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Cigarette Smoke Extract Disturbs Mitochondria-Regulated Airway Epithelial Cell Responses to Pneumococci.
Aghapour, M, Tulen, CBM, Abdi Sarabi, M, Weinert, S, Müsken, M, Relja, B, van Schooten, FJ, Jeron, A, Braun-Dullaeus, R, Remels, AH, et al
Cells. 2022;11(11)
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Cigarette smoking can affect airway epithelial cells, causing overproduction of mucus, damage, and inflammation, which may result in the progression of airway diseases. Airway epithelial cells (AEC) rely on mitochondria for energy, and mitochondrial dysfunction may affect innate immunity and the integrity of the airway epithelium. Cigarette smoking is found to accelerate mitochondrial damage within AEC. Maintaining a normal microbial composition within the respiratory tract is essential for maintaining immunity. There is evidence that smoking cigarettes disrupts the microbial composition and increases the spread of pathogenic bacteria such as Streptococcus pneumoniae (Sp) which causes inflammation. By exposing 16HBE cells to Sp and cigarette smoke extract (CSE), this study investigated the effect of cigarette smoking on mitochondrial dysfunction in ACE in an in vitro model. Additionally, the study examined the direct and indirect pathways involved in cigarette smoking-induced mitochondrial dysfunction and altered innate immune response to Sp infection. CSE exposure decreases mitochondrial complex protein levels and mitochondrial membrane potential, which affects energy production. It also increases mitochondrial oxidative stress and mitochondrial degradation. All these factors lead to mitochondrial dysfunction in ACE. CSE exposure to ACE was associated with altered gene expression in the tight and adherence junctions that serve as a protective barrier against pathogens and pollutants and reduced type I interferon immune responses to Sp. Using the results of this study, healthcare professionals can gain a better understanding of the impact of cigarette smoking on mitochondrial dysfunction and how it increases susceptibility to Sp-related immune responses. It is necessary to conduct further studies to evaluate the effects of cigarette smoking on mitochondrial dysfunction, microbial composition disruption, and the interaction between AECs and elevated immune responses.
Abstract
Mitochondrial functionality is crucial for the execution of physiologic functions of metabolically active cells in the respiratory tract including airway epithelial cells (AECs). Cigarette smoke is known to impair mitochondrial function in AECs. However, the potential contribution of mitochondrial dysfunction in AECs to airway infection and airway epithelial barrier dysfunction is unknown. In this study, we used an in vitro model based on AECs exposed to cigarette smoke extract (CSE) followed by an infection with Streptococcus pneumoniae (Sp). The levels of oxidative stress as an indicator of mitochondrial stress were quantified upon CSE and Sp treatment. In addition, expression of proteins associated with mitophagy, mitochondrial content, and biogenesis as well as mitochondrial fission and fusion was quantified. Transcriptional AEC profiling was performed to identify the potential changes in innate immune pathways and correlate them with indices of mitochondrial function. We observed that CSE exposure substantially altered mitochondrial function in AECs by suppressing mitochondrial complex protein levels, reducing mitochondrial membrane potential and increasing mitochondrial stress and mitophagy. Moreover, CSE-induced mitochondrial dysfunction correlated with reduced enrichment of genes involved in apical junctions and innate immune responses to Sp, particularly type I interferon responses. Together, our results demonstrated that CSE-induced mitochondrial dysfunction may contribute to impaired innate immune responses to Sp.
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Effect of mitochondrial-targeted antioxidants on glycaemic control, cardiovascular health, and oxidative stress in humans: A systematic review and meta-analysis of randomized controlled trials.
Mason, SA, Wadley, GD, Keske, MA, Parker, L
Diabetes, obesity & metabolism. 2022;24(6):1047-1060
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Reactive oxygen species (ROS) are free radical oxygen molecules produced by mitochondria, which cause molecular damage known as oxidative stress. Chronic diseases such as diabetes, heart disease, cancer, and Parkinson's disease are more likely to develop when ROS levels are elevated. Mitochondrial‐targeted antioxidants (mitoAOX) may be effective in treating chronic diseases by targeting mitochondrial ROS. In this systematic review and meta-analysis, 19 randomised controlled trials were included to evaluate the effects of mitoAOXs on glycaemic control, cardiovascular health, and oxidative stress in humans. The evidence is limited, but there were improvements in endothelial function, blood pressure, oxidative stress, and functional capacity. The mitoAOX agents, dosage, and participant characteristics varied between the studies, making it difficult to draw conclusions. Due to the heterogeneity of studies included in this study, there is a need for larger, longer-term robust studies to investigate mitoAOXs' effects on mitochondrial ROS and markers of oxidative stress in different clinical populations. As a result of this study, healthcare professionals can gain a better understanding of mitoAOX's potential in tackling oxidative stress. However, caution must be exercised before implementing it as a therapeutic strategy due to concerns over possible adverse effects and a low evidence certainty.
