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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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Plain language summary
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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Effects of the Peroxisome Proliferator-Activated Receptor-γ Agonist Pioglitazone on Peripheral Vessel Function and Clinical Parameters in Nondiabetic Patients: A Double-Center, Randomized Controlled Pilot Trial.
Christoph, M, Herold, J, Berg-Holldack, A, Rauwolf, T, Ziemssen, T, Schmeisser, A, Weinert, S, Ebner, B, Ibrahim, K, Strasser, RH, et al
Cardiology. 2015;(3):165-71
Abstract
OBJECTIVE Despite the advanced therapy with statins, antithrombotics, and antihypertensive agents, the medical treatment of atherosclerotic disease is less than optimal. Therefore, additional therapeutic antiatherosclerotic options are desirable. This pilot study was performed to assess the potential antiatherogenic effect of the peroxisome proliferator-activated receptor-γ agonist pioglitazone in nondiabetic patients. METHODS A total of 54 nondiabetic patients were observed in a prospective, double-blind, placebo-controlled study. Patients were randomized to pioglitazone or placebo. The following efficacy parameters were determined by serial analyses: artery pulse wave analysis and carotid-femoral pulse wave velocity (PWV), static and dynamic retinal vessel function, and the common carotid intima-media thickness (IMT). The main secondary endpoint was the change in different biochemical markers. RESULTS After 9 months, no relevant differences could be determined in the two treatment groups in PWV (pioglitazone 14.3 ± 4.4 m/s vs. placebo 14.2 ± 4.2 m/s), retinal arterial diameter (pioglitazone 112.1 ± 23.3 µm vs. placebo 117.9 ± 21.5 µm) or IMT (pioglitazone 0.85 ± 0.30 mm vs. placebo 0.79 ± 0.15 mm). Additionally, there were no differences in the change in biochemical markers like cholesteryl ester transfer protein, low-density lipoprotein cholesterol, high-sensitivity C-reactive protein or white blood cell count. CONCLUSIONS Treatment with a peroxisome proliferator-activated receptor-γ agonist in nondiabetic patients did not improve the function of large and small peripheral vessels (PPP Trial, clinicaltrialsregister.eu: 2006-000186-11).
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Feasibility of overnight closed-loop control based on hourly blood glucose measurements.
Patte, C, Pleus, S, Galley, P, Weinert, S, Haug, C, Freckmann, G
Journal of diabetes science and technology. 2012;(4):902-9
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Abstract
INTRODUCTION Safe and effective closed-loop control (artificial pancreas) is the ultimate goal of insulin delivery. In this study, we examined the performance of a closed-loop control algorithm used for the overnight time period to safely achieve a narrow target range of blood glucose (BG) concentrations prior to breakfast. The primary goal was to compare the quality of algorithm control during repeated overnight experiments. MATERIALS AND METHODS Twenty-three subjects with type 1 diabetes performed 2 overnight experiments on each of three visits at the study site, resulting in 138 overnight experiments. On the first evening, the subject's insulin therapy was applied; on the second, the insulin was delivered by an algorithm based on subcutaneous continuous glucose measurements (including meal control) until midnight. Overnight closed-loop control was applied between midnight and 6 a.m. based on hourly venous BG measurements during the first and second nights. RESULTS The number of BG values within the target range (90-150 mg/dl) increased from 52.9% (219 out of 414 measurements) during the first nights to 72.2% (299 out of 414 measurements) during the second nights (p < .001, χ²-test). The occurrence of hypoglycemia interventions was reduced from 14 oral glucose interventions, the latest occurring at 2:36 a.m. during the first nights, to 1 intervention occurring at 1:02 a.m. during the second nights (p < .001, χ²-test). CONCLUSIONS Overnight controller performance improved when optimized initial control was given; this was suggested by the better metabolic control during the second night. Adequate controller run-in time seems to be important for achieving good overnight control. In addition, the findings demonstrate that hourly BG data are sufficient for the closed-loop control algorithm tested to achieve appropriate glycemic control.