TY - JOUR A1 - Bishop, Christopher Allen A1 - Machate, Tina A1 - Henning, Thorsten A1 - Henkel-Oberländer, Janin A1 - Püschel, Gerhard A1 - Weber, Daniela A1 - Grune, Tilman A1 - Klaus, Susanne A1 - Weitkunat, Karolin T1 - Detrimental effects of branched-chain amino acids in glucose tolerance can be attributed to valine induced glucotoxicity in skeletal muscle JF - Nutrition & Diabetes N2 - Objective: Current data regarding the roles of branched-chain amino acids (BCAA) in metabolic health are rather conflicting, as positive and negative effects have been attributed to their intake. Methods: To address this, individual effects of leucine and valine were elucidated in vivo (C57BL/6JRj mice) with a detailed phenotyping of these supplementations in high-fat (HF) diets and further characterization with in vitro approaches (C2C12 myocytes). Results: Here, we demonstrate that under HF conditions, leucine mediates beneficial effects on adiposity and insulin sensitivity, in part due to increasing energy expenditure-likely contributing partially to the beneficial effects of a higher milk protein intake. On the other hand, valine feeding leads to a worsening of HF-induced health impairments, specifically reducing glucose tolerance/ insulin sensitivity. These negative effects are driven by an accumulation of the valine-derived metabolite 3-hydroxyisobutyrate (3HIB). Higher plasma 3-HIB levels increase basal skeletal muscle glucose uptake which drives glucotoxicity and impairs myocyte insulin signaling. Conclusion: These data demonstrate the detrimental role of valine in an HF context and elucidate additional targetable pathways in the etiology of BCAA-induced obesity and insulin resistance. Y1 - 2022 U6 - https://doi.org/10.1038/s41387-022-00200-8 SN - 2044-4052 VL - 12 IS - 1 PB - Nature Publishing Group CY - London ER - TY - JOUR A1 - Castaño Martínez, María Teresa A1 - Schumacher, Fabian A1 - Schumacher, Silke A1 - Kochlik, Bastian Max A1 - Weber, Daniela A1 - Grune, Tilman A1 - Biemann, Ronald A1 - McCann, Adrian A1 - Abraham, Klaus A1 - Weikert, Cornelia A1 - Kleuse, Burkhard A1 - Schürmann, Annette A1 - Laeger, Thomas T1 - Methionine restriction prevents onset of type 2 diabetes in NZO mice JF - The FASEB journal : the official journal of the Federation of American Societies for Experimental Biology N2 - Dietary methionine restriction (MR) is well known to reduce body weight by increasing energy expenditure (EE) and insulin sensitivity. An elevated concentration of circulating fibroblast growth factor 21 (FGF21) has been implicated as a potential underlying mechanism. The aims of our study were to test whether dietary MR in the context of a high-fat regimen protects against type 2 diabetes in mice and to investigate whether vegan and vegetarian diets, which have naturally low methionine levels, modulate circulating FGF21 in humans. New Zealand obese (NZO) mice, a model for polygenic obesity and type 2 diabetes, were placed on isocaloric high-fat diets (protein, 16 kcal%; carbohydrate, 52 kcal%; fat, 32 kcal%) that provided methionine at control (Con; 0.86% methionine) or low levels (0.17%) for 9 wk. Markers of glucose homeostasis and insulin sensitivity were analyzed. Among humans, low methionine intake and circulating FGF21 levels were investigated by comparing a vegan and a vegetarian diet to an omnivore diet and evaluating the effect of a short-term vegetarian diet on FGF21 induction. In comparison with the Con group, MR led to elevated plasma FGF21 levels and prevented the onset of hyperglycemia in NZO mice. MR-fed mice exhibited increased insulin sensitivity, higher plasma adiponectin levels, increased EE, and up-regulated expression of thermogenic genes in subcutaneous white adipose tissue. Food intake and fat mass did not change. Plasma FGF21 levels were markedly higher in vegan humans compared with omnivores, and circulating FGF21 levels increased significantly in omnivores after 4 d on a vegetarian diet. These data suggest that MR induces FGF21 and protects NZO mice from high-fat diet-induced glucose intolerance and type 2 diabetes. The normoglycemic phenotype in vegans and vegetarians may be caused by induced FGF21. MR akin to vegan and vegetarian diets in humans may offer metabolic benefits via increased circulating levels of FGF21 and merits further investigation.