Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing
Identifieur interne : 000943 ( Main/Corpus ); précédent : 000942; suivant : 000944Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing
Auteurs : Valerie Cullen ; S. Pablo Sardi ; Juliana Ng ; You-Hai Xu ; Ying Sun ; Julianna J. Tomlinson ; Piotr Kolodziej ; Ilana Kahn ; Paul Saftig ; John Woulfe ; Jean-Christophe Rochet ; Marcie A. Glicksman ; Seng H. Cheng ; Gregory A. Grabowski ; Lamya S. Shihabuddin ; Michael G. SchlossmacherSource :
- Annals of Neurology [ 0364-5134 ] ; 2011-06.
Abstract
Objective:: Heterozygous mutations in the GBA1 gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic GBA1 mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk. Methods:: We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols. Results:: We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (p < 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; p < 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (p = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; p < 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; p < 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409Vgba knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; p = 0.019). In young Gaucher disease mice (V394Lgba+/+//prosaposin[ps]‐null//ps‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice. Interpretation:: Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between GBA1 mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;
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DOI: 10.1002/ana.22400
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Schlossmacher</name><affiliation><mods:affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</mods:affiliation></affiliation><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author></titleStmt><publicationStmt><idno type="wicri:source">ISTEX</idno><idno type="RBID">ISTEX:CC9A43851B491441CFC64245FB061A1CE9852FB4</idno><date when="2011" year="2011">2011</date><idno type="doi">10.1002/ana.22400</idno><idno type="url">https://api.istex.fr/document/CC9A43851B491441CFC64245FB061A1CE9852FB4/fulltext/pdf</idno><idno type="wicri:Area/Main/Corpus">000943</idno></publicationStmt><sourceDesc><biblStruct><analytic><title level="a" type="main" xml:lang="en">Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title><author><name sortKey="Cullen, Valerie" sort="Cullen, Valerie" uniqKey="Cullen V" first="Valerie" last="Cullen">Valerie Cullen</name><affiliation><mods:affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</mods:affiliation></affiliation><affiliation><mods:affiliation>Current Address: Dr Cullen: LINK Medicine Corp, Cambridge, MA 02142</mods:affiliation></affiliation></author><author><name sortKey="Sardi, S Pablo" sort="Sardi, S Pablo" uniqKey="Sardi S" first="S. Pablo" last="Sardi">S. Pablo Sardi</name><affiliation><mods:affiliation>Genzyme Corporation, Framingham, MA</mods:affiliation></affiliation></author><author><name sortKey="Ng, Juliana" sort="Ng, Juliana" uniqKey="Ng J" first="Juliana" last="Ng">Juliana Ng</name><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author><author><name sortKey="Xu, You Ai" sort="Xu, You Ai" uniqKey="Xu Y" first="You-Hai" last="Xu">You-Hai Xu</name><affiliation><mods:affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</mods:affiliation></affiliation></author><author><name sortKey="Sun, Ying" sort="Sun, Ying" uniqKey="Sun Y" first="Ying" last="Sun">Ying Sun</name><affiliation><mods:affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</mods:affiliation></affiliation></author><author><name sortKey="Tomlinson, Julianna J" sort="Tomlinson, Julianna J" uniqKey="Tomlinson J" first="Julianna J." last="Tomlinson">Julianna J. Tomlinson</name><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author><author><name sortKey="Kolodziej, Piotr" sort="Kolodziej, Piotr" uniqKey="Kolodziej P" first="Piotr" last="Kolodziej">Piotr Kolodziej</name><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author><author><name sortKey="Kahn, Ilana" sort="Kahn, Ilana" uniqKey="Kahn I" first="Ilana" last="Kahn">Ilana Kahn</name><affiliation><mods:affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</mods:affiliation></affiliation></author><author><name sortKey="Saftig, Paul" sort="Saftig, Paul" uniqKey="Saftig P" first="Paul" last="Saftig">Paul Saftig</name><affiliation><mods:affiliation>Institute of Biochemistry, Christian‐Albrechts University, Kiel, Germany</mods:affiliation></affiliation></author><author><name sortKey="Woulfe, John" sort="Woulfe, John" uniqKey="Woulfe J" first="John" last="Woulfe">John Woulfe</name><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author><author><name sortKey="Rochet, Jean Hristophe" sort="Rochet, Jean Hristophe" uniqKey="Rochet J" first="Jean-Christophe" last="Rochet">Jean-Christophe Rochet</name><affiliation><mods:affiliation>Department of Medicinal Chemistry