Expert Review
Conflicts of interest:
None
Take Home Message:
- Mitochondria are a major producer of reactive oxygen species (ROS) in cells. Excess mitochondrial ROS has been implicated in the pathophysiology of various chronic diseases including Parkinson’s disease, cardiovascular disease (CVD), Type 2 diabetes and cancer.
- This review reported that there is limited evidence to support the use of mitoAOXs in the management of glycaemic control and cardiovascular health. However, there are promising findings on the effect of mitoAOXs on endothelial function that warrant consideration and further investigation in target clinical population groups.
Evidence Category:
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A: Meta-analyses, position-stands, randomized-controlled trials (RCTs)
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X
B: Systematic reviews including RCTs of limited number
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C: Non-randomized trials, observational studies, narrative reviews
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D: Case-reports, evidence-based clinical findings
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E: Opinion piece, other
Summary Review:
Background
A systematic review and meta-analysis was conducted to evaluate the current evidence from randomised control trials (RCTs) in humans on the effects of mitochondrial-targeted antioxidant (mitoAOXs) on glycaemic control, cardiovascular health, and oxidative stress.
Methodology
19 Randomised control trials (n= 884 participants) using mitoAOXs (including Elamipretide, MitoQ and MitoTEMPO) were included from MEDLINE-PubMed, Scopus, EMBASE and Cochrane Library databases. A Cochrane Collaboration’s tool was used to assess risk bias and to grade the quality of the trials and their certainty of the evidence.
Results
Primary clinical outcomes were:
- A quantitative analysis on glycaemic control found no significant effect for fasting glucose in response to MitoQ supplementation.
- A quantitative analysis on cardiovascular health related outcomes found a significant lowering effect of mitoAOXs brachial flow-mediated dilation (FMD) (standardized mean difference: 1.19, 95% CI: 0.28, 2.16; I2: 67%) and an improved blood pressure (standardized mean difference: -0.32, 95% CI:-0.95, 0.30; I2: 0%) in patients with atherosclerosis-related impairment of renal blood flow.
- A quantitative analysis on oxidative stress-related outcomes found no significant effect of mitoAOX on malondialdehyde or F2-Isoprostanes.
Clinical practice applications:
- The findings from this review suggest limited evidence to support the use of mitoAOX in the management of glycaemic control or cardiovascular health.
- However, there are some potential promising findings which included improved endothelial function (particularly brachial FMD) and improved blood pressure in patients with atherosclerosis-related impairment of renal blood flow.
- Based on this review, practitioners may consider recommending the use of mitoAOXs only in quite specific circumstances, namely to improve endothelial function in patients with a risk of brachial FMD or high blood pressure associated with atherosclerosis-related impairment of renal blood flow.
Considerations for future research:
- The studies included in this review were mostly one to three months in duration therefore, there is a need for long-term, follow-up studies to be conducted to better investigate these outcomes.
- Given the pathogenic factors of elevated mitochondrial ROS and oxidative stress in chronic diseases such as CVD and Type2 diabetes, further investigation is needed into the effects of mitoAOXs on mitochondrial ROS and oxidative stress markers in target clinical population groups.
- It appears that mitoAOXs may improve endothelial function, therefore further research is needed to focus on the effect of mitoAOXs on endothelial function in target clinical populations.
- Additionally, further reviews are required to provide a more comprehensive review of the safety and adverse effects of mitoAOXs.
- Furthermore, only antioxidants specific to microconidia were included in this review. It is possible that other more general acting antioxidants may have redox-related effects in mitochondria. Therefore, a more comprehensive review is needed to include all possible antioxidant compounds that have mitochondrial effect.
Abstract
AIM: To investigate the effects of mitochondrial-targeted antioxidants (mitoAOXs) on glycaemic control, cardiovascular health, and oxidative stress outcomes in humans. MATERIALS AND METHODS Randomized controlled trials investigating mitoAOX interventions in humans were searched for in databases (MEDLINE-PubMed, Scopus, EMBASE and Cochrane Library) and clinical trial registries up to 10 June 2021. The Cochrane Collaboration's tool for assessing risk of bias and Grading of Recommendations, Assessment, Development and Evaluations were used to assess trial quality and evidence certainty, respectively. RESULTS Nineteen studies (n = 884 participants) using mitoAOXs (including Elamipretide, MitoQ and MitoTEMPO) were included in the systematic review. There were limited studies investigating the effects of mitoAOXs on glycaemic control; and outcomes and population groups in studies focusing on cardiovascular health were diverse. MitoAOXs significantly improved brachial flow-mediated dilation (n = 3 trials; standardized mean difference: 1.19, 95% CI: 0.28, 2.16; I2 : 67%) with very low evidence certainty. No significant effects were found for any other glycaemic, cardiovascular or oxidative stress-related outcomes with mitoAOXs in quantitative analyses, with evidence certainty rated mostly as low. There was a lack of serious treatment-emergent adverse events with mitoAOXs, although subcutaneous injection of Elamipretide increased mild-moderate injection site-related events. CONCLUSION While short-term studies indicate that mitoAOXs are generally well tolerated, there is currently limited evidence to support the use of mitoAOXs in the management of glycaemic control and cardiovascular health. Review findings suggest that future research should focus on the effects of mitoAOXs on glycaemic control and endothelial function in target clinical population groups.
