bims-glecem Biomed News
on Glycogen metabolism in exercise, cancer and energy metabolism
Issue of 2022‒08‒28
ten papers selected by
Dipsikha Biswas, Københavns Universitet
  1. A Micro-Scale Analytical Method for Determining Glycogen Turnover by NMR and FTMS.
  2. Comparative transcriptome analysis of diurnal alterations of liver glycogen structure: A pilot study.
  3. Characterization of stenocephol from Seriphidium stenocephalum as potent HepG2 cell growth and glycogen phosphorylase inhibitor.
  4. Skeletal-Muscle-Specific Overexpression of Chrono Leads to Disruption of Glucose Metabolism and Exercise Capacity.
  5. Studies on glycogen storage disease type 1a animal models: a brief perspective.
  6. Fetal Left Ventricular Apical Aneurysm Progressing to Dilated Cardiomyopathy Due to Glycogen Storage Disease.
  7. Dynamics of the Glycogen β-Particle Number in Rat Hepatocytes during Glucose Refeeding.
  8. Deletion of Macrophage-Specific Glycogen Synthase Kinase (GSK)-3α Promotes Atherosclerotic Regression in Ldlr-/- Mice.
  9. Influence of protein corona on the interaction of glycogen-siRNA constructs with ex vivo human blood immune cells.
  10. Fruit Fly in a Challenging Environment: Impact of Short-Term Temperature Stress on the Survival, Development, Reproduction, and Trehalose Metabolism of Bactrocera dorsalis (Diptera: Tephritidae).
  1. Metabolites. 2022 Aug 18. pii: 760. [Epub ahead of print]12(8):
    A Micro-Scale Analytical Method for Determining Glycogen Turnover by NMR and FTMS.
    Timothy L Scott, Juan Zhu, Teresa A Cassel, Sara Vicente-Muñoz, Penghui Lin, Richard M Higashi, Andrew N Lane, Teresa W-M Fan.
      Glycogen is a readily deployed intracellular energy storage macromolecule composed of branched chains of glucose anchored to the protein glycogenin. Although glycogen primarily occurs in the liver and muscle, it is found in most tissues, and its metabolism has been shown to be important in cancers and immune cells. Robust analysis of glycogen turnover requires stable isotope tracing plus a reliable means of quantifying total and labeled glycogen derived from precursors such as 13C6-glucose. Current methods for analyzing glycogen are time- and sample-consuming, at best semi-quantitative, and unable to measure stable isotope enrichment. Here we describe a microscale method for quantifying both intact and acid-hydrolyzed glycogen by ultra-high-resolution Fourier transform mass spectrometric (UHR-FTMS) and/or NMR analysis in stable isotope resolved metabolomics (SIRM) studies. Polar metabolites, including intact glycogen and their 13C positional isotopomer distributions, are first measured in crude biological extracts by high resolution NMR, followed by rapid and efficient acid hydrolysis to glucose under N2 in a focused beam microwave reactor, with subsequent analysis by UHR-FTMS and/or NMR. We optimized the microwave digestion time, temperature, and oxygen purging in terms of recovery versus degradation and found 10 min at 110-115 °C to give >90% recovery. The method was applied to track the fate of 13C6-glucose in primary human lung BEAS-2B cells, human macrophages, murine liver and patient-derived tumor xenograft (PDTX) in vivo, and the fate of 2H7-glucose in ex vivo lung organotypic tissue cultures of a lung cancer patient. We measured the incorporation of 13C6-glucose into glycogen and its metabolic intermediates, UDP-Glucose and glucose-1-phosphate, to demonstrate the utility of the method in tracing glycogen turnover in cells and tissues. The method offers a quantitative, sensitive, and convenient means to analyze glycogen turnover in mg amounts of complex biological materials.
