25. Conclusions In order to survive in the host, Pneumocystis organisms change the expression profile of alveolar macrophages. Results of this study revealed that Pneumocystis infection affects many cellular functions leading to reduced number and activity of alveolar macrophages during Pneumocystis pneumonia.Item Polyamines and Alveolar Macrophage Apoptosis during Pneumocystis Pneumonia(2009-10-01T18:06:46Z) Liao, Chung-Ping; Lee, Chao-Hung; Lasbury, Mark E.; Davis, Thomas E.; Gregory, Richard L.Pneumocystis pneumonia (PCP) is the leading opportunistic disease in immunocompromised individuals, particularly in AIDS patients. The alveolar macrophage (AM) is the major type of cell responsible for the clearance of Pneumocystis organisms; however, they undergo a high rate of apoptosis during PCP due to increased intracellular polyamine levels. This study examined the mechanism of this polyamine mediated apoptosis and investigated an alternative therapy for PCP by targeting this mechanism. The elevated polyamine levels were determined to be caused by increased polyamine synthesis and uptake. Increased polyamine uptake was found to be AM-specific, and recruited inflammatory cells including monocytes, B cells, and CD8+ T cells were found to be a potential source of polyamines. The expression of the antizyme inhibitor (AZI), which regulates both polyamine synthesis and uptake, was found to be greatly up-regulated in AMs during PCP. AZI overexpression was confirmed to be the cause of increased polyamine synthesis and uptake and apoptosis of AMs during PCP by gene knockdown assays. Pneumocystis organisms and zymosan were found to induce AZI overexpression in AMs, suggesting that the β-glucan of the Pneumocystis cell wall is responsible for this AZI up-regulation. In addition, levels of mRNA, protein, and activity of polyamine oxidase (PAO) were also found to be increased in AMs during PCP, and its substrates N1-acetylspermidine and N1-acetylspermine were found to induce its up-regulation. These results indicate that the H2O2 generated during PAO-mediated polyamine catabolism caused AMs to undergo apoptosis. Since increased polyamine uptake was demonstrated to be a pathogenic mechanism of PCP in this study, the potential therapeutic activity of five putative polyamine transport inhibitors against PCP was tested. Results showed that compound 44-Ant-44 significantly decreased pulmonary inflammation, organism burden, and macrophage apoptosis, and prolonged the survival of rats with PCP. In summary, this study demonstrated that Pneumocystis organisms induce AZI overexpression, leading to increased polyamine synthesis, uptake, and apoptosis rate in AMs and that targeting polyamine transport is a viable therapeutic approach against PCP.