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Circadian Clock Regulation of the Glycogen Metabolism in Neurospora CrassaBaek, Mokryun January 2018 (has links)
No description available.
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Starch-binding domain-containing protein 1: a novel participant in glycogen metabolismJiang, Sixin 23 August 2011 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Glycogen, a branched polymer of glucose, acts as an intracellular carbon and energy reserve in many tissues and cell types. The breakdown of glycogen by hormonally regulated degradation involving the coordinated action of glycogen phosphorylase and debranching enzyme has been well studied. However, the importance of lysosomal disposal of glycogen has been underscored by a glycogen storage disorder, Pompe disease. This disease destroys tissues by over-accumulating glycogen in lysosomes due to a genetic defect in the lysosomal acid α-glucosidase. Details of the intracellular trafficking of glycogen are not well understood. Starch-binding domain-containing protein 1 (Stbd1) is a protein of previously unknown function with predicted hydrophobic N-terminus and C-terminal CBM20 carbohydrate binding domain. The protein is highly expressed in the liver and muscle, the major repositories of glycogen. Stbd1 binds to glycogen in vitro and in vivo with a preference for less branched and more phosphorylated polysaccharides. In animal models, the protein level of Stbd1 correlates with the genetic depletion of glycogen. Endogenous Stbd1 is found in perinuclear compartments in cultured mouse and rat cells. When over-expressed in cells, Stbd1 accumulates and coincides with glycogen and GABARAPL1, the autophagy protein. They form enlarged perinuclear structures which are abolished by removing the hydrophobic N-terminus of Stbd1. Stbd1, with point mutations in the CBM20 domain, retains the perinuclear localization but without concentration of glycogen in this compartment. In cells that are stably over-expressing glycogen synthase, glycogen exists as large perinuclear deposits, where Stbd1 can also be present. Removing glucose from the culture leads to a breakdown of the massive glycogen accumulation into numerous smaller and scattered deposits which are still positive for Stbd1. Furthermore, the autophagy protein GABARAPL1 co-immunoprecipates and co-localizes with Stbd1 when co-expressed in cells. Point mutation or deletion of the autophagy protein interacting region on Stbd1 eliminates the interaction and co-localization with GABARAPL1 but not the characteristic perinuclear distribution of Stbd1. We propose that Stbd1 is involved in glycogen metabolism. In particular, it participates in the vesicular transfer of glycogen to the lysosome with the recruitment of autophagy related proteins GABARAPL1 and/or GABARAP, as these vesicles mature prior to lysosomal fusion.
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Effect of insulin on glycogen stores in innervated and chronically denervated red and white skeletal muscle of the ratMiller, Allen L. 03 June 2011 (has links)
Glycogen levels were studied in 15 Sprague-Dawley adult male rats. Three aspects of glycogen metabolism were considered. First, the glycogen concentrations of normally innervated red (soleus) and white (gastrocnemius) muscles were compared. Second, the glycogen content of innervated red and white muscles were compared to chronically denervated red and white muscles. Third, the effect of insulin upon glycogen stores in innervated and chronically denervated red and white muscles was examined.Innervated white muscles had higher glycogen levels than innervated red muscles. However, chronic denervation resulted in statistically significant decreases in red and white muscle glycogen content. In addition, insulin markedly increased glycogen stores in innervated red muscles, but not in white muscles. Further, the increase in glycogen levels in red muscle caused by insulin was abolished in chronically denervated preparations.The results suggest that the effects of insulin on skeletal muscle glycogen stores could be related to trophic influences of motor nerves.Ball State UniversityMuncie, IN 47306
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Geographical variation of freeze tolerance in the wood frog, <i>Rana sylvatica</i>: the role of hepatic glycogen metabolismdo Amaral, Maria Clara Figueirinhas 04 August 2014 (has links)
No description available.
