Refine
Has Fulltext
- yes (11)
Is part of the Bibliography
- yes (11) (remove)
Document Type
- Journal article (8)
- Doctoral Thesis (3)
Keywords
- reactive oxygen species (11) (remove)
Institute
- Deutsches Zentrum für Herzinsuffizienz (DZHI) (3)
- Theodor-Boveri-Institut für Biowissenschaften (3)
- Frauenklinik und Poliklinik (1)
- Graduate School of Life Sciences (1)
- Institut für Anatomie und Zellbiologie (1)
- Klinik und Poliklinik für Allgemein-, Viszeral-, Gefäß- und Kinderchirurgie (Chirurgische Klinik I) (1)
- Klinik und Poliklinik für Anästhesiologie (ab 2004) (1)
- Klinik und Poliklinik für Haut- und Geschlechtskrankheiten (bis 2003) (1)
- Lehrstuhl für Tissue Engineering und Regenerative Medizin (1)
- Medizinische Fakultät (1)
Purpose of Review
We review therapeutic approaches aimed at restoring function of the failing heart by targeting mitochondrial reactive oxygen species (ROS), ion handling, and substrate utilization for adenosine triphosphate (ATP) production.
Recent Findings
Mitochondria-targeted therapies have been tested in animal models of and humans with heart failure (HF). Cardiac benefits of sodium/glucose cotransporter 2 inhibitors might be partly explained by their effects on ion handling and metabolism of cardiac myocytes.
Summary
The large energy requirements of the heart are met by oxidative phosphorylation in mitochondria, which is tightly regulated by the turnover of ATP that fuels cardiac contraction and relaxation. In heart failure (HF), this mechano-energetic coupling is disrupted, leading to bioenergetic mismatch and production of ROS that drive the progression of cardiac dysfunction. Furthermore, HF is accompanied by changes in substrate uptake and oxidation that are considered detrimental for mitochondrial oxidative metabolism and negatively affect cardiac efficiency. Mitochondria lie at the crossroads of metabolic and energetic dysfunction in HF and represent ideal therapeutic targets.
Oxidative stress and inflammation play a pivotal role in the development of cardiovascular diseases, an ever-growing worldwide problem. As a non-pharmacological approach, diet, especially a flavonoid-rich diet, showed promising results in the reduction of cardiovascular diseases and alleviation of their symptoms. In this study, in vitro systems based on human microvascular endothelial cells (hmvEC) and human umbilical cord endothelial cells (HUVEC) were established to determine the effect of Healthberry 865\(^®\) (HB) and ten of its relating single anthocyanins on oxidative stress. Furthermore, five metabolites were used in order to examine the effect of anthocyanin's most common breakdown molecules. The results showed an effect of HB in both models after 24 h, as well as most of its single anthocyanins. Cyanidin-rutinoside, peonidin-galactoside, and petunidin-glucoside had a model-specific effect. For the metabolites, phloroglucinaldeyhde (PGA) showed an effect in both models, while vanillic acid (VA) only had an effect in HUVEC. When combined, a combination of several anthocyanins did not have a cumulative effect, except for combining glucosides in hmvEC. The combination of PGA and VA even revealed an inhibitive behavior. Overall, the study demonstrates the antioxidative effect of HB and several of its single anthocyanins and metabolites, which are partially model specific, and coincides with animal studies.
Energy-demanding organs like the heart are strongly dependent on oxidative phosphorylation in mitochondria. Oxidative phosphorylation is governed by the respiratory chain located in the inner mitochondrial membrane. The inner mitochondrial membrane is the only cellular membrane with significant amounts of the phospholipid cardiolipin, and cardiolipin was found to directly interact with a number of essential protein complexes, including respiratory chain complexes I to V. An inherited defect in the biogenesis of cardiolipin causes Barth syndrome, which is associated with cardiomyopathy, skeletal myopathy, neutropenia and growth retardation. Energy conversion is dependent on reducing equivalents, which are replenished by oxidative metabolism in the Krebs cycle. Cardiolipin deficiency in Barth syndrome also affects Krebs cycle activity, metabolite transport and mitochondrial morphology. During excitation-contraction coupling, calcium (Ca\(^{2+}\)) released from the sarcoplasmic reticulum drives sarcomeric contraction. At the same time, Ca\(^{2+}\) influx into mitochondria drives the activation of Krebs cycle dehydrogenases and the regeneration of reducing equivalents. Reducing equivalents are essential not only for energy conversion, but also for maintaining a redox buffer, which is required to detoxify reactive oxygen species (ROS). Defects in CL may also affect Ca\(^{2+}\) uptake into mitochondria and thereby hamper energy supply and demand matching, but also detoxification of ROS. Here, we review the impact of cardiolipin deficiency on mitochondrial function in Barth syndrome and discuss potential therapeutic strategies.
In heart failure, a functional block of complex I of the respiratory chain provokes superoxide generation, which is transformed to H\(_2\)O\(_2\) by dismutation. The Krebs cycle produces NADH, which delivers electrons to complex I, and NADPH for H\(_2\)O\(_2\) elimination via isocitrate dehydrogenase and nicotinamide nucleotide transhydrogenase (NNT). At high NADH levels, α-ketoglutarate dehydrogenase (α-KGDH) is a major source of superoxide in skeletal muscle mitochondria with low NNT activity. Here, we analyzed how α-KGDH and NNT control H\(_2\)O\(_2\) emission in cardiac mitochondria. In cardiac mitochondria from NNT-competent BL/6N mice, H\(_2\)O\(_2\) emission is equally low with pyruvate/malate (P/M) or α-ketoglutarate (α-KG) as substrates. Complex I inhibition with rotenone increases H2O2 emission from P/M, but not α-KG respiring mitochondria, which is potentiated by depleting H\(_2\)O\(_2\)-eliminating capacity. Conversely, in NNT-deficient BL/6J mitochondria, H2O2 emission is higher with α-KG than with P/M as substrate, and further potentiated by complex I blockade. Prior depletion of H\(_2\)O\(_2\)-eliminating capacity increases H\(_2\)O\(_2\) emission from P/M, but not α-KG respiring mitochondria. In cardiac myocytes, downregulation of α-KGDH activity impaired dynamic mitochondrial redox adaptation during workload transitions, without increasing H\(_2\)O\(_2\) emission. In conclusion, NADH from α-KGDH selectively shuttles to NNT for NADPH formation rather than to complex I of the respiratory chain for ATP production. Therefore, α-KGDH plays a key role for H\(_2\)O\(_2\) elimination, but is not a relevant source of superoxide in heart. In heart failure, α-KGDH/NNT-dependent NADPH formation ameliorates oxidative stress imposed by complex I blockade. Downregulation of α-KGDH may, therefore, predispose to oxidative stress in heart failure.
Background
High doses of capsaicin are recommended for the treatment of neuropathic pain. However, low doses evoke mechanical hypersensitivity. Activation of the capsaicin chemosensor transient receptor potential vanilloid 1 (TRPV1) induces neurogenic inflammation. In addition to the release of pro-inflammatory mediators, reactive oxygen species are produced. These highly reactive molecules generate oxidised phospholipids and 4-hydroxynonenal (4-HNE) which then directly activate TRP ankyrin 1 (TRPA1). The apolipoprotein A-I mimetic peptide D-4F neutralises oxidised phospholipids. Here, we asked whether D-4F ameliorates neurogenic hypersensitivity in rodents by targeting reactive oxygen species and 4-HNE in the capsaicin-evoked pain model.
Results
Co-application of D-4F ameliorated capsaicin-induced mechanical hypersensitivity and allodynia as well as persistent heat hypersensitivity measured by Randell–Selitto, von Frey and Hargreaves test, respectively. In addition, mechanical hypersensitivity was blocked after co-injection of D-4F with the reactive oxygen species analogue H2O2 or 4-HNE. In vitro studies on dorsal root ganglion neurons and stably transfected cell lines revealed a TRPA1-dependent inhibition of the calcium influx when agonists were pre-incubated with D-4F. The capsaicin-induced calcium influx in TRPV1-expressing cell lines and dorsal root ganglion neurons sustained in the presence of D-4F.
Conclusions
D-4F is a promising compound to ameliorate TRPA1-dependent hypersensitivity during neurogenic inflammation.
Aging is an independent risk factor for cardiovascular diseases and therefore of particular interest for the prevention of cardiovascular events. However, the mechanisms underlying vascular aging are not well understood. Since carcinoembryonic antigen‐related cell adhesion molecule 1 (CEACAM1) is crucially involved in vascular homeostasis, we sought to identify the role of CEACAM1 in vascular aging. Using human internal thoracic artery and murine aorta, we show that CEACAM1 is upregulated in the course of vascular aging. Further analyses demonstrated that TNF‐α is CEACAM1‐dependently upregulated in the aging vasculature. Vice versa, TNF‐α induces CEACAM1 expression. This results in a feed‐forward loop in the aging vasculature that maintains a chronic pro‐inflammatory milieu. Furthermore, we demonstrate that age‐associated vascular alterations, that is, increased oxidative stress and vascular fibrosis, due to increased medial collagen deposition crucially depend on the presence of CEACAM1. Additionally, age‐dependent upregulation of vascular CEACAM1 expression contributes to endothelial barrier impairment, putatively via increased VEGF/VEGFR‐2 signaling. Consequently, aging‐related upregulation of vascular CEACAM1 expression results in endothelial dysfunction that may promote atherosclerotic plaque formation in the presence of additional risk factors. Our data suggest that CEACAM1 might represent an attractive target in order to delay physiological aging and therefore the transition to vascular disorders such as atherosclerosis.
