4 research outputs found
Transcriptional Events during the Recovery from MRSA Lung Infection: A Mouse Pneumonia Model
Community associated methicillin-resistant Staphylococcus aureus (CA-MRSA) is an emerging threat to human health throughout the world. Rodent MRSA pneumonia models mainly focus on the early innate immune responses to MRSA lung infection. However, the molecular pattern and mechanisms of recovery from MRSA lung infection are largely unknown. In this study, a sublethal mouse MRSA pneumonia model was employed to investigate late events during the recovery from MRSA lung infection. We compared lung bacterial clearance, bronchoalveolar lavage fluid (BALF) characterization, lung histology, lung cell proliferation, lung vascular permeability and lung gene expression profiling between days 1 and 3 post MRSA lung infection. Compared to day 1 post infection, bacterial colony counts, BALF total cell number and BALF protein concentration significantly decreased at day 3 post infection. Lung cDNA microarray analysis identified 47 significantly up-regulated and 35 down-regulated genes (p<0.01, 1.5 fold change [up and down]). The pattern of gene expression suggests that lung recovery is characterized by enhanced cell division, vascularization, wound healing and adjustment of host adaptive immune responses. Proliferation assay by PCNA staining further confirmed that at day 3 lungs have significantly higher cell proliferation than at day 1. Furthermore, at day 3 lungs displayed significantly lower levels of vascular permeability to albumin, compared to day 1. Collectively, this data helps us elucidate the molecular mechanisms of the recovery after MRSA lung infection
Particulate matter air pollution disrupts endothelial cell barrier via calpain-mediated tight junction protein degradation
BACKGROUND:
Exposure to particulate matter (PM) is a significant risk factor for increased cardiopulmonary morbidity and mortality. The mechanism of PM-mediated pathophysiology remains unknown. However, PM is proinflammatory to the endothelium and increases vascular permeability in vitro and in vivo via ROS generation.
OBJECTIVES:
We explored the role of tight junction proteins as targets for PM-induced loss of lung endothelial cell (EC) barrier integrity and enhanced cardiopulmonary dysfunction.
METHODS:
Changes in human lung EC monolayer permeability were assessed by Transendothelial Electrical Resistance (TER) in response to PM challenge (collected from Ft. McHenry Tunnel, Baltimore, MD, particle size >0.1 μm). Biochemical assessment of ROS generation and Ca2+ mobilization were also measured.
RESULTS:
PM exposure induced tight junction protein Zona occludens-1 (ZO-1) relocation from the cell periphery, which was accompanied by significant reductions in ZO-1 protein levels but not in adherens junction proteins (VE-cadherin and β-catenin). N-acetyl-cysteine (NAC, 5 mM) reduced PM-induced ROS generation in ECs, which further prevented TER decreases and atteneuated ZO-1 degradation. PM also mediated intracellular calcium mobilization via the transient receptor potential cation channel M2 (TRPM2), in a ROS-dependent manner with subsequent activation of the Ca2+-dependent protease calpain. PM-activated calpain is responsible for ZO-1 degradation and EC barrier disruption. Overexpression of ZO-1 attenuated PM-induced endothelial barrier disruption and vascular hyperpermeability in vivo and in vitro.
CONCLUSIONS:
These results demonstrate that PM induces marked increases in vascular permeability via ROS-mediated calcium leakage via activated TRPM2, and via ZO-1 degradation by activated calpain. These findings support a novel mechanism for PM-induced lung damage and adverse cardiovascular outcomes
Peripheral Blood Gene Expression as a Novel Genomic Biomarker in Complicated Sarcoidosis
Sarcoidosis, a systemic granulomatous syndrome invariably affecting the lung, typically spontaneously remits but in ,20%
of cases progresses with severe lung dysfunction or cardiac and neurologic involvement (complicated sarcoidosis).
Unfortunately, current biomarkers fail to distinguish patients with remitting (uncomplicated) sarcoidosis from other fibrotic
lung disorders, and fail to identify individuals at risk for complicated sarcoidosis. We utilized genome-wide peripheral blood
gene expression analysis to identify a 20-gene sarcoidosis biomarker signature distinguishing sarcoidosis (n = 39) from
healthy controls (n = 35, 86% classification accuracy) and which served as a molecular signature for complicated sarcoidosis
(n = 17). As aberrancies in T cell receptor (TCR) signaling, JAK-STAT (JS) signaling, and cytokine-cytokine receptor (CCR)
signaling are implicated in sarcoidosis pathogenesis, a 31-gene signature comprised of T cell signaling pathway genes
associated with sarcoidosis (TCR/JS/CCR) was compared to the unbiased 20-gene biomarker signature but proved inferior in
prediction accuracy in distinguishing complicated from uncomplicated sarcoidosis. Additional validation strategies included
significant association of single nucleotide polymorphisms (SNPs) in signature genes with sarcoidosis susceptibility and
severity (unbiased signature genes - CX3CR1, FKBP1A, NOG, RBM12B, SENS3, TSHZ2; T cell/JAK-STAT pathway genes such as
AKT3, CBLB, DLG1, IFNG, IL2RA, IL7R, ITK, JUN, MALT1, NFATC2, PLCG1, SPRED1). In summary, this validated peripheral blood
molecular gene signature appears to be a valuable biomarker in identifying cases with sarcoidoisis and predicting risk for
complicated sarcoidosis
Particulate matter air pollution disrupts endothelial cell barrier via calpain-mediated tight junction protein degradation
Background: Exposure to particulate matter (PM) is a significant risk factor for increased cardiopulmonary morbidity
and mortality. The mechanism of PM-mediated pathophysiology remains unknown. However, PM is
proinflammatory to the endothelium and increases vascular permeability in vitro and in vivo via ROS generation.
Objectives: We explored the role of tight junction proteins as targets for PM-induced loss of lung endothelial cell
(EC) barrier integrity and enhanced cardiopulmonary dysfunction.
Methods: Changes in human lung EC monolayer permeability were assessed by Transendothelial Electrical
Resistance (TER) in response to PM challenge (collected from Ft. McHenry Tunnel, Baltimore, MD, particle size
>0.1 μm). Biochemical assessment of ROS generation and Ca2+ mobilization were also measured.
Results: PM exposure induced tight junction protein Zona occludens-1 (ZO-1) relocation from the cell periphery,
which was accompanied by significant reductions in ZO-1 protein levels but not in adherens junction proteins
(VE-cadherin and β-catenin). N-acetyl-cysteine (NAC, 5 mM) reduced PM-induced ROS generation in ECs, which
further prevented TER decreases and atteneuated ZO-1 degradation. PM also mediated intracellular calcium
mobilization via the transient receptor potential cation channel M2 (TRPM2), in a ROS-dependent manner with
subsequent activation of the Ca2+-dependent protease calpain. PM-activated calpain is responsible for ZO-1
degradation and EC barrier disruption. Overexpression of ZO-1 attenuated PM-induced endothelial barrier
disruption and vascular hyperpermeability in vivo and in vitro.
Conclusions: These results demonstrate that PM induces marked increases in vascular permeability via ROS-mediated
calcium leakage via activated TRPM2, and via ZO-1 degradation by activated calpain. These findings support a novel
mechanism for PM-induced lung damage and adverse cardiovascular outcomes