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The regulatory design of glycogen metabolism in mammalian skeletal musclePalm, Daniel Christiaan 03 1900 (has links)
Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: It is widely accepted that insufficient insulin-stimulated activation of muscle glycogen
synthesis is one of the major components of non-insulin-dependent (type 2)
diabetes mellitus. Glycogen synthase, a key enzyme in glycogen synthesis, is extensively
regulated, both allosterically (by glucose-6-phosphate, ATP, and other ligands)
and covalently (by phosphorylation). Although glycogen synthase has been
a topic of intense study for more than 50 years, its kinetic characterization has been
confounded by its large number of phosphorylation states. Questions remain regarding
the function of glycogen synthase regulation and the relative importance
of allosteric and covalent modification in fulfilling this function. The regulation
of glycogen synthase and glycogen phosphorylase, the enzyme that catalyses the
degradation of glycogen chains, are reciprocal in many respects.
In the present research, using mathematical modelling, we aim to establish the
function of the allosteric and covalent regulation of glycogen synthase and glycogen
phosphorylase in muscle and, in the case of glycogen synthase, the relative importance
of these two mechanisms in performing this function. In order to realize
these aims it is essential that a detailed kinetic model of glycogen metabolism is
constructed.
We begin with a thorough review of the kinetics and regulation of glycogen synthase
inwhich we propose that both allosteric and covalent modification of glycogen
synthase can be described by a Monod-Wyman-Changeux model in terms of apparent
changes to L0, the equilibrium constant between the T and R conformers. We
then proceed to develop a rate equation according to the proposed Monod-Wyman-Changeux model and determine values for its kinetic parameters from published experimental data using non-linear least-squares regression. We show that the application
of the Monod-Wyman-Changeux model to glycogen synthase kinetics also
has important implications for the rate equations of enzymes that catalyse the phosphorylation
and dephosphorylation of glycogen synthase. We formalize these implications for a generic protein that follows Monod-Wyman-Changeux-type conformational
change and then also show how the findings apply to glycogen synthase. Taking
into account the kinetic model of glycogen synthase and how it also influences
the covalent regulation of the enzyme, we proceed to construct a detailed mathematical
model of glycogen synthesis that includes the glycogen synthase phosphorylation
cascade. A variation of this model in which glycogen synthase phosphorylation
is described with a single parameter is also provided. We reuse an existing model of
muscle glycogenolysis and also combine these models in an overall model of glycogen
metabolism. Finally, we employ the theoretical frameworks of metabolic control
analysis, supply-demand analysis, and co-response analysis to investigate the function
of glycogen synthase and glycogen phosphorylase regulation. We show that
the function of glycogen synthase regulation is not flux control, as assumed in the
textbook view, but rather the maintenance of glucose-6-phosphate within a narrow
range far from equilibrium. Similarly, we show that regulation of glycogen phosphorylase
functions to minimize variation in cellular energy charge in the face of
highly variable energy demand. We conclude with an appeal for a renewed interest
in the enzyme kinetics of muscle glycogen metabolism. / AFRIKAANSE OPSOMMING: Daar word wyd aanvaar dat onvoldoende insulien-gestimuleerde aktivering van
spierglikogeensintese een van die hoofkomponente van insulien-onafhanklike (tipe
2) diabetes mellitus is. Glikogeensintase, ’n sleutelensiem in glikogeensintese is
onderworpe aan breedvoerige regulering, beide allosteries (deur glukose-6-fosfaat,
ATP, en ander ligande) en kovalent (deur fosforilering). Alhoewel glikogeensintase
reeds vir meer as 50 jaar deeglik bestudeer word, word die kinetiese karakterisering
daarvan bemoeilik deur die groot aantal fosforilasiestate waarin die ensiem
voorkom. Daar is steeds vrae betreffende die funksie van die regulering van glikogeensintase
en die relatiewe bydrae van allosteriese en kovalente regulering in die
vervulling van hierdie funksie. Die regulering van glikogeensintase en glikogeenfosforilase,
die ensiem wat die afbraak van glikogeenkettings kataliseer, is in baie
opsigte resiprook.
