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Cross-talk between the calpain and caspase-3 proteolytic systems in the diaphragm during prolonged mechanical ventilation.

ABSTRACT: Diaphragmatic weakness, due to both atrophy and contractile dysfunction, is a well-documented response following prolonged mechanical ventilation. Evidence indicates that activation of the proteases calpain and caspase-3 is essential for mechanical ventilation-induced diaphragmatic weakness to occur. We tested the hypothesis that a regulatory cross-talk exists between calpain and caspase-3 in the diaphragm during prolonged mechanical ventilation. To test this prediction, we determined whether selective pharmacological inhibition of calpain would prevent activation of caspase-3 and conversely whether selective inhibition of caspase-3 would abate calpain activation.Animal study.University Research Laboratory.Female Sprague-Dawley rats.Animals were randomly divided into control or one of three 12-hr mechanical ventilation groups that were treated with/without a selective pharmacological protease inhibitor: 1) control, 2) mechanical ventilation, 3) mechanical ventilation with a selective caspase-3 inhibitor, and 4) mechanical ventilation with a selective calpain inhibitor.Compared to control, mechanical ventilation resulted in calpain and caspase-3 activation in the diaphragm accompanied by atrophy of type I, type IIa, and type IIx/IIb fibers. Independent inhibition of either calpain or caspase-3 prevented this mechanical ventilation-induced atrophy. Pharmacological inhibition of calpain prevented mechanical ventilation-induced activation of diaphragmatic caspase-3 and inhibition of caspase-3 prevented activation of diaphragmatic calpain. Furthermore, calpain inhibition also prevented the activation of caspase-9 and caspase-12, along with the cleavage of Bid to tBid, all upstream signals for caspase-3 activation. Lastly, caspase-3 inhibition prevented the mechanical ventilation-induced degradation of the endogenous calpain inhibitor, calpastatin.Collectively, these results indicate that mechanical ventilation-induced diaphragmatic atrophy is dependent on the activation of both calpain and caspase-3. Importantly, these findings provide the first experimental evidence in diaphragm muscle that calpain inhibition prevents the activation of caspase-3 and vice versa and caspase-3 inhibition prevents the activation of calpain. These findings support our hypothesis that a regulatory calpain/caspase-3 cross-talk exists whereby calpain can promote caspase-3 activation and active caspase-3 can enhance calpain activity in diaphragm muscle during prolonged mechanical ventilation.

SUBMITTER: Nelson WB

PROVIDER: S-EPMC3358441 | biostudies-literature | 2012 Jun

REPOSITORIES: biostudies-literature

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Cross-talk between the calpain and caspase-3 proteolytic systems in the diaphragm during prolonged mechanical ventilation.

Nelson W Bradley WB Smuder Ashley J AJ Hudson Matthew B MB Talbert Erin E EE Powers Scott K SK

Critical care medicine 20120601 6

<h4>Objective</h4>Diaphragmatic weakness, due to both atrophy and contractile dysfunction, is a well-documented response following prolonged mechanical ventilation. Evidence indicates that activation of the proteases calpain and caspase-3 is essential for mechanical ventilation-induced diaphragmatic weakness to occur. We tested the hypothesis that a regulatory cross-talk exists between calpain and caspase-3 in the diaphragm during prolonged mechanical ventilation. To test this prediction, we det ...[more]

PMID: 22487998

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Project description:BACKGROUND:In intensive care unit (ICU) patients, diaphragmatic dysfunction (DD) can occur on admission or during the subsequent stay. The respective incidence of these two phenomena has not been previously studied in humans. The study was designed to describe temporal trends in diaphragm function in mechanically ventilated (MV) patients. METHODS:Ancillary study of a prospective, 6-month, observational cohort study conducted in two ICUs. MV patients were studied within 24 h following intubation (day-1) and every 48-72 h thereafter. Diaphragm function was assessed by twitch tracheal pressure (Ptr,stim) in response to bilateral anterior magnetic phrenic nerve stimulation. Diaphragm dysfunction was defined as Ptr,stim < 11 cmH2O. Patients who received MV for at least 5 days were retained, and the first and the last measures were analysed. RESULTS:Forty-three patients were included. Overall, 79 % of patients developed DD at some point during their ICU stay: 23 (53 %) patients presented DD on initiation of mechanical ventilation, 14 (33 %) of whom had persistent DD, while diaphragm function improved in 9 (21 %). Among the remaining 20 (47 %) patients who did not present DD on initiation of MV, 11 (26 %) developed DD during the ICU stay, while 9 (21 %) did not. Mortality was higher in patients with DD either on initiation of mechanical ventilation or during the subsequent ICU stay than in those who never developed DD (35 vs. 0 %, p = 0.04). Duration of MV was higher in patients with DD on initiation of MV that subsequently persisted than in patients who never exhibited diaphragm dysfunction (18 vs. 5 days, p = 0.04). Factors associated with a change in Ptr,stim were: age [linear coefficient regression (Coeff.) -0.097, standard error (SD) 0.047, p = 0.046], PaO2/FiO2 ratio (Coeff. 0.014, SD 0.006, p = 0.0211) and the proportion of the time under MV with sedation (per 10 %, Coeff. -5.359, SD 2.451, p = 0.035). CONCLUSIONS:DD is observed in a large majority of MV patients ?5 days at some point of their ICU stay. Various patterns of DD are observed, including DD on initiation of mechanical ventilation and ICU-acquired DD. Trial registration clinicaltrials.gov Identifier # NCT00786526.