    Keywords:  13C6-glucose; glycogen turnover; microwave-assisted hydrolysis; stable isotope resolved metabolomics (SIRM)
    DOI:  https://doi.org/10.3390/metabo12080760
  2. Carbohydr Polym. 2022 Nov 01. pii: S0144-8617(22)00615-4. [Epub ahead of print]295 119710
    Comparative transcriptome analysis of diurnal alterations of liver glycogen structure: A pilot study.
    Qing-Hua Liu, Zi-Yi Wang, Jia-Wei Tang, Jing-Yi Mou, Zhang-Wen Ma, Bin Deng, Zhao Liu, Liang Wang.
      Molecular mechanisms behind structural alterations between fragile and stable glycogen α particles in liver are not clear yet. In this pilot study, we re-examined the diurnal alterations of glycogen structure from the perspective of liver tissue transcriptome. By comparing the structures of liver glycogen from mice at 12 am, 8 am, 12 pm, and 8 pm (light-on: 6 am; light-off: 6 pm), we re-confirmed that the liver glycogen was fragile at 12 am and 8 am and stable at 12 pm and 8 pm as previously reported. The structural differences of glycogen particles at 12 am and 12 pm were thoroughly compared via transcriptomics. Differentially expressed genes (DEGs) with statistical significance were identified, while expression level of the gene ppp1r3g (log2Fold_Change = -6.368, P-value = 2.89E-04) that encoded PPP1R3G with glycogen binding domain was most significantly changed, which provided preliminary clues to the structural alterations of glycogen α particles during the diurnal cycle.
    Keywords:  Circadian rhythm; DEG; Diabetes; Glycogen; Transcriptome
    DOI:  https://doi.org/10.1016/j.carbpol.2022.119710
  3. Nat Prod Res. 2022 Aug 25. 1-7
    Characterization of stenocephol from Seriphidium stenocephalum as potent HepG2 cell growth and glycogen phosphorylase inhibitor.
    Nusrat Shafiq, Uzma Arshad, Simone Brogi, Maryam Rashid, Naila Rafiq, Shagufta Parveen.
      Plant-derived compounds represent an important source for developing innovative drugs. One of the widely distributed plants, especially in Afghanistan and Pakistan, Seriphidium stenocephalum, was investigated in this study to identify bioactive compounds. The plant extract was subjected to silica gel column chromatography, four phenolic acid derivatives were isolated, while stenocephol was obtained by ethyl acetate fraction. Stenocephol was subjected to experimental screening for anti-diabetic and anti-cancer activities, measuring its inhibitory potency against glycogen phosphorylase, and its cytotoxicity against HepG2 cells. Further insights into the mechanism of action of stenocephol were obtained from a computational investigation. Stenocephol showed a dose-dependent manner of inhibition against glycogen phosphorylase and HepG2 cells in the low micromolar range. Notably, coupling in vitro and computational investigation, we identified the natural product stenocephol as a possible anti-diabetic and anti-cancer agent, representing a possible starting point for developing novel therapeutics, enriching the armamentarium against the mentioned diseases.
    Keywords:  HepG2 cells; Seriphidium stenocephalum; anti-diabetic activity; anticancer activity; glycogen phosphorylase inhibition; molecular modeling; stenocephol
    DOI:  https://doi.org/10.1080/14786419.2022.2117177
  4. Life (Basel). 2022 Aug 15. pii: 1233. [Epub ahead of print]12(8):
    Skeletal-Muscle-Specific Overexpression of Chrono Leads to Disruption of Glucose Metabolism and Exercise Capacity.
    Shiyi He, Lu Yan, Rongxin Zhu, Hao Wei, Jianxiong Wang, Lan Zheng, Ying Zhang.