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Metabolic stress-dependent regulation of the mitochondrial biogenic molecular response to high-intensity exercise in human skeletal muscle.
Fiorenza, M, Gunnarsson, TP, Hostrup, M, Iaia, FM, Schena, F, Pilegaard, H, Bangsbo, J
The Journal of physiology. 2018;596(14):2823-2840
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Endurance exercise stimulates mitochondrial biogenesis in skeletal muscles, a crucial adaptive protective mechanism against various metabolic disorders. Mitochondrial biogenesis is a process that involves the expansion of mitochondrial volume and changes in mitochondrial composition. Continuous moderate‐intensity exercise (CM) may lead to mild but prolonged metabolic disturbances, and low‐volume intense intermittent exercise regimes such as repeated‐sprint (RE) and speed endurance (SE) exercises may lead to a distinct degree of metabolic stress. This randomised counter-balanced crossover trial included 12 healthy trained men to investigate the effect of RE and SE exercise and high‐volume CM on metabolic perturbations and its impact on the regulation of molecular response stimulating mitochondrial biogenesis in human skeletal muscle. Compared to CM, PGC‐1α mRNA (Peroxisome proliferator‐activated receptor gamma coactivator 1‐alpha (PGC‐1α) mRNA) showed elevation in response to RS and SE exercises in well-trained subjects, and this was associated with high accumulation of muscle lactate, greater decline in muscle pH and elevated plasma adrenaline levels. Elevated metabolic perturbations lead to enhanced mitochondrial biogenesis-related mRNA responses. SE was associated with a greater increase in the PGC‐1α mRNA and severe metabolic stress. SE and CM elevated exercise-induced signalling and mRNA content of genes controlling mtDNA. Further robust research is required to elucidate the role of metabolic stress in initiating mitochondrial biogenesis in skeletal muscles in response to acute exercise, regulating genes modulating mtDNA transcription and mitochondrial remodelling dynamics. However, healthcare professionals can use the results of this study to understand that low-volume high-intensity exercise programmes can promote mitochondrial biogenesis in skeletal muscles in healthy trained men and have a similar effect to that of high-volume moderate-intensity exercise programmes.
Abstract
KEY POINTS Low-volume high-intensity exercise training promotes muscle mitochondrial adaptations that resemble those associated with high-volume moderate-intensity exercise training. These training-induced mitochondrial adaptations stem from the cumulative effects of transient transcriptional responses to each acute exercise bout. However, whether metabolic stress is a key mediator of the acute molecular responses to high-intensity exercise is still incompletely understood. Here we show that, by comparing different work-matched low-volume high-intensity exercise protocols, more marked metabolic perturbations were associated with enhanced mitochondrial biogenesis-related muscle mRNA responses. Furthermore, when compared with high-volume moderate-intensity exercise, only the low-volume high-intensity exercise eliciting severe metabolic stress compensated for reduced exercise volume in the induction of mitochondrial biogenic mRNA responses. The present results, besides improving our understanding of the mechanisms mediating exercise-induced mitochondrial biogenesis, may have implications for applied and clinical research that adopts exercise as a means to increase muscle mitochondrial content and function in healthy or diseased individuals. ABSTRACT The aim of the present study was to examine the impact of exercise-induced metabolic stress on regulation of the molecular responses promoting skeletal muscle mitochondrial biogenesis. Twelve endurance-trained men performed three cycling exercise protocols characterized by different metabolic profiles in a randomized, counter-balanced order. Specifically, two work-matched low-volume supramaximal-intensity intermittent regimes, consisting of repeated-sprint (RS) and speed endurance (SE) exercise, were employed and compared with a high-volume continuous moderate-intensity exercise (CM) protocol. Vastus lateralis muscle samples were obtained before, immediately after, and 3 h after exercise. SE produced the most marked metabolic perturbations as evidenced by the greatest changes in muscle lactate and pH, concomitantly with higher post-exercise plasma adrenaline levels in comparison with RS and CM. Exercise-induced phosphorylation of CaMKII and p38 MAPK was greater in SE than in RS and CM. The exercise-induced PGC-1α mRNA response was higher in SE and CM than in RS, with no difference between SE and CM. Muscle NRF-2, TFAM, MFN2, DRP1 and SOD2 mRNA content was elevated to the same extent by SE and CM, while RS had no effect on these mRNAs. The exercise-induced HSP72 mRNA response was larger in SE than in RS and CM. Thus, the present results suggest that, for a given exercise volume, the initial events associated with mitochondrial biogenesis are modulated by metabolic stress. In addition, high-intensity exercise seems to compensate for reduced exercise volume in the induction of mitochondrial biogenic molecular responses only when the intense exercise elicits marked metabolic perturbations.
