N-acétyltransférase lysosomale : organisation, fonctionnement et défauts moléculaires chez les patients atteints du syndrome de Sanfilippo type C

Feldhammer, Matthew

12 1900

L’acétylation des résidus de glucosamine terminaux par la N-acétyltransférase lysosomale (HGSNAT) est une étape essentielle de la dégradation catabolique de l’héparan sulfate. Des défauts dans cette réaction causent une maladie de surcharge lysosomale autosomale récessive rare : le désordre de Sanfilippo type C (SFC). À ce jour, 54 mutations ont été rapportées chez des patients SFC, incluant 13 mutations des sites d’épissage, 11 insertions et délétions, 8 mutations non-sens, 18 mutations faux-sens et 4 polymorphismes, avec différentes manifestations phénotypiques. Nous avons identifié 10 d’entre elles et effectué une étude exhaustive portant sur l’éventail des mutations SFC, leur distribution dans la population de patients, ainsi que leur impact potentiel sur la structure de la HGSNAT. Les erreurs d’épissage, les mutations non-sens, les insertions et les délétions devraient toutes entraîner un ARN non fonctionnel qui est rapidement dégradé par des mécanismes de contrôle qualité cellulaire. Les 4 polymorphismes identifiés sont des changements d'acides aminés qui ne modifient pas l'activité enzymatique, la glycosylation ou la localisation et n'ont donc pas de signification au niveau clinique. Au niveau des enzymes, les polymorphismes sont des changements d’acides aminés qui n’affectent pas la fonction, mais dans un contexte d’acides nucléiques ils peuvent être considérés comme des mutations faux-sens. Les dix-huit mutations faux-sens qui ont été exprimées ont produit des protéines inactives, en raison d'erreurs dans leur repliement. Ceci expliquerait donc la progression sévère de la maladie chez les personnes porteuses de ces mutations. Les protéines mutantes mal repliées sont anormalement glycosylées et conservées dans le réticulum endoplasmique. La thérapie par amélioration de l’activité enzymatique par des chaperonnes est une option thérapeutique potentielle, spécifiquement conçue pour exploiter l'activité enzymatique résiduelle de mutants mal repliés, afin d’éliminer les substrats stockés. Nous avons démontré que le traitement de plusieurs lignées de fibroblastes de patients SFC avec le chlorhydrate de glucosamine, un inhibiteur spécifique de la HGSNAT, a partiellement restauré l’activité de l'enzyme mutante, fournissant une preuve de l’utilité future de la thérapie par des chaperonnes dans le traitement de la maladie de SFC. / The acetylation of terminal glucosamine residues by lysosomal N-acetyltransferase (HGSNAT) is an essential part of the catabolic breakdown of heparan sulfate. Defects in this reaction result in the rare autosomal recessive lysosomal storage disorder Sanfilippo syndrome type C (SFC). To date 54 mutations in SFC patients have been reported including 13 splice-site mutations, 11 insertions and deletions, 8 nonsense, 18 missense and 4 polymorphisms, with different phenotypic manifestations. We have identified 10 of them and conducted a comprehensive review discussing the spectrum of Sanfilippo C mutations, their distribution within the patient population as well as how the mutations could potentially affect the structure of HGSNAT. Splicing errors, nonsense mutations, insertions and deletions were all predicted to result in non-functional RNA which is rapidly degraded by cellular quality control mechanisms. The 4 identified polymorphisms resulted in amino acid changes which did not affect the enzyme activity, glycosylation or targeting and were therefore not clinically significant. Polymorphisms, in the context of enzymes are amino acid changes not affecting function, but in the context of nucleic acids can still be considered as missense mutations. Eighteen missense mutations were expressed and shown be inactive due to errors in protein folding providing an explanation for the severe disease progression seen in individuals with these mutations. Misfolded mutants were abnormally glycosylated and retained in the endoplasmic reticulum. Enzyme enhancement/chaperone therapy is a potential treatment option specifically designed to exploit the residual enzyme activity of misfolded mutants in order to clear stored substrates. We demonstrated that treatment of several fibroblast lines of SFC patients with a specific inhibitor of HGSNAT; glucosamine-hydrochloride partially rescued mutant enzyme activity providing a proof of principle for the future use of chaperone therapeutics in the treatment of SFC.

