Mechanical ventilation induces diaphragmatic mitochondrial dysfunction and increased oxidant production

Background Protective ventilatory strategies have resulted in a decreased mortality rate in acute respiratory distress syndrome, but the underlying mechanisms remain unclear. The authors hypothesized that (1) mechanical ventilation modulates activation of polymorphonuclear leukocytes (PMNs), (2) the consequent release of proteinases is correlated with a systemic inflammatory response and with multiple organ dysfunction, and (3) these deleterious effects can be minimized by a protective ventilatory strategy. Methods Human PMNs were incubated with bronchoalveolar lavage fluid obtained from patients at entry or 36 h after randomization to ventilation with either a conventional (control) or a lung-protective strategy. PMN oxidant production and surface expression of adhesion molecules and granule markers, including CD18, CD63, and L-selectin, were measured by flow cytometry. Extracellular elastase activity was quantified using a fluorescent substrate. Results Bronchoalveolar lavage obtained from both groups of patients at entry showed similar effects on PMN oxidant production and expression of surface markers. At 36 h, exposure of PMNs to bronchoalveolar lavage fluid from the control group resulted in increased PMN activation as manifested by a significant increase in oxidant production, CD18, and CD63 surface expression, and shedding of L-selectin. By contrast, these variables were unchanged at 36 h in the lung-protective group. There was a significant correlation between the changes of the variables and changes in interleukin-6 level and the number of failing organs. Conclusions Polymorphonuclear leukocytes can be activated by mechanical ventilation, and the consequent release of elastase was correlated with the degree of systemic inflammatory response and multiple organ failure. This result may possibly explain the decreased mortality in acute respiratory distress syndrome patients treated with a lung-protective strategy.

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Xanthine oxidase contributes to mechanical ventilation-induced diaphragmatic oxidative stress and contractile dysfunction

Journal of Applied Physiology ◽

10.1152/japplphysiol.91106.2008 ◽

2009 ◽

Vol 106 (2) ◽

pp. 385-394 ◽

Cited By ~ 67

Author(s):

Melissa A. Whidden ◽

Joseph M. McClung ◽

Darin J. Falk ◽

Matthew B. Hudson ◽

Ashley J. Smuder ◽

...

Keyword(s):

Oxidative Stress ◽

Mechanical Ventilation ◽

Xanthine Oxidase ◽

Prolonged Mechanical Ventilation ◽

Oxidative Injury ◽

Contractile Dysfunction ◽

Sprague Dawley ◽

Sprague Dawley Rats ◽

Oxidant Production ◽

Diaphragmatic Weakness

Respiratory muscle weakness resulting from both diaphragmatic contractile dysfunction and atrophy has been hypothesized to contribute to the weaning difficulties associated with prolonged mechanical ventilation (MV). While it is clear that oxidative injury contributes to MV-induced diaphragmatic weakness, the source(s) of oxidants in the diaphragm during MV remain unknown. These experiments tested the hypothesis that xanthine oxidase (XO) contributes to MV-induced oxidant production in the rat diaphragm and that oxypurinol, a XO inhibitor, would attenuate MV-induced diaphragmatic oxidative stress, contractile dysfunction, and atrophy. Adult female Sprague-Dawley rats were randomly assigned to one of six experimental groups: 1) control, 2) control with oxypurinol, 3) 12 h of MV, 4) 12 h of MV with oxypurinol, 5) 18 h of MV, or 6) 18 h of MV with oxypurinol. XO activity was significantly elevated in the diaphragm after MV, and oxypurinol administration inhibited this activity and provided protection against MV-induced oxidative stress and contractile dysfunction. Specifically, oxypurinol treatment partially attenuated both protein oxidation and lipid peroxidation in the diaphragm during MV. Further, XO inhibition retarded MV-induced diaphragmatic contractile dysfunction at stimulation frequencies >60 Hz. Collectively, these results suggest that oxidant production by XO contributes to MV-induced oxidative injury and contractile dysfunction in the diaphragm. Nonetheless, the failure of XO inhibition to completely prevent MV-induced diaphragmatic oxidative damage suggests that other sources of oxidant production are active in the diaphragm during prolonged MV.

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Diaphragmatic nitric oxide synthase is not induced during mechanical ventilation

Journal of Applied Physiology ◽

10.1152/japplphysiol.00043.2006 ◽

2007 ◽

Vol 102 (1) ◽

pp. 157-162 ◽

Cited By ~ 15

Author(s):

Darin Van Gammeren ◽

Darin J. Falk ◽

Melissa A. Deering ◽

Keith C. DeRuisseau ◽

Scott K. Powers

Keyword(s):