and Molecular Pharmacology, Purdue University, West Lafayette, IN</mods:affiliation></affiliation></author><author><name sortKey="Glicksman, Marcie A" sort="Glicksman, Marcie A" uniqKey="Glicksman M" first="Marcie A." last="Glicksman">Marcie A. Glicksman</name><affiliation><mods:affiliation>Laboratory for Drug Discovery in Neurodegeneration, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</mods:affiliation></affiliation></author><author><name sortKey="Cheng, Seng H" sort="Cheng, Seng H" uniqKey="Cheng S" first="Seng H." last="Cheng">Seng H. Cheng</name><affiliation><mods:affiliation>Genzyme Corporation, Framingham, MA</mods:affiliation></affiliation></author><author><name sortKey="Grabowski, Gregory A" sort="Grabowski, Gregory A" uniqKey="Grabowski G" first="Gregory A." last="Grabowski">Gregory A. Grabowski</name><affiliation><mods:affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</mods:affiliation></affiliation></author><author><name sortKey="Shihabuddin, Lamya S" sort="Shihabuddin, Lamya S" uniqKey="Shihabuddin L" first="Lamya S." last="Shihabuddin">Lamya S. Shihabuddin</name><affiliation><mods:affiliation>Genzyme Corporation, Framingham, MA</mods:affiliation></affiliation></author><author><name sortKey="Schlossmacher, Michael G" sort="Schlossmacher, Michael G" uniqKey="Schlossmacher M" first="Michael G." last="Schlossmacher">Michael G. Schlossmacher</name><affiliation><mods:affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</mods:affiliation></affiliation><affiliation><mods:affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</mods:affiliation></affiliation></author></analytic><monogr></monogr><series><title level="j">Annals of Neurology</title><title level="j" type="abbrev">Ann Neurol.</title><idno type="ISSN">0364-5134</idno><idno type="eISSN">1531-8249</idno><imprint><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><pubPlace>Hoboken</pubPlace><date type="published" when="2011-06">2011-06</date><biblScope unit="volume">69</biblScope><biblScope unit="issue">6</biblScope><biblScope unit="page" from="940">940</biblScope><biblScope unit="page" to="953">953</biblScope></imprint><idno type="ISSN">0364-5134</idno></series><idno type="istex">CC9A43851B491441CFC64245FB061A1CE9852FB4</idno><idno type="DOI">10.1002/ana.22400</idno><idno type="ArticleID">ANA22400</idno></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0364-5134</idno></seriesStmt></fileDesc><profileDesc><textClass></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Objective:: Heterozygous mutations in the GBA1 gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic GBA1 mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk. Methods:: We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols. Results:: We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (p < 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; p < 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (p = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; p < 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; p < 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409Vgba knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; p = 0.019). In young Gaucher disease mice (V394Lgba+/+//prosaposin[ps]‐null//ps‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice. Interpretation:: Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between GBA1 mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;</div></front></TEI><istex><corpusName>wiley</corpusName><author><json:item><name>Valerie Cullen PhD</name><affiliations><json:string>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</json:string><json:string>Current Address: Dr Cullen: LINK Medicine Corp, Cambridge, MA 02142</json:string></affiliations></json:item><json:item><name>S. Pablo Sardi PhD</name><affiliations><json:string>Genzyme Corporation, Framingham, MA</json:string></affiliations></json:item><json:item><name>Juliana Ng BSc</name><affiliations><json:string>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</json:string></affiliations></json:item><json:item><name>You‐Hai Xu PhD</name><affiliations><json:string>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</json:string></affiliations></json:item><json:item><name>Ying Sun PhD</name><affiliations><json:string>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</json:string></affiliations></json:item><json:item><name>Julianna J. Tomlinson PhD</name><affiliations><json:string>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</json:string></affiliations></json:item><json:item><name>Piotr Kolodziej BSc</name><affiliations><json:string>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</json:string></affiliations></json:item><json:item><name>Ilana Kahn MD</name><affiliations><json:string>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</json:string></affiliations></json:item><json:item><name>Paul Saftig