In hierdie studie beoog ons om met die hulp van wiskundige modellering vas
te stel watter funksie die regulering van glikogeensintase en glikogeenfosforilase
vervul en, in die geval van glikogeensintase, wat die relatiewe belang is van allosteriese
en kovalente regulering in die vervulling van hierdie funksie. Om hierdie oogmerke
te verwesentlik is dit nodig dat ’n kinetiese model van glikogeenmetabolisme
ontwikkel word.
Ons begin met ’n omvattende oorsig van die kinetika en regulering van glikogeensintase
waarin ons voorstel dat beide die allosteriese en kovalente regulering
van glikogeensintase beskryf kan word met die Monod-Wyman-Changeux model
in terme van oënskynlike veranderings aan L0, die ekwilibriumkonstante tussen
die T en R konformasies. Ons gaan dan voort om ’n snelheidsvergelyking te ontwikkel
volgens die voorgestelde Monod-Wyman-Changuex-model en bepaal ook
die waardes van hierdie vergelyking se parameters vanaf gepubliseerde eksperimentele
data deur middel van nie-lineêre kleinste-vierkantsregressie. Ons wys dat
die toepassing van die Monod-Wyman-Changuex-model op glikogeensintase-kinetika belangrike gevolge het vir die snelheidsvergelykings van die ensieme wat die fosforilering
en defosforilering van glikogeensintase kataliseer. Ons formaliseer hierdie
gevolge vir ’n generiese Monod-Wyman-Changeux-tipe proteïen en wys dan ook
hoe die bevindings op glikogeensintase van toepassing is. Met inagneming van die
kinetiese model vir glikogeensintase en hoe dit die kovalente regulering van die
ensiem be¨ınvloed, gaan ons voort om ’n gedetaileerde wiskundige model van glikogeensintese,
wat ook die glikogeensintase-fosforileringskaskade insluit, te ontwikkel.
’n Variasie op hierdie model waarin die fosforilering van glikogeensintase deur
’n enkele parameter beskryf word, word ook voorsien. Ons herbruik ’n bestaande
model van spierglikogenolise en kombineer ook hierdie modelle in ’n oorkoepelende
model van glikogeenmetabolisme. Uiteindelik span ons die teoretiese raamwerke
van metaboliese kontrole-analise, vraag-aanbod-analise, en ko-responsanalise in om
die funksie van die regulering van glikogeensintase en glikogeenfosforilase te ondersoek.
Ons wys dat die funksie van die regulering van glikogeensintase nie fluksiekontrole,
soos algemeen in handboeke aangeneem word, is nie, maar liewer dat
dit glukose-6-fosfaat handhaaf binne ’n noue band ver vanaf ekwilibrium. Insgelyks
wys ons dat die regulering van glikogeenfosforilase funksioneer om variasie
in sellulˆere energielading te beperk ten spyte van hoogs wisselende vlakke van
energie-aanvraag. Ons sluit af met ’n pleidooi vir hernieude belangstelling in die
ensiemkinetika van glikogeenmetabolisme in die spier. / National Research Foundation
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Effects of passive and active recovery on the resynthesis of muscle glycogenChoi, DaiHyuk January 1993 (has links)
The purpose of this investigation was to determine the effect of passive and active recovery on the resynthesis of muscle glycogen after high intensity cycle ergometer exercise in untrained subjects. In a cross over design, six college-age males performed three, one min exercise bouts, at 130% V02max with a 4 min rest period between each work bout. Subjects refrained from exercise for two days prior to testing, and consumed a 15% carbohydrate solution (300g sugar in 2000ml of water) the day before each trial to help elevate glycogen concentration. The exercise protocol for each trial was identical, while the recovery following exercise was eitheractive (40-50% VO2max) or passive. The initial muscle glycogen values averaged 144.2 mmol•kg-1 w.w. for the active trial and 158.7 mmol•kg-1 w.w. for the passive trial. Corresponding post-exercise glycogen contents were 97.7 and 106.8 mmol•kg-1 w.w., respectively. These differences were not significant (P>0.05). However, the rate of muscle glycogen resynthesis during passive recovery increased 15 mmol•kg-1 w.w. whereas it decreased 6.27 mmol•kg-1 w.w. following active recovery (P<0.01). Also, the decrease in blood lactate concentration during active recovery was much faster than during passive recovery and significantly different at 10 and 30 min of the recovery period (P<0.01). The major finding of this investigation was that the rate of muscle glycogen resynthesis during passive recovery was significantly greater than that during active recovery. These data suggest that lactate can be used as an endogenous glycogenic precusor in muscle, and that glycogenesis was the prevalent pathway of lactate removal during passive recovery following high intensity cycle ergometer exercise. / Human Performance Laboratory
