Gaucher disease an immunoelectron microscopic and biochemical study /

Willemsen, Robert,

January 1995

Thesis Erasmus University Rotterdam. / Auteursnaam op omslag: Rob Willemsen. ook verschenen in gedrukte versie. With bibliogr., with a summary in Dutch.

Humanização específica do sistema de glicosilação de Pichia pastoris pela técnica CRISPR/Cas9 visando a expressão de glicoproteínas humanas / Specific humanization of Pichia pastoris glycosylation system with the CRISPR/Cas9 technique aiming the expression of human glycoproteins

Vitarelli, Marcela de Oliveira

06 December 2016

A produção de proteínas terapêuticas recombinantes compreende moléculas complexas e de alto valor agregado, incluindo a enzima glucocerebrosidase (GCase). Sua deficiência resulta na Doença de Gaucher, passível de tratamento por meio da terapia de reposição enzimática. A forma ativa da GCase recombinante usada na terapia apresenta resíduos terminais de manose expostos no seu perfil de glicosilação. Perfil este que espera-se ser reproduzido por meio da construção de uma linhagem de Pichia pastoris com um padrão de glicosilação humanizado, por meio da deleção de dois genes envolvidos no sistema de glicosilação da levedura: alg3 e och1, responsáveis pela posterior hiper-manosilação característica desse organismo. Assim, a expressão da GCase será usada como modelo no desenvolvimento desta linhagem de Pichia pastoris que permita a expressão de glicoproteínas com um perfil humanizado específico de glicosilação. Além da produção da linhagem mutante pela técnica de CRISPR/Cas9, propomos a construção de duas linhagens controle: uma expressando a proteína GCase para análise do seu padrão selvagem de glicosilação em P. pastoris e outra expressando a proteína Cas9 de Streptoccocus pyogenes (SpCas9). A linhagem P. pastoris/GCase foi construída testando-se duas sequências sinal de secreção diferentes: fosfatase alcalina (PHO1) e albumina humana (Alb). Resultados de western blot mostraram a GCase no lisado celular e baixos níveis de proteína secretada no sobrenadante de cultura, sendo mais expresso na linhagem contendo a sequência PHO1. A linhagem P. pastoris/SpCas9 foi construída e a enzima SpCas9 foi detectada via western blot no lisado celular após indução com metanol. Para a produção da linhagem com padrão de glicosilação humanizado propôs-se a deleção dos genes alg3 e och1 e a inserção, pela via de reparo por recombinação homóloga (HDR), de marcas de resistência aos antibióticos higromicina ou canamicina. Para tal, propusemos a construção de dois vetores finais de expressão do sistema CRISPR/Cas9 em P. pastoris, cada um contendo a enzima SpCas9 e os RNAs guia (gRNAs) para deleção do gene alg3 ou och1, e também a construção de dois fragmentos para HDR contendo o gene de resistência ao antibiótico flanqueado por regiões de 1Kb de homologia com a região de deleção do gene alg3 ou och1. A construção dos vetores e fragmentos para HDR foram inicialmente feitas por meio de técnicas de clonagem clássica. No entanto, apesar de inúmeras tentativas, resultados de PCR e sequenciamento mostraram o insucesso das construções. Partiu-se então para a técnica de Gibson Assembly®, através da qual os dois fragmentos para HDR foram construídos. Porém, os vetores de expressão contendo SpCas9 e os gRNAs ainda apresentam dificuldades na sua construção. Esforços ainda estão sendo feitos para a construção dos vetores e consequente tentativa de estabelecimento das linhagens mutantes. O sucesso no estabelecimento de um sistema de expressão de proteínas heterólogas com este padrão de glicosilação humano específico permitirá a obtenção e possível comercialização da GCase em sua forma terapêutica. Além disso, permitirá possíveis edições genômicas futuras para um padrão de maior complexidade de glicosilação humanizado, criando uma plataforma nacional para produção de outras glicoproteínas terapêuticas de interesse biotecnológico. / The production of therapeutic recombinant protein comprises complex and high valued molecules, including the glucocerebrosidase enzyme (GCase). Its deficiency results in Gaucher Disease, susceptible of treatment by enzymatic replacement therapy. The active form of recombinant GCase employed in therapy presents exposed terminal mannose residues in its glycosylation pattern. We hope to reproduce such pattern by constructing a Pichia pastoris strain with a specific human glycosylation pattern through the deletion of two genes involved in yeast glycosylation system, alg3 and och1, responsible for the final hyper-mannosylation characteristic of this organism. Therefore, the expression of GCase will be a case model for the development of the recombinant Pichia pastoris strain that could allow the expression of glycoproteins with a specific humanized glycosylation profile. Despite the establishment of the mutant strain using the CRISPR/Cas9 technique, we propose the construction of two control strains: one expressing the GCase protein for analysis of its wild type glycosylation pattern and another one expressing the Cas9 protein from Streptoccocus pyogenes (SpCas9). The P. pastoris/GCase strain was constructed testing two different secretion signal sequences: alkaline fosfatase (PHO1) and human albumin (Alb). Western blot results have shown GCase in cell lysate and in low expression levels in culture supernatant, being more expressed in the strain containing the PHO1 signal sequence. P. pastoris/SpCas9 strain was constructed and SpCas9 enzyme was detected via western blot in cell lysate after the induction with methanol. To produce the strain with the humanized glycosylation pattern, the deletion of alg3 and och1 genes was proposed along with the insertion, by homology directed repair pathway (HDR), of hygromycin and kanamycin antibiotics resistance marks. In order to do so, we have proposed the construction of two final expression vectors of the CRISPR/Cas9 system in P. pastoris, each one containing SpCas9 enzyme and the guide RNAs (gRNAs) for deletion of alg3 or och1, and also the construction of two fragments for HDR containing the antibiotics resistance gene flanked by 1Kb regions of homology with the deleted regions of alg3 or och1. Vectors and HDR fragments constructions were initially performed using classic cloning techniques. However, despite numerous tries, PCR and sequencing results have shown the failure of the constructions. Then, we moved on to the Gibson Assembly® technique, through which the two HDR fragments were built. Still, the expression vectors containing SpCas9 and the gRNAs presented difficulties in its assembly. Efforts continue to be made to successfully construct the remaining vectors and to establish the mutant lineage. Success in the establishment of a heterologous protein expression system with specific human glycosylation pattern will allow the obtainment and possible commercialization of the therapeutic form of GCase. Furthermore, it will also allow possible future genomic editing to a high complexity human glycosylation pattern, creating a national platform for the production of other therapeutic glycoproteins of biotechnological interest.