Introduction: During inflammation, reactive oxygen species (ROS) such as Hydrogen peroxide accumulate at the inflammation site and by oxidizing lipids, they produce metabolites such as 4-hydroxynonenal (4-HNE) and oxidized phospholipids (OxPLs). Transient receptor potential ankyrin 1 (TRPA1) and vanilloid 1 (TRPV1) are ligand gated ion channels that are expressed on nociceptors and their activation elicits pain. Hydrogen peroxide and 4-HNE are endogenous ligands for TRPA1 and their role in inflammatory pain conditions has been shown. OxPLs play a major pro-inflammatory role in many pathologies including atherosclerosis and multiple sclerosis. E06/T15 is a mouse IgM mAb that specifically binds oxidized phosphatidylcholine. D-4F is an apolipoprotein A-I mimetic peptide with a very high affinity for OxPLs and possess anti-inflammatory properties. E06 mAb and D-4F peptide protect against OxPLs-induced damage in atherosclerosis in vivo.
Methods: To investigate the role of ROS and their metabolites in inflammatory pain, I utilized a combination of diverse and complex behavioral pain measurements and binding assays. I examined E06 mAb and D-4F as local treatment options for hypersensitivity evoked by endogenous and exogenous activators of TRPA1 and TRPV1 as well as in inflammatory and OxPL-induced pain models in vivo. 4-HNE, hydrogen peroxide as ROS source and mustard oil (AITC) were used to activate TRPA1, while capsaicin was used to activate TRPV1.
Results: Intraplantar injection of oxidized 1-palmitoyl-2-arachidonoyl-sn-glycero-3-phosphocholine (OxPAPC) into rats’ hind paw elicited thermal and mechanical hypersensitivity. Genetic and pharmacological evidence in vivo confirmed the role of TRPA1 in OxPLs-induced hypersensitivity. OxPLs formation increased in complete Freund’s adjuvant (CFA)-induced inflamed rats’ paw. E06 mAb and D-4F prevented OxPAPC–induced mechanical and thermal hypersensitivity (hyperalgesia) as well as CFA-induced mechanical hypersensitivity. Also, all irritants induced thermal and mechanical hypersensitivity as well as affective-emotional responses and spontaneous nocifensive behaviors. E06 mAb blocked prolonged mechanical hypersensitivity by all but hydrogen peroxide. In parallel, D-4F prevented mechanical hypersensitivity induced by all irritants as well as thermal hypersensitivity induced by capsaicin and 4-HNE. In addition, competitive binding assays showed that all TRPA1/V1 agonists induced prolonged formation of OxPLs in the paw tissue explaining the anti-nociceptive properties of E06 mAb and D-4F. Finally, the potential of gait analysis as a readout for non-provoked pain behavioral measurements were examined.
Conclusion and implications: OxPLs were characterized as novel targets in inflammatory pain. Treatment with the monoclonal antibody E06 or apolipoprotein A-I mimetic peptide D-4F are suggested as potential inflammatory pain medications. OxPLs’ role in neuropathic pain is yet to be investigated.
Background
Fermented wheat germ extract (FWGE) sold under the trade name Avemar exhibits anticancer activity in vitro and in vivo. Its mechanisms of action are divided into antiproliferative and antimetabolic effects. Its influcence on cancer cell metabolism needs further investigation. One objective of this study, therefore, was to further elucidate the antimetabolic action of FWGE. The anticancer compound 2,6-dimethoxy-1,4-benzoquinone (DMBQ) is the major bioactive compound in FWGE and is probably responsible for its anticancer activity. The second objective of this study was to compare the antiproliferative properties in vitro of FWGE and the DMBQ compound.
Methods
The IC\(_{50}\) values of FWGE were determined for nine human cancer cell lines after 24 h of culture. The DMBQ compound was used at a concentration of 24 μmol/l, which is equal to the molar concentration of DMBQ in FWGE. Cell viability, cell cycle, cellular redox state, glucose consumption, lactic acid production, cellular ATP levels, and the NADH/NAD\(^+\) ratio were measured.
Results
The mean IC\(_{50}\) value of FWGE for the nine human cancer cell lines tested was 10 mg/ml. Both FWGE (10 mg/ml) and the DMBQ compound (24 μmol/l) induced massive cell damage within 24 h after starting treatment, with changes in the cellular redox state secondary to formation of intracellular reactive oxygen species. Unlike the DMBQ compound, which was only cytotoxic, FWGE exhibited cytostatic and growth delay effects in addition to cytotoxicity. Both cytostatic and growth delay effects were linked to impaired glucose utilization which influenced the cell cycle, cellular ATP levels, and the NADH/NAD\(^+\) ratio. The growth delay effect in response to FWGE treatment led to induction of autophagy.