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Muscle glycogen repletion without food intake during recovery from exercise in humansLow, Chee Yong January 2010 (has links)
[Truncated abstract] It is well established that fish, amphibians and reptiles recovering from physical activity of near maximal intensity can replenish completely their muscle glycogen stores in the absence of food. In contrast, the extent to which these stores are replenished under these conditions in humans has been reported in all but one study to be partial. This implies that a few consecutive bouts of intense exercise might eventually lead to the sustained depletion of the muscle glycogen stores in humans if food is unavailable, thus limiting their capacity to engage in fight or flight behaviors unless mechanisms exist to protect muscle glycogen against sustained depletion. The objective of Study 1 was to test this prediction. Eight participants performed three intense exercise bouts each separated by a recovery period of 75 minutes. Although only 53% of muscle glycogen was replenished after the first exercise bout (postexercise and post-recovery glycogen levels of 246 ± 25 and 320 ± 36 mmol.kg-1 dry mass, respectively), all the glycogen mobilised during the second and third bouts was completely replenished during the respective recovery periods, with glycogen reaching levels of 319 ± 29 mmol.kg-1 dry mass after recovery from the third bout. These findings show that humans are not different from other vertebrate species in that there are conditions where humans have the ability to completely replenish without food intake the muscle glycogen mobilised during exercise. The results of our first study raise the intriguing possibility that humans have pre-set muscle glycogen levels that are protected against sustained depletion, with the extent to which muscle glycogen stores are replenished after exercise being dependent on the amount of glycogen required to attain those protected levels. ... During recovery, glycogen levels in the NORM group increased by more than ~50% and reached levels close to those alleged to be protected (189 ± 21 mmol.kg-1 dry mass), whereas no glycogen was deposited in the HCHO group. The sustained post-exercise activation of glycogen synthase, the transient fall in whole body carbohydrate oxidation rate, the increased mobilisation of body proteins, and the prolonged elevation in NEFA levels most probably played important roles in enabling glycogen synthesis in the NORM group. In conclusion, this thesis shows for the first time that there are some conditions (e.g. low pre-exercise muscle glycogen levels) where humans recovering from intense exercise have the capacity, like other species, to replenish completely their muscle glycogen stores from endogenous carbon sources. This study also suggests that humans protect preset levels of muscle glycogen against sustained depletion and at levels high enough to support at least one maximal sprint effort to exhaustion. Evidence is also provided for the existence of a feedback mechanism whereby glycogen below their protected levels mediate the activation of glycogen synthase to restore the depleted muscle glycogen stores back to their protected levels. Our findings, however, leave us with a number of novel unanswered questions which clearly show that the regulation of glycogen metabolism is far from the simple process generally depicted in most textbooks of biochemistry.
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Identification of substrates and pathways regulated by PAS kinaseProbst, Brandon Linn. January 2005 (has links)
Thesis (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Embargoed. Vita. Bibliography: 118-133.