      Disruption of circadian rhythms is related to disorders of glucose metabolism, and the molecular clock also exists in skeletal muscle. The ChIP-derived repressor of network oscillator (Chrono) and brain and muscle ARNT-like 1 (Bmal1) are core circadian components. Chrono is considered to be the repressor of Bmal1, and the Chrono-Bmal1 pathway is important in regulating the circadian rhythm; it has been speculated that this pathway could be a new mechanism for regulating glucose metabolism. The purpose of this study was to investigate the effects of Chrono on glucose metabolism in skeletal muscle and exercise capacity by using mice with skeletal-muscle-specific overexpression of Chrono (Chrono TG) and wild-type (WT) mice as the animal models. The results of this cross-sectional study indicated that the Chrono TG mice had an impaired glucose tolerance, lower exercise capacity, and higher levels of nonfasted blood glucose and glycogen content in skeletal muscle compared to WT mice. In addition, the Chrono TG mice also showed a significant increase in the amount of Chrono bound to Bmal1 according to a co-IP analysis; a remarkable decrease in mRNA expression of Tbc1d1, Glut4, Hk2, Pfkm, Pdp1, Gbe1, and Phka1, as well as in activity of Hk and protein expression of Ldhb; but higher mRNA expression of Pdk4 and protein expression of Ldha compared with those of WT mice. These data suggested the skeletal-muscle-specific overexpression of Chrono led to a greater amount of Chrono bound to Bmal1, which then could affect the glucose transporter, glucose oxidation, and glycogen utilization in skeletal muscle, as well as exercise capacity.
    Keywords:  Chrono; exercise capacity; glucose metabolism; mice; skeletal muscle
    DOI:  https://doi.org/10.3390/life12081233
  5. Transgenic Res. 2022 Aug 25.
    Studies on glycogen storage disease type 1a animal models: a brief perspective.
    Irina O Petrova, Svetlana A Smirnikhina.
      Glycogen storage disease type 1 (GSD1) is a rare hereditary monogenic disease characterized by the disturbed glucose metabolism. The most widespread variant of GSD1 is GSD1a, which is a deficiency of glucose-6-phosphatase-ɑ. Glucose-6-phosphatase-ɑ is expressed only in liver, kidney, and intestine, and these organs are primarily affected by its deficiency, and long-term complications of GSD1a include hepatic tumors and chronic liver disease. This article is a brief overview of existing animal models for GSD1a, from the first mouse model of 1996 to modern CRISPR/Cas9-generated ones. First whole-body murine models demonstrated exact metabolic symptoms of GSD1a, but the animals did not survive weaning. The protocol for glucose treatment allowed prolonged survival of affected animals, but long-term complications, such as hepatic tumorigenesis, could not be investigated. Next, organ-specific knockout models were developed, and most of the metabolic research was performed on liver glucose-6-phosphate-deficient mice. Naturally occuring mutation was also discovered in dogs. All these models are widely used to study GSD1a from metabolic and physiological standpoints and to develop possible treatments involving gene therapy. Research performed using these models helped elucidate the role of glycogen and lipid accumulation, hypoxia, mitochondrial dysfunction, and autophagy impairment in long-term complications of GSD1a, including hepatic tumorigenesis. Recently, gene replacement therapy and genome editing were tested on described models, and some of the developed approaches have reached clinical trials.
    Keywords:  Autophagy; Gene therapy; Genome editing; Glucose-6 phosphatase-ɑ; Organ-specific model
    DOI:  https://doi.org/10.1007/s11248-022-00325-7
  6. Tex Heart Inst J. 2022 Sep 01. pii: e207364. [Epub ahead of print]49(4):
    Fetal Left Ventricular Apical Aneurysm Progressing to Dilated Cardiomyopathy Due to Glycogen Storage Disease.
    Geetha Challapudi, Gerard J Boyle, E Rene Rodriguez, Rukmini Komarlu.
      Fetal dilated cardiomyopathy is a rare anomaly characterized by ventricular dilation and dysfunction. Its causes are diverse, and its outcomes are generally dismal. We describe a rare case of prenatally diagnosed left ventricular apical aneurysm that progressed rapidly to dilated cardiomyopathy. At age 2 months, the infant underwent heart transplantation. Pathologic examination of the explanted heart revealed that the cause of the dilated cardiomyopathy was glycogen storage disease. This case highlights the crucial roles of timely diagnosis, frequent close monitoring, and multidisciplinary care in achieving a successful postnatal outcome.