Oxidative Stress ◽

Nitric Oxide ◽

Mechanical Ventilation ◽

Nitric Oxide Synthase ◽

Protein Levels ◽

Nitric Oxide Metabolism ◽

Neuronal Nos ◽

Oxidant Production ◽

Oxide Synthase ◽

Inducible Nos

Mechanical ventilation (MV) is associated with diaphragmatic oxidative stress that contributes to both diaphragmatic atrophy and contractile dysfunction. However, the pathways responsible for oxidant production in the diaphragm during MV remain unknown. To address this issue, we tested the hypothesis that diaphragmatic nitric oxide synthase (NOS) activity is elevated during MV, resulting in nitration of diaphragmatic proteins. Rats were mechanically ventilated for 18 h, and time-matched, anesthetized but spontaneously breathing animals served as controls. Protein levels of endothelial NOS, inducible NOS, and neuronal NOS were measured in diaphragms from all animals. 3-Nitrotyrosine levels were also measured as an index of protein nitration, and S-nitrosothiol levels were measured as a marker of nitric oxide reactions with molecules containing sulfhydryl groups. Levels of nitrates and nitrites were measured as markers of stable end products of nitric oxide metabolism. Finally, as a marker of oxidative stress, diaphragmatic levels of reduced GSH were also analyzed. MV did not promote an increase in diaphragmatic protein levels of endothelial NOS or neuronal NOS. Moreover, inducible NOS was not detected in the diaphragms of either experimental group. Consistent with these findings, MV did not elevate diaphragmatic 3-nitrotyrosine levels in any subcellular fraction of the diaphragm, including the cytosolic, mitochondrial, membrane, and insoluble protein fractions. Moreover, prolonged MV did not elevate diaphragmatic levels of S-nitrosothiols, nitrate, or nitrite. Finally, prolonged MV significantly reduced diaphragmatic levels of GSH, which is consistent with diaphragmatic oxidative stress. Collectively, these data reveal that MV-induced oxidative stress in the diaphragm is not due to increases in nitric oxide production by NOS.

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Mechanical ventilation triggers abnormal mitochondrial dynamics and morphology in the diaphragm

Journal of Applied Physiology ◽

10.1152/japplphysiol.00873.2014 ◽

2015 ◽

Vol 118 (9) ◽

pp. 1161-1171 ◽

Cited By ~ 40

Author(s):

Martin Picard ◽

Ilan Azuelos ◽

Boris Jung ◽

Christian Giordano ◽

Stefan Matecki ◽

...

Keyword(s):

Mechanical Ventilation ◽

Mitochondrial Dysfunction ◽

Mitochondrial Dynamics ◽

Physiological State ◽

Rapid Onset ◽

Medical Intervention ◽

Quantitative Electron Microscopy ◽

Short Period ◽

Physical Interactions ◽

Activation Status

The diaphragm is a unique skeletal muscle designed to be rhythmically active throughout life, such that its sustained inactivation by the medical intervention of mechanical ventilation (MV) represents an unanticipated physiological state in evolutionary terms. Within a short period after initiating MV, the diaphragm develops muscle atrophy, damage, and diminished strength, and many of these features appear to arise from mitochondrial dysfunction. Notably, in response to metabolic perturbations, mitochondria fuse, divide, and interact with neighboring organelles to remodel their shape and functional properties—a process collectively known as mitochondrial dynamics. Using a quantitative electron microscopy approach, here we show that diaphragm contractile inactivity induced by 6 h of MV in mice leads to fragmentation of intermyofibrillar (IMF) but not subsarcolemmal (SS) mitochondria. Furthermore, physical interactions between adjacent organellar membranes were less abundant in IMF mitochondria during MV. The profusion proteins Mfn2 and OPA1 were unchanged, whereas abundance and activation status of the profission protein Drp1 were increased in the diaphragm following MV. Overall, our results suggest that mitochondrial morphological abnormalities characterized by excessive fission-fragmentation represent early events during MV, which could potentially contribute to the rapid onset of mitochondrial dysfunction, maladaptive signaling, and associated contractile dysfunction of the diaphragm.

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Mitochondrial Dysfunction And Lipid Accumulation In The Human Diaphragm During Mechanical Ventilation

10.1164/ajrccm-conference.2011.183.1_meetingabstracts.a4257 ◽

2011 ◽

Author(s):

Martin Picard ◽

Feng Liang ◽

Sabbah N. Hussain ◽

Peter Goldberg ◽

Gawiyou Danialou ◽

...

Keyword(s):

Mechanical Ventilation ◽

Mitochondrial Dysfunction ◽

Lipid Accumulation

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AT1 receptor blocker losartan protects against mechanical ventilation-induced diaphragmatic dysfunction

Journal of Applied Physiology ◽

10.1152/japplphysiol.00237.2015 ◽

2015 ◽

Vol 119 (10) ◽

pp. 1033-1041 ◽

Cited By ~ 20

Author(s):

Oh Sung Kwon ◽

Ashley J. Smuder ◽

Michael P. Wiggs ◽

Stephanie E. Hall ◽

Kurt J. Sollanek ◽

...

