bims-kimdis Biomed News
on Ketones, inflammation and mitochondria in disease
Issue of 2024‒09‒01
nineteen papers selected by
Matías Javier Monsalves Álvarez, Universidad Andrés Bello
  1. Exploring the ketogenic diet's potential in reducing neuroinflammation and modulating immune responses.
  2. Two-month ketogenic diet alters systemic and brain metabolism in middle-aged female mice.
  3. Ketones and the cardiovascular system.
  4. Ketone monoester attenuates oxygen desaturation during weighted ruck exercise under acute hypoxic exposure but does not impact cognitive performance.
  5. Acute Ketone Monoester Supplementation Does Not Change Exercise Efficiency during Incremental Cycling in Trained Individuals.
  6. Hyperglycemia Stimulates the Irreversible Catabolism of Branched-Chain Amino Acids and Generation of Ketone Bodies by Cultured Human Astrocytes.
  7. New anti-inflammatory mechanism of glucocorticoids uncovered.
  8. Anti-inflammatory diets.
  9. Intermittent fasting increases fat oxidation and promotes metabolic flexibility in lean mice but not obese type 2 diabetic mice.
  10. Loss of mitochondria long-chain fatty acid oxidation impairs skeletal muscle contractility by disrupting myofibril structure and calcium homeostasis.
  11. HFrEF and HFpEF: are mitochondria at the heart of the matter?
  12. The impact of time-restricted eating on beta-cell function in adults with type 2 diabetes: a randomized cross-over trial.
  13. Skeletal muscle myosin heavy chain fragmentation as a potential marker of protein degradation in response to resistance training and disuse atrophy.
  14. Mitochondrial translation is the primary determinant of secondary mitochondrial complex I deficiencies.
  15. Betaine delays age-related muscle loss by mitigating Mss51-induced impairment in mitochondrial respiration via Yin Yang1.
  16. Does AMPK bind glycogen in skeletal muscle or is the relationship correlative?
  17. Metabolic small talk during exercise: The role of metabokines and lipokines in interorgan signalling.
  18. Madness or progress? The dilemma of standardizing exercise physiology thresholds.
  19. Nutritional Strategies in Major Depression Disorder: From Ketogenic Diet to Modulation of the Microbiota-Gut-Brain Axis.
  1. Front Immunol. 2024 ;15 1425816
    Exploring the ketogenic diet's potential in reducing neuroinflammation and modulating immune responses.
    Antonietta Monda, Maria Ester La Torre, Antonietta Messina, Girolamo Di Maio, Vincenzo Monda, Fiorenzo Moscatelli, Marida De Stefano, Marco La Marra, Marilena Di Padova, Anna Dipace, Pierpaolo Limone, Maria Casillo, Marcellino Monda, Giovanni Messina, Rita Polito.
      The ketogenic diet (KD) is marked by a substantial decrease in carbohydrate intake and an elevated consumption of fats and proteins, leading to a metabolic state referred to as "ketosis," where fats become the primary source of energy. Recent research has underscored the potential advantages of the KD in mitigating the risk of various illnesses, including type 2 diabetes, hyperlipidemia, heart disease, and cancer. The macronutrient distribution in the KD typically entails high lipid intake, moderate protein consumption, and low carbohydrate intake. Restricting carbohydrates to below 50 g/day induces a catabolic state, prompting metabolic alterations such as gluconeogenesis and ketogenesis. Ketogenesis diminishes fat and glucose accumulation as energy reserves, stimulating the production of fatty acids. Neurodegenerative diseases, encompassing Alzheimer's disease, Parkinson's disease are hallmarked by persistent neuroinflammation. Evolving evidence indicates that immune activation and neuroinflammation play a significant role in the pathogenesis of these diseases. The protective effects of the KD are linked to the generation of ketone bodies (KB), which play a pivotal role in this dietary protocol. Considering these findings, this narrative review seeks to delve into the potential effects of the KD in neuroinflammation by modulating the immune response. Grasping the immunomodulatory effects of the KD on the central nervous system could offer valuable insights into innovative therapeutic approaches for these incapacitating conditions.
    Keywords:  central nervous system; immunomodulation; ketogenic diet; ketone bodies; neuroinflammation
    DOI:  https://doi.org/10.3389/fimmu.2024.1425816
  2. Geroscience. 2024 Aug 24.
    Two-month ketogenic diet alters systemic and brain metabolism in middle-aged female mice.