Project description:Mechanical ventilation is a life-saving intervention used to provide adequate pulmonary ventilation in patients suffering from respiratory failure. However, prolonged mechanical ventilation is associated with significant diaphragmatic weakness resulting from both myofiber atrophy and contractile dysfunction. Although several signaling pathways contribute to diaphragm weakness during mechanical ventilation, it is established that oxidative stress is required for diaphragmatic weakness to occur. Therefore, identifying the site(s) of mechanical ventilation- induced reactive oxygen species production in the diaphragm is important.These experiments tested the hypothesis that elevated mitochondrial reactive oxygen species emission is required for mechanical ventilation-induced oxidative stress, atrophy, and contractile dysfunction in the diaphragm.Cause and effect was determined by preventing mechanical ventilation-induced mitochondrial reactive oxygen species emission in the diaphragm of rats using a novel mitochondria-targeted antioxidant (SS-31).None.Compared to mechanically ventilated animals treated with saline, animals treated with SS-31 were protected against mechanical ventilation-induced mitochondrial dysfunction, oxidative stress, and protease activation in the diaphragm. Importantly, treatment of animals with the mitochondrial antioxidant also protected the diaphragm against mechanical ventilation-induced myofiber atrophy and contractile dysfunction.These results reveal that prevention of mechanical ventilation-induced increases in diaphragmatic mitochondrial reactive oxygen species emission protects the diaphragm from mechanical ventilation-induced diaphragmatic weakness. This important new finding indicates that mitochondria are a primary source of reactive oxygen species production in the diaphragm during prolonged mechanical ventilation. These results could lead to the development of a therapeutic intervention to impede mechanical ventilation-induced diaphragmatic weakness.

Project description:Previous workers have demonstrated that controlled mechanical ventilation results in diaphragm inactivity and elicits a rapid development of diaphragm weakness as a result of both contractile dysfunction and fiber atrophy. Limited data exist regarding the impact of pressure support ventilation, a commonly used mode of mechanical ventilation-that permits partial mechanical activity of the diaphragm-on diaphragm structure and function. We carried out the present study to test the hypothesis that high-level pressure support ventilation decreases the diaphragm pathology associated with CMV.Sprague-Dawley rats were randomly assigned to one of the following five groups:1) control (no mechanical ventilation); 2) 12 hrs of controlled mechanical ventilation (12CMV); 3) 18 hrs of controlled mechanical ventilation (18CMV); 4) 12 hrs of pressure support ventilation (12PSV); or 5) 18 hrs of pressure support ventilation (18PSV).We carried out the following measurements on diaphragm specimens: 4-hydroxynonenal-a marker of oxidative stress, active caspase-3 (casp-3), active calpain-1 (calp-1), fiber type cross-sectional area, and specific force (sp F). Compared with the control, both 12PSV and 18PSV promoted a significant decrement in diaphragmatic specific force production, but to a lesser degree than 12CMV and 18CMV. Furthermore, 12CMV, 18PSV, and 18CMV resulted in significant atrophy in all diaphragm fiber types as well as significant increases in a biomarker of oxidative stress (4-hydroxynonenal) and increased proteolytic activity (20S proteasome, calpain-1, and caspase-3). Furthermore, although no inspiratory effort occurs during controlled mechanical ventilation, it was observed that pressure support ventilation resulted in large decrement, approximately 96%, in inspiratory effort compared with spontaneously breathing animals.High levels of prolonged pressure support ventilation promote diaphragmatic atrophy and contractile dysfunction. Furthermore, similar to controlled mechanical ventilation, pressure support ventilation-induced diaphragmatic atrophy and weakness are associated with both diaphragmatic oxidative stress and protease activation.

Project description:Although mechanical ventilation is a life-saving measure for patients in respiratory failure, prolonged mechanical ventilation results in diaphragmatic weakness attributable to fiber atrophy and contractile dysfunction. Therefore, identifying the signaling pathways responsible for mechanical ventilation-induced diaphragmatic weakness is important. In this context, it is established that oxidative stress is required for mechanical ventilation-induced diaphragmatic weakness to occur. Numerous redox-sensitive signaling pathways exist in muscle including the transcription factor nuclear factor-?B. Although it has been suggested that nuclear factor-?B contributes to proteolytic signaling in inactivity-induced atrophy in locomotor muscles, the role that nuclear factor-?B plays in mechanical ventilation-induced diaphragmatic weakness is unknown. We tested the hypothesis that nuclear factor-?B activation plays a key signaling role in mechanical ventilation-induced diaphragmatic weakness and that oxidative stress is required for nuclear factor-?B activation.Cause and effect was determined by independently treating mechanically ventilated animals with either a specific nuclear factor-?B inhibitor (SN50) or a clinically relevant antioxidant (curcumin).Inhibition of nuclear factor-?B activity partially attenuated both mechanical ventilation-induced diaphragmatic atrophy and contractile dysfunction. Further, treatment with the antioxidant curcumin prevented mechanical ventilation-induced activation of nuclear factor-?B in the diaphragm and rescued the diaphragm from both mechanical ventilation-induced atrophy and contractile dysfunction.Collectively, these findings support the hypothesis that nuclear factor-?B activation plays a significant signaling role in mechanical ventilation-induced diaphragmatic weakness and that oxidative stress is an upstream activator of nuclear factor-?B. Finally, our results suggest that prevention of mechanical ventilation-induced oxidative stress in the diaphragm could be a useful clinical strategy to prevent or delay mechanical ventilation-induced diaphragmatic weakness.

Dataset Information

Cross-talk between the calpain and caspase-3 proteolytic systems in the diaphragm during prolonged mechanical ventilation.

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Cross-talk between the calpain and caspase-3 proteolytic systems in the diaphragm during prolonged mechanical ventilation.

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