-Castano-Martinez, T., Schumacher, F., Schumacher, S., Kochlik, B., Weber, D., Grune, T., Biemann, R., McCann, A., Abraham, K., Weikert, C., Kleuser, B., Schurmann, A., Laeger, T. Methionine restriction prevents onset of type 2 diabetes in NZO mice. KW - energy expenditure KW - hyperglycemia KW - obesity KW - vegan KW - vegetarian Y1 - 2019 U6 - https://doi.org/10.1096/fj.201900150R SN - 0892-6638 SN - 1530-6860 VL - 33 IS - 6 SP - 7092 EP - 7102 PB - Federation of American Societies for Experimental Biology CY - Bethesda ER - TY - JOUR A1 - Castro, Jose Pedro A1 - Fernando, Raquel A1 - Reeg, Sandra A1 - Meinl, Walter A1 - Almeida, Henrique A1 - Grune, Tilman T1 - Non-enzymatic cleavage of Hsp90 by oxidative stress leads to actin aggregate formation BT - A novel gain-of-function mechanism JF - Redox Biology N2 - Aging is accompanied by the accumulation of oxidized proteins. To remove them, cells employ the proteasomal and autophagy-lysosomal systems; however, if the clearance rate is inferior to its formation, protein aggregates form as a hallmark of proteostasis loss. In cells, during stress conditions, actin aggregates accumulate leading to impaired proliferation and reduced proteasomal activity, as observed in cellular senescence. The heat shock protein 90 (Hsp90) is a molecular chaperone that binds and protects the proteasome from oxidative inactivation. We hypothesized that in oxidative stress conditions a malfunction of Hsp90 occurs resulting in the aforementioned protein aggregates. Here, we demonstrate that upon oxidative stress Hsp90 loses its function in a highly specific non-enzymatic iron-catalyzed oxidation event and its breakdown product, a cleaved form of Hsp90 (Hsp90cl), acquires a new function in mediating the accumulation of actin aggregates. Moreover, the prevention of Hsp90 cleavage reduces oxidized actin accumulation, whereas transfection of the cleaved form of Hsp90 leads to an enhanced accumulation of oxidized actin. This indicates a clear role of the Hsp90cl in the aggregation of oxidized proteins. KW - Oxidative stress KW - Protein oxidation KW - Heat shock protein 90 KW - Proteasome KW - Protein aggregates Y1 - 2019 U6 - https://doi.org/10.1016/j.redox.2019.101108 SN - 2213-2317 VL - 21 PB - Elsevier CY - Amsterdam ER - TY - JOUR A1 - Castro, Jose Pedro A1 - Wardelmann, Kristina A1 - Grune, Tilman A1 - Kleinridders, Andre T1 - Mitochondrial Chaperones in the Brain BT - safeguarding Brain Health and Metabolism? JF - Frontiers in Endocrinology N2 - The brain orchestrates organ function and regulates whole body metabolism by the concerted action of neurons and glia cells in the central nervous system. To do so, the brain has tremendously high energy consumption and relies mainly on glucose utilization and mitochondrial function in order to exert its function. As a consequence of high rate metabolism, mitochondria in the brain accumulate errors over time, such as mitochondrial DNA (mtDNA) mutations, reactive oxygen species, and misfolded and aggregated proteins. Thus, mitochondria need to employ specific mechanisms to avoid or ameliorate the rise of damaged proteins that contribute to aberrant mitochondrial function and oxidative stress. To maintain mitochondria homeostasis (mitostasis), cells evolved molecular chaperones that shuttle, refold, or in coordination with proteolytic systems, help to maintain a low steady-state level of misfolded/aggregated proteins. Their importance is exemplified by the occurrence of various brain diseases which exhibit reduced action of chaperones. Chaperone loss (expression and/or function) has