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Effect of ubiquinol supplementation on biochemical and oxidative stress indexes after intense exercise in young athletes.
Orlando, P, Silvestri, S, Galeazzi, R, Antonicelli, R, Marcheggiani, F, Cirilli, I, Bacchetti, T, Tiano, L
Redox report : communications in free radical research. 2018;23(1):136-145
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Strenuous exercise or overtraining increases the production of reactive oxygen species (ROS), especially in mitochondria. ROS production in excess leads to oxidative stress, cellular dysfunction, and oxidation of molecules such as DNA, polyunsaturated fatty acids, amino acids, and proteins. Previous research has shown that antioxidant supplementation might lead to the downregulation of ROS production. Coenzyme Q10 is an antioxidant believed to be effective in downregulating the effects of oxidative stress and preventing cellular damage. However, most previous studies have used ubiquinone, an oxidised form of Coenzyme Q10. Ubiquinol, a reduced form of Coenzyme Q10, is highly bioavailable, stable and in a form that the body can readily use. This randomised, double-blinded, crossover-controlled trial investigated ubiquinol's antioxidant and anti-inflammatory effects on biochemical and oxidative stress indexes after an intense bout of exercise in trained athletes. Twenty-one male athletes in constant training were randomly taking 200 mg/day of ubiquinol for a month. After a single bout of intense aerobic and endurance exercise, the participants showed a rapid and significant reduction in ubiquinol levels, especially lipoprotein CoQ10 and increased muscle damage markers such as Creatine kinase (CK) and Myoglobin (Mb). Ubiquinol supplementation prevented exercise-induced CoQ10 scarcity and reduced the activity of paraoxonase, an anti-inflammatory and antioxidant enzyme protective against oxidative stress in lipoprotein and circulating cells. Ubiquinol supplementation was associated with a significant decrease in cytosolic ROS in peripheral blood mononuclear cells. Ubiquinol supplementation enhanced plasma and cellular antioxidant levels. Healthcare professionals can use the results of this study to understand the antioxidant effects of ubiquinol supplementation and its buffering effect on plasma CoQ10 balances and exercise-induced CoQ10 depletion. However, further robust studies are required to evaluate the therapeutic potential of ubiquinol supplementation in sports nutrition.
Abstract
OBJECTIVES Physical exercise significantly impacts the biochemistry of the organism. Ubiquinone is a key component of the mitochondrial respiratory chain and ubiquinol, its reduced and active form, is an emerging molecule in sport nutrition. The aim of this study was to evaluate the effect of ubiquinol supplementation on biochemical and oxidative stress indexes after an intense bout of exercise. METHODS 21 male young athletes (26 + 5 years of age) were randomized in two groups according to a double blind cross-over study, either supplemented with ubiquinol (200 mg/day) or placebo for 1 month. Blood was withdrawn before and after a single bout of intense exercise (40 min run at 85% maxHR). Physical performance, hematochemical parameters, ubiquinone/ubiquinol plasma content, intracellular reactive oxygen species (ROS) level, mitochondrial membrane depolarization, paraoxonase activity and oxidative DNA damage were analyzed. RESULTS A single bout of intense exercise produced a significant increase in most hematochemical indexes, in particular CK and Mb while, on the contrary, normalized coenzyme Q10 plasma content decreased significantly in all subjects. Ubiquinol supplementation prevented exercise-induced CoQ deprivation and decrease in paraoxonase activity. Moreover at a cellular level, in peripheral blood mononuclear cells, ubiquinol supplementation was associated with a significant decrease in cytosolic ROS while mitochondrial membrane potential and oxidative DNA damage remained unchanged. DISCUSSION Data highlights a very rapid dynamic of CoQ depletion following intense exercise underlying an increased demand by the organism. Ubiquinol supplementation minimized exercise-induced depletion and enhanced plasma and cellular antioxidant levels but it was not able to improve physical performance indexes or markers of muscular damage.