    Kirsten J Roslund, Jon J Ramsey, Jennifer M Rutkowsky, Zeyu Zhou, Carolyn M Slupsky.
      The ketogenic diet (KD) is a very low-carbohydrate, high-fat diet that reduces glucose catabolism and enhances β-oxidation and ketogenesis. While research in female rodents is limited, research in male rodents suggests that ketogenic interventions initiated at midlife may slow age-related cognitive decline, as well as preserve muscle mass and physical function later in life. This study aimed to investigate the effects of a KD on global metabolic changes in middle-aged females to inform potential mechanisms behind the anti-aging effects of this diet in an understudied sex. Targeted 1H-NMR metabolomics was conducted on serum, the liver, the kidney, and the gastrocnemius muscle, as well as the cortex and the hippocampal brain regions in 16-month-old female mice after a 2-month KD. Analysis of the serum and liver metabolome revealed that the 2-month KD resulted in increased concentrations of fatty acid catabolism metabolites, as well as system-wide elevations in ketones, consistent with the ketogenic phenotype. Metabolites involved in the glucose-alanine cycle were altered in the gastrocnemius muscle, serum and the liver. Other tissue-specific alterations were detected, including distinct effects on hepatic and renal one-carbon metabolism, as well as region specific differences in metabolism across hippocampal and cortical parts of the brain. Alterations to hippocampal metabolites involved in myelinogenesis could relate to the potential beneficial effects of a KD on memory.
    Keywords:  Aging; Female; Ketogenic diet; Ketones; Metabolism; β-Hydroxybutyrate
    DOI:  https://doi.org/10.1007/s11357-024-01314-w
  3. Nat Cardiovasc Res. 2023 May;2(5): 425-437
    Ketones and the cardiovascular system.
    Gary D Lopaschuk, Jason R B Dyck.
      Ketone bodies, the main one being β-hydroxybutyrate, have emerged as important regulators of the cardiovascular system. In healthy individuals, as well as in individuals with heart failure or post-myocardial infarction, ketones provide a supplemental energy source for both the heart and the vasculature. In the failing heart, this additional energy may contribute to improved cardiac performance, whereas increasing ketone oxidation in vascular smooth muscle and endothelial cells enhances cell proliferation and prevents blood vessel rarefication. Ketones also have important actions in signaling pathways, posttranslational modification pathways and gene transcription; many of which modify cell proliferation, inflammation, oxidative stress, endothelial function and cardiac remodeling. Attempts to therapeutically increase ketone delivery to the cardiovascular system are numerous and have shown mixed results in terms of effectiveness. Here we review the bioenergetic and signaling effects of ketones on the cardiovascular system, and we discuss how ketones can potentially be used to treat cardiovascular diseases.
    DOI:  https://doi.org/10.1038/s44161-023-00259-1
  4. Exp Physiol. 2024 Aug 27.
    Ketone monoester attenuates oxygen desaturation during weighted ruck exercise under acute hypoxic exposure but does not impact cognitive performance.
    Tyler S McClure, Jeffrey Phillips, Dawn Kernagis, Kody Coleman, Ed Chappe, Gary R Cutter, Brendan Egan, Todd Norell, Brianna J Stubbs, Marcas M Bamman, Andrew P Koutnik.
      Acute ingestion of exogenous ketone supplements in the form of a (R)-3-hydroxybutyl (R)-3-hydroxybutyrate (R-BD R-βHB) ketone monoester (KME) can attenuate declines in oxygen availability during hypoxic exposure and might impact cognitive performance at rest and in response to moderate-intensity exercise. In a single-blind randomized crossover design, 16 males performed assessments of cognitive performance before and during hypoxic exposure with moderate exercise [2 × 20 min weighted ruck (∼22 kg) at 3.2 km/h at 10% incline] in a normobaric altitude chamber (4572 m, 11.8% O2). The R-BD R-βHB KME (573 mg/kg) or a calorie- and taste-matched placebo (∼50 g maltodextrin) were co-ingested with 40 g of dextrose before exposure to hypoxia. The R-βHB concentrations were rapidly elevated and sustained (>3 mM; P < 0.001) by KME. The decline in oxygen saturation during hypoxic exposure was attenuated in KME conditions by 2.4%-4.2% (P < 0.05) compared with placebo. Outcomes of cognitive performance tasks, in the form of the Defense Automated Neurobehavioral Assessment (DANA) code substitution task, the Stroop color and word task, and a shooting simulation, did not differ between trials before and during hypoxic exposure. These data suggest that the acute exogenous ketosis induced by KME ingestion can attenuate declining blood oxygen saturation during acute hypoxic exposure both at rest and during moderate-intensity exercise, but this did not translate into differences in cognitive performance before or after exercise in the conditions investigated. HIGHLIGHTS: What is the central question of this study? Can exogenous ketosis act as a countermeasure to declines in blood oxygen saturation and cognitive performance during acute hypoxic exposure while performing a weighted ruck exercise? What is the main finding and its importance? Acute exogenous ketosis via ingestion of a drink containing the (R)-3-hydroxybutyl (R)-3-hydroxybutyrate ketone monoester prior to acute hypoxic exposure attenuated hypoxia-induced declines in blood oxygen saturation but had no effect on cognitive performance during exercise.
    Keywords:  cognitive performance; exogenous ketones; heart rate variability; oxygen saturation; β‐hydroxybutyrate
    DOI:  https://doi.org/10.1113/EP091789
  5. Med Sci Sports Exerc. 2024 Aug 23.
    Acute Ketone Monoester Supplementation Does Not Change Exercise Efficiency during Incremental Cycling in Trained Individuals.
    Jack Bone, Sydney Baumgarten, Devin G McCarthy, William Bostad, Douglas L Richards, Martin J Gibala.
      METHODS: 28 adults (16 males and 12 females) aged 30 ± 10 y [peak oxygen uptake (V̇O2peak): 59 ± 11 ml·kg-1·min-1] completed three experimental trials in a randomized, crossover, and double-blinded manner. Participants ingested either 0.3 (KE-LO) or 0.6 (KE-HI) g·kg-1 body mass of KE or a flavour-matched placebo (PLAC) ~30 min prior to exercise. Exercise involved a 3-minute warm-up, three 5-minute stages at fixed incremental workloads corresponding to 75%, 100%, and 125% of individual ventilatory threshold, followed by a ramp protocol to volitional exhaustion to determine peak power output (PPO).RESULTS: Venous blood [ß-hydroxybutyrate], the major circulating ketone body, was higher after KE ingestion compared to PLAC (KE-HI: 3.0 ± 1.1 ≥ KE-LO: 2.3 ± 0.6 ≥ PLAC: 0.2 ± 0.1 mM; all p ≤ 0.001. There were no differences between conditions in the primary outcome exercise economy, nor gross efficiency or delta efficiency, when analyzed over the entire submaximal exercise period or by stage. Heart rate and ventilation were higher in KE-HI and KE-LO compared to PLAC when assessed over the entire submaximal exercise period and by stage (all p ≤ 0.05). PPO after the ramp was lower in KE-HI compared to both KE-LO and PLAC (329 ± 60 vs 339 ± 62 and 341 ± 61 W respectively; both p < 0.05) despite no difference in V̇O2peak.
    CONCLUSIONS: KE ingestion did not change indices of exercise efficiency but increased markers of cardiorespiratory stress during submaximal incremental cycling and reduced PPO.
    DOI:  https://doi.org/10.1249/MSS.0000000000003532
  6. Biomedicines. 2024 Aug 08. pii: 1803. [Epub ahead of print]12(8):
    Hyperglycemia Stimulates the Irreversible Catabolism of Branched-Chain Amino Acids and Generation of Ketone Bodies by Cultured Human Astrocytes.
    Eduard Gondáš, Eva Baranovičová, Jakub Šofranko, Radovan Murín.
      Astrocytes are considered to possess a noticeable role in brain metabolism and, as a partners in neuron-glia cooperation, to contribute to the synthesis, bioconversion, and regulation of the flux of substrates for neuronal metabolism. With the aim of investigating to what extent human astrocytes are metabolizing amino acids and by which compounds are they enriching their surroundings, we employed a metabolomics analysis of their culture media by 1H-NMR. In addition, we compared the composition of media with either 5 mM or 25 mM glucose. The quantitative analysis of culture media by 1H-NMR revealed that astrocytes readily dispose from their milieu glutamine, branched-chain amino acids, and pyruvate with significantly high rates, while they enrich the culture media with lactate, branched-chain keto acids, citrate, acetate, ketone bodies, and alanine. Hyperglycemia suppressed the capacity of astrocytes to release branched-chain 2-oxo acids, while stimulating the generation of ketone bodies. Our results highlight the active involvement of astrocytes in the metabolism of several amino acids and the regulation of key metabolic intermediates. The observed metabolic activities of astrocytes provide valuable insights into their roles in supporting neuronal function, brain metabolism, and intercellular metabolic interactions within the brain. Understanding the complex metabolic interactions between astrocytes and neurons is essential for elucidating brain homeostasis and the pathophysiology of neurological disorders. The observed metabolic activities of astrocytes provide hints about their putative metabolic roles in brain metabolism.
    Keywords:  amino acid; astrocyte; branched-chain 2-oxo acid; branched-chain amino acid; euglycemia; hyperglycemia; isoleucine; ketone body; leucine; metabolomics; proton-nuclear magnetic resonance (1H-NMR); valine
    DOI:  https://doi.org/10.3390/biomedicines12081803
  7. Trends Endocrinol Metab. 2024 Aug 23. pii: S1043-2760(24)00222-4. [Epub ahead of print]
    New anti-inflammatory mechanism of glucocorticoids uncovered.
    Carolyn L Cummins, Ido Goldstein.
      Glucocorticoids (GCs) are potent anti-inflammatory drugs. A new study by Auger et al. found that GCs increase itaconate, an anti-inflammatory tricarboxylic acid (TCA) cycle intermediate, by promoting movement of cytosolic pyruvate dehydrogenase (PDH) to mitochondria. Itaconate was sufficient for mediating the anti-inflammatory effects of GCs in mice, overriding the notion that nuclear glucocorticoid receptor (GR) is necessary for inflammation inhibition.
    Keywords:  GR; LPS; PDH; itaconate; macrophage
    DOI:  https://doi.org/10.1016/j.tem.2024.08.003
  8. Nursing. 2024 Sep 01. 54(9): 23-24
    Anti-inflammatory diets.
      
    DOI:  https://doi.org/10.1097/NSG.0000000000000070
  9. Am J Physiol Endocrinol Metab. 2024 Aug 28.
    Intermittent fasting increases fat oxidation and promotes metabolic flexibility in lean mice but not obese type 2 diabetic mice.
    Meghan O Conn, Daniel M Marko, Jonathan D Schertzer.
      Obesity and type 2 diabetes (T2D) are associated with metabolic inflexibility, characterized by an impaired ability to switch between substrate storage and utilization pathways. Metabolic inflexibility during obesity is typified by lower engagement of fatty acid metabolism despite an ample supply of stored lipids. Intermittent fasting (IF) can promote metabolic flexibility. However, it is not clear how obesity and T2D alter metabolic flexibility after repeated IF. Male obese db/db and control db/+ mice were fasted for 24 hours twice a week for 10 weeks. This 5:2 IF regimen did not alter body mass, body composition, food intake, or physical activity in db/db or db/+ mice. After IF, db/db mice had lower fatty acid oxidation and higher carbohydrate oxidation in the fed state, indicating metabolic inflexibility to metabolize lipids. After IF, control db/+ mice had higher fatty acid oxidation and lower carbohydrate oxidation in the fed state, characteristic of metabolic flexibility and increased engagement of lipid metabolism. In the fasted state, IF lowered carbohydrate oxidation and increased fatty acid oxidation in control db/+ mice but not in obese db/db mice. After IF, db/db mice also had lower serum β-hydroxybutyrate than control db/+ mice. 10 weeks of IF decreased adipocyte size in visceral adipose tissue of control db/+ mice, but this IF regimen did not change adipocyte size in obese db/db mice. Therefore, IF increases fatty acid oxidation and metabolic flexibility in lean mice, but this adaptation is absent in a mouse model of obesity and type 2 diabetes.
    Keywords:  Insulin; Intermittent Fasting; Obesity; Type 2 Diabetes; mice
    DOI:  https://doi.org/10.1152/ajpendo.00255.2024
  10. Mol Metab. 2024 Aug 27. pii: S2212-8778(24)00146-7. [Epub ahead of print] 102015
    Loss of mitochondria long-chain fatty acid oxidation impairs skeletal muscle contractility by disrupting myofibril structure and calcium homeostasis.