been observed during aging, metabolic diseases such as type 2 diabetes and in neurode-generative diseases such as Alzheimer's (AD), Parkinson's (PD) or even Huntington's (HD) diseases, where the accumulation of damage proteins is evidenced. Within this perspective, we propose that proper brain function is maintained by the joint action of mitochondrial chaperones to ensure and maintain mitostasis contributing to brain health, and that upon failure, alter brain function which can cause metabolic diseases. KW - insulin signaling KW - brain KW - chaperones KW - mitochondria homeostasis KW - mitochondrial dysfunction KW - neurodegeneration Y1 - 2018 U6 - https://doi.org/10.3389/fendo.2018.00196 SN - 1664-2392 VL - 9 PB - Frontiers Research Foundation CY - Lausanne ER - TY - JOUR A1 - Castro, José Pedro A1 - Grune, Tilman A1 - Speckmann, Bodo T1 - The two faces of reactive oxygen species (ROS) in adipocyte function and dysfunction JF - Biological chemistry N2 - White adipose tissue (WAT) is actively involved in the regulation of whole-body energy homeostasis via storage/ release of lipids and adipokine secretion. Current research links WAT dysfunction to the development of metabolic syndrome (MetS) and type 2 diabetes (T2D). The expansion of WAT during oversupply of nutrients prevents ectopic fat accumulation and requires proper preadipocyte-to-adipocyte differentiation. An assumed link between excess levels of reactive oxygen species (ROS), WAT dysfunction and T2D has been discussed controversially. While oxidative stress conditions have conclusively been detected in WAT of T2D patients and related animal models, clinical trials with antioxidants failed to prevent T2D or to improve glucose homeostasis. Furthermore, animal studies yielded inconsistent results regarding the role of oxidative stress in the development of diabetes. Here, we discuss the contribution of ROS to the (patho) physiology of adipocyte function and differentiation, with particular emphasis on sources and nutritional modulators of adipocyte ROS and their functions in signaling mechanisms controlling adipogenesis and functions of mature fat cells. We propose a concept of ROS balance that is required for normal functioning of WAT. We explain how both excessive and diminished levels of ROS, e. g. resulting from over supplementation with antioxidants, contribute to WAT dysfunction and subsequently insulin resistance. KW - adipogenesis KW - adipose tissue dysregulation KW - antioxidants KW - metabolic disorders KW - oxidative stress Y1 - 2016 U6 - https://doi.org/10.1515/hsz-2015-0305 SN - 1431-6730 SN - 1437-4315 VL - 397 SP - 709 EP - 724 PB - De Gruyter CY - Berlin ER - TY - GEN A1 - Castro, José Pedro A1 - Grune, Tilman A1 - Speckmann, Bodo T1 - The two faces of reactive oxygen species (ROS) in adipocyte function and dysfunction N2 - White adipose tissue (WAT) is actively involved in the regulation of whole-body energy homeostasis via storage/release of lipids and adipokine secretion. Current research links WAT dysfunction to the development of metabolic syndrome (MetS) and type 2 diabetes (T2D). The expansion of WAT during oversupply of nutrients prevents ectopic fat accumulation and requires proper preadipocyte-to-adipocyte differentiation. An assumed link between excess levels of reactive oxygen species (ROS), WAT dysfunction and T2D has been discussed controversially. While oxidative stress conditions have conclusively been detected in WAT of T2D patients and related animal models, clinical trials with antioxidants failed to prevent T2D or to improve glucose homeostasis. Furthermore, animal studies yielded inconsistent results regarding the role of oxidative stress in the development of diabetes. Here, we discuss the contribution of ROS to the (patho)physiology of adipocyte function and differentiation, with particular emphasis on sources and nutritional modulators of adipocyte ROS and their functions in signaling mechanisms controlling adipogenesis and functions of mature fat cells. We propose a concept of ROS balance that is required for normal functioning of WAT. We explain how both excessive and diminished levels of ROS, e.g. resulting from over supplementation with antioxidants, contribute to WAT dysfunction and subsequently insulin resistance. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 339 KW - adipogenesis KW - adipose tissue dysregulation KW - antioxidants KW - metabolic disorders KW - oxidative stress Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-398039 ER - TY - GEN A1 - Castro, José Pedro A1 - Wardelmann, Kristina A1 - Grune, Tilman A1 - Kleinridders, André T1 - Mitochondrial chaperones in the brain BT - safeguarding brain health and metabolism? T2 - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe N2 - The brain orchestrates organ function and regulates whole body metabolism by the concerted action of neurons and glia cells in the central nervous system. To do so, the brain has tremendously high energy consumption and relies mainly on glucose utilization and mitochondrial function in order to exert its function. As a consequence of high rate metabolism, mitochondria in the brain accumulate errors over time, such as mitochondrial DNA (mtDNA) mutations, reactive oxygen species, and misfolded and aggregated proteins. Thus, mitochondria need to employ specific mechanisms to avoid or ameliorate the rise of damaged proteins that contribute to aberrant mitochondrial function and oxidative stress. To maintain mitochondria homeostasis (mitostasis), cells evolved molecular chaperones that shuttle, refold, or in coordination with proteolytic systems, help to maintain a low steady-state level of misfolded/aggregated proteins. Their importance is exemplified by the occurrence of various brain diseases which exhibit reduced action of chaperones. Chaperone loss (expression and/or function) has been observed during aging, metabolic diseases such as type 2 diabetes and in neurode-generative diseases such as Alzheimer's (AD), Parkinson's (PD) or even Huntington's (HD) diseases, where the accumulation of damage proteins is evidenced. Within this perspective, we propose that proper brain function is maintained by the joint action of mitochondrial chaperones to ensure and maintain mitostasis contributing to brain health, and that upon failure, alter brain function which can cause metabolic diseases. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1031 KW - insulin signaling KW - brain KW - chaperones KW - mitochondria homeostasis KW - mitochondrial dysfunction KW - neurodegeneration Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-460650 SN - 1866-8372 IS - 1031 ER - TY - GEN A1 - Fernando, Raquel A1 - Drescher, Cathleen A1 - Deubel, Stefanie A1 - Grune, Tilman A1 - Castro, Jose Pedro T1 - Distinct proteasomal activity for fast and slow twitch skeletal muscle during aging T2 - Free radical biology and medicine : the official journal of the Oxygen Society, a constituent member of the International Society for Free Radical Research N2 - Skeletal muscle alterations during aging lead to dysfunctional metabolism, correlating with frailty and early mortality. The loss of proteostasis is a hallmark of aging. Whether proteostasis loss plays a role in muscle aging remains elusive. To address this question we collected muscles, Soleus (SOL, type I) and Extensor digitorum longus (EDL, type II), from young (4 months) and old (25 months) C57BL/6 mice and evaluated the proteasomal system. Initial work showed decreased 26 S activity in old SOL. EDL displayed lower proteasomal activity in both ages compared to any of the SOL ages. Moreover, in order to understand if during aging there is the so-called “fiber switch from fast-to-slow”, we performed western blots against sMHC and fMHC (slow and fast myosin heavy chain, respectively). Preliminary results suggest that young SOL is composed by slow twitch fibers but also contains fast twitch fibers, while young EDL seems to be mostly composed by fast twitch fibers that level down during aging, suggesting the switch. As a conclusion, EDL seems to have less proteasomal activity, however, if this is a contributor or a consequence to the muscle fiber switch during aging still needs further investigation. Y1 - 2018 U6 - https://doi.org/10.1016/j.freeradbiomed.2018.04.393 SN - 0891-5849 SN - 1873-4596 VL - 120 SP - S119 EP - S119 PB - Elsevier CY - New York ER - TY - JOUR A1 - Fernando, Raquel A1 - Drescher, Cathleen A1 - Deubel, Stefanie A1 - Jung, Tobias A1 - Ost, Mario A1 - Klaus, Susanne A1 - Grune, Tilman A1 - Castro, Jose Pedro T1 - Low proteasomal activity in fast skeletal muscle fibers is not associated with increased age-related oxidative damage JF - Experimental gerontology N2 - The skeletal muscle is a crucial tissue for maintaining whole body homeostasis. Aging seems to have a disruptive effect on skeletal muscle homeostasis including proteostasis. However, how aging specifically impacts slow and fast twitch fiber types remains elusive. Muscle proteostasis is largely maintained by the proteasomal system. Here we characterized the proteasomal system in two different fiber types, using a non-sarcopenic aging model. By analyzing the proteasomal activity and amount, as well as the polyubiquitinated proteins and the level of protein oxidation in Musculus soleus (Sol) and Musculus extensor digitorum longus (EDL), we found that the slow twitch Sol muscle shows an overall higher respiratory and proteasomal activity in young and old animals. However, especially during aging the fast twitch EDL muscle reduces protein oxidation by an increase of antioxidant capacity. Thus, under adaptive non-sarcopenic conditions, the two fibers types seem to have different strategies to avoid age-related changes. KW - Proteasomal system KW - Skeletal muscle KW - Fast and slow fibers KW - Polyubiquitination KW - Oxidized proteins KW - Antioxidants KW - Aging KW - Mitochondrial respiration Y1 - 2018 U6 - https://doi.org/10.1016/j.exger.2018.10.018 SN - 0531-5565 SN - 1873-6815 VL - 117 SP - 45 EP - 52 PB - Elsevier CY - Oxford ER - TY - JOUR A1 - Fernando, Raquel A1 - Drescher, Cathleen A1 - Nowotny, Kerstin A1 - Grune, Tilman A1 - Castro, Jose Pedro T1 - Impaired proteostasis during skeletal muscle aging JF - Free radical biology and medicine : the official journal of the Oxygen Society, a constituent member of the International Society for Free Radical Research N2 - Aging is a complex phenomenon that has detrimental effects on tissue homeostasis. The skeletal muscle is one of the earliest tissues to be affected and to manifest age-related changes such as functional impairment and the loss of mass. Common to these alterations and to most of tissues during aging is the disruption of the proteostasis network by detrimental changes in the ubiquitin-proteasomal system (UPS) and the autophagy-lysosomal system (ALS). In fact, during aging the accumulation of protein aggregates, a process mainly driven by increased levels of oxidative stress, has been observed, clearly demonstrating UPS and ALS dysregulation. Since the UPS and ALS are the two most important pathways for the removal of misfolded and aggregated proteins and also of damaged organelles, we provide here an overview on the current knowledge regarding the connection between the loss of proteostasis and skeletal muscle functional impairment and also how redox regulation can play a role during aging. Therefore, this review serves for a better understanding of skeletal muscle aging in regard to the loss of proteostasis and how redox regulation can impact its function and maintenance. KW - Skeletal muscle KW - Proteostasis KW - Proteasome and lysosome KW - Oxidative stress KW - Redox regulation KW - Aging Y1 - 2018 U6 - https://doi.org/10.1016/j.freeradbiomed.2018.08.037 SN - 0891-5849 SN - 1873-4596 VL - 132 SP - 58 EP - 66 PB - Elsevier CY - New York ER -