The goal of this project is to utilize the unique window into cellular metabolism that Lafora disease offers to define both normal glycogen metabolism and disease implications when the process is disrupted. Lafora disease (LD), one of five major progressive myoclonic epilepsies, is a fatal, recessive neurodegenerative disorder that presents as an epileptic event in the 2nd decade of life. A hallmark of LD is the accumulation of cytoplasmic, hyperphosphorylated, water-insoluble glycogen-like particles called Lafora bodies. These inclusions occur throughout the body, but disease results from acute neurotoxicity due to the sensitivity of neurons to energy perturbations. LD is the result of loss of function mutations or mutations that cause aberrant function in either of the genes encoding the glucan phosphatase laforin or E3 ubiquitin ligase malin. We established laforin as the founding member of the glucan phosphatase family, i.e. phosphatases that dephosphorylate glycogen or starch. A laforin structure is needed to determine how reversible glycogen phosphorylation impacts glycogen metabolism and define why laforin mutations result in LD. We also demonstrated that malin is an E3 ubiquitin ligase and reported that malin ubiquitinates proteins involved in glycogen synthesis. However, malin does not promote degradation of these enzymes and it has remained unknown as to how malin impacts glycogen metabolism and why mutations in malin result in LD. While mutations in the laforin or malin gene result in LD, it is increasingly recognized that multiple mechanisms lead to LD and that a spectrum of mutations yields different degrees of disease progression. Because our work has defined the molecular function of laforin and malin, we are uniquely poised to define the clinical biochemistry of LD mutations in both laforin and malin. Therefore, we propose to: 1. Determine the structural mechanism of laforin. We will utilize X-ray crystallography combined with structure-guided mutagenesis and functional assays to determine how laforin binds to glycogen, how phosphorylated glycogen is dephosphorylated, laforin's role in glycogen metabolism, and laforin's role in LD. 2. Define the role of malin in LD and glycogen metabolism. Using multiple methods we have identified malin substrates, and established the type of ubiquitination as well as defined the consequences of ubiquitination for one substrate. We will define the signaling events that drive ubiquitination of malin substrates, the dynamics of the events, the functional consequences, and how misregulation leads to LD. We will utilize cell culture and mouse models to determine the role of malin in glycogen metabolism and LD. 3. Translate current insights into patient-specific diagnosis and treatment. LD results from both missense mutations as well as Premature Termination Codons. Our initial analysis revealed that not all point mutations abolish activity. We will utilize our biochemical tools to define mutation specific mechanisms for laforin and malin LD mutations and explore therapeutic options using our recently developed bioassay.

Public Health Relevance

The focus of our work is to determine how mutations in either of two gene products lead to the fatal, neurodegenerative epilepsy called Lafora disease. Our proposal is built on our past discoveries and uses complementary approaches to advance our understanding of the intertwined events of cell metabolism, neurodegeneration, and epilepsy. Completion of this work will yield a better comprehension of these complex events and will allow us to translate our insights into diagnoses, bioassays, and treatments.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS070899-07
Application #
9012116
Study Section
Neural Oxidative Metabolism and Death Study Section (NOMD)
Program Officer
Stewart, Randall R
Project Start
2010-07-01
Project End
2020-04-30
Budget Start
2016-05-01
Budget End
2017-04-30
Support Year
7
Fiscal Year
2016
Total Cost
Indirect Cost
Name
University of Kentucky
Department
Biochemistry
Type
Schools of Medicine
DUNS #
939017877
City
Lexington
State
KY
Country
United States
Zip Code
40506
Gentry, Matthew S; Guinovart, Joan J; Minassian, Berge A et al. (2018) Lafora disease offers a unique window into neuronal glycogen metabolism. J Biol Chem 293:7117-7125
Brewer, M Kathryn; Gentry, Matthew S (2018) The 3rd International Lafora Epilepsy Workshop: Evidence for a cure. Epilepsy Behav 81:125-127
Kuchtová, Andrea; Gentry, Matthew S; Jane?ek, Štefan (2018) The unique evolution of the carbohydrate-binding module CBM20 in laforin. FEBS Lett 592:586-598
Sharma, Savita; Vander Kooi, Carl D; Gentry, Matthew S et al. (2018) Oligomerization and carbohydrate binding of glucan phosphatases. Anal Biochem 563:51-55
Garcia-Gimeno, Maria Adelaida; Rodilla-Ramirez, Pilar Natalia; Viana, Rosa et al. (2018) A novel EPM2A mutation yields a slow progression form of Lafora disease. Epilepsy Res 145:169-177
Romá-Mateo, Carlos; Raththagala, Madushi; Gentry, Mathew S et al. (2016) Assessing the Biological Activity of the Glucan Phosphatase Laforin. Methods Mol Biol 1447:107-19
Gentry, Matthew S; Brewer, M Kathryn; Vander Kooi, Craig W (2016) Structural biology of glucan phosphatases from humans to plants. Curr Opin Struct Biol 40:62-69
Emanuelle, Shane; Brewer, M Kathryn; Meekins, David A et al. (2016) Unique carbohydrate binding platforms employed by the glucan phosphatases. Cell Mol Life Sci 73:2765-2778
Meekins, David A; Vander Kooi, Craig W; Gentry, Matthew S (2016) Structural mechanisms of plant glucan phosphatases in starch metabolism. FEBS J 283:2427-47
Meekins, David A; Raththagala, Madushi; Auger, Kyle D et al. (2015) Mechanistic Insights into Glucan Phosphatase Activity against Polyglucan Substrates. J Biol Chem 290:23361-70

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