    Andrea S Pereyra, Regina F Fernandez, Adam Amorese, Jasmine N Castro, Chien-Te Lin, Espen E Spangenburg, Jessica M Ellis.
      Abnormal lipid metabolism in mammalian tissues can be highly deleterious, leading to organ failure. Carnitine Palmitoyltransferase 2 (CPT2) deficiency is an inherited metabolic disorder affecting the liver, heart, and skeletal muscle due to impaired mitochondrial oxidation of long-chain fatty acids (mLCFAO) for energy production. However, the basis of tissue damage in mLCFAO disorders is not fully understood. Mice lacking CPT2 in skeletal muscle (Cpt2Sk-/-) were generated to investigate the nexus between mFAO deficiency and myopathy. Compared to controls, ex-vivo contractile force was reduced by 70% in Cpt2Sk-/- oxidative soleus muscle despite the preserved capacity to couple ATP synthesis to mitochondrial respiration on alternative substrates to long-chain fatty acids. Increased mitochondrial biogenesis, lipid accumulation, and the downregulation of 80% of dystrophin-related and contraction-related proteins severely compromised the structure and function of Cpt2Sk-/- soleus. CPT2 deficiency affected oxidative muscles more than glycolytic ones. Exposing isolated sarcoplasmic reticulum to long-chain acylcarnitines (LCACs) inhibited calcium uptake. In agreement, Cpt2Sk-/- soleus had decreased calcium uptake and significant accumulation of palmitoyl-carnitine, suggesting that LCACs and calcium dyshomeostasis are linked in skeletal muscle. Our data demonstrate that loss of CPT2 and mLCFAO compromise muscle structure and function due to excessive mitochondrial biogenesis, downregulation of the contractile proteome, and disruption of calcium homeostasis.
    Keywords:  CPT2; Calcium; Fatty acid oxidation; Muscle contraction; Palmitoyl-carnitine
    DOI:  https://doi.org/10.1016/j.molmet.2024.102015
  11. J Physiol. 2024 Aug 27.
    HFrEF and HFpEF: are mitochondria at the heart of the matter?
    Amanda Groenewald, Liam Zhang, Amelia S Power.
      
    Keywords:  calcium dynamics; heart failure; mitochondria
    DOI:  https://doi.org/10.1113/JP287344
  12. J Clin Endocrinol Metab. 2024 Aug 28. pii: dgae594. [Epub ahead of print]
    The impact of time-restricted eating on beta-cell function in adults with type 2 diabetes: a randomized cross-over trial.
    Caroline Kaercher Kramer, Bernard Zinman, Denice S Feig, Ravi Retnakaran.
      OBJECTIVE: Time-restricted eating (TRE) which consists of restricting the eating window to typically 4-8h (while fasting for the remaining hours of the day) has been proposed as a non-pharmacological strategy with cardio-metabolic benefits but little is known about its metabolic impact in type 2 diabetes (T2DM). We evaluated whether TRE can improve pancreatic beta-cell function and metabolic status in overweight individuals with early T2DM.RESEARCH DESIGN AND METHODS: In a randomized cross-over trial, 39 participants [mean 2.9 years of diabetes duration, baseline glycated hemoglobin (HbA1c) 6.6% ± 0.7% and body mass index (BMI) 32.4 ± 5.7 kg/m2] were randomized to either an initial intervention consisting of 6-weeks of TRE (20h-fasting/4h-eating) or standard lifestyle. The primary outcome of beta-cell function was assessed by Insulin Secretion-Sensitivity Index-2 (ISSI-2) derived from an oral glucose tolerance test. Trial registration: clinicaltrials.gov NCT05717127.
    RESULTS: As compared to standard lifestyle, TRE induced a 14% increase in ISSI-2 (+14.0 ± 39.2%, p = 0.03) accompanied by 14% reduction of hepatic insulin resistance as evaluated by HOMA-IR [-11.6% (-49.3-21.9), p = 0.03]. Fasting glucose did not differ between interventions, but TRE yielded a significant reduction in HbA1c (-0.32 ± 0.48%, p <0.001). These metabolic improvements were coupled by a reduction of body weight of 3.86% (-3.86 ± 3.1%, p <0.001) and waist circumference of 3.8 cm (-3.8 ± 7.5 cm, p = 0.003).
    CONCLUSION: TRE improved beta-cell function and insulin resistance in overweight patients with early diabetes, accompanied by beneficial effects on adiposity.
    Keywords:  abdominal obesity; beta-cell function; body weight; insulin resistance; intermittent fasting; metabolic health; time-restricted eating; type 2 diabetes
    DOI:  https://doi.org/10.1210/clinem/dgae594
  13. Exp Physiol. 2024 Aug 24.
    Skeletal muscle myosin heavy chain fragmentation as a potential marker of protein degradation in response to resistance training and disuse atrophy.
    Daniel L Plotkin, Madison L Mattingly, Derick A Anglin, J Max Michel, Joshua S Godwin, Mason C McIntosh, Nicholas J Kontos, João G A Bergamasco, Maíra C Scarpelli, Vitor Angleri, Lemuel W Taylor, Darryn S Willoughby, C Brooks Mobley, Andreas N Kavazis, Carlos Ugrinowitsch, Cleiton A Libardi, Michael D Roberts.
      We examined how resistance exercise (RE), cycling exercise and disuse atrophy affect myosin heavy chain (MyHC) protein fragmentation. The 1boutRE study involved younger men (n = 8; 5 ± 2 years of RE experience) performing a lower body RE bout with vastus lateralis (VL) biopsies being obtained prior to and acutely following exercise. With the 10weekRT study, VL biopsies were obtained in 36 younger adults before and 24 h after their first/naïve RE bout. Participants also engaged in 10 weeks of resistance training and donated VL biopsies before and 24 h after their last RE bout. VL biopsies were also examined in an acute cycling study (n = 7) and a study involving 2 weeks of leg immobilization (n = 20). In the 1boutRE study, fragmentation of all MyHC isoforms (MyHCTotal) increased 3 h post-RE (∼200%, P = 0.018) and returned to pre-exercise levels by 6 h post-RE. Interestingly, a greater magnitude increase in MyHC type IIa versus I isoform fragmentation occurred 3 h post-RE (8.6 ± 6.3-fold vs. 2.1 ± 0.7-fold, P = 0.018). In 10weekRT participants, the first/naïve and last RE bouts increased MyHCTotal fragmentation 24 h post-RE (+65% and +36%, P < 0.001); however, the last RE bout response was attenuated compared to the first bout (P = 0.045). Although cycling exercise did not alter MyHCTotal fragmentation, ∼8% VL atrophy with 2 weeks of leg immobilization increased MyHCTotal fragmentation (∼108%, P < 0.001). Mechanistic C2C12 myotube experiments indicated that MyHCTotal fragmentation is likely due to calpain proteases. In summary, RE and disuse atrophy increase MyHC protein fragmentation. Research into how ageing and disease-associated muscle atrophy affect these outcomes is needed. HIGHLIGHTS: What is the central question of this study? How different exercise stressors and disuse affect skeletal muscle myosin heavy chain fragmentation. What is the main finding and its importance? This investigation is the first to demonstrate that resistance exercise and disuse atrophy lead to skeletal muscle myosin heavy chain protein fragmentation in humans. Mechanistic in vitro experiments provide additional evidence that MyHC fragmentation occurs through calpain proteases.
    Keywords:  immunoblotting; myosin heavy chain; proteolysis; resistance exercise; skeletal muscle
    DOI:  https://doi.org/10.1113/EP092093
  14. iScience. 2024 Aug 16. 27(8): 110560
    Mitochondrial translation is the primary determinant of secondary mitochondrial complex I deficiencies.
    Kristýna Čunátová, Marek Vrbacký, Guillermo Puertas-Frias, Lukáš Alán, Marie Vanišová, María José Saucedo-Rodríguez, Josef Houštěk, Erika Fernández-Vizarra, Jiří Neužil, Alena Pecinová, Petr Pecina, Tomáš Mráček.
      Individual complexes of the mitochondrial oxidative phosphorylation system (OXPHOS) are not linked solely by their function; they also share dependencies at the maintenance/assembly level, where one complex depends on the presence of a different individual complex. Despite the relevance of this "interdependence" behavior for mitochondrial diseases, its true nature remains elusive. To understand the mechanism that can explain this phenomenon, we examined the consequences of the aberration of different OXPHOS complexes in human cells. We demonstrate here that the complete disruption of each of the OXPHOS complexes resulted in a decrease in the complex I (cI) level and that the major reason for this is linked to the downregulation of mitochondrial ribosomal proteins. We conclude that the secondary cI defect is due to mitochondrial protein synthesis attenuation, while the responsible signaling pathways could differ based on the origin of the OXPHOS defect.
