Cimicifuga racemosa Extract Ze 450 Re-Balances Energy Metabolism and Promotes Longevity.

Recently, we reported that the Cimicifuga racemosa extract Ze 450 mediated protection from oxidative cell damage through a metabolic shift from oxidative phosphorylation to glycolysis. Here, we investigated the molecular mechanisms underlying the effects of Ze 450 against ferroptosis in neuronal cells, with a particular focus on mitochondria. The effects of Ze 450 on respiratory complex activity and hallmarks of ferroptosis were studied in isolated mitochondria and in cultured neuronal cells, respectively. In addition, Caenorhabditis elegans served as a model organism to study mitochondrial damage and longevity in vivo. We found that Ze 450 directly inhibited complex I activity in mitochondria and enhanced the metabolic shift towards glycolysis via cMyc and HIF1α regulation. The protective effects against ferroptosis were mediated independently of estrogen receptor activation and were distinct from effects exerted by metformin. In vivo, Ze 450 protected C. elegans from the mitochondrial toxin paraquat and promoted longevity in a dose-dependent manner. In conclusion, Ze 450 mediated a metabolic shift to glycolysis via direct effects on mitochondria and altered cell signaling, thereby promoting sustained cellular resilience to oxidative stress in vitro and in vivo.

Dynasore Blocks Ferroptosis through Combined Modulation of Iron Uptake and Inhibition of Mitochondrial Respiration.

Ferroptosis is a form of regulated necrosis characterized by a chain-reaction of detrimental membrane lipid peroxidation following collapse of glutathione peroxidase 4 (Gpx4) activity. This lipid peroxidation is catalyzed by labile ferric iron. Therefore, iron import mediated via transferrin receptors and both, enzymatic and non-enzymatic iron-dependent radical formation are crucial prerequisites for the execution of ferroptosis. Intriguingly, the dynamin inhibitor dynasore, which has been shown to block transferrin receptor endocytosis, can protect from ischemia/reperfusion injury as well as neuronal cell death following spinal cord injury. Yet, it is unknown how dynasore exerts these cell death-protective effects. Using small interfering RNA suppression, lipid reactive oxygen species (ROS), iron tracers and bona fide inducers of ferroptosis, we find that dynasore treatment in lung adenocarcinoma and neuronal cell lines strongly protects these from ferroptosis. Surprisingly, while the dynasore targets dynamin 1 and 2 promote extracellular iron uptake, their silencing was not sufficient to block ferroptosis suggesting that this route of extracellular iron uptake is dispensable for acute induction of ferroptosis and dynasore must have an additional off-target activity mediating full ferroptosis protection. Instead, in intact cells, dynasore inhibited mitochondrial respiration and thereby mitochondrial ROS production which can feed into detrimental lipid peroxidation and ferroptotic cell death in the presence of labile iron. In addition, in cell free systems, dynasore showed radical scavenger properties and acted as a broadly active antioxidant which is superior to N-acetylcysteine (NAC) in blocking ferroptosis. Thus, dynasore can function as a highly active inhibitor of ROS-driven types of cell death via combined modulation of the iron pool and inhibition of general ROS by simultaneously blocking two routes required for ROS and lipid-ROS driven cell death, respectively. These data have important implications for the interpretation of studies observing tissue-protective effects of this dynamin inhibitor as well as raise awareness that off-target ROS scavenging activities of small molecules used to interrogate the ferroptosis pathway should be taken into consideration.

Metabolic switch induced by Cimicifuga racemosa extract prevents mitochondrial damage and oxidative cell death.

BACKGROUND: Cimicifuga racemosa extract is a well-established therapy for menopausal symptoms. The mechanisms underlying the multiple therapeutic effects of Cimicifuga extract, e.g. reducing hot flushes and profuse sweating are not well defined. Recent studies revealed pronounced effects of Ze 450, a Cimicifuga racemosa extract that was produced by a standardized procedure, on energy metabolism through activation of AMP-activated protein kinase in vitro and beneficial anti-diabetic effects in vivo. PURPOSE: The aim of the study was to investigate the effects of Ze 450 on energy metabolism. Since mitochondria are the key regulators of cellular energy homeostasis, we wanted to elucidate whether Ze 450 affects mitochondrial resilience and can provide protection against oxidative damage in neuronal and liver cells. METHODS/STUDY DESIGN: In this study, we investigated the effects of Ze 450 (1-200 µg/ml) on mitochondrial integrity and function, and cell viability in models of oxidative stress induced by erastin and RSL-3 in neuronal and liver cells. The effects of Ze 450 in control conditions and after induction of oxidative stress were analyzed using FACS for detecting lipid peroxidation (BODIPY), mitochondrial ROS formation (MitoSOX), mitochondrial membrane potential (TMRE) and cell death (AnnexinV/PI staining). Furthermore, we determined metabolic activity (MTT assay), ATP levels and mitochondrial respiration and glycolysis (oxygen consumption rates, extracellular acidification rates; Seahorse). RESULTS: Ze 450 preserved mitochondrial integrity and ATP levels, and prevented mitochondrial ROS formation, loss of mitochondrial membrane potential and cell death. Notably, Cimicifuga racemosa extract alone did not alter mitochondrial ROS levels, and subtle inhibitory effects on cell proliferation were reversed after withdrawal of the extract. In addition, Ze 450 did not exert toxic effects to liver cells, but rather protected these from the oxidative challenge. Further analysis of the mitochondrial oxygen consumption rate and the extracellular acidification rate revealed that Ze 450 mediated a switch from mitochondrial respiration to glycolysis, and this metabolic shift was a prerequisite for the protective effects against oxidative damage. CONCLUSION: In conclusion, the bioenergetic shift induced by Ze 450 exerted protective effects in different cell types, and offers promising therapeutic potential in age related diseases involving oxidative stress and mitochondrial damage.

Effects of Cimicifuga racemosa extract Ze450 on mitochondria in models of oxidative stress in neuronal cells.

This data article describes the influence of Cimicifuga racemosa extract Ze 450 on neuronal cells in models of glutamate-induced excitotoxicity and cell death induced by oxidative stress. Effects of Ze 450 on glutamate-mediated excitotoxicity were assessed in primary cortical rat and mouse neurons and, further, glutamate-mediated oxidative stress was analyzed in HT22 cells lacking ionotropic glutamate receptors. This study especially focusses on mitochondrial parameters like mitochondrial ROS formation, mitochondrial membrane potential, ATP production and mitochondrial integrity. Further the effects of Ze 450 on lipid-peroxidation, metabolic activity, cell proliferation and cell death were assessed under control conditions and oxidative challenge evoked by millimolar concentrations of glutamate in HT22 cells. These data support the findings in HT22, mHypo and HepG2 liver cells (Rabenau et al., 2018) [1].

Delivery of drugs and macromolecules to the mitochondria for cancer therapy.

Mitochondria are organelles that have pivotal functions in producing the energy necessary for life and executing the cell death pathway. Targeting drugs and macromolecules to the mitochondria may provide an effective means of inducing cell death for cancer therapy, and has been actively pursued in the last decade. This review will provide a brief overview of mitochondrial structure and function, how it relates to cancer, and importantly, will discuss different strategies of mitochondrial delivery including delivery using small molecules, peptides, genes encoding proteins and MTSs, and targeting polymers/nanoparticles with payloads to the mitochondria. The advantages and disadvantages for each strategy will be discussed. Specific examples using the latest strategies for mitochondrial targeting will be evaluated, as well as potential opportunities for specific mitochondrial compartment localization, which may lead to improvements in mitochondrial therapeutics. Future perspectives in mitochondrial targeting of drugs and macromolecules will be discussed. Currently this is an under-explored area that is prime for new discoveries in cancer therapeutics.