Beyond energy storage: roles of glycogen metabolism in health and disease.

Beyond storing and supplying energy in the liver and muscles, glycogen also plays critical roles in cell differentiation, signaling, redox regulation, and stemness under various physiological and pathophysiological conditions. Such versatile functions have been revealed by various forms of glycogen storage diseases. Here, we outline the source of carbon flux in glycogen metabolism and discuss how glycogen metabolism guides CD8+ T-cell memory formation and maintenance. Likewise, we review how this affects macrophage polarization and inflammatory responses. Furthermore, we dissect how glycogen metabolism supports tumor development by promoting tumor-repopulating cell growth in hypoxic tumor microenvironments. This review highlights the essential role of the gluconeogenesis-glycogenesis-glycogenolysis-PPP metabolic chain in redox homeostasis, thus providing insights into potential therapeutic strategies against major chronic diseases including cancer.

Regional Distribution of Glycogen in the Mouse Brain Visualized by Immunohistochemistry.

Considering that the brain constantly consumes a substantial amount of energy, the nature of its energy reserve is an important issue. Although the brain is rich in lipid content encompassing membranes, myelin sheath, and astrocytic lipid droplets, it is devoid of adipose tissue which serves as an energy reserve. Notably, glycogen represents the major energy store in the brain. While glycogen has been observed mainly in astrocytes for decades by electron microscopy, glycogen distribution in the brain has only been partially documented. The involvement of glycogen metabolism in memory consolidation, demonstrated by several research groups, has reiterated the functional significance of this macromolecule and the need for description of its comprehensive distribution in the brain. The combination of focused microwave-assisted brain fixation and glycogen immunohistochemistry permits assessment of glycogen distribution in the rodent brain. In this article, we describe glycogen distribution in the mouse brain using glycogen immunohistochemistry. We find heterogeneous glycogen storage patterns at multiple spatial scales. The heterogeneous glycogen distribution patterns may underlie local energy metabolism or synaptic activity, and its mechanistic understanding should extend our knowledge on brain metabolism in health and disease.

Akkermansia muciniphila can reduce the damage of gluco/lipotoxicity, oxidative stress and inflammation, and normalize intestine microbiota in streptozotocin-induced diabetic rats.

This study aimed to investigate how Akkermansia muciniphila can implicate type 2 diabetes mellitus and the mechanisms underlying the effects A. muciniphila on type 2 diabetes mellitus. Normal and streptozotocin-induced diabetic Sprague-Dawley rats were orally administered with A. muciniphila and solvent. After 4 weeks of treatment, diabetic rats orally administered with live or pasteurized A. muciniphila exhibited significant increase in the blood concentration of high-density lipoprotein, and decrease in the hepatic glycogen, serum plasminogen activator inhibitor-1, tumor necrosis factor-α, lipopolysaccharide, malondialdehyde and total glucagon-like peptide-1. Moreover, diabetic rats orally administered with A. muciniphila showed significantly increased species alpha diversity and gene function in gut microbes. These results indicated that A. muciniphila can improve liver function, reduce gluco/lipotoxicity, alleviate oxidative stress, suppress inflammation and normalize intestine microbiota of the host animal, thereby ameliorating type 2 diabetes mellitus. Akkermansia muciniphila might be considered as one of the ideal new probiotics used in the management of type 2 diabetes mellitus in future.

A Pck1-directed glycogen metabolic program regulates formation and maintenance of memory CD8+ T cells.

CD8+ memory T (Tm) cells are fundamental for protective immunity against infections and cancers 1-5 . Metabolic activities are crucial in controlling memory T-cell homeostasis, but mechanisms linking metabolic signals to memory formation and survival remain elusive. Here we show that CD8+ Tm cells markedly upregulate cytosolic phosphoenolpyruvate carboxykinase (Pck1), the hub molecule regulating glycolysis, tricarboxylic acid cycle and gluconeogenesis, to increase glycogenesis via gluconeogenesis. The resultant glycogen is then channelled to glycogenolysis to generate glucose-6-phosphate and the subsequent pentose phosphate pathway (PPP) that generates abundant NADPH, ensuring high levels of reduced glutathione in Tm cells. Abrogation of Pck1-glycogen-PPP decreases GSH/GSSG ratios and increases levels of reactive oxygen species (ROS), leading to impairment of CD8+ Tm formation and maintenance. Importantly, this metabolic regulatory mechanism could be readily translated into more efficient T-cell immunotherapy in mouse tumour models.