    Keywords:  Biochemistry; Cell biology; Molecular biology
    DOI:  https://doi.org/10.1016/j.isci.2024.110560
  15. J Cachexia Sarcopenia Muscle. 2024 Aug 26.
    Betaine delays age-related muscle loss by mitigating Mss51-induced impairment in mitochondrial respiration via Yin Yang1.
    Si Chen, Tongtong He, Jiedong Chen, Dongsheng Wen, Chen Wang, Wenge Huang, Zhijun Yang, Mengtao Yang, Mengchu Li, Siyu Huang, Zihui Huang, Huilian Zhu.
      BACKGROUND: Mitochondrial dysfunction is one of the hallmarks of aging and a leading contributor to sarcopenia. Nutrients are essential for improving mitochondrial function and skeletal muscle health during the aging process. Betaine is a nutrient with potential muscle-preserving properties. However, whether and how betaine could regulate the mitochondria function in aging muscle are poorly understood. We aimed to explore the molecular target and underlying mechanism of betaine in attenuating the age-related mitochondrial dysfunction in skeletal muscle.METHODS: Young mice (YOU, 2 months), old mice (OLD, 15 months), and old mice with betaine treatment (BET, 15 months) were fed for 12 weeks. The effects of betaine on muscle mass, strength, function, and subcellular structure of muscle fibres were assessed. RNA sequencing (RNA-seq) was conducted to identify the molecular target of betaine. The impacts of betaine on mitochondrial-related molecules, superoxide accumulation, and oxidative respiration were examined using western blotting (WB), immunofluorescence (IF) and seahorse assay. The underlying mechanism of betaine regulation on the molecular target to maintain mitochondrial function was investigated by luciferase reporter assay, chromatin immunoprecipitation and electrophoretic mobility shift assay. Adenoassociated virus transfection, succinate dehydrogenase staining (SDH), and energy expenditure assessment were performed on 20-month-old mice for validating the mechanism in vivo.
    RESULTS: Betaine intervention demonstrated anti-aging effects on the muscle mass (P = 0.017), strength (P = 0.010), and running distance (P = 0.013). Mitochondrial-related markers (ATP5a, Sdha, and Uqcrc2) were 1.1- to 1.5-fold higher in BET than OLD (all P ≤ 0.036) with less wasted mitochondrial vacuoles accumulating in sarcomere. Bioinformatic analysis from RNA-seq displayed pathways related to mitochondrial respiration activity was higher enriched in BET group (NES = -0.87, FDR = 0.10). The quantitative real time PCR (qRT-PCR) revealed betaine significantly reduced the expression of a novel mitochondrial regulator, Mss51 (-24.9%, P = 0.002). In C2C12 cells, betaine restored the Mss51-mediated suppression in mitochondrial respiration proteins (all P ≤ 0.041), attenuated oxygen consumption impairment, and superoxide accumulation (by 20.7%, P = 0.001). Mechanically, betaine attenuated aging-induced repression in Yy1 mRNA expression (BET vs. OLD: 2.06 vs. 1.02, P = 0.009). Yy1 transcriptionally suppressed Mss51 mRNA expression both in vitro and in vivo. This contributed to the preservation of mitochondrial respiration, improvement for energy expenditure (P = 0.008), and delay of muscle loss during aging process.
    CONCLUSIONS: Altogether, betaine transcriptionally represses Mss51 via Yy1, improving age-related mitochondrial respiration in skeletal muscle. These findings suggest betaine holds promise as a dietary supplement to delay skeletal muscle degeneration and improve age-related mitochondrial diseases.
    Keywords:  Betaine; Mitochondrial dysfunction; Mss51; Muscle loss; Transcription factor; Yin yang1 (Yy1)
    DOI:  https://doi.org/10.1002/jcsm.13558
  16. Essays Biochem. 2024 Aug 28. pii: EBC20240006. [Epub ahead of print]
    Does AMPK bind glycogen in skeletal muscle or is the relationship correlative?
    Barnaby P Frankish, Robyn M Murphy.