PhD</name><affiliations><json:string>Institute of Biochemistry, Christian‐Albrechts University, Kiel, Germany</json:string></affiliations></json:item><json:item><name>John Woulfe MD, PhD</name><affiliations><json:string>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</json:string></affiliations></json:item><json:item><name>Jean‐Christophe Rochet PhD</name><affiliations><json:string>Department of Medicinal Chemistry and Molecular Pharmacology, Purdue University, West Lafayette, IN</json:string></affiliations></json:item><json:item><name>Marcie A. Glicksman PhD</name><affiliations><json:string>Laboratory for Drug Discovery in Neurodegeneration, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</json:string></affiliations></json:item><json:item><name>Seng H. Cheng PhD</name><affiliations><json:string>Genzyme Corporation, Framingham, MA</json:string></affiliations></json:item><json:item><name>Gregory A. Grabowski MD</name><affiliations><json:string>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</json:string></affiliations></json:item><json:item><name>Lamya S. Shihabuddin PhD</name><affiliations><json:string>Genzyme Corporation, Framingham, MA</json:string></affiliations></json:item><json:item><name>Michael G. Schlossmacher MD, FRCPC</name><affiliations><json:string>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</json:string><json:string>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</json:string></affiliations></json:item></author><articleId><json:string>ANA22400</json:string></articleId><language><json:string>eng</json:string></language><abstract>Objective:: Heterozygous mutations in the GBA1 gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic GBA1 mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk. Methods:: We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols. Results:: We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (p > 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; p > 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (p = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; p > 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; p > 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409Vgba knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; p = 0.019). In young Gaucher disease mice (V394Lgba+/+//prosaposin[ps]‐null//ps‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice. Interpretation:: Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between GBA1 mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;</abstract><qualityIndicators><score>8</score><pdfVersion>1.3</pdfVersion><pdfPageSize>612 x 801 pts</pdfPageSize><refBibsNative>true</refBibsNative><keywordCount>0</keywordCount><abstractCharCount>2686</abstractCharCount><pdfWordCount>8325</pdfWordCount><pdfCharCount>54184</pdfCharCount><pdfPageCount>14</pdfPageCount><abstractWordCount>389</abstractWordCount></qualityIndicators><title>Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title><genre><json:string>article</json:string></genre><host><volume>69</volume><publisherId><json:string>ANA</json:string></publisherId><pages><total>14</total><last>953</last><first>940</first></pages><issn><json:string>0364-5134</json:string></issn><issue>6</issue><subject><json:item><value>Original Article</value></json:item></subject><genre><json:string>Journal</json:string></genre><language><json:string>unknown</json:string></language><eissn><json:string>1531-8249</json:string></eissn><title>Annals of Neurology</title><doi><json:string>10.1002/(ISSN)1531-8249</json:string></doi></host><publicationDate>2011</publicationDate><copyrightDate>2011</copyrightDate><doi><json:string>10.1002/ana.22400</json:string></doi><id>CC9A43851B491441CFC64245FB061A1CE9852FB4</id><fulltext><json:item><original>true</original><mimetype>application/pdf</mimetype><extension>pdf</extension><uri>https://api.istex.fr/document/CC9A43851B491441CFC64245FB061A1CE9852FB4/fulltext/pdf</uri></json:item><json:item><original>false</original><mimetype>application/zip</mimetype><extension>zip</extension><uri>https://api.istex.fr/document/CC9A43851B491441CFC64245FB061A1CE9852FB4/fulltext/zip</uri></json:item><istex:fulltextTEI uri="https://api.istex.fr/document/CC9A43851B491441CFC64245FB061A1CE9852FB4/fulltext/tei"><teiHeader><fileDesc><titleStmt><title level="a" type="main" xml:lang="en">Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title></titleStmt><publicationStmt><authority>ISTEX</authority><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><pubPlace>Hoboken</pubPlace><availability><p>WILEY</p></availability><date>2011</date></publicationStmt><sourceDesc><biblStruct type="inbook"><analytic><title level="a" type="main" xml:lang="en">Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title><author><persName><forename type="first">Valerie</forename><surname>Cullen</surname></persName><roleName