J. Valles-Ortega scite author profile

Lafora disease (LD) is caused by mutations in either the laforin or malin gene. The hallmark of the disease is the accumulation of polyglucosan inclusions called Lafora Bodies (LBs). Malin knockout (KO) mice present polyglucosan accumulations in several brain areas, as do patients of LD. These structures are abundant in the cerebellum and hippocampus. Here, we report a large increase in glycogen synthase (GS) in these mice, in which the enzyme accumulates in LBs. Our study focused on the hippocampus where, under physiological conditions, astrocytes and parvalbumin-positive (PV+) interneurons expressed GS and malin. Although LBs have been described only in neurons, we found this polyglucosan accumulation in the astrocytes of the KO mice. They also had LBs in the soma and some processes of PV+ interneurons. This phenomenon was accompanied by the progressive loss of these neuronal cells and, importantly, neurophysiological alterations potentially related to impairment of hippocampal function. Our results emphasize the relevance of the laforin–malin complex in the control of glycogen metabolism and highlight altered glycogen accumulation as a key contributor to neurodegeneration in LD.

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Neuronal glycogen synthesis contributes to physiological aging

Sinadinos

Valles-Ortega

Boulan

et al. 2014

Aging Cell

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Glycogen is a branched polymer of glucose and the carbohydrate energy store for animal cells. In the brain, it is essentially found in glial cells, although it is also present in minute amounts in neurons. In humans, loss-of-function mutations in laforin and malin, proteins involved in suppressing glycogen synthesis, induce the presence of high numbers of insoluble polyglucosan bodies in neuronal cells. Known as Lafora bodies (LBs), these deposits result in the aggressive neurodegeneration seen in Lafora’s disease. Polysaccharide-based aggregates, called corpora amylacea (CA), are also present in the neurons of aged human brains. Despite the similarity of CA to LBs, the mechanisms and functional consequences of CA formation are yet unknown. Here, we show that wild-type laboratory mice also accumulate glycogen-based aggregates in the brain as they age. These structures are immunopositive for an array of metabolic and stress-response proteins, some of which were previously shown to aggregate in correlation with age in the human brain and are also present in LBs. Remarkably, these structures and their associated protein aggregates are not present in the aged mouse brain upon genetic ablation of glycogen synthase. Similar genetic intervention in Drosophila prevents the accumulation of glycogen clusters in the neuronal processes of aged flies. Most interestingly, targeted reduction of Drosophila glycogen synthase in neurons improves neurological function with age and extends lifespan. These results demonstrate that neuronal glycogen accumulation contributes to physiological aging and may therefore constitute a key factor regulating age-related neurological decline in humans.

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Hepatic Overexpression of a Constitutively Active Form of Liver Glycogen Synthase Improves Glucose Homeostasis

Ros

Zafra

Valles-Ortega

et al. 2010

Journal of Biological Chemistry

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In this study, we tested the efficacy of increasing liver glycogen synthase to improve blood glucose homeostasis. The overexpression of wild-type liver glycogen synthase in rats had no effect on blood glucose homeostasis in either the fed or the fasted state. In contrast, the expression of a constitutively active mutant form of the enzyme caused a significant lowering of blood glucose in the former but not the latter state. Moreover, it markedly enhanced the clearance of blood glucose when fasted rats were challenged with a glucose load. Hepatic glycogen stores in rats overexpressing the activated mutant form of liver glycogen synthase were enhanced in the fed state and in response to an oral glucose load but showed a net decline during fasting. In order to test whether these effects were maintained during long term activation of liver glycogen synthase, we generated liver-specific transgenic mice expressing the constitutively active LGS form. These mice also showed an enhanced capacity to store glycogen in the fed state and an improved glucose tolerance when challenged with a glucose load. Thus, we conclude that the activation of liver glycogen synthase improves glucose tolerance in the fed state without compromising glycogenolysis in the postabsorptive state. On the basis of these findings, we propose that the activation of liver glycogen synthase may provide a potential strategy for improvement of glucose tolerance in the postprandial state.The liver responds to an increase in blood glucose concentration in the postprandial state by net uptake of glucose and conversion to glycogen, which is subsequently mobilized in the postabsorptive state to maintain blood glucose homeostasis. Various attempts have been made to improve blood glucose homeostasis through the modulation of the expression or activity of proteins involved in the control of liver glycogen metabolism. Glucokinase (GK) 3 catalyzes the first step in hepatic glucose metabolism and exerts high control on liver glycogen synthesis (1). Previous studies using either transgenic models (2, 3) or adenoviral vectors targeting the liver (4) demonstrated improved glucose tolerance and/or a lowering of blood glucose in basal conditions. However, GK overexpression also increases flux through glycolysis, and in some circumstances this leads to hypertriglyceridemia (4). An alternative approach to modulating liver glycogen metabolism without stimulating glycolysis and triglyceride formation is through modifying the enzymes that are involved exclusively in glycogen synthesis and degradation or regulatory proteins that may affect the activity of the former, such as protein targeting to glycogen (PTG) (5). Overexpression of PTG in the liver by means of an adenoviral vector increases glucose tolerance without perturbing lipid homeostasis (6). However, a limitation of this experimental model is that it leads to the progressive accumulation of glycogen because PTG promotes the inactivation of glycogen phosphorylase (GP) also during fasting, and consequently there is ne...

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J. Valles-Ortega

Neurodegeneration and functional impairments associated with glycogen synthase accumulation in a mouse model of Lafora disease

Neuronal glycogen synthesis contributes to physiological aging

Hepatic Overexpression of a Constitutively Active Form of Liver Glycogen Synthase Improves Glucose Homeostasis

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