    Keywords:  Cardiomyopathy, dilated/diagnosis; delivery rooms/organization & administration; fetal diseases/diagnosis/diagnostic imaging/etiology/pathology/physiopathology; glycogen storage disease; heart ventricles; infant, newborn; prenatal diagnosis; treatment outcome; ultrasonography, prenatal
    DOI:  https://doi.org/10.14503/THIJ-20-7364
  7. Int J Mol Sci. 2022 Aug 17. pii: 9263. [Epub ahead of print]23(16):
    Dynamics of the Glycogen β-Particle Number in Rat Hepatocytes during Glucose Refeeding.
    Natalia N Bezborodkina, Andrei V Stepanov, Mikhail L Vorobev, Grigory I Stein, Sergey V Okovityi, Boris N Kudryavtsev.
      Glycogen is an easily accessible source of energy for various processes. In hepatocytes, it can be found in the form of individual molecules (β-particles) and their agglomerates (α-particles). The glycogen content in hepatocytes depends on the physiological state and can vary due to the size and number of the particles. Using biochemical, cytofluorometric, interferometric and morphometric methods, the number of β-particles in rat hepatocytes was determined after 48 h of fasting at different time intervals after glucose refeeding. It has been shown that after starvation, hepatocytes contain ~1.6 × 108 β-particles. During refeeding, their number of hepatocytes gradually increases and reaches a maximum (~5.9 × 108) at 45 min after glucose administration, but then quickly decreases. The data obtained suggest that in cells there is a continuous synthesis and degradation of particles, and at different stages of life, one or another process predominates. It has been suggested that in the course of glycogenesis, pre-existing β-particles are replaced by those formed de novo. The main contribution to the deposition of glycogen is made by an increase in the glucose residue number in its molecules. The average diameter of β-particles of glycogen during glycogenesis increases from ~11 nm to 21 nm.
    Keywords:  glucose; glycogen; rat hepatocytes; refeeding; β-particles
    DOI:  https://doi.org/10.3390/ijms23169263
  8. Int J Mol Sci. 2022 Aug 18. pii: 9293. [Epub ahead of print]23(16):
    Deletion of Macrophage-Specific Glycogen Synthase Kinase (GSK)-3α Promotes Atherosclerotic Regression in Ldlr-/- Mice.
    Sarvatit Patel, Lauren Mastrogiacomo, Madison Fulmer, Yuanyuan Shi, Geoff H Werstuck.
      Recent evidence from our laboratory suggests that impeding ER stress-GSK3α/β signaling attenuates the progression and development of atherosclerosis in mouse model systems. The objective of this study was to determine if the tissue-specific genetic ablation of GSK3α/β could promote the regression of established atherosclerotic plaques. Five-week-old low-density lipoprotein receptor knockout (Ldlr-/-) mice were fed a high-fat diet for 16 weeks to promote atherosclerotic lesion formation. Mice were then injected with tamoxifen to induce macrophage-specific GSK3α/β deletion, and switched to standard diet for 12 weeks. All mice were sacrificed at 33 weeks of age and atherosclerosis was quantified and characterized. Female mice with induced macrophage-specific GSK3α deficiency, but not GSK3β deficiency, had reduced plaque volume (~25%) and necrosis (~40%) in the aortic sinus, compared to baseline mice. Atherosclerosis was also significantly reduced (~60%) in the descending aorta. Macrophage-specific GSK3α-deficient mice showed indications of increased plaque stability and reduced inflammation in plaques, as well as increased CCR7 and ABCA1 expression in lesional macrophages, consistent with regressive plaques. These results suggest that GSK3α ablation promotes atherosclerotic plaque regression and identify GSK3α as a potential target for the development of new therapies to treat existing atherosclerotic lesions in patients with cardiovascular disease.
