Susanne Rohrbach

Mitochondrial connexin 43 impacts on respiratory complex I activity and mitochondrial oxygen consumption

Connexin 43 (Cx43) is present at the sarcolemma and the inner membrane of cardiomyocyte subsarcolemmal mitochondria (SSM). Lack or inhibition of mitochondrial Cx43 is associated with reduced mitochondrial potassium influx, which might affect mitochondrial respiration. Therefore, we analysed the importance of mitochondrial Cx43 for oxygen consumption. Acute inhibition of Cx43 in rat left ventricular (LV) SSM by 18α glycyrrhetinic acid (GA) or Cx43 mimetic peptides (Cx43‐MP) reduced ADP‐stimulated complex I respiration and ATP generation. Chronic reduction of Cx43 in conditional knockout mice (Cx43Cre‐ER(T)/fl + 4‐OHT, 5–10% of Cx43 protein compared with control Cx43fl/fl mitochondria) reduced ADP‐stimulated complex I respiration of LV SSM to 47.8 ± 2.4 nmol O2/min.*mg protein (n = 8) from 61.9 ± 7.4 nmol O2/min.*mg protein in Cx43fl/fl mitochondria (n = 10, P < 0.05), while complex II respiration remained unchanged. The LV complex I activities (% of citrate synthase activity) of Cx43Cre‐ER(T)/fl+4‐OHT mice (16.1 ± 0.9%, n = 9) were lower than in Cx43fl/fl mice (19.8 ± 1.3%, n = 8, P < 0.05); complex II activities were similar between genotypes. Supporting the importance of Cx43 for respiration, in Cx43‐overexpressing HL‐1 cardiomyocytes complex I respiration was increased, whereas complex II respiration remained unaffected. Taken together, mitochondrial Cx43 is required for optimal complex I activity and respiration and thus mitochondrial ATP‐production.

Caloric restriction delays cardiac ageing in rats: role of mitochondria

AIMS We tested whether long-term caloric restriction (CR) corrects pre-existing manifestations of cardiac ageing in rats. METHODS AND RESULTS The age-specific effects of CR (-40%, 6 months) on mortality, left ventricular (LV) function, mitochondrial function, oxidative damage, and apoptosis were analysed in young (6 + 6 months) and senescent rats (24 + 6 months). CR in senescent rats significantly reduced mortality. LV and cardiomyocyte hypertrophy were reduced together with the mRNA expression and plasma concentrations of overload indicators BNP/ANP. Mitochondrial function was improved, resulting in lower oxidative damage and apoptotic activation. In particular, the pro-apoptotic Bcl-xS/Bcl-xL isoform pattern, mitochondrial translocation of Bax, release of cytochrome C into cytosol, and caspase-9 activation were reduced in comparison to age-matched rats on the control diet. However, CR resulted only in minor changes in young rats. Serum obtained from old control or CR rats was used for in vitro experiments. H9C2 cardiomyoblasts and adult rat ventricular cardiomyocytes preconditioned with CR serum demonstrated a low Bcl-xS/Bcl-xL ratio. H9C2 cells were resistant against H(2)O(2)-mediated loss of mitochondrial membrane potential, apoptosis activation, and reduced cell viability. Thus, beneficial effects of CR are mediated through circulating factors and can be mimicked with CR serum. However, this protection critically depended on a high Bcl-xL protein expression as seen after siRNA-mediated Bcl-xL knockdown. CONCLUSION CR is cardioprotective in senescent myocardium by correcting pre-existing mitochondrial dysfunction and apoptotic activation and by preventing deterioration in LV function. Therefore, interventions that mimic these effects of CR may represent an additional therapeutic option for the aged or failing heart.

Hypoxia–reoxygenation‐induced endothelial barrier failure: role of RhoA, Rac1 and myosin light chain kinase

•  Hypoxia–reoxygenation induces loss of endothelial barrier function and oedema formation accompanied by a rise in intracellular Ca2+, an increase in myosin light chain (MLC) phosphorylation, and RhoA/Rho kinase (Rock) signalling and an inactivation of Rac1. •  Neither inhibition of RhoA/Rock signalling nor antagonising Ca2+ increase could protect against this hypoxia–reoxygenation‐induced loss of barrier function. •  Inhibition of MLC kinase (MLCK) abrogates hypoxia–reoxygenation‐induced MLC phosphorylation and partially protects against hypoxia–reoxygenation‐induced endothelial hyperpermeability. •  Activation of Rac1 using a cAMP analogue, 8‐CPT‐O′‐Me‐cAMP, which specifically activates Epac/Rap1 signalling abrogated reoxygenation‐induced hyperpermeability. The data help us to better understand the role of Rho GTPases and contractile machinery in the regulation of endothelial barrier function during hypoxia–reoxygenation.

Oxidative Stress and Cardiovascular Risk: Obesity, Diabetes, Smoking, and Pollution: Part 3 of a 3-Part Series

Oxidative stress occurs whenever the release of reactive oxygen species (ROS) exceeds endogenous antioxidant capacity. In this paper, we review the specific role of several cardiovascular risk factors in promoting oxidative stress: diabetes, obesity, smoking, and excessive pollution. Specifically, the risk of developing heart failure is higher in patients with diabetes or obesity, even with optimal medical treatment, and the increased release of ROS from cardiac mitochondria and other sources likely contributes to the development of cardiac dysfunction in this setting. Here, we explore the role of different ROS sources arising in obesity and diabetes, and the effect of excessive ROS production on the development of cardiac lipotoxicity. In parallel, contaminants in the air that we breathe pose a significant threat to human health. This paper provides an overview of cigarette smoke and urban air pollution, considering how their composition and biological effects have detrimental effects on cardiovascular health.

Mitochondria and ageing: role in heart, skeletal muscle and adipose tissue

Age is the most important risk factor for most diseases. Mitochondria play a central role in bioenergetics and metabolism. In addition, several lines of evidence indicate the impact of mitochondria in lifespan determination and ageing. The best‐known hypothesis to explain ageing is the free radical theory, which proposes that cells, organs, and organisms age because they accumulate reactive oxygen species (ROS) damage over time. Mitochondria play a central role as the principle source of intracellular ROS, which are mainly formed at the level of complex I and III of the respiratory chain. Dysfunctional mitochondria generating less ATP have been observed in various aged organs. Mitochondrial dysfunction comprises different features including reduced mitochondrial content, altered mitochondrial morphology, reduced activity of the complexes of the electron transport chain, opening of the mitochondrial permeability transition pore, and increased ROS formation. Furthermore, abnormalities in mitochondrial quality control or defects in mitochondrial dynamics have also been linked to senescence. Among the tissues affected by mitochondrial dysfunction are those with a high‐energy demand and thus high mitochondrial content. Therefore, the present review focuses on the impact of mitochondria in the ageing process of heart and skeletal muscle. In this article, we review different aspects of mitochondrial dysfunction and discuss potential therapeutic strategies to improve mitochondrial function. Finally, novel aspects of adipose tissue biology and their involvement in the ageing process are discussed.

Age and obesity-associated changes in the expression and activation of components of the AMPK signaling pathway in human right atrial tissue

BACKGROUND Obesity is associated with an increased incidence of left ventricular hypertrophy, diastolic dysfunction, heart failure, and premature cardiac aging. In the heart, intrinsic activation of the AMP-dependent protein kinase (AMPK) plays a pivotal role in the stress response to ischemia and hypertrophy. Furthermore, AMPK is an important regulator of cardiac mitochondrial biogenesis. The purpose of the present study was to investigate the influence of obesity and aging on the AMPK signaling pathway in human cardiac tissue. METHODS 60 male cardiac surgery patients were included in the study and divided into 4 groups (old normal weight: ON; old obese: OO; young normal weight: YN, young obese: YO) according to their body mass index (18.5-25: normal weight or 30-35: obese) and age (<55 years: young or >70: old) with 15 patients each. Right atrial tissue (RA) was analyzed for the expression of the AMPK upstream kinases CAMKK and LKB1, activation of AMPK as well as phosphorylation of the AMPK downstream targets ACC, eEF2, mTOR and eNOS. Epicardial adipose tissue was analyzed for the expression of the endogenous AMPK activator adiponectin. The metabolic state of all patients was further characterized in fasting blood samples. RESULTS Old patients (ON, OO) and young obese (YO) subjects displayed higher fasting glucose, insulin and leptin serum levels compared to the young, normal weight group, although HbA1c was below the threshold required for the diagnosis of type 2 diabetes. Serum adiponectin as well as total adiponectin protein expression in epicardial adipose tissue was decreased in these three groups. Analyses of adiponectin isoforms by native gel electrophoresis revealed significant differences in the high molecular weight (HMW) isoforms between the groups. Despite the low total serum adiponectin and HMW adiponectin, AMPK activation was high in the RA of obese patients (YO, OO). Among the AMPK upstream kinases, LKB1 expression showed a strong positive correlation with AMPK activation. While the phosphorylation of the AMPK downstream targets mTOR, eEF-2 and ACC was not altered, phospho-eNOS was significantly lower in old patients (ON, OO). Despite strong AMPK activation, mitochondrial biogenesis and respiration were impaired in old (ON, OO) and young obese (YO) subjects. CONCLUSION These data indicate that obesity and aging result in significant changes although many direct parameters in the AMPK signaling pathway are not changed in the same direction. LKB1 may represent a stronger activator of the AMPK pathway than adiponectin or the CAMKKs in human right atrial tissue.

Diastolic dysfunction in prediabetic male rats: Role of mitochondrial oxidative stress

Although incidence and prevalence of prediabetes are increasing, little is known about its cardiac effects. Therefore, our aim was to investigate the effect of prediabetes on cardiac function and to characterize parameters and pathways associated with deteriorated cardiac performance. Long-Evans rats were fed with either control or high-fat chow for 21 wk and treated with a single low dose (20 mg/kg) of streptozotocin at week 4 High-fat and streptozotocin treatment induced prediabetes as characterized by slightly elevated fasting blood glucose, impaired glucose and insulin tolerance, increased visceral adipose tissue and plasma leptin levels, as well as sensory neuropathy. In prediabetic animals, a mild diastolic dysfunction was observed, the number of myocardial lipid droplets increased, and left ventricular mass and wall thickness were elevated; however, no molecular sign of fibrosis or cardiac hypertrophy was shown. In prediabetes, production of reactive oxygen species was elevated in subsarcolemmal mitochondria. Expression of mitofusin-2 was increased, while the phosphorylation of phospholamban and expression of Bcl-2/adenovirus E1B 19-kDa protein-interacting protein 3 (BNIP3, a marker of mitophagy) decreased. However, expression of other markers of cardiac auto- and mitophagy, mitochondrial dynamics, inflammation, heat shock proteins, Ca2+/calmodulin-dependent protein kinase II, mammalian target of rapamycin, or apoptotic pathways were unchanged in prediabetes. This is the first comprehensive analysis of cardiac effects of prediabetes indicating that mild diastolic dysfunction and cardiac hypertrophy are multifactorial phenomena that are associated with early changes in mitophagy, cardiac lipid accumulation, and elevated oxidative stress and that prediabetes-induced oxidative stress originates from the subsarcolemmal mitochondria.

Specific Mechanisms Underlying Right Heart Failure: The Missing Upregulation of Superoxide Dismutase-2 and Its Decisive Role in Antioxidative Defense.

AIMS Research into right ventricular (RV) physiology and identification of pathomechanisms underlying RV failure have been neglected for many years, because function of the RV is often considered less important for overall hemodynamics and maintenance of blood circulation. In view of this, this study focuses on identifying specific adaptive mechanisms of the RV and left ventricle (LV) during a state of chronic nitric oxide (NO) deficiency, one of the main causes of cardiac failure. NO deficiency was induced in rats by L-NAME feeding over a 4 week period. The cardiac remodeling was then characterized separately for the RV/LV using quantitative real-time polymerase chain reaction, histology, and functional measurements. RESULTS Only the RV underwent remodeling that corresponded morphologically and functionally with the pattern of dilated cardiomyopathy. Symptoms in the LV were subtle and consisted primarily of moderate hypertrophy. A massive increase in reactive oxygen species (ROS) (+4.5±0.8-fold, vs. control) and a higher degree of oxidized tropomyosin (+46%±4% vs. control) and peroxynitrite (+32%±2% vs. control) could be identified as the cause of both RV fibrosis and contractile dysfunction. The expression of superoxide dismutase-2 was specifically increased in the LV by 51%±3% and prevented the ROS increase and the corresponding structural and functional remodeling. INNOVATION This study identified the inability of the RV to increase its antioxidant capacity as an important risk factor for developing RV failure. CONCLUSION Unlike the LV, the RV did not display the necessary adaptive mechanisms to cope with increased oxidative stress during a state of chronic NO deficiency.

Impact of caloric restriction on myocardial ischaemia/reperfusion injury and new therapeutic options to mimic its effects.

Caloric restriction (CR) is the most reliable intervention to extend lifespan and prevent age‐related disorders in various species from yeast to rodents. Short‐ and long‐term CR confers cardio protection against ischaemia/reperfusion injury in young and even in aged rodents. A few human trials suggest that CR has the potential to mediate improvement of cardiac or vascular function and induce retardation of cardiac senescence also in humans. The underlying mechanisms are diverse and have not yet been clearly defined. Among the known mediators for the benefits of CR are NO, the AMP‐activated PK, sirtuins and adiponectin. Mitochondria, which play a central role in such complex processes within the cell as apoptosis, ATP‐production or oxidative stress, are centrally involved in many aspects of CR‐induced protection against ischaemic injury. Here, we discuss the relevant literature regarding the protection against myocardial ischaemia/reperfusion injury conferred by CR. Furthermore, we will discuss drug targets to mimic CR and the possible role of calorie restriction in preserving cardiovascular function in humans.

Mitochondria and ageing

Age is the most important risk factor for most diseases. Mitochondria play a central role in bioenergetics and metabolism. In addition, several lines of evidence indicate the impact of mitochondria in lifespan determination and ageing. The best‐known hypothesis to explain ageing is the free radical theory, which proposes that cells, organs, and organisms age because they accumulate reactive oxygen species (ROS) damage over time. Mitochondria play a central role as the principle source of intracellular ROS, which are mainly formed at the level of complex I and III of the respiratory chain. Dysfunctional mitochondria generating less ATP have been observed in various aged organs. Mitochondrial dysfunction comprises different features including reduced mitochondrial content, altered mitochondrial morphology, reduced activity of the complexes of the electron transport chain, opening of the mitochondrial permeability transition pore, and increased ROS formation. Furthermore, abnormalities in mitochondrial quality control or defects in mitochondrial dynamics have also been linked to senescence. Among the tissues affected by mitochondrial dysfunction are those with a high‐energy demand and thus high mitochondrial content. Therefore, the present review focuses on the impact of mitochondria in the ageing process of heart and skeletal muscle. In this article, we review different aspects of mitochondrial dysfunction and discuss potential therapeutic strategies to improve mitochondrial function. Finally, novel aspects of adipose tissue biology and their involvement in the ageing process are discussed.