Development of novel monoclonal antibodies against starch and ulvan - implications for antibody production against polysaccharides with limited immunogenicity.

Monoclonal antibodies (mAbs) are widely used and powerful research tools, but the generation of mAbs against glycan epitopes is generally more problematic than against proteins. This is especially significant for research on polysaccharide-rich land plants and algae (Viridiplantae). Most antibody production is based on using single antigens, however, there are significant gaps in the current repertoire of mAbs against some glycan targets with low immunogenicity. We approached mAb production in a different way and immunised with a complex mixture of polysaccharides. The multiplexed screening capability of carbohydrate microarrays was then exploited to deconvolute the specificities of individual mAbs. Using this strategy, we generated a set of novel mAbs, including one against starch (INCh1) and one against ulvan (INCh2). These polysaccharides are important storage and structural polymers respectively, but both are generally considered as having limited immunogenicity. INCh1 and INCh2 therefore represent important new molecular probes for Viridiplantae research. Moreover, since the α-(1-4)-glucan epitope recognised by INCh1 is also a component of glycogen, this mAb can also be used in mammalian systems. We describe the detailed characterisation of INCh1 and INCh2, and discuss the potential of a non-directed mass-screening approach for mAb production against some glycan targets.

The impact of sleeping with reduced glycogen stores on immunity and sleep in triathletes.

PURPOSE: We investigated the effects of a 3-week dietary periodization on immunity and sleep in triathletes. METHODS: 21 triathletes were divided into two groups with different nutritional guidelines during a 3-week endurance training program including nine twice a day sessions with lowered (SL group) or maintained (CON group) glycogen availability during the overnight recovery period. In addition to performance tests, sleep was monitored every night. Systemic and mucosal immune parameters as well as the incidence of URTI were monitored every week of the training/nutrition protocol. Two-ways ANOVA and effect sizes were used to examine differences in dependent variables between groups at each time point. RESULTS: The SL group significantly improved 10 km running performance (-1 min 13 s, P < 0.01, d = 0.38), whereas no improvement was recorded in the CON group (-2 s, NS). No significant changes in white blood cells counts, plasma cortisol and IL-6 were recorded over the protocol in both groups. The vitamin D status decreased in similar proportions between groups, whereas salivary IgA decreased in the SL group only (P < 0.05, d = 0.23). The incidence of URTI was not altered in both groups. All participants in both groups went to bed earlier during the training program (SL -20 min, CON -27 min, P < 0.05, d = 0.28). In the SL group, only sleep efficiency slightly decreased by 1.1 % (P < 0.05, d = 0.25) and the fragmentation index tended to increase at the end of the protocol (P = 0.06). CONCLUSION: Sleeping and training the next morning regularly with reduced glycogen availability has minimal effects on selected markers of immunity, the incidence of URTI and sleeping patterns in trained athletes.

A murine monoclonal antibody to glycogen: characterization of epitope-fine specificity by saturation transfer difference (STD) NMR spectroscopy and its use in mycobacterial capsular α-glucan research.

