Lafora Disease: Mechanisms Involved in Pathogenesis

Indiana University-Purdue University Indianapolis (IUPUI)Lafora disease is a neurodegenerative disorder caused by mutations in either the EPM2A or the EPM2B gene that encode a glycogen phosphatase, laforin and an E3 ubiquitin ligase, malin, respectively. A hallmark of the disease is accumulation of insoluble, poorly branched, hyperphosphorylated glycogen in brain, muscle and heart. The laforin-malin complex has been proposed to play a role in the regulation of glycogen metabolism and protein degradation/quality control. We evaluated three arms of protein quality control (the autophagolysosomal pathway, the ubiquitin-proteasomal pathway, and ER stress response) in embryonic fibroblasts from Epm2a-/-, Epm2b-/- and Epm2a-/- Epm2b-/- mice. There was an mTOR-dependent impairment in autophagy, decreased proteasomal activity but an uncompromised ER stress response in the knockout cells. These defects may be secondary to the glycogen overaccumulation. The absence of malin, but not laforin, decreased the level of LAMP1, a marker of lysosomes, suggesting a malin function independent of laforin, possibly in lysosomal biogenesis and/or lysosomal glycogen disposal. To understand the physiological role of malin, an unbiased diGly proteomics approach was developed to search for malin substrates. Ubiquitin forms an isopeptide bond with lysine of the protein upon ubiquitination. Proteolysis by trypsin cleaves the C-terminal Arg-Gly-Gly residues in ubiquitin and yields a diGly remnant on the peptides. These diGly peptides were immunoaffinity purified using anti-diGly antibody and then analyzed by mass spectrometry. The mouse skeletal muscle ubiquitylome was studied using diGly proteomics and we identified 244 nonredundant ubiquitination sites in 142 proteins. An approach for differential dimethyl labeling of proteins with diGly immunoaffinity purification was also developed. diGly peptides from skeletal muscle of wild type and Epm2b-/- mice were immunoaffinity purified followed by differential dimethyl labeling and analyzed by mass spectrometry. About 70 proteins were identified that were present in the wild type and absent in the Epm2b-/- muscle tissue. The initial results identified 14 proteins as potential malin substrates, which would need validation in future studies

The malin-laforin complex suppresses the cellular toxicity of misfolded proteins by promoting their degradation through the ubiquitin-proteasome system

Lafora disease (LD), a progressive form of inherited epilepsy, is associated with widespread neurodegeneration and the formation of polyglucosan bodies in the neurons. Laforin, a protein phosphatase, and malin, an E3 ubiquitin ligase, are two of the proteins that are defective in LD. We have shown recently that laforin and malin (referred together as LD proteins) are recruited to aggresome upon proteasomal blockade, possibly to clear misfolded proteins through the ubiquitin–proteasome system (UPS). Here we test this possibility using a variety of cytotoxic misfolded proteins, including the expanded polyglutamine protein, as potential substrates. Laforin and malin, together with Hsp70 as a functional complex, suppress the cellular toxicity of misfolded proteins, and all the three members of this complex are required for this function. Laforin and malin interact with misfolded proteins and promote their degradation through the UPS. LD proteins are recruited to the polyglutamine aggregates and reduce the frequency of aggregate-positive cells. Taken together, our results suggest that the malin–laforin complex is a novel player in the neuronal response to misfolded proteins and could be potential therapeutic targets for neurodegenerative disorders associated with cytotoxic proteins

Novel mutation in the NHLRC1 gene in a Malian family with a severe phenotype of Lafora disease

We studied a Malian family with parental consanguinity and two of eight siblings affected with late-childhood-onset progressive myoclonus epilepsy and cognitive decline, consistent with the diagnosis of Lafora disease. Genetic analysis showed a novel homozygous single-nucleotide variant in the NHLRC1 gene, c.560A>C, producing the missense change H187P. The changed amino acid is highly conserved, and the mutation impairs malin's ability to degrade laforin in vitro. Pathological evaluation showed manifestations of Lafora disease in the entire brain, with particularly severe involvement of the pallidum, thalamus, and cerebellum. Our findings document Lafora disease with severe manifestations in the West African population

Laforin, a Dual Specificity Phosphatase Involved in Lafora Disease, Is Present Mainly as Monomeric Form with Full Phosphatase Activity