      Since its discovery over five decades ago, an emphasis on better understanding the structure and functional role of AMPK has been prevalent. In that time, the role of AMPK as a heterotrimeric enzyme that senses the energy state of various cell types has been established. Skeletal muscle is a dynamic, plastic tissue that adapts to both functional and metabolic demands of the human body, such as muscle contraction or exercise. With a deliberate focus on AMPK in skeletal muscle, this review places a physiological lens to the association of AMPK and glycogen that has been established biochemically. It discusses that, to date, no in vivo association of AMPK with glycogen has been shown and this is not altered with interventions, either by physiological or biochemical utilisation of glycogen in skeletal muscle. The reason for this is likely due to the persistent phosphorylation of Thr148 in the β-subunit of AMPK which prevents AMPK from binding to carbohydrate domains. This review presents the correlative data that suggests AMPK senses glycogen utilisation through a direct interaction with glycogen, the biochemical data showing that AMPK can bind carbohydrate in vitro, and highlights that in a physiological setting of rodent skeletal muscle, AMPK does not directly bind to glycogen.
    Keywords:  AMPK; glycogen; skeletal muscle
    DOI:  https://doi.org/10.1042/EBC20240006
  17. Curr Opin Endocr Metab Res. 2024 Jun;35 100525
    Metabolic small talk during exercise: The role of metabokines and lipokines in interorgan signalling.
    Shaimaa A Gad, Hannah Smith, Lee D Roberts.
      Metabolites in exercise have traditionally been viewed as a fuel source, waste product, or anabolic components required for exercise-induced biosynthetic processes. However, it is now recognised that metabolites and lipids may act as mediators of interorgan crosstalk to coordinate the local and systemic physiological adaptations required to meet the complex system-wide challenge of exercise. These bioactive metabolite and lipid signals have been termed metabokines and lipokines, respectively. There is emerging evidence that metabokines and lipokines contribute to the health benefits of exercise. This review highlights several of the key recent discoveries related to metabokine and lipokine signalling during exercise. The discovery of these metabokines and lipokines, and their signalling targets, may provide the basis of future therapies for human disease.
    Keywords:  Exercise; Interorgan signalling; Lipokine; Metabokine; Metabolism; Metabolite; Skeletal muscle
    DOI:  https://doi.org/10.1016/j.coemr.2024.100525
  18. J Physiol. 2024 Aug 27.
    Madness or progress? The dilemma of standardizing exercise physiology thresholds.
    Billy Sperlich, Thomas Gronwald.
      
    Keywords:  blood lactate; exercise physiology thresholds; metabolic threshold; standaridization; system‐dynamic; threshold; ventilatory threshold
    DOI:  https://doi.org/10.1113/JP287312
  19. Mol Neurobiol. 2024 Aug 28.
    Nutritional Strategies in Major Depression Disorder: From Ketogenic Diet to Modulation of the Microbiota-Gut-Brain Axis.
    Ali Nikdasti, Elaheh Sadat Khodadadi, Felora Ferdosi, Ehsan Dadgostar, Sheida Yahyazadeh, Parasta Heidari, Sajad Ehtiati, Omid Vakili, Seyyed Hossein Khatami.
      Major depressive disorder (MDD) is a leading cause of disability worldwide. While traditional pharmacological treatments are effective for many cases, a significant proportion of patients do not achieve full remission or experience side effects. Nutritional interventions hold promise as an alternative or adjunctive approach, especially for treatment-resistant depression. This review examines the potential role of nutrition in managing MDD through addressing biological deficits and modulating pathways relevant to its pathophysiology. Specifically, it explores the ketogenic diet and gut microbiome modulation through various methods, including probiotics, prebiotics, synbiotics, postbiotics, and fecal microbiota transplantation. Numerous studies link dietary inadequacies to increased MDD risk and deficiencies in nutrients like omega-3 s, vitamins D and B, magnesium, and zinc. These deficiencies impact neurotransmitters, inflammation, and other biological factors in MDD. The gut-brain axis also regulates mood, stress response, and immunity, and disruptions are implicated in MDD. While medications aid acute symptoms, nutritional strategies may improve long-term outcomes by preventing relapse and promoting sustained remission. This comprehensive review aims to provide insights into nutrition's multifaceted relationship with MDD and its potential for developing more effective integrated treatment approaches.
    Keywords:  Diet therapy; Gastrointestinal microbiome; Ketogenic diet; Major depressive disorder (MDD); Nutritional interventions; Therapeutics
    DOI:  https://doi.org/10.1007/s12035-024-04446-4
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