Mycobacterium tuberculosis, the causative agent of tuberculosis (TB), is a major pathogen responsible for 1.5 million deaths annually. This bacterium is characterized by a highly unusual and impermeable cell envelope, which plays a key role in mycobacterial survival and virulence. Although many studies have focused on the composition and functioning of the mycobacterial cell envelope, the capsular α-glucan has received relatively minor attention. Here we show that a murine monoclonal antibody (Mab) directed against glycogen cross-reacts with mycobacterial α-glucans, polymers of α(1-4)-linked glucose residues with α(1-6)-branch points. We identified the Mab epitope specificity by saturation transfer difference NMR and show that the α(1-4)-linked glucose residues are important in glucan-Mab interaction. The minimal epitope is formed by (linear) maltotriose. Notably, a Mycobacterium mutant lacking the branching enzyme GlgB does not react with the Mab; this suggests that the α(1-6)-branches form part of the epitope. These seemingly conflicting data can be explained by the fact that in the mutant the linear form of the α-glucan (amylose) is insoluble. This Mab was subsequently used to develop several techniques helpful in capsular α-glucan research. By using a capsular glucan-screening methodology based on this Mab we were able to identify several unknown genes involved in capsular α-glucan biogenesis. Additionally, we developed two methods for the detection of capsular α-glucan levels. This study therefore opens new ways to study capsular α-glucan and to identify possible targets for further research.

The (1->6)-ß-glucan moiety represents a cross-reactive epitope of infection-induced malignancy surveillance.

Exposure to pathogen-associated molecular patterns (PAMPs) by vaccination or infection is known to have beneficial effects on neoplastic diseases, although the underlying molecular mechanisms are so far unclear. In this article, we report that Abs against (1→6)-ß-d-glucan, a typical microbial PAMP and a major target for high titer circulating natural Abs in healthy human subjects, cross-recognize a novel tumor-associated carbohydrate Ag on cancer cells. The (1→6)-ß-glucan cross-reactive moiety is immunologically dominant in tumor cells, as C57BL/6 mice harboring EL-4 solid tumors produced anti-(1→6)-ß-glucan Abs and the titer of which significantly correlated with enhanced survival and smaller tumor burden. Moreover, the (1→6)-ß-glucan-specific Abs exhibited potent tumoricidal activities in vitro. C57BL/6 mice immunized with Candida albicans produced protective immunity against inoculated EL-4 tumors, which was attributed to the formation of (1→6)-ß-glucan-specific Abs. Importantly, (1→6)-ß-glucan-specific Abs significantly prolonged the survival and reduced the tumor size in mice inoculated with EL-4 tumors. Our results demonstrate that the (1→6)-ß-glucan cross-reactive moiety represents a focal point between infection immunity and cancer surveillance, and natural Abs against this epitope may contribute to the first-line antitumor surveillance in humans. Our data also provide important explanation for the long-observed relationship between feverish infection and concurrent remission from cancer.

Comparative analysis of carbohydrate-binding specificities of two anti-glycogen monoclonal antibodies using ELISA and surface plasmon resonance.

For immunological experiments on glycogens, anti-glycogen antibodies are indispensable to capture, detect, and visualize sugar molecules. An anti-glycogen monoclonal antibody (IV58B6) and newly constructed antibody (ESG1A9mAb) have a common immunoglobulin type (IgM) and binding ability to glycogens, but overall possess different binding features. Therefore, they may prove useful for the construction of an advanced system of quantitative ELISA based on their molecular structures. For this purpose, detailed information on the carbohydrate-specificities of ESG1A9mAb and IV58B6 is first required, but their fine specificities for various types of glycogens have not been elucidated. To overcome this problem, we performed interaction analysis by ELISA of ESG1A9mAb and IV58B6 toward 15 glucose polymers, that is, 5 enzymatically-synthesized glycogens (ESGs), 6 natural source glycogens (NSGs), 3 enzymatically digested glycogens (EDGs), and soluble starch. To provide a more detailed analysis, we determined the association constants (K(a)) of the two antibodies toward these glycogens by surface plasmon resonance. The results indicated that the carbohydrate-binding properties toward NSGs of ESG1A9mAb and IV58B6 were similar, but markedly differed for ESGs and EDGs. ESG1A9mAb showed significant affinity for all the ESGs and NSGs tested, whereas IV58B6 had only slight affinity for ESGs, although the affinities were increased when the ESGs were enzymatically digested. This information should be helpful for the design of both in vitro and in vivo immunological assays.