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Metabolism of the covalent phosphate in glycogenTagliabracci, Vincent S. 31 August 2010 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Glycogen is a highly branched polymer of glucose that functions to store glucose residues for future metabolic use. Skeletal muscle and liver comprise the largest glycogen reserves and play critical roles in maintaining whole body glucose homeostasis. In addition to glucose, glycogen contains small amounts of covalent phosphate of unknown function, origin and structure. Evidence to support the involvement of glycogen associated phosphate in glycogen metabolism comes from patients with Lafora Disease. Lafora disease is an autosomal recessive, fatal form of progressive myoclonus epilepsy. Approximately 90% of cases of Lafora disease are caused by mutations in either the EPM2A or EPM2B genes that encode, respectively, a dual specificity phosphatase called laforin and an E3 ubiquitin ligase called malin. Lafora patients accumulate intracellular inclusion bodies, known as Lafora bodies that are primarily composed of poorly branched, insoluble glycogen-like polymers. We have shown that laforin is a glycogen phosphatase capable of releasing phosphate from glycogen in vitro and that this activity is dependent on a functional carbohydrate binding domain. In studies of laforin knockout mice, we observed a progressive change in the properties and structure of glycogen that paralleled the formation of Lafora bodies. Glycogen isolated from these mice showed increased glycogen phosphate, up to 6-fold (p< 0.001) compared to WT, providing strong evidence that laforin acts as a glycogen phosphatase in vivo. Furthermore we have demonstrated that glycogen synthase introduces phosphate into glycogen during synthesis by transferring the beta-phosphate of UDP-glucose into the polymer and that laforin is capable of releasing the phosphate incorporated by glycogen synthase. Analysis of mammalian glycogen revealed the presence of covalently linked phosphate at the 2 hydroxyl and the 3 hydroxyl of glucose residues in the polysaccharide, providing the first direct evidence of the chemical nature of the phosphate linkage. We envision a glycogen damage/repair process, analogous to errors during DNA synthesis that are subsequently repaired. We propose that laforin action parallels that of DNA repair enzymes and Lafora disease results from the inability of the phosphatase to repair damaged glycogen, adding another biological polymer to the list of those prone to errors by their respective polymerizing enzymes.
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The effects of laforin, malin, Stbd1, and Ptg deficiencies on heart glycogen levels in Pompe disease mouse modelsConway, Betsy Ann 08 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Pompe disease (PD) is a rare metabolic myopathy characterized by loss of acid alpha-glucosidase (GAA), the enzyme responsible for breaking down glycogen to glucose within the lysosomes. PD cells accumulate massive quantities of glycogen within their lysosomes, and as such, PD is classified as a “lysosomal storage disease” (LSD). GAA-deficient cells also exhibit accumulation of autophagic debris. Symptoms of severe infantile PD include extreme muscle weakness, hypotonia, and hypertrophic cardiomyopathy, resulting in death before one year of age.
Certain LSDs are currently being successfully treated with enzyme replacement therapy (ERT), which involves intravenous infusion of a recombinant enzyme to counteract the endogenous deficiency. ERT has been less successful in PD, however, due to ineffective delivery of the recombinant enzyme. Alternatively, specific genes deletion may reduce lysosomal glycogen load, and could thus be targeted in PD therapy development. Absence of malin (EPM2B) or laforin (EPM2A) has been proposed to impair autophagy, which could reduce lysosomal glycogen levels. Additionally, deficiency of Stbd1 has been postulated to disable lysosomal glycogen import. Furthermore, Ptg deficiency was previously reported to abrogate Lafora body formation and correct neurological abnormalities in Lafora disease mouse models and could have similar effects on PD pathologies.
The goal of this study was to characterize the effects of homozygous disruption of Epm2a, Epm2b, Stbd1, and Ptg loci on total glycogen levels in PD mouse model heart tissue, as in severe infantile PD, it is accumulation of glycogen in the heart that results in fatal hypertrophic cardiomyopathy. Gaa-/- mice were intercrossed with Epm2a-/-, Epm2b-/-, Stbd1-/-, and Ptg-/- mice to generate wildtype (WT), single knockout, and double knockout mice. The results indicated that Gaa-/- hearts accumulated up to 100-fold more glycogen than the WT. These mice also displayed cardiac hypertrophy. However, deficiency of Epm2a, Epm2b, Stbd1, or PTG in the Gaa-/- background did not reveal changes of statistical significance in either heart glycogen or cardiac hypertrophy. Nevertheless, since total glycogen was measured, these deficiencies should not be discarded in future discussions of PD therapy, as increasing sample sizes and/or distinguishing cytosolic from lysosomal glycogen content may yet reveal differences of greater significance.
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