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8. Profiling Distinctive Inflammatory and Redox Responses to Hydrogen Sulfide in Stretched and Stimulated Lung Cells.

Author

Spassov, Sashko G., Faller, Simone, Goeft, Andreas, von Itter, Marc-Nicolas A., Birkigt, Andreas, Meyerhoefer, Peter, Ihle, Andreas, Seiler, Raphael, Schumann, Stefan, and Hoetzel, Alexander

Subjects
MACROPHAGE inflammatory proteins, EPITHELIAL cells, NICOTINAMIDE adenine dinucleotide phosphate, HYDROGEN sulfide, INFLAMMATION, CELL cycle
Abstract

Hydrogen sulfide (H2S) protects against stretch-induced lung injury. However, the impact of H2S on individual cells or their crosstalk upon stretch remains unclear. Therefore, we addressed this issue in vitro using relevant lung cells. We have explored (i) the anti-inflammatory properties of H2S on epithelial (A549 and BEAS-2B), macrophage (RAW264.7) and endothelial (HUVEC) cells subjected to cycling mechanical stretch; (ii) the intercellular transduction of inflammation by co-culturing epithelial cells and macrophages (A549 and RAW264.7); (iii) the effect of H2S on neutrophils (Hoxb8) in transmigration (co-culture setup with HUVECs) and chemotaxis experiments. In stretched epithelial cells (A549, BEAS-2B), the release of interleukin-8 was not prevented by H2S treatment. However, H2S reduced macrophage inflammatory protein-2 (MIP-2) release from unstretched macrophages (RAW264.7) co-cultured with stretched epithelial cells. In stretched macrophages, H2S prevented MIP-2 release by limiting nicotinamide adenine dinucleotide phosphate oxidase-derived superoxide radicals (ROS). In endothelial cells (HUVEC), H2S inhibited interleukin-8 release and preserved endothelial integrity. In neutrophils (Hoxb8), H2S limited MIP-2-induced transmigration through endothelial monolayers, ROS formation and their chemotactic movement. H2S induces anti-inflammatory effects in a cell-type specific manner. H2S limits stretch- and/or paracrine-induced inflammatory response in endothelial, macrophage, and neutrophil cells by maintaining redox homeostasis as underlying mechanism. [ABSTRACT FROM AUTHOR]

Published
2022
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13. Sevoflurane posttreatment prevents oxidative and inflammatory injury in ventilator-induced lung injury.

Author

Wagner, Julie, Strosing, Karl M., Spassov, Sashko G., Lin, Ziwei, Engelstaedter, Helen, Tacke, Sabine, Hoetzel, Alexander, and Faller, Simone

Subjects
VENTILATION, LUNG injuries, REACTIVE oxygen species, CYTOKINES, SEVOFLURANE
Abstract

Mechanical ventilation is a life-saving clinical treatment but it can induce or aggravate lung injury. New therapeutic strategies, aimed at reducing the negative effects of mechanical ventilation such as excessive production of reactive oxygen species, release of pro-inflammatory cytokines, and transmigration as well as activation of neutrophil cells, are needed to improve the clinical outcome of ventilated patients. Though the inhaled anesthetic sevoflurane is known to exert organ-protective effects, little is known about the potential of sevoflurane therapy in ventilator-induced lung injury. This study focused on the effects of delayed sevoflurane application in mechanically ventilated C57BL/6N mice. Lung function, lung injury, oxidative stress, and inflammatory parameters were analyzed and compared between non-ventilated and ventilated groups with or without sevoflurane anesthesia. Mechanical ventilation led to a substantial induction of lung injury, reactive oxygen species production, pro-inflammatory cytokine release, and neutrophil influx. In contrast, sevoflurane posttreatment time dependently reduced histological signs of lung injury. Most interestingly, increased production of reactive oxygen species was clearly inhibited in all sevoflurane posttreatment groups. Likewise, the release of the pro-inflammatory cytokines interleukin-1β and MIP-1β and neutrophil transmigration were completely prevented by sevoflurane independent of the onset of sevoflurane administration. In conclusion, sevoflurane posttreatment time dependently limits lung injury, and oxidative and pro-inflammatory responses are clearly prevented by sevoflurane irrespective of the onset of posttreatment. These findings underline the therapeutic potential of sevoflurane treatment in ventilator-induced lung injury. [ABSTRACT FROM AUTHOR]

Published
2018
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15. Pre- and posttreatment with hydrogen sulfide prevents ventilator-induced lung injury by limiting inflammation and oxidation.