[Indices of immune reactivity of sportsmen organism after one time physical load of different intensity and duration].

The aim of this research was to determine and to compare the indices of immune reactivity of sportsmen during one time physical load of different intensity and duration. Observation was carried out on 15 wrestlers of average qualification during the annual cycle after three one time physical loadings of different intensity and duration (15 sec.-maximum intensity; 60 sec.-maximum intensity; stepped growth loading), spontaneous rosette-formation, G.A.M.- concentration of immunoglobulin, neutrophil/lymphocyte ratio were determined. Immune reactivity of organism was decreasing after one time physical load. Expressed dependence of the sportsmen organism upon the duration and intensity of one time physical loadings was not revealed.

"Fluorescent glycogen" formation with sensibility for in vivo and in vitro detection.

There are presently many methods of detecting complex carbohydrates, and particularly glycogen. However most of them require radioisotopes or destruction of the tissue and hydrolysis of glycogen to glucose. Here we present a new method based on the incorporation of 2-NBDG (2-{N-[7-nitrobenz-2-oxa-1, 3-diazol 4-yl] amino}-2-deoxyglucose), a D-glucose fluorescent derivative, into glycogen. Two kinds of approaches were carried out by using Clone 9 rat hepatocytes as a cellular model; (1) Incubation of cell lysates with 2-NBDG, carbohydrate precipitation in filters and measurement of fluorescence in a microplate reader (2) Incubation of living hepatocytes with 2-NBDG and recording of fluorescence images by confocal microscopy. 2-NBDG labeled glycogen in both approaches. We confirmed this fact by comparison to the labeling obtained with a specific monoclonal anti-glycogen antibody. Also drugs that trigger glycogen synthesis or degradation induced an increase or decrease of fluorescence, respectively. This is a simple but efficient method of detecting glycogen with 2-NBDG. It could be used to record changes in glycogen stores in living cells and cell-free systems and opens the prospect of understanding the role of this important energy reserve under various physiological and pathophysiological conditions.

Relationship between structure and immunostimulating activity of enzymatically synthesized glycogen.

Glycogen acts as energy and carbon reserves in animal cells and in microorganisms. Although anti-tumor activity has recently been reported for shellfish glycogen and enzymatically synthesized glycogen, the activity of glycogen has not yet been fully clarified. We enzymatically prepared various sizes of glycogens with controlled structures to investigate the relationship between the structure and immunostimulating activity of glycogen. The results revealed that glycogens with a weight-average molecular weight (M(w)) of more than 10,000K hardly activated RAW264.7, a murine macrophage cell line, whereas glycogens of M(w) 5000K and 6500K strongly stimulated RAW264.7 in the presence of interferon-gamma (IFN-gamma), leading to augmented production of nitric oxide (NO), tumor necrosis factor-alpha (TNF-alpha), and interleukin-6 (IL-6). Comparing the fine structure of the glycogens, the average-number of chain length, as well as the exterior and the interior chain lengths of the glycogens, had minor correlation between active and less-active glycogen derivatives. The available evidence suggests that the macrophage-stimulating activity of glycogen is strictly related to its molecular weight rather than to any fine structural property.

In vivo biodegradability and biocompatibility of porcine type I atelocollagen newly crosslinked by oxidized glycogen.

Oxidized glycogen is used as a collagen crosslinker to prepare materials with defined crosslinking rates. Thus, films are prepared from native or denatured porcine type I atelocollagen crosslinked with three crosslinking levels defined by the ratios between the aldehyde groups of the glycogen and the amino groups of the collagen. The remaining free aldehyde groups and the imine bonds formed in the reaction are subsequently reduced or not. All the materials are subjected to in vivo biocompatibility and biodegradability evaluations by subcutaneous implantation in mice, while immunogenicity is evaluated by rabbit immunizations. As a result, cellular reactions on the implantation site are more important with nonreduced materials, and biodegradability is correlated to the structural integrity of the collagen molecule, the crosslinking rate and the reduction state of the material. No immunological reaction or calcification is detected in our in vivo experimental model. This new method for collagen crosslinking using oxidized glycogen as a crosslinking agent enables the obtention of reproducible and biocompatible materials with a large scale of biodegradability, starting from 28 days to more than 7 months.

