Your search keyword '"Glaros, Trevor"' showing total 7 results

1. Network Topologies and Dynamics Leading to Endotoxin Tolerance and Priming in Innate Immune Cells

Author

Fu, Yan, Glaros, Trevor, Zhu, Meng, Wang, Piang, Wu, Zhanghan, Tyson, John J., Li, Liwu, Xing, Jianghua, Fu, Yan, Glaros, Trevor, Zhu, Meng, Wang, Piang, Wu, Zhanghan, Tyson, John J., Li, Liwu, and Xing, Jianghua

Abstract

The innate immune system, acting as the first line of host defense, senses and adapts to foreign challenges through complex intracellular and intercellular signaling networks. Endotoxin tolerance and priming elicited by macrophages are classic examples of the complex adaptation of innate immune cells. Upon repetitive exposures to different doses of bacterial endotoxin (lipopolysaccharide) or other stimulants, macrophages show either suppressed or augmented inflammatory responses compared to a single exposure to the stimulant. Endotoxin tolerance and priming are critically involved in both immune homeostasis and the pathogenesis of diverse inflammatory diseases. However, the underlying molecular mechanisms are not well understood. By means of a computational search through the parameter space of a coarse-grained three-node network with a two-stage Metropolis sampling approach, we enumerated all the network topologies that can generate priming or tolerance. We discovered three major mechanisms for priming (pathway synergy, suppressor deactivation, activator induction) and one for tolerance (inhibitor persistence). These results not only explain existing experimental observations, but also reveal intriguing test scenarios for future experimental studies to clarify mechanisms of endotoxin priming and tolerance.

Published

2012

2. Molecular Mechanism Underlying Persistent Induction of LCN2 by Lipopolysaccharide in Kidney Fibroblasts

Author

Glaros, Trevor, Fu, Yan, Xing, Jianhua, Li, Liwu, Glaros, Trevor, Fu, Yan, Xing, Jianhua, and Li, Liwu

Abstract

The neutrophil gelatinase-associated lipocalin 2 (LCN2) is a critical inflammatory mediator persistently induced during endotoxemia, contributing to tubular damage and kidney failure. The intracellular process responsible for persistent induction of LCN2 by bacterial endotoxin Lipopolysaccharide (LPS) is not well understood. Using primary kidney fibroblasts, we observed that LPS-induced LCN2 expression requires a coupled circuit involving an early transient phase of AP-1 path and a late persistent phase of C/EBPδ path, both of which are dependent upon the interleukin 1 receptor associated kinase 1 (IRAK-1). Using immunoprecipitation analysis we observed transient binding of AP-1 to the promoters of both TNFα and C/ebpδ. On the other hand, we only observed persistent binding of C/EBPδ to its own promoter but not on TNFα. Blockage of new protein synthesis using cyclohexamide significantly reduced the expression of C/EBPδ as well as LCN2. By chromatin immunoprecipitation analyses, we demonstrated that LPS recruited C/EBPδ to the Lcn2 promoter in WT, but not IRAK-1 deficient fibroblasts. A differential equation-based computational model captured the dynamic circuit leading to the persistent induction of LCN2. In vivo, we observed elevated levels of LCN2 in kidneys harvested from LPS-injected WT mice as compared to IRAK-1 deficient mice. Taken together, this study has identified an integrated intracellular network involved in the persistent induction of LCN2 by LPS.

Published

2012

3. Network Topologies and Dynamics Leading to Endotoxin Tolerance and Priming in Innate Immune Cells

Author

Biological Sciences, Fu, Yan, Glaros, Trevor, Zhu, Meng, Wang, Piang, Wu, Zhanghan, Tyson, John J., Li, Liwu, Xing, Jianghua, Biological Sciences, Fu, Yan, Glaros, Trevor, Zhu, Meng, Wang, Piang, Wu, Zhanghan, Tyson, John J., Li, Liwu, and Xing, Jianghua

Abstract

The innate immune system, acting as the first line of host defense, senses and adapts to foreign challenges through complex intracellular and intercellular signaling networks. Endotoxin tolerance and priming elicited by macrophages are classic examples of the complex adaptation of innate immune cells. Upon repetitive exposures to different doses of bacterial endotoxin (lipopolysaccharide) or other stimulants, macrophages show either suppressed or augmented inflammatory responses compared to a single exposure to the stimulant. Endotoxin tolerance and priming are critically involved in both immune homeostasis and the pathogenesis of diverse inflammatory diseases. However, the underlying molecular mechanisms are not well understood. By means of a computational search through the parameter space of a coarse-grained three-node network with a two-stage Metropolis sampling approach, we enumerated all the network topologies that can generate priming or tolerance. We discovered three major mechanisms for priming (pathway synergy, suppressor deactivation, activator induction) and one for tolerance (inhibitor persistence). These results not only explain existing experimental observations, but also reveal intriguing test scenarios for future experimental studies to clarify mechanisms of endotoxin priming and tolerance.

Published

2012

4. Histone modification analysis by chromatin immunoprecipitation from a low number of cells on a microfluidic platform

Author

Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, Lu, Chang, Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, and Lu, Chang

Abstract

Histone modifications are important epigenetic mechanisms involved in eukaryotic gene regulation. Chromatin immunoprecipitation (ChIP) assay serves as the primary technique to characterize the genomic locations associated with histone modifications. However, traditional tube-based ChIP assays rely on large numbers of cells as well as laborious and time-consuming procedures. Here we demonstrate a novel microfluidics-based native ChIP assay which dramatically reduces the required cell number and the assay time by conducting cell collection, lysis, chromatin fragmentation, immunoprecipitation, and washing on a microchip. Coupled with real-time PCR, our assay permits the analysis of histone modifications from as few as similar to 50 cells within 8.5 h. We envision that our method will provide a new approach for the analysis of epigenetic regulations and protein-DNA interactions in general, based on scarce cell samples such as those derived from animals and patients.

Published

2011

5. Histone modification analysis by chromatin immunoprecipitation from a low number of cells on a microfluidic platform

Author

Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, Lu, Chang, Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, and Lu, Chang

Abstract

Histone modifications are important epigenetic mechanisms involved in eukaryotic gene regulation. Chromatin immunoprecipitation (ChIP) assay serves as the primary technique to characterize the genomic locations associated with histone modifications. However, traditional tube-based ChIP assays rely on large numbers of cells as well as laborious and time-consuming procedures. Here we demonstrate a novel microfluidics-based native ChIP assay which dramatically reduces the required cell number and the assay time by conducting cell collection, lysis, chromatin fragmentation, immunoprecipitation, and washing on a microchip. Coupled with real-time PCR, our assay permits the analysis of histone modifications from as few as similar to 50 cells within 8.5 h. We envision that our method will provide a new approach for the analysis of epigenetic regulations and protein-DNA interactions in general, based on scarce cell samples such as those derived from animals and patients.

Published

2011

6. Histone modification analysis by chromatin immunoprecipitation from a low number of cells on a microfluidic platform

Author

Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, Lu, Chang, Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, and Lu, Chang

Abstract

Histone modifications are important epigenetic mechanisms involved in eukaryotic gene regulation. Chromatin immunoprecipitation (ChIP) assay serves as the primary technique to characterize the genomic locations associated with histone modifications. However, traditional tube-based ChIP assays rely on large numbers of cells as well as laborious and time-consuming procedures. Here we demonstrate a novel microfluidics-based native ChIP assay which dramatically reduces the required cell number and the assay time by conducting cell collection, lysis, chromatin fragmentation, immunoprecipitation, and washing on a microchip. Coupled with real-time PCR, our assay permits the analysis of histone modifications from as few as similar to 50 cells within 8.5 h. We envision that our method will provide a new approach for the analysis of epigenetic regulations and protein-DNA interactions in general, based on scarce cell samples such as those derived from animals and patients.

Published

2011

7. Histone modification analysis by chromatin immunoprecipitation from a low number of cells on a microfluidic platform

Author

Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, Lu, Chang, Geng, Tao, Bao, Ning, Litt, Michael D., Glaros, Trevor G., Li, Liwu, and Lu, Chang

Abstract

Histone modifications are important epigenetic mechanisms involved in eukaryotic gene regulation. Chromatin immunoprecipitation (ChIP) assay serves as the primary technique to characterize the genomic locations associated with histone modifications. However, traditional tube-based ChIP assays rely on large numbers of cells as well as laborious and time-consuming procedures. Here we demonstrate a novel microfluidics-based native ChIP assay which dramatically reduces the required cell number and the assay time by conducting cell collection, lysis, chromatin fragmentation, immunoprecipitation, and washing on a microchip. Coupled with real-time PCR, our assay permits the analysis of histone modifications from as few as similar to 50 cells within 8.5 h. We envision that our method will provide a new approach for the analysis of epigenetic regulations and protein-DNA interactions in general, based on scarce cell samples such as those derived from animals and patients.

Published

2011