Conclusions
FWGE and the DMBQ compound both induced oxidative stress-promoted cytotoxicity. In addition, FWGE exhibited cytostatic and growth delay effects associated with impaired glucose utilization which led to autophagy, a possible previously unknown mechanism behind the influence of FWGE on cancer cell metabolism.
Tumor angiogenesis is a process which is traditionally regarded as the tumor’s response to low nutrient supply occurring under hypoxic conditions. However, hypoxia is not a pre-requisite for angiogenesis. The fact that even single tumor cells or small tumor cell aggregates are capable of attracting blood vessels reveals the early metastatic capability of tumor cells. This review sheds light on the hypoxia-independent mechanisms of tumor angiogenesis in melanoma.
Cysteines play important roles in the biochemistry of many proteins. The high reactivity, redox properties, and ability of the free thiol group to coordinate metal ions designate cysteines as the amino acids of choice to form key catalytic components of many enzymes. Also, cysteines readily react with reactive oxygen and nitrogen species to form reversible oxidative thiol modifications. Over the last few years, an increasing number of proteins have been identified that use redox-mediated thiol modifications to modulate their function, activity, or localization. These redox-regulated proteins are central players in numerous important cellular processes. First aim of this study was to discover nitric oxide (NO) sensitive proteins in E. coli, whose redox-mediated functional changes might explain the physiological alterations observed in E. coli cells suffering from NO-stress. To identify E. coli proteins that undergo reversible thiol modifications upon NO-treatment in vivo, I applied a differential thiol trapping technique combined with two-dimensional gel analysis. 10 proteins were found to contain thiol groups sensitive to NO-treatment. Subsequent genetic studies revealed that the oxidative modifications of AceF & IlvC are, in part, responsible for the observed NO-induced growth inhibition. Noteworthy, the majority of identified protein targets turned out to be specifically sensitive towards reactive nitrogen species. This oxidant specificity was tested on one NO-sensitive protein, the small subunit of glutamate synthase. In vivo and in vitro activity studies demonstrated that glutamate synthase rapidly inactivates upon nitric oxide treatment but is resistant towards other oxidative stressors. These results imply that reactive oxygen and nitrogen species affect distinct physiological processes in bacteria. The second aim of my study was to identify redox-sensitive proteins in S. cerevisiae and to use their redox state as in vivo read-out to assess the role of oxidative stress during the eukaryotic aging process. I first determined the precise in vivo thiol status of almost 300 yeast proteins located in the cytosol and sub-cellular compartments of yeast cells using a highly quantitative mass spectrometry based thiol trapping technique, called OxICAT. The identified proteins can be clustered in four groups: 1) proteins, whose cysteine residues are oxidation resistant; 2) proteins with structurally or functionally important cysteine modifications 3) proteins with highly oxidation-sensitive active site cysteines, which are partially oxidized in exponentially growing yeast cells due to their exquisite sensitivity towards low amounts of ROS; 4) proteins that are reduced in exponentially growing cells but harbor redox-sensitive cysteine(s) that affect the catalytic function of the protein during oxidative stress. These oxidative stress sensitive proteins were identified by exposure of yeast cells to sublethal concentrations of H2O2 or superoxide. It was shown that the major targets of peroxide- and superoxide-mediated stress in the cell are proteins involved in translation, glycolysis, TCA cycle and amino acid biosynthesis. These targets indicate that cells rapidly redirect the metabolic flux and energy towards the pentose phosphate pathway in an attempt to ensure the production of the reducing equivalent NADPH to counterattack oxidative stress. These results reveal that the quantitative assessment of a protein’s oxidation state is a valuable tool to identify catalytically active and redox-sensitive cysteine residues. The OxICAT technology was then used to precisely determine extent and onset of oxidative stress in chronologically aging S. cerevisiae cells by utilizing the redox status of proteins as physiological read-out. I found that chronological aging yeast cells undergo a global collapse of the cellular redox homeostasis, which precedes cell death. The onset of this collapse appears to correlate with the yeast life span, as caloric restriction increases the life span and delays the redox collapse. These results suggest that maintenance of the redox balance might contribute to the life expanding benefits of regulating the caloric intake of yeast. Clustering analysis of all oxidatively modified proteins in chronological aging yeast revealed a subset of proteins whose oxidative thiol modifications significantly precede the general redox collapse. Oxidation of these early target proteins, which most likely results in a loss of their activity, might contribute to or even cause the observed loss of redox homeostasis (i.e., thioredoxin reductase) in chronologically aging yeast. These studies in aging yeast expand our understanding how changes in redox homeostasis affect the life span of yeast cells and confirm the importance of oxidative thiol modifications as key posttranslational modifications in pro- and eukaryotic organisms.