Lafora Disease (LD) is a fatal neurodegenerative epileptic disorder that presents as a neurological deterioration with the accumulation of insoluble, intracellular, hyperphosphorylated carbohydrates called Lafora bodies (LBs). LD is caused by mutations in either the gene encoding laforin or malin. Laforin contains a dual specificity phosphatase domain and a carbohydrate-binding module, and is a member of the recently described family of glucan phosphatases. In the current study, we investigated the functional and physiological relevance of laforin dimerization. We purified recombinant human laforin and subjected the monomer and dimer fractions to denaturing gel electrophoresis, mass spectrometry, phosphatase assays, protein-protein interaction assays, and glucan binding assays. Our results demonstrate that laforin prevalently exists as a monomer with a small dimer fraction both in vitro and in vivo. Of mechanistic importance, laforin monomer and dimer possess equal phosphatase activity, and they both associate with malin and bind glucans to a similar extent. However, we found differences between the two states' ability to interact simultaneously with malin and carbohydrates. Furthermore, we tested other members of the glucan phosphatase family. Cumulatively, our data suggest that laforin monomer is the dominant form of the protein and that it contains phosphatase activity

ChronOS Linux: a best-effort real-time multiprocessor Linux kernel,”

ABSTRACT We present ChronOS Linux, a best-effort real-time Linux kernel for chip multiprocessors (CMPs). ChronOS addresses the intersection of three problem spaces: a) OS-support for obtaining best-effort timing assurances, b) real-time Linux kernel augmented with the PREEMPT_RT patch, and c) OS support for CMP-aware real-time scheduling. While each of these spaces have been studied in the past, their intersection, which has strong problem motivations, was previously empty. Best-effort timeliness targets real-time applications with run-time uncertainties and resource overloads, and optimizes collective application timeliness -as specified by the application. ChronOS directly supports the implementation of best-effort real-time schedulers on CMPs, in addition to others, in the global and partitioned scheduling disciplines. ChronOS extends the PREEMPT RT Linux patch, and thus provides full kernel preemptibility and retains stock Linux features. We validate our claims by reporting on the implementation of a suite of best-effort and non-best-effort CMP schedulers on a quad-core AMD Phenom platform

A short new synthesis of ethyl trans-chrysanthemate

The discovery of synthetic pyrethroids with increased insecticidal activity and low mammalian toxicity led to abundance of new synthetic results in the chemistry of pyrethroids. Many of these methods adopted on an industrial scale make use of sigmatropic rearrangement, radical addition and nucleophilic ring closer with carbanions. Herein we report a simple and stereospecific route for the synthesis of ethyl trans-chrysanthernate (1) by utilizing carbonyl stabilized sulphuranes. Although the use of Sulphurane was demonstrated at a much earlier stage for the synthesis of methyl trans-chrysanthe-mate, the present approach makes use of simple reagents and offers some operational advantages

Protein degradation and quality control in cells from laforin and malin knockout mice

Lafora disease is a progressive myoclonus epilepsy caused by mutations in the EPM2A or EPM2B genes that encode a glycogen phosphatase, laforin, and an E3 ubiquitin ligase, malin, respectively. Lafora disease is characterized by accumulation of insoluble, poorly branched, hyperphosphorylated glycogen in brain, muscle, heart, and liver. The laforinmalin complex has been proposed to play a role in the regulation of glycogen metabolism and protein quality control. We evaluated three arms of the protein degradation/ quality control process (the autophago-lysosomal pathway, the ubiquitin-proteasomal pathway, and the endoplasmic reticulum (ER) stress response) in mouse embryonic fibroblasts from Epm2a(-/-), Epm2b(-/-), and Epm2a(-/-) Epm2b(-/-) mice. The levels of LC3-II, a marker of autophagy, were decreased in all knock-out cells as compared with wild type even though they still showed a slight response to starvation and rapamycin. Furthermore, ribosomal protein S6 kinase and S6 phosphorylation were increased. Under basal conditions there was no effect on the levels of ubiquitinated proteins in the knock-out cells, but ubiquitinated protein degradation was decreased during starvation or stress. Lack of malin (Epm2b(-/-) and Epm2a(-/-) Epm2b(-/-) cells) but not laforin (Epm2a(-/-) cells) decreased LAMP1, a lysosomal marker. CHOP expression was similar in wild type and knock-out cells under basal conditions or with ER stress-inducing agents. In conclusion, both laforin and malin knock-out cells display mTOR-dependent autophagy defects and reduced proteasomal activity but no defects in the ER stress response. We speculate that these defects may be secondary to glycogen overaccumulation. This study also suggests a malin function independent of laforin, possibly in lysosomal biogenesis and/or lysosomal glycogen disposal

Enantiospecific synthesis of (R-(+)-α-lipoic acid from D-glucose

The first enantiospecific synthesis of natural (R)-(+)-α-lipoic acid in 13 steps starting from D-glucose is described