    Keywords:  atherosclerosis; glycogen synthase kinase (GSK)-3α/β; inflammation; macrophages; mice model; migration; regression; reverse cholesterol transport
    DOI:  https://doi.org/10.3390/ijms23169293
  9. Biomater Adv. 2022 Aug 18. pii: S2772-9508(22)00360-0. [Epub ahead of print]140 213083
    Influence of protein corona on the interaction of glycogen-siRNA constructs with ex vivo human blood immune cells.
    Marcin Wojnilowicz, Petra Laznickova, Yi Ju, Ching-Seng Ang, Federico Tidu, Kamila Bendickova, Giancarlo Forte, Magdalena Plebanski, Frank Caruso, Francesca Cavalieri, Jan Fric.
      Glycogen-nucleic acid constructs i.e., glycoplexes are emerging promising platforms for the alteration of gene expression and transcription. Understanding the interaction of glycoplexes with human blood components, such as serum proteins and peripheral blood mononuclear cells (PBMCs), is important to overcome immune cell activation and control biodistribution upon administration of the glycoplexes in vivo. Herein, we investigated the interactions of polyethylene glycol (PEG)ylated and non-PEGylated glycoplexes carrying siRNA molecules with PBMCs isolated from the blood of healthy donors. We found that both types of glycoplexes were non-toxic and were primarily phagocytosed by monocytes without triggering a pro-inflammatory interleukin 6 cytokine production. Furthermore, we investigated the role of the protein corona on controlling the internalization efficiency in immune cells - we found that the adsorption of serum proteins, in particular haptoglobin, alpha-1-antitrypsin and apolipoprotein A-II, onto the non-PEGylated glycoplexes, significantly reduced the uptake of the glycoplexes by PBMCs. Moreover, the non-PEGylated glycoplexes were efficient in the nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) knockdown in monocytic THP-1 cell line. This study provides an insight into the rational design of glycogen-based nanocarriers for the safe delivery of siRNA without eliciting unwanted immune cell activation and efficient siRNA activity upon its delivery.
    Keywords:  Glycogen nanoparticles; Peripheral blood mononuclear cells; Phagocytosis; Protein corona; Stochastic optical reconstruction microscopy; THP-1; siRNA glycoplexes
    DOI:  https://doi.org/10.1016/j.bioadv.2022.213083
  10. Insects. 2022 Aug 22. pii: 753. [Epub ahead of print]13(8):
    Fruit Fly in a Challenging Environment: Impact of Short-Term Temperature Stress on the Survival, Development, Reproduction, and Trehalose Metabolism of Bactrocera dorsalis (Diptera: Tephritidae).
    Chun Yu, Runa Zhao, Wei Zhou, Yingna Pan, Hui Tian, Zhengyan Yin, Wenlong Chen.
      An understanding of physiological damage and population development caused by uncomfortable temperature plays an important role in pest control. In order to clarify the adaptability of different temperatures and physiological response mechanism of B. dorsalis, we focused on the adaptation ability of this pest to environmental stress from physiological and ecological viewpoints. In this study, we explored the relationship between population parameters and glucose, glycogen, trehalose, and trehalose-6-phosphate synthase responses to high and low temperatures. Compared with the control group, temperature stress delayed the development duration of all stages, and the survival rates and longevity decreased gradually as temperature decreased to 0 °C and increased to 36 °C. Furthermore, with low temperature decrease from 10 °C to 0 °C, the average fecundity per female increased at 10 °C but decreased later. Reproduction of the species was negatively affected during high-temperature stresses, reaching the lowest value at 36 °C. In addition to significantly affecting biological characteristics, temperature stress influenced physiological changes of B. dorsalis in cold and heat tolerance. When temperature deviated significantly from the norm, the levels of substances associated with temperature resistance were altered: glucose, trehalose, and TPS levels increased, but glycogen levels decreased. These results suggest that temperature stresses exert a detrimental effect on the populations' survival, but the metabolism of trehalose and glycogen may enhance the pest's temperature resistance.
    Keywords:  glycogen; growth and development; temperature tolerance; trehalose
    DOI:  https://doi.org/10.3390/insects13080753
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