type="degree">PhD</roleName><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><affiliation>Current Address: Dr Cullen: LINK Medicine Corp, Cambridge, MA 02142</affiliation></author><author><persName><forename type="first">S. Pablo</forename><surname>Sardi</surname></persName><roleName type="degree">PhD</roleName><affiliation>Genzyme Corporation, Framingham, MA</affiliation></author><author><persName><forename type="first">Juliana</forename><surname>Ng</surname></persName><roleName type="degree">BSc</roleName><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation></author><author><persName><forename type="first">You‐Hai</forename><surname>Xu</surname></persName><roleName type="degree">PhD</roleName><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation></author><author><persName><forename type="first">Ying</forename><surname>Sun</surname></persName><roleName type="degree">PhD</roleName><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation></author><author><persName><forename type="first">Julianna J.</forename><surname>Tomlinson</surname></persName><roleName type="degree">PhD</roleName><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation></author><author><persName><forename type="first">Piotr</forename><surname>Kolodziej</surname></persName><roleName type="degree">BSc</roleName><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation></author><author><persName><forename type="first">Ilana</forename><surname>Kahn</surname></persName><roleName type="degree">MD</roleName><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation></author><author><persName><forename type="first">Paul</forename><surname>Saftig</surname></persName><roleName type="degree">PhD</roleName><affiliation>Institute of Biochemistry, Christian‐Albrechts University, Kiel, Germany</affiliation></author><author><persName><forename type="first">John</forename><surname>Woulfe</surname></persName><roleName type="degree">MD, PhD</roleName><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation></author><author><persName><forename type="first">Jean‐Christophe</forename><surname>Rochet</surname></persName><roleName type="degree">PhD</roleName><affiliation>Department of Medicinal Chemistry and Molecular Pharmacology, Purdue University, West Lafayette, IN</affiliation></author><author><persName><forename type="first">Marcie A.</forename><surname>Glicksman</surname></persName><roleName type="degree">PhD</roleName><affiliation>Laboratory for Drug Discovery in Neurodegeneration, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation></author><author><persName><forename type="first">Seng H.</forename><surname>Cheng</surname></persName><roleName type="degree">PhD</roleName><affiliation>Genzyme Corporation, Framingham, MA</affiliation></author><author><persName><forename type="first">Gregory A.</forename><surname>Grabowski</surname></persName><roleName type="degree">MD</roleName><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation></author><author><persName><forename type="first">Lamya S.</forename><surname>Shihabuddin</surname></persName><roleName type="degree">PhD</roleName><affiliation>Genzyme Corporation, Framingham, MA</affiliation></author><author><persName><forename type="first">Michael G.</forename><surname>Schlossmacher</surname></persName><roleName type="degree">MD, FRCPC</roleName><note type="correspondence"><p>Correspondence: 451 Smyth Road, Roger Guindon Hall, Ottawa, Ontario, Canada K1M 8M5</p></note><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation></author></analytic><monogr><title level="j">Annals of Neurology</title><title level="j" type="abbrev">Ann Neurol.</title><idno type="pISSN">0364-5134</idno><idno type="eISSN">1531-8249</idno><idno type="DOI">10.1002/(ISSN)1531-8249</idno><imprint><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><pubPlace>Hoboken</pubPlace><date type="published" when="2011-06"></date><biblScope unit="volume">69</biblScope><biblScope unit="issue">6</biblScope><biblScope unit="page" from="940">940</biblScope><biblScope unit="page" to="953">953</biblScope></imprint></monogr><idno type="istex">CC9A43851B491441CFC64245FB061A1CE9852FB4</idno><idno type="DOI">10.1002/ana.22400</idno><idno type="ArticleID">ANA22400</idno></biblStruct></sourceDesc></fileDesc><profileDesc><creation><date>2011</date></creation><langUsage><language ident="en">en</language></langUsage><abstract xml:lang="en"><p>Objective:: Heterozygous mutations in the GBA1 gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic GBA1 mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk. Methods:: We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols. Results:: We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (p < 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; p < 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (p = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; p < 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; p < 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409Vgba knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; p = 0.019). In young Gaucher disease mice (V394Lgba+/+//prosaposin[ps]‐null//ps‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice. Interpretation:: Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between GBA1 mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;</p></abstract><textClass><keywords scheme="Journal Subject"><list><head>article category</head><item><term>Original Article</term></item></list></keywords></textClass></profileDesc><revisionDesc><change when="2010-10-06">Received</change><change when="2011-02-11">Registration</change><change when="2011-06">Published</change></revisionDesc></teiHeader></istex:fulltextTEI><json:item><original>false</original><mimetype>text/plain</mimetype><extension>txt</extension><uri>https://api.istex.fr/document/CC9A43851B491441CFC64245FB061A1CE9852FB4/fulltext/txt</uri></json:item></fulltext><metadata><istex:metadataXml wicri:clean="Wiley, elements deleted: body"><istex:xmlDeclaration>version="1.0" encoding="UTF-8" standalone="yes"</istex:xmlDeclaration><istex:document><component version="2.0" type="serialArticle" xml:lang="en"><header><publicationMeta level="product"><publisherInfo><publisherName>Wiley Subscription Services, Inc., A Wiley Company</publisherName><publisherLoc>Hoboken</publisherLoc></publisherInfo><doi registered="yes">10.1002/(ISSN)1531-8249</doi><issn type="print">0364-5134</issn><issn type="electronic">1531-8249</issn><idGroup><id type="product" value="ANA"></id></idGroup><titleGroup><title type="main" xml:lang="en" sort="ANNALS OF NEUROLOGY">Annals of Neurology</title><title type="short">Ann Neurol.</title></titleGroup></publicationMeta><publicationMeta level="part" position="60"><doi origin="wiley" registered="yes">10.1002/ana.v69.6</doi><numberingGroup><numbering type="journalVolume" number="69">69</numbering><numbering type="journalIssue">6</numbering></numberingGroup><coverDate startDate="2011-06">June 2011</coverDate></publicationMeta><publicationMeta level="unit" type="article" position="100" status="forIssue"><doi origin="wiley" registered="yes">10.1002/ana.22400</doi><idGroup><id type="unit" value="ANA22400"></id></idGroup><countGroup><count type="pageTotal" number="14"></count></countGroup><titleGroup><title type="articleCategory">Original Article</title><title type="tocHeading1">Original Articles</title></titleGroup><copyright ownership="publisher">Copyright © 2011 American Neurological Association</copyright><eventGroup><event type="manuscriptReceived" date="2010-10-06"></event><event type="manuscriptRevised" date="2011-01-20"></event><event type="manuscriptAccepted" date="2011-02-11"></event><event type="xmlConverted" agent="Converter:JWSART34_TO_WML3G version:3.0.1 mode:FullText" date="2012-02-06"></event><event type="publishedOnlineAccepted" date="2011-02-18"></event><event type="publishedOnlineEarlyUnpaginated" date="2011-04-06"></event><event type="publishedOnlineFinalForm" date="2011-06-16"></event><event type="firstOnline" date="2011-04-06"></event><event type="xmlConverted" agent="Converter:WILEY_ML3G_TO_WILEY_ML3GV2 version:3.8.8" date="2014-01-03"></event><event type="xmlConverted" agent="Converter:WML3G_To_WML3G version:4.1.7 mode:FullText,remove_FC" date="2014-10-14"></event></eventGroup><numberingGroup><numbering type="pageFirst">940</numbering><numbering type="pageLast">953</numbering></numberingGroup><correspondenceTo>451 Smyth Road, Roger Guindon Hall, Ottawa, Ontario, Canada K1M 8M5</correspondenceTo><linkGroup><link type="toTypesetVersion" href="file:ANA.ANA22400.pdf"></link></linkGroup></publicationMeta><contentMeta><countGroup><count type="figureTotal" number="6"></count><count type="tableTotal" number="1"></count><count type="referenceTotal" number="43"></count><count type="wordTotal" number="10282"></count></countGroup><titleGroup><title type="main" xml:lang="en">Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title><title type="short" xml:lang="en">Acid β‐Glucosidase Mutants</title></titleGroup><creators><creator xml:id="au1" creatorRole="author" affiliationRef="#af1" currentRef="#curr1"><personName><givenNames>Valerie</givenNames><familyName>Cullen</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au2" creatorRole="author" affiliationRef="#af2"><personName><givenNames>S. Pablo</givenNames><familyName>Sardi</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au3" creatorRole="author" affiliationRef="#af3"><personName><givenNames>Juliana</givenNames><familyName>Ng</familyName><degrees>BSc</degrees></personName></creator><creator xml:id="au4" creatorRole="author" affiliationRef="#af4"><personName><givenNames>You‐Hai</givenNames><familyName>Xu</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au5" creatorRole="author" affiliationRef="#af4"><personName><givenNames>Ying</givenNames><familyName>Sun</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au6" creatorRole="author" affiliationRef="#af3"><personName><givenNames>Julianna J.</givenNames><familyName>Tomlinson</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au7" creatorRole="author" affiliationRef="#af3"><personName><givenNames>Piotr</givenNames><familyName>Kolodziej</familyName><degrees>BSc</degrees></personName></creator><creator xml:id="au8" creatorRole="author" affiliationRef="#af1"><personName><givenNames>Ilana</givenNames><familyName>Kahn</familyName><degrees>MD</degrees></personName></creator><creator xml:id="au9" creatorRole="author" affiliationRef="#af5"><personName><givenNames>Paul</givenNames><familyName>Saftig</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au10" creatorRole="author" affiliationRef="#af3"><personName><givenNames>John</givenNames><familyName>Woulfe</familyName><degrees>MD, PhD</degrees></personName></creator><creator xml:id="au11" creatorRole="author" affiliationRef="#af6"><personName><givenNames>Jean‐Christophe</givenNames><familyName>Rochet</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au12" creatorRole="author" affiliationRef="#af7"><personName><givenNames>Marcie A.</givenNames><familyName>Glicksman</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au13" creatorRole="author" affiliationRef="#af2"><personName><givenNames>Seng H.</givenNames><familyName>Cheng</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au14" creatorRole="author" affiliationRef="#af4"><personName><givenNames>Gregory A.</givenNames><familyName>Grabowski</familyName><degrees>MD</degrees></personName></creator><creator xml:id="au15" creatorRole="author" affiliationRef="#af2"><personName><givenNames>Lamya S.</givenNames><familyName>Shihabuddin</familyName><degrees>PhD</degrees></personName></creator><creator xml:id="au16" creatorRole="author" affiliationRef="#af1 #af3" corresponding="yes"><personName><givenNames>Michael G.</givenNames><familyName>Schlossmacher</familyName><degrees>MD, FRCPC</degrees></personName><contactDetails><email>mschlossmacher@ohri.ca</email></contactDetails></creator></creators><affiliationGroup><affiliation xml:id="af1" countryCode="US" type="organization"><unparsedAffiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</unparsedAffiliation></affiliation><affiliation xml:id="af2" countryCode="US" type="organization"><unparsedAffiliation>Genzyme Corporation, Framingham, MA</unparsedAffiliation></affiliation><affiliation xml:id="af3" countryCode="CA" type="organization"><unparsedAffiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</unparsedAffiliation></affiliation><affiliation xml:id="af4" countryCode="US" type="organization"><unparsedAffiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</unparsedAffiliation></affiliation><affiliation xml:id="af5" countryCode="DE" type="organization"><unparsedAffiliation>Institute of Biochemistry, Christian‐Albrechts University, Kiel, Germany</unparsedAffiliation></affiliation><affiliation xml:id="af6" countryCode="US" type="organization"><unparsedAffiliation>Department of Medicinal Chemistry and Molecular Pharmacology, Purdue University, West Lafayette, IN</unparsedAffiliation></affiliation><affiliation xml:id="af7" countryCode="US" type="organization"><unparsedAffiliation>Laboratory for Drug Discovery in Neurodegeneration, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</unparsedAffiliation></affiliation><affiliation xml:id="curr1"><unparsedAffiliation>Dr Cullen: LINK Medicine Corp, Cambridge, MA 02142</unparsedAffiliation></affiliation></affiliationGroup><supportingInformation><p> Additional supporting information can be found in the online version of this article. </p><supportingInfoItem><mediaResource alt="supporting information" href="urn-x:wiley:03645134:media:ana22400:ANA_22400_sm_suppinfofig1"></mediaResource><caption>Supporting Information Figure 1.</caption></supportingInfoItem><supportingInfoItem><mediaResource alt="supporting information" href="urn-x:wiley:03645134:media:ana22400:ANA_22400_sm_suppinfofig2"></mediaResource><caption>Supporting Information Figure 2.</caption></supportingInfoItem><supportingInfoItem><mediaResource alt="supporting information" href="urn-x:wiley:03645134:media:ana22400:ANA_22400_sm_suppinfofig3"></mediaResource><caption>Supporting Information Figure 3.</caption></supportingInfoItem></supportingInformation><abstractGroup><abstract type="main" xml:lang="en"><title type="main">Abstract</title><section xml:id="abs1-1"><title type="main">Objective:</title><p>Heterozygous mutations in the <i>GBA1</i> gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic <i>GBA1</i> mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk.</p></section><section xml:id="abs1-2"><title type="main">Methods:</title><p>We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols.</p></section><section xml:id="abs1-3"><title type="main">Results:</title><p>We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (<i>p</i> < 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; <i>p</i> < 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (<i>p</i> = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; <i>p</i> < 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; <i>p</i> < 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409V<i>gba</i> knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; <i>p</i> = 0.019). In young Gaucher disease mice (V394L<i>gba</i>+/+//prosaposin[<i>ps</i>]‐null//<i>ps</i>‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice.</p></section><section xml:id="abs1-4"><title type="main">Interpretation:</title><p>Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between <i>GBA1</i> mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;</p></section></abstract></abstractGroup></contentMeta></header></component></istex:document></istex:metadataXml><mods version="3.6"><titleInfo lang="en"><title>Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title></titleInfo><titleInfo type="abbreviated" lang="en"><title>Acid β‐Glucosidase Mutants</title></titleInfo><titleInfo type="alternative" contentType="CDATA" lang="en"><title>Acid β‐glucosidase mutants linked to gaucher disease, parkinson disease, and lewy body dementia alter α‐synuclein processing</title></titleInfo><name type="personal"><namePart type="given">Valerie</namePart><namePart type="family">Cullen</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><affiliation>Current Address: Dr Cullen: LINK Medicine Corp, Cambridge, MA 02142</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">S. Pablo</namePart><namePart type="family">Sardi</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Genzyme Corporation, Framingham, MA</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Juliana</namePart><namePart type="family">Ng</namePart><namePart type="termsOfAddress">BSc</namePart><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">You‐Hai</namePart><namePart type="family">Xu</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Ying</namePart><namePart type="family">Sun</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Julianna J.</namePart><namePart type="family">Tomlinson</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Piotr</namePart><namePart type="family">Kolodziej</namePart><namePart type="termsOfAddress">BSc</namePart><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Ilana</namePart><namePart type="family">Kahn</namePart><namePart type="termsOfAddress">MD</namePart><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Paul</namePart><namePart type="family">Saftig</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Institute of Biochemistry, Christian‐Albrechts University, Kiel, Germany</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">John</namePart><namePart type="family">Woulfe</namePart><namePart type="termsOfAddress">MD, PhD</namePart><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Jean‐Christophe</namePart><namePart type="family">Rochet</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Department of Medicinal Chemistry and Molecular Pharmacology, Purdue University, West Lafayette, IN</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Marcie A.</namePart><namePart type="family">Glicksman</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Laboratory for Drug Discovery in Neurodegeneration, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Seng H.</namePart><namePart type="family">Cheng</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Genzyme Corporation, Framingham, MA</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Gregory A.</namePart><namePart type="family">Grabowski</namePart><namePart type="termsOfAddress">MD</namePart><affiliation>Division of Human Genetics, Cincinnati Children's Hospital Medical Center and Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Lamya S.</namePart><namePart type="family">Shihabuddin</namePart><namePart type="termsOfAddress">PhD</namePart><affiliation>Genzyme Corporation, Framingham, MA</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Michael G.</namePart><namePart type="family">Schlossmacher</namePart><namePart type="termsOfAddress">MD, FRCPC</namePart><affiliation>Center for Neurologic Diseases, Department of Neurology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA</affiliation><affiliation>Division of Neuroscience, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, Ontario, Canada</affiliation><description>Correspondence: 451 Smyth Road, Roger Guindon Hall, Ottawa, Ontario, Canada K1M 8M5</description><role><roleTerm type="text">author</roleTerm></role></name><typeOfResource>text</typeOfResource><genre type="article" displayLabel="article"></genre><originInfo><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><place><placeTerm type="text">Hoboken</placeTerm></place><dateIssued encoding="w3cdtf">2011-06</dateIssued><dateCaptured encoding="w3cdtf">2010-10-06</dateCaptured><dateValid encoding="w3cdtf">2011-02-11</dateValid><copyrightDate encoding="w3cdtf">2011</copyrightDate></originInfo><language><languageTerm type="code" authority="rfc3066">en</languageTerm><languageTerm type="code" authority="iso639-2b">eng</languageTerm></language><physicalDescription><internetMediaType>text/html</internetMediaType><extent unit="figures">6</extent><extent unit="tables">1</extent><extent unit="references">43</extent><extent unit="words">10282</extent></physicalDescription><abstract lang="en">Objective:: Heterozygous mutations in the GBA1 gene elevate the risk of Parkinson disease and dementia with Lewy bodies; both disorders are characterized by misprocessing of α‐synuclein (SNCA). A loss in lysosomal acid–β‐glucosidase enzyme (GCase) activity due to biallelic GBA1 mutations underlies Gaucher disease. We explored mechanisms for the gene's association with increased synucleinopathy risk. Methods:: We analyzed the effects of wild‐type (WT) and several GBA mutants on SNCA in cellular and in vivo models using biochemical and immunohistochemical protocols. Results:: We observed that overexpression of all GBA mutants examined (N370S, L444P, D409H, D409V, E235A, and E340A) significantly raised human SNCA levels to 121 to 248% of vector control (p < 0.029) in neural MES23.5 and PC12 cells, but without altering GCase activity. Overexpression of WT GBA in neural and HEK293‐SNCA cells increased GCase activity, as expected (ie, to 167% in MES‐SNCA, 128% in PC12‐SNCA, and 233% in HEK293‐SNCA; p < 0.002), but had mixed effects on SNCA. Nevertheless, in HEK293‐SNCA cells high GCase activity was associated with SNCA reduction by ≤32% (p = 0.009). Inhibition of cellular GCase activity (to 8–20% of WT; p < 0.0017) did not detectably alter SNCA levels. Mutant GBA‐induced SNCA accumulation could be pharmacologically reversed in D409V‐expressing PC12‐SNCA cells by rapamycin, an autophagy‐inducer (≤40%; 10μM; p < 0.02). Isofagomine, a GBA chaperone, showed a related trend. In mice expressing two D409Vgba knockin alleles without signs of Gaucher disease (residual GCase activity, ≥20%), we recorded an age‐dependent rise of endogenous Snca in hippocampal membranes (125% vs WT at 52 weeks; p = 0.019). In young Gaucher disease mice (V394Lgba+/+//prosaposin[ps]‐null//ps‐transgene), which demonstrate neurological dysfunction after age 10 weeks (GCase activity, ≤10%), we recorded no significant change in endogenous Snca levels at 12 weeks of age. However, enhanced neuronal ubiquitin signals and axonal spheroid formation were already present. The latter changes were similar to those seen in three week‐old cathepsin D‐deficient mice. Interpretation:: Our results demonstrate that GBA mutants promote SNCA accumulation in a dose‐ and time‐dependent manner, thereby identifying a biochemical link between GBA1 mutation carrier status and increased synucleinopathy risk. In cell culture models, this gain of toxic function effect can be mitigated by rapamycin. Loss in GCase activity did not immediately raise SNCA concentrations, but first led to neuronal ubiquitinopathy and axonal spheroids, a phenotype shared with other lysosomal storage disorders. ANN NEUROL 2011;</abstract><relatedItem type="host"><titleInfo><title>Annals of Neurology</title></titleInfo><titleInfo type="abbreviated"><title>Ann Neurol.</title></titleInfo><genre type="Journal">journal</genre><note type="content"> Additional supporting information can be found in the online version of this article.Supporting Info Item: Supporting Information Figure 1. - Supporting Information Figure 2. - Supporting Information Figure 3. - </note><subject><genre>article category</genre><topic>Original Article</topic></subject><identifier type="ISSN">0364-5134</identifier><identifier type="eISSN">1531-8249</identifier><identifier type="DOI">10.1002/(ISSN)1531-8249</identifier><identifier type="PublisherID">ANA</identifier><part><date>2011</date><detail type="volume"><caption>vol.</caption><number>69</number></detail><detail type="issue"><caption>no.</caption><number>6</number></detail><extent unit="pages"><start>940</start><end>953</end><total>14</total></extent></part></relatedItem><identifier type="istex">CC9A43851B491441CFC64245FB061A1CE9852FB4</identifier><identifier type="DOI">10.1002/ana.22400</identifier><identifier type="ArticleID">ANA22400</identifier><accessCondition type="use and reproduction" contentType="copyright">Copyright © 2011 American Neurological Association</accessCondition><recordInfo><recordContentSource>WILEY</recordContentSource><recordOrigin>Wiley Subscription Services, Inc., A Wiley Company</recordOrigin></recordInfo></mods></metadata><serie></serie></istex></record>Pour manipuler ce document sous Unix (Dilib)
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