A comparative ontogenic study of urinary bladder: impact of the epithelial differentiation in embryonic and newborn rats.

The present study aimed to show the cellular and subcellular distribution of glycogen content during the differentiation of urothelial cells from simple cuboidal to stratified transitional epithelium. Bladder samples were taken from rat embryos on the 15th to 19th days and newborn at 21st day. During the development of the bladder, the formation of fusiform vesicles, asymmetric unit membrane (AUM) and microridges were examined with staining with haematoxylin-eosin and periodic acid Schiff for light microscope and periodic acid-thiocharbohydrazide-silver proteinate for transmission electron microscope. The topographical changes of luminal differentiation were examined with the scanning electron microscope. The urothelium was simple cuboidal from 15th till the 17th days of gestation. Glycogen content was present in the cytoplasm till the 18th day of gestation. At the early stage (16th day) of gestation, the apical surface contains microvilli that points the undifferentiated cells. The density of microvilli decreased and ropy microridges appeared at the 17th day of gestation. The small discoid vesicles lined with AUM developed at the apical cytoplasm of the surface cells at the 17th day of gestation. After this stage, both the density of microridges and large and elongated fusiform vesicles increased. The differentiation of the urothelium begins with the formation of the round and small vesicles, continues with the formation of the AUM and at the final stage there is a decrease in both glycogen content and the appearance of the microridges at the luminal surface of the urothelial cells.

Dual role of polymorphonuclear neutrophils on the growth of Ehrlich ascites tumor (EAT) in mice.

We show that granulocytes (PMN) have a dual role in the development of Ehrlich Ascites Tumor (EAT) in mice. EAT intraperitoneal inoculation causes a local inflammatory reaction, ascites development and mortality that distinguish resistant and susceptible strains. In resistant mice (CAF1), there is a less pronounced PMN influx after EAT inoculation than in susceptible Swiss mice. Accordingly, the increase in peritoneal PMN numbers enhanced tumor growth in CAF1 mice, but had no effect in the susceptible Swiss animals. Contrastingly, PMN depletion had no effect in resistant mice but facilitated tumor growth in susceptible animals. Though no differences were noted between the strains in peritoneal cell spreading and hydrogen peroxide release after tumor inoculation, in vitro PMN cytotoxic activity against EAT was significantly higher in susceptible Swiss mice. These data indicate a paradoxical dual role for PMN against EAT: while they help control tumor development in susceptible animals, they seem to enhance tumor growth in resistant mice.

Glucan is a component of the Mycobacterium tuberculosis surface that is expressed in vitro and in vivo.

The outermost layer of Mycobacterium tuberculosis is composed primarily of two polysaccharides, glucan (GC) and arabinomannan. To analyze the surface polysaccharide composition of M. tuberculosis, we generated a monoclonal antibody (MAb) that binds M. tuberculosis GC and is known as MAb 24c5. Immunofluorescence and whole-mount immunoelectron microscopy indicated that GC is on the outermost portion of the bacteria. M. tuberculosis strains Erdman and CDC 1551 were analyzed for their ability to bind MAb 24c5 after in vitro growth in media with and without the detergent Tween 80. MAb 24c5 bound to Erdman and CDC 1551 at all culture times with only slightly greater apparent affinity after extended culture in the absence of Tween 80, indicating that a stable amount of GC polysaccharide antigen is associated with the cell surface of M. tuberculosis. An enzyme-linked immunosorbent assay indicated that GC is antigenically similar to glycogen, and the amount of GC antigen increased in the media of M. tuberculosis cultures grown either with or without the detergent Tween 80. Other nontuberculosis mycobacteria have antigenically similar GCs on their surfaces after in vitro growth. Inoculation of mice with live bacilli but not inoculation with dead bacilli elicited a strong antibody response to GC consistent with production of this antigen in vivo. Our results provide a more comprehensive picture of the M. tuberculosis cell envelope and the conditions that allow expression of M. tuberculosis GC.

[Production of monoclonal antibody that recognizes glycogen and its application for immunohistochemistry].

In this study, I made a monoclonal antibody, using the mandibular condylar cartilage as antigen. By light microscopic immunocytochemical observations, this antibody reacted with the chondrocytes both in the mandibular condyle and the costal cartilage, hepatocytes and skeletal muscle cells. By electron microscopic immunocytochemical observations, reaction products (gold particles) were seen on the glycogen particles in the chondrocytes. Further, by dot blotting assay, this antibody was found to react directly with the purified glycogen. Meanwhile, all these reactions disappeared after alpha-amylase digestion. These results indicate that this antibody specifically recognizes glycogen or glycogen-related sugar chains. Therefore, I think that this antibody is very much useful for detecting the glycogen instead of the PAS reaction, since PAS reaction is not a specific method to detect the glycogen.

A spectrum of antibody response with time after Trichinella spiralis infection in rats.

A chronology of class-specific antibody response against the Trichinella spiralis infection in Fischer rats was investigated. G-class antibodies against the cuticle inner layer(s), hypodermis, hemolymph, glycogen aggregates, discrete areas in genital primordial cells, intestinal gland cell granules, and cytoplasmic granules in the cords were detectable 2 wk after infection (the rapid-responding group), whereas G-class antibodies against the cuticle surface, stichocyte granules, and the esophagus-occupying substance were detected 6 wk after infection (the slow-responding group). M-class antibodies recognized a narrower spectrum of antigens than did G-class antibodies; M-class antibodies against hemolymph, cord granules, and intestinal gland cell granules were not detectable. M-class antibodies tended to decrease in titer with time after infection. This tendency was more striking with antibodies against the rapid-responding group than with those against the slow-responding group. This information sheds light upon antibody response against many antigenic components of T. spiralis muscle larvae.

Cortical granule-specific components are present within oocytes and accessory cells during sea urchin oogenesis.

The coordinate expression of cortical granule-specific components in sea urchin oogenesis was studied using antibody probes. The components used to generate the organelle-specific antibodies included the whole cortical granule exudate, fertilization envelopes, hyalin, beta, 1-3,glucanase, and Ig8. Using immunolocalization techniques at both the light and electron microscopic levels, these molecules were found to be specific to cortical granules in three distinct cell types: developing oocytes, eggs, and accessory cells. In early oocytes, each of the cortical granule components are coordinately accumulated in the developing cortical granules dispersed throughout the cytoplasm. No other organelle within the developing oocytes or eggs contained detectable levels of any of these epitopes. In the somatic interstitial tissue of the ovary, cortical granule components also were accumulated specifically within cortical granule structures. Found only in select accessory cells, these cortical granules were indistinguishable in morphology and epitope composition from eggs and were contained within cytoplasmic aggregates termed mosaic globules. The mechanism of cortical granule concentration into mosaic globules is unknown, but this demonstration of common organelle constituents between oocytes and accessory cells may provide insight for such an understanding.

Phagocytosis of yeast by Biomphalaria glabrata: carbohydrate specificity of hemocyte receptors and a plasma opsonin.

In vitro phagocytosis of yeast cells by hemocytes of the mollusc Biomphalaria glabrata can occur in the absence of plasma, but is enhanced by opsonization in plasma from certain snail strains. We have investigated the carbohydrate specificity of the hemocyte-bound receptor for phagocytosis and the free plasma opsonin using two dominant carbohydrate components of the yeast cell wall (laminarin and mannan). Phagocytic uptake in the absence of plasma of both untreated and opsonized yeast is strongly inhibited by laminarin, but is unaffected by mannan. In contrast, laminarin does not interfere with opsonization whereas mannan blocks the process, blocking the binding of a 57 kD plasma component as detected by Western immunoblot. These results suggest that the opsonic lectin in plasma is not simply a free form of the hemocyte-bound receptor for yeast phagocytosis.