Lysosomes

Ddésordres métaboliques

Mucopolysaccharidose IIIC

Syndrome de Sanfilippo type C

Analyse mutationnelle

Repliement de protéines

Metabolic disorders

Mutational analysis

Protein folding

Mucopolysaccharidosis IIIC

Sanfilippo syndrome C

Enzyme enhancement therapy

N-acétyltransférase lysosomale : organisation, fonctionnement et défauts moléculaires chez les patients atteints du syndrome de Sanfilippo type C

Feldhammer, Matthew

12 1900

L’acétylation des résidus de glucosamine terminaux par la N-acétyltransférase lysosomale (HGSNAT) est une étape essentielle de la dégradation catabolique de l’héparan sulfate. Des défauts dans cette réaction causent une maladie de surcharge lysosomale autosomale récessive rare : le désordre de Sanfilippo type C (SFC). À ce jour, 54 mutations ont été rapportées chez des patients SFC, incluant 13 mutations des sites d’épissage, 11 insertions et délétions, 8 mutations non-sens, 18 mutations faux-sens et 4 polymorphismes, avec différentes manifestations phénotypiques. Nous avons identifié 10 d’entre elles et effectué une étude exhaustive portant sur l’éventail des mutations SFC, leur distribution dans la population de patients, ainsi que leur impact potentiel sur la structure de la HGSNAT. Les erreurs d’épissage, les mutations non-sens, les insertions et les délétions devraient toutes entraîner un ARN non fonctionnel qui est rapidement dégradé par des mécanismes de contrôle qualité cellulaire. Les 4 polymorphismes identifiés sont des changements d'acides aminés qui ne modifient pas l'activité enzymatique, la glycosylation ou la localisation et n'ont donc pas de signification au niveau clinique. Au niveau des enzymes, les polymorphismes sont des changements d’acides aminés qui n’affectent pas la fonction, mais dans un contexte d’acides nucléiques ils peuvent être considérés comme des mutations faux-sens. Les dix-huit mutations faux-sens qui ont été exprimées ont produit des protéines inactives, en raison d'erreurs dans leur repliement. Ceci expliquerait donc la progression sévère de la maladie chez les personnes porteuses de ces mutations. Les protéines mutantes mal repliées sont anormalement glycosylées et conservées dans le réticulum endoplasmique. La thérapie par amélioration de l’activité enzymatique par des chaperonnes est une option thérapeutique potentielle, spécifiquement conçue pour exploiter l'activité enzymatique résiduelle de mutants mal repliés, afin d’éliminer les substrats stockés. Nous avons démontré que le traitement de plusieurs lignées de fibroblastes de patients SFC avec le chlorhydrate de glucosamine, un inhibiteur spécifique de la HGSNAT, a partiellement restauré l’activité de l'enzyme mutante, fournissant une preuve de l’utilité future de la thérapie par des chaperonnes dans le traitement de la maladie de SFC. / The acetylation of terminal glucosamine residues by lysosomal N-acetyltransferase (HGSNAT) is an essential part of the catabolic breakdown of heparan sulfate. Defects in this reaction result in the rare autosomal recessive lysosomal storage disorder Sanfilippo syndrome type C (SFC). To date 54 mutations in SFC patients have been reported including 13 splice-site mutations, 11 insertions and deletions, 8 nonsense, 18 missense and 4 polymorphisms, with different phenotypic manifestations. We have identified 10 of them and conducted a comprehensive review discussing the spectrum of Sanfilippo C mutations, their distribution within the patient population as well as how the mutations could potentially affect the structure of HGSNAT. Splicing errors, nonsense mutations, insertions and deletions were all predicted to result in non-functional RNA which is rapidly degraded by cellular quality control mechanisms. The 4 identified polymorphisms resulted in amino acid changes which did not affect the enzyme activity, glycosylation or targeting and were therefore not clinically significant. Polymorphisms, in the context of enzymes are amino acid changes not affecting function, but in the context of nucleic acids can still be considered as missense mutations. Eighteen missense mutations were expressed and shown be inactive due to errors in protein folding providing an explanation for the severe disease progression seen in individuals with these mutations. Misfolded mutants were abnormally glycosylated and retained in the endoplasmic reticulum. Enzyme enhancement/chaperone therapy is a potential treatment option specifically designed to exploit the residual enzyme activity of misfolded mutants in order to clear stored substrates. We demonstrated that treatment of several fibroblast lines of SFC patients with a specific inhibitor of HGSNAT; glucosamine-hydrochloride partially rescued mutant enzyme activity providing a proof of principle for the future use of chaperone therapeutics in the treatment of SFC.

Lysosomes

Ddésordres métaboliques

Mucopolysaccharidose IIIC

Syndrome de Sanfilippo type C

Analyse mutationnelle

Repliement de protéines

Metabolic disorders

Mutational analysis

Protein folding

Mucopolysaccharidosis IIIC

Sanfilippo syndrome C

Enzyme enhancement therapy

Novel Intrinsic and Extrinsic Approaches to Selectively Regulate Glycosphingolipid Metabolism

Kamani, Mustafa

08 August 2013

Glycosphingolipid (GSL) metabolism is a complex process involving proteins and enzymes at distinct locations within the cell. Mammalian GSLs are typically based on glucose or galactose, forming glucosylceramide (GlcCer) and galactosylceramide (GalCer). Most GSLs are derived from GlcCer, which is synthesized on the cytosolic leaflet of the Golgi, while all subsequent GSLs are synthesized on the lumenal side. We have utilized both pharamacological and genetic manipulation approaches to selectively regulate GSL metabolism and better understand its mechanistic details. We have developed analogues of GlcCer and GalCer by substituting the fatty acid moiety with an adamanatane frame. The resulting adamantylGSLs are more water-soluble than their natural counterparts. These analogues selectively interfere with GSL metabolism at particular points within the metabolic pathway. At 40 µM, adaGlcCer prevents synthesis of all GSLs downstream of GlcCer, while also elevating GlcCer levels, by inhibiting lactosylceramide (LacCer) synthase and glucocerebrosidase, respectively. AdaGalCer specifically reduces synthesis of globotriaosylceramide (Gb3) and downstream globo-series GSLs. AdaGalCer also increases Gaucher disease N370S glucocerebrosidase expression, lysosomal localization and activity. AdaGSLs, therefore, have potential as novel therapeutic agents in diseases characterized by GSL anomalies and as tools to study the effects of GSL modulation. Two predominant theories have been developed to explain how GlcCer accesses the Golgi lumen: one involving direct translocation from the cytosolic-to-lumenal leaflet of the Golgi by the ABC transporter P-glycoprotein (P-gp, ABCB1, MDR1), and the other involving retrograde transport of GlcCer by FAPP2 to the ER, followed by entry into the vesicular transport system for Golgi lumenal access. To examine the in vivo involvement of P-gp in GSL metabolism, we generated a knockout model by crossbreeding the Fabry disease mouse with the P-gp knockout mouse. HPLC analyses of tissue Gb3 levels revealed a tissue-specific reduction in MDR1/Fabry mice. TLC analyses, however, did not show such reduction. In addition, we performed a gene knockdown study using siRNA against P-gp and FAPP2. Results show these siRNA to have distinct effects on GSL levels that are cell-type specific. These results give rise to the prospect of unique therapeutic approaches by targeting P-gp or FAPP2 for synthesis inhibition of particular GSL pathways.

Sphingolipids

Metabolism

Lysosomal storage disorders

adamantane

Glucosylceramide

Lactosylceramide

P-glycoprotein

MDR1

Gaucher disease

Fabry disease

siRNA

Gb2 galabiosylceramide

Glycolipids

Inhibitors

Knockout mouse

Crossbreeding

Glucosylceramide synthase

Lactosylceramide synthase

Ganglioside

Globo-series

Gb3 synthase

pharmacological chaperone

Glucocerebrosidase

Substrate reduction therapy

ATP8B1

Cholesterol

ABC Transporters

P-type ATPase

Flippase

FAPP2

GLTP

Glycosyltransferase

Glycolipid analogues

ERAD

ABCB1

knockdown

GM3 and EGFR

GM3 and insulin receptor

Glycolipid synthesis

Glycolipid metabolism

enzyme enhancement therapy

0487

0307

0491

0379

0306

Novel Intrinsic and Extrinsic Approaches to Selectively Regulate Glycosphingolipid Metabolism

Kamani, Mustafa

08 August 2013

Glycosphingolipid (GSL) metabolism is a complex process involving proteins and enzymes at distinct locations within the cell. Mammalian GSLs are typically based on glucose or galactose, forming glucosylceramide (GlcCer) and galactosylceramide (GalCer). Most GSLs are derived from GlcCer, which is synthesized on the cytosolic leaflet of the Golgi, while all subsequent GSLs are synthesized on the lumenal side. We have utilized both pharamacological and genetic manipulation approaches to selectively regulate GSL metabolism and better understand its mechanistic details. We have developed analogues of GlcCer and GalCer by substituting the fatty acid moiety with an adamanatane frame. The resulting adamantylGSLs are more water-soluble than their natural counterparts. These analogues selectively interfere with GSL metabolism at particular points within the metabolic pathway. At 40 µM, adaGlcCer prevents synthesis of all GSLs downstream of GlcCer, while also elevating GlcCer levels, by inhibiting lactosylceramide (LacCer) synthase and glucocerebrosidase, respectively. AdaGalCer specifically reduces synthesis of globotriaosylceramide (Gb3) and downstream globo-series GSLs. AdaGalCer also increases Gaucher disease N370S glucocerebrosidase expression, lysosomal localization and activity. AdaGSLs, therefore, have potential as novel therapeutic agents in diseases characterized by GSL anomalies and as tools to study the effects of GSL modulation. Two predominant theories have been developed to explain how GlcCer accesses the Golgi lumen: one involving direct translocation from the cytosolic-to-lumenal leaflet of the Golgi by the ABC transporter P-glycoprotein (P-gp, ABCB1, MDR1), and the other involving retrograde transport of GlcCer by FAPP2 to the ER, followed by entry into the vesicular transport system for Golgi lumenal access. To examine the in vivo involvement of P-gp in GSL metabolism, we generated a knockout model by crossbreeding the Fabry disease mouse with the P-gp knockout mouse. HPLC analyses of tissue Gb3 levels revealed a tissue-specific reduction in MDR1/Fabry mice. TLC analyses, however, did not show such reduction. In addition, we performed a gene knockdown study using siRNA against P-gp and FAPP2. Results show these siRNA to have distinct effects on GSL levels that are cell-type specific. These results give rise to the prospect of unique therapeutic approaches by targeting P-gp or FAPP2 for synthesis inhibition of particular GSL pathways.

Sphingolipids

Metabolism

Lysosomal storage disorders

adamantane

Glucosylceramide

Lactosylceramide

P-glycoprotein

MDR1

Gaucher disease

Fabry disease

siRNA

Gb2 galabiosylceramide

Glycolipids

Inhibitors

Knockout mouse

Crossbreeding

Glucosylceramide synthase

Lactosylceramide synthase

Ganglioside

Globo-series

Gb3 synthase

pharmacological chaperone

Glucocerebrosidase

Substrate reduction therapy

ATP8B1

Cholesterol

ABC Transporters

P-type ATPase

Flippase

FAPP2

GLTP

Glycosyltransferase

Glycolipid analogues

ERAD

ABCB1

knockdown

GM3 and EGFR

GM3 and insulin receptor

Glycolipid synthesis

Glycolipid metabolism

enzyme enhancement therapy

0487

0307

0491

0379

0306