Author

Faller, Simone, Seiler, Raphael, Donus, Rosa, Engelstaedter, Helen, Hoetzel, Alexander, and Spassov, Sashko Gregoriev

Subjects
HYDROGEN sulfide, MECHANICAL ventilators, CRITICAL care medicine, INFLAMMATION, OXIDATION
Abstract

Although essential in critical care medicine, mechanical ventilation often results in ventilator-induced lung injury. Low concentrations of hydrogen sulfide have been proven to have anti-inflammatory and anti-oxidative effects in the lung. The aim of this study was to analyze the kinetic effects of pre- and posttreatment with hydrogen sulfide in order to prevent lung injury as well as inflammatory and oxidative stress upon mechanical ventilation. Mice were either non-ventilated or mechanically ventilated with a tidal volume of 12 ml/kg for 6 h. Pretreated mice inhaled hydrogen sulfide in low dose for 1, 3, or 5 h prior to mechanical ventilation. Posttreated mice were ventilated with air followed by ventilation with hydrogen sulfide in various combinations. In addition, mice were ventilated with air for 10 h, or with air for 5 h and subsequently with hydrogen sulfide for 5 h. Histology, interleukin-1β, neutrophil counts, and reactive oxygen species formation were examined in the lungs. Both pre-and posttreatment with hydrogen sulfide time-dependently reduced or even prevented edema formation, gross histological damage, neutrophil influx and reactive oxygen species production in the lung. These results were also observed in posttreatment, when the experimental time was extended and hydrogen sulfide administration started as late as after 5 h air ventilation. In conclusion, hydrogen sulfide exerts lung protection even when its application is limited to a short or delayed period. The observed lung protection is mediated by inhibition of inflammatory and oxidative signaling. [ABSTRACT FROM AUTHOR]

Published
2017
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18. Genetic Targets of Hydrogen Sulfide in Ventilator-Induced Lung Injury – A Microarray Study.

Author

Spassov, Sashko, Pfeifer, Dietmar, Strosing, Karl, Ryter, Stefan, Hummel, Matthias, Faller, Simone, and Hoetzel, Alexander

Subjects
GENE targeting, HYDROGEN sulfide, MECHANICAL ventilators, LUNG injuries, DNA microarrays, GENE expression
Abstract

Recently, we have shown that inhalation of hydrogen sulfide (H2S) protects against ventilator-induced lung injury (VILI). In the present study, we aimed to determine the underlying molecular mechanisms of H2S-dependent lung protection by analyzing gene expression profiles in mice. C57BL/6 mice were subjected to spontaneous breathing or mechanical ventilation in the absence or presence of H2S (80 parts per million). Gene expression profiles were determined by microarray, sqRT-PCR and Western Blot analyses. The association of Atf3 in protection against VILI was confirmed with a Vivo-Morpholino knockout model. Mechanical ventilation caused a significant lung inflammation and damage that was prevented in the presence of H2S. Mechanical ventilation favoured the expression of genes involved in inflammation, leukocyte activation and chemotaxis. In contrast, ventilation with H2S activated genes involved in extracellular matrix remodelling, angiogenesis, inhibition of apoptosis, and inflammation. Amongst others, H2S administration induced Atf3, an anti-inflammatory and anti-apoptotic regulator. Morpholino mediated reduction of Atf3 resulted in elevated lung injury despite the presence of H2S. In conclusion, lung protection by H2S during mechanical ventilation is associated with down-regulation of genes related to oxidative stress and inflammation and up-regulation of anti-apoptotic and anti-inflammatory genes. Here we show that Atf3 is clearly involved in H2S mediated protection. [ABSTRACT FROM AUTHOR]

Published
2014
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21. Carbon monoxide prevents ventilator-induced lung injury via caveolin-1.

Author

Hoetzel, Alexander, Schmidt, Rene, Vallbracht, Simone, Goebel, Ulrich, Dolinay, Tamas, Hong Pyo Kim, Ifedigbo, Emeka, Ryter, Stefan W., and Choi, Augustine M. K.

Subjects
*CARBON monoxide, *ARTIFICIAL respiration, *LABORATORY mice, *ANTI-inflammatory agents
Abstract

The article highlights a prospective experimental study which evaluates the role of caveolin-1 in the tissue-protective effects of carbon monoxide (CO) in the ventilator-induced lung injury (VILI) model in the U.S. The study focused on wild type (wt) and caveolin-1 deficient mice in a university laboratory. It found that caveolin-1 null mice are more susceptible to VILI and CO executes lung-protective effects during mechanical ventilation that are partly dependent on caveolin-1 expression.

Published
2009
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22. Carbon monoxide protects against ventilator-induced lung injury via PPAR-gamma and inhibition of Egr-1.

Author

Hoetzel A, Dolinay T, Vallbracht S, Zhang Y, Kim HP, Ifedigbo E, Alber S, Kaynar AM, Schmidt R, Ryter SW, Choi AM, Hoetzel, Alexander, Dolinay, Tamas, Vallbracht, Simone, Zhang, Yingze, Kim, Hong Pyo, Ifedigbo, Emeka, Alber, Sean, Kaynar, A Murat, and Schmidt, Rene

Abstract

Rationale: Ventilator-induced lung injury (VILI) leads to an unacceptably high mortality. In this regard, the antiinflammatory properties of inhaled carbon monoxide (CO) may provide a therapeutic option.Objectives: This study explores the mechanisms of CO-dependent protection in a mouse model of VILI.Methods: Mice were ventilated (12 ml/kg, 1-8 h) with air in the absence or presence of CO (250 ppm). Airway pressures, blood pressure, and blood gases were monitored. Lung tissue was analyzed for inflammation, injury, and gene expression. Bronchoalveolar lavage fluid was analyzed for protein, cell and neutrophil counts, and cytokines.Measurements and Main Results: Mechanical ventilation caused significant lung injury reflected by increases in protein concentration, total cell and neutrophil counts in the bronchoalveolar lavage fluid, as well as the induction of heme oxygenase-1 and heat shock protein-70 in lung tissue. In contrast, CO application prevented lung injury during ventilation, inhibited stress-gene up-regulation, and decreased lung neutrophil infiltration. These effects were preceded by the inhibition of ventilation-induced cytokine and chemokine production. Furthermore, CO prevented the early ventilation-dependent up-regulation of early growth response-1 (Egr-1). Egr-1-deficient mice did not sustain lung injury after ventilation, relative to wild-type mice, suggesting that Egr-1 acts as a key proinflammatory regulator in VILI. Moreover, inhibition of peroxysome proliferator-activated receptor (PPAR)-gamma, an antiinflammatory nuclear regulator, by GW9662 abolished the protective effects of CO.Conclusions: Mechanical ventilation causes profound lung injury and inflammatory responses. CO treatment conferred protection in this model dependent on PPAR-gamma and inhibition of Egr-1. [ABSTRACT FROM AUTHOR]

Published
2008
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23. Mitogen-Activated Protein Kinases Regulate Susceptibility to Ventilator-Induced Lung Injury.

Author

Dolinay, Tamás, Wei Wu, Kaminski, Naftali, Ifedigbo, Emeka, Kaynar, A. Murat, Szilasi, Mária, Watkins, Simon C., Ryter, Stefan W., Hoetzel, Alexander, and Choi, Augustine M. K.

Subjects
MITOGEN-activated protein kinases, LUNG injury treatment, MECHANICAL ventilators, GENE expression, DNA fingerprinting, METALLOPROTEINASES, EDEMA, CARCINOGENESIS
Abstract

Background: Mechanical ventilation causes ventilator-induced lung injury in animals and humans. Mitogen-activated protein kinases have been implicated in ventilator-induced lung injury though their functional significance remains incomplete. We characterize the role of p38 mitogen-activated protein kinase/mitogen activated protein kinase kinase-3 and c-Jun-NH2-terminal kinase-1 in ventilator-induced lung injury and investigate novel independent mechanisms contributing to lung injury during mechanical ventilation. Methodology and Principle Findings: C57/BL6 wild-type mice and mice genetically deleted for mitogen-activated protein kinase kinase-3 (mkk-3-/-) or c-Jun-NH2-terminal kinase-1 (jnk1-/-) were ventilated, and lung injury parameters were assessed. We demonstrate that mkk3-/- or jnk1-/- mice displayed significantly reduced inflammatory lung injury and apoptosis relative to wild-type mice. Since jnk1-/- mice were highly resistant to ventilator-induced lung injury, we performed comprehensive gene expression profiling of ventilated wild-type or jnk1-/- mice to identify novel candidate genes which may play critical roles in the pathogenesis of ventilator-induced lung injury. Microarray analysis revealed many novel genes differentially expressed by ventilation including matrix metalloproteinase-8 (MMP8) and GADD45α. Functional characterization of MMP8 revealed that mmp8-/- mice were sensitized to ventilator-induced lung injury with increased lung vascular permeability. Conclusions: We demonstrate that mitogen-activated protein kinase pathways mediate inflammatory lung injury during ventilator-induced lung injury. C-Jun-NH2-terminal kinase was also involved in alveolo-capillary leakage and edema formation, whereas MMP8 inhibited alveolo-capillary protein leakage. [ABSTRACT FROM AUTHOR]

Published
2008
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25. Mechanism of hepatic heme oxygenase-1 induction by isoflurane.

Author

Hoetzel A, Leitz D, Schmidt R, Tritschler E, Bauer I, Loop T, Humar M, Geiger KK, Pannen BH, Hoetzel, Alexander, Leitz, Daniel, Schmidt, Rene, Tritschler, Eva, Bauer, Inge, Loop, Torsten, Humar, Matjaz, Geiger, Klaus K, and Pannen, Benedikt H J

Published
2006

31. Hemorrhagic shock primes the hepatic portal circulation for the vasoconstrictive effects of endothelin-1.

Author

Pannen, Benedikt H.J., Schroll, Stephan, Loop, Torsten, Bauer, Michael, Hoetzel, Alexander, and Geiger, Klaus K.

Subjects
HEMORRHAGIC shock, RESUSCITATION, VASCULAR endothelium, ENDOTHELINS, PHYSIOLOGY
Abstract

Presents a study which investigated whether hemorrhagic shock and resuscitation alters the vascular responsiveness of the portohepatic circulation to endothelins. Materials and methods; Results; Discussion.

Published
2001
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36. P48 Hydrogen sulfide mediated Atf3 activation is involved in protection against ventilator induced lung injury.

Author

Spassov, Sashko, Faller, Simone, Strosing, Karl, Hummel, Matthias, Buerkle, Hartmut, and Hoetzel, Alexander

Subjects
*HYDROGEN sulfide, *POISONOUS gases, *LUNGS, *WOUNDS & injuries, *REFRIGERANTS
Abstract

Rational Our group has recently shown that inhalation of hydrogen sulfide (H 2 S) during mechanical ventilation protects against VILI [1] . Here we explored the gene expression profile of this model in order to identify underlying molecular mechanisms. Methods C57/BL6 mice were randomized into four groups ( n = 5/group). Two groups of control animals were breathing spontaneously air with or without H 2 S (80 ppm). Two groups were ventilated with synthetic air with or without H 2 S as described previously [1] . Lung injury was assessed by an acute lung injury scoring system in hematoxylin and eosin (H& E) stained tissue sections. Bronchoalveolar lavage fluid (BALF) was analysed for inflammatory infiltration. Micro array analysis was performed with RNA from lung tissue samples. Genes with different expression (ANOVA p ⩽ 0.05; fold induction or suppression ⩾2.2) were considered for further analysis. Gene expression of Atf3 was validated by sqPCR and Western Blot. The functional relevance of Atf3 up-regulation was validated in Atf3-Morpfolino knockout mice ventilated in presence of H 2 S. Results Mechanical ventilation led to lung injury, i . e ., H& E-stained samples revealed clear thickening of alveolar walls and increased amounts of inflammatory cell infiltrates in lung sections and BALF from animals ventilated with synthetic air. In contrast, the presence of H 2 S prevented lung injury as well as neutrophil and macrophage infiltration. Spontaneous breathing control animals regardless of the presence or absence of H 2 S showed no significant effects on lung injury or inflammation. H 2 S application led to differential expression of 137 genes. Among these, Atf3 was chosen for further analysis. In contrast to the protective effects of H 2 S in ventilated mice, Atf3-Morpholino mice developed despite the presence of H 2 S sings of lung injury, i . e ., enlarged alveolar walls, increased inflammatory cell infiltrates, and occurrence of sporadic blood vessel leakages. Further analysis revealed significant increase of the VILI score in the Atf3-Morpholino group as compared to the air control and control-Morpholino groups. However, histology demonstrated that down-regulated Atf3 protein synthesis failed to completely abolish H 2 S mediated protection in VILI. Thus, Atf3 significantly contributes to the protective effect of H 2 S, but seems not to be the only player. Likewise and with respect to the inflammatory response, inhibition Atf3 protein synthesis in H 2 S ventilated mice resulted in significant increase of neutrophils in BALF as compared to H 2 S ventilation alone, but neutrophil counts were still lower as compared to injurious ventilation without any treatment. Conclusions (1) VILI can be prevented by application of H 2 S. (2) 137 genes were differentially expressed in the presence of H 2 S during mechanical ventilation. (3) Our data suggest that the Atf3 signaling pathway significantly contributes to the lung protective and anti-inflammatory effects of H 2 S. [ABSTRACT FROM AUTHOR]

Published
2013
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