A Modular Cell-type Focused Inflammatory Process Network Model for Non-diseased Pulmonary Tissue

Overview

Journal Bioinform Biol Insights

Publisher Sage Publications

Specialty Biology

Date 2013 Jul 12

PMID 23843693

Citations 20

Authors

Jurjen W Westra

Walter K Schlage

Arnd Hengstermann

Stephan Gebel

Carole Mathis

Ty Thomson

Ben Wong

Vy Hoang

Emilija Veljkovic

Michael Peck

Rosemarie B Lichtner

Dirk Weisensee

Marja Talikka

Renee Deehan

Julia Hoeng

Manuel C Peitsch

Affiliations

Soon will be listed here.

Abstract

Exposure to environmental stressors such as cigarette smoke (CS) elicits a variety of biological responses in humans, including the induction of inflammatory responses. These responses are especially pronounced in the lung, where pulmonary cells sit at the interface between the body's internal and external environments. We combined a literature survey with a computational analysis of multiple transcriptomic data sets to construct a computable causal network model (the Inflammatory Process Network (IPN)) of the main pulmonary inflammatory processes. The IPN model predicted decreased epithelial cell barrier defenses and increased mucus hypersecretion in human bronchial epithelial cells, and an attenuated pro-inflammatory (M1) profile in alveolar macrophages following exposure to CS, consistent with prior results. The IPN provides a comprehensive framework of experimentally supported pathways related to CS-induced pulmonary inflammation. The IPN is freely available to the scientific community as a resource with broad applicability to study the pathogenesis of pulmonary disease.

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