Keyword(s):

Oxidative Stress ◽

Mechanical Ventilation ◽

Enzyme Inhibitor ◽

Ang Ii ◽

Diaphragmatic Dysfunction ◽

Life Saving ◽

Clinical Benefits ◽

Oxidant Production ◽

Diaphragm Weakness

Mechanical ventilation is a life-saving intervention for patients in respiratory failure. Unfortunately, prolonged ventilator support results in diaphragmatic atrophy and contractile dysfunction leading to diaphragm weakness, which is predicted to contribute to problems in weaning patients from the ventilator. While it is established that ventilator-induced oxidative stress is required for the development of ventilator-induced diaphragm weakness, the signaling pathway(s) that trigger oxidant production remain unknown. However, recent evidence reveals that increased plasma levels of angiotensin II (ANG II) result in oxidative stress and atrophy in limb skeletal muscles. Using a well-established animal model of mechanical ventilation, we tested the hypothesis that increased circulating levels of ANG II are required for both ventilator-induced diaphragmatic oxidative stress and diaphragm weakness. Cause and effect was determined by administering an angiotensin-converting enzyme inhibitor (enalapril) to prevent ventilator-induced increases in plasma ANG II levels, and the ANG II type 1 receptor antagonist (losartan) was provided to prevent the activation of ANG II type 1 receptors. Enalapril prevented the increase in plasma ANG II levels but did not protect against ventilator-induced diaphragmatic oxidative stress or diaphragm weakness. In contrast, losartan attenuated both ventilator-induced oxidative stress and diaphragm weakness. These findings indicate that circulating ANG II is not essential for the development of ventilator-induced diaphragm weakness but that activation of ANG II type 1 receptors appears to be a requirement for ventilator-induced diaphragm weakness. Importantly, these experiments provide the first evidence that the Food and Drug Administration-approved drug losartan may have clinical benefits to protect against ventilator-induced diaphragm weakness in humans.

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Mitochondrial Dysfunction and Lipid Accumulation in the Human Diaphragm during Mechanical Ventilation

American Journal of Respiratory and Critical Care Medicine ◽

10.1164/rccm.201206-0982oc ◽

2012 ◽

Vol 186 (11) ◽

pp. 1140-1149 ◽

Cited By ~ 116

Author(s):

Martin Picard ◽

Boris Jung ◽

Feng Liang ◽

Ilan Azuelos ◽

Sabah Hussain ◽

...

Keyword(s):

Mechanical Ventilation ◽

Mitochondrial Dysfunction ◽

Lipid Accumulation

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Protein kinase C-ε activation induces mitochondrial dysfunction and fragmentation in renal proximal tubules

AJP Renal Physiology ◽

10.1152/ajprenal.00364.2010 ◽

2011 ◽

Vol 301 (1) ◽

pp. F197-F208 ◽

Cited By ~ 24

Author(s):

Grazyna Nowak ◽

Diana Bakajsova ◽

Allen M. Samarel

Keyword(s):

Cell Death ◽

Mitochondrial Dysfunction ◽

Ischemia Reperfusion Injury ◽

Ischemia Reperfusion ◽

Primary Cultures ◽

Protective Effects ◽

Mitochondrial Fragmentation ◽

Atp Production ◽

Mitochondrial Functions ◽

Oxidant Production

PKC-ε activation mediates protection from ischemia-reperfusion injury in the myocardium. Mitochondria are a subcellular target of these protective mechanisms of PKC-ε. Previously, we have shown that PKC-ε activation is involved in mitochondrial dysfunction in oxidant-injured renal proximal tubular cells (RPTC; Nowak G, Bakajsova D, Clifton GL Am J Physiol Renal Physiol 286: F307–F316, 2004). The goal of this study was to examine the role of PKC-ε activation in mitochondrial dysfunction and to identify mitochondrial targets of PKC-ε in RPTC. The constitutively active and inactive mutants of PKC-ε were overexpressed in primary cultures of RPTC using the adenoviral technique. Increases in active PKC-ε levels were accompanied by PKC-ε translocation to mitochondria. Sustained PKC-ε activation resulted in decreases in state 3 respiration, electron transport rate, ATP production, ATP content, and activities of complexes I and IV and F0F1-ATPase. Furthermore, PKC-ε activation increased mitochondrial membrane potential and oxidant production and induced mitochondrial fragmentation and RPTC death. Accumulation of the dynamin-related protein in mitochondria preceded mitochondrial fragmentation. Antioxidants blocked PKC-ε-induced increases in the oxidant production but did not prevent mitochondrial fragmentation and cell death. The inactive PKC-ε mutant had no effect on mitochondrial functions, morphology, oxidant production, and RPTC viability. We conclude that active PKC-ε targets complexes I and IV and F0F1-ATPase in RPTC. PKC-ε activation mediates mitochondrial dysfunction, hyperpolarization, and fragmentation. It also induces oxidant generation and cell death, but oxidative stress is not the mechanism of RPTC death. These results show that in contrast to protective effects of PKC-ε activation in cardiomyocytes, sustained PKC-ε activation is detrimental to mitochondrial function and viability in RPTC.

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