CRISPR-Cas9

CRISPR-Cas9

Edição gênica

Genome editing

Glucocerebrosidase

Glucocerebrosidase

Pichia pastoris

Pichia pastoris

Humanização específica do sistema de glicosilação de Pichia pastoris pela técnica CRISPR/Cas9 visando a expressão de glicoproteínas humanas / Specific humanization of Pichia pastoris glycosylation system with the CRISPR/Cas9 technique aiming the expression of human glycoproteins

Marcela de Oliveira Vitarelli

06 December 2016

A produção de proteínas terapêuticas recombinantes compreende moléculas complexas e de alto valor agregado, incluindo a enzima glucocerebrosidase (GCase). Sua deficiência resulta na Doença de Gaucher, passível de tratamento por meio da terapia de reposição enzimática. A forma ativa da GCase recombinante usada na terapia apresenta resíduos terminais de manose expostos no seu perfil de glicosilação. Perfil este que espera-se ser reproduzido por meio da construção de uma linhagem de Pichia pastoris com um padrão de glicosilação humanizado, por meio da deleção de dois genes envolvidos no sistema de glicosilação da levedura: alg3 e och1, responsáveis pela posterior hiper-manosilação característica desse organismo. Assim, a expressão da GCase será usada como modelo no desenvolvimento desta linhagem de Pichia pastoris que permita a expressão de glicoproteínas com um perfil humanizado específico de glicosilação. Além da produção da linhagem mutante pela técnica de CRISPR/Cas9, propomos a construção de duas linhagens controle: uma expressando a proteína GCase para análise do seu padrão selvagem de glicosilação em P. pastoris e outra expressando a proteína Cas9 de Streptoccocus pyogenes (SpCas9). A linhagem P. pastoris/GCase foi construída testando-se duas sequências sinal de secreção diferentes: fosfatase alcalina (PHO1) e albumina humana (Alb). Resultados de western blot mostraram a GCase no lisado celular e baixos níveis de proteína secretada no sobrenadante de cultura, sendo mais expresso na linhagem contendo a sequência PHO1. A linhagem P. pastoris/SpCas9 foi construída e a enzima SpCas9 foi detectada via western blot no lisado celular após indução com metanol. Para a produção da linhagem com padrão de glicosilação humanizado propôs-se a deleção dos genes alg3 e och1 e a inserção, pela via de reparo por recombinação homóloga (HDR), de marcas de resistência aos antibióticos higromicina ou canamicina. Para tal, propusemos a construção de dois vetores finais de expressão do sistema CRISPR/Cas9 em P. pastoris, cada um contendo a enzima SpCas9 e os RNAs guia (gRNAs) para deleção do gene alg3 ou och1, e também a construção de dois fragmentos para HDR contendo o gene de resistência ao antibiótico flanqueado por regiões de 1Kb de homologia com a região de deleção do gene alg3 ou och1. A construção dos vetores e fragmentos para HDR foram inicialmente feitas por meio de técnicas de clonagem clássica. No entanto, apesar de inúmeras tentativas, resultados de PCR e sequenciamento mostraram o insucesso das construções. Partiu-se então para a técnica de Gibson Assembly®, através da qual os dois fragmentos para HDR foram construídos. Porém, os vetores de expressão contendo SpCas9 e os gRNAs ainda apresentam dificuldades na sua construção. Esforços ainda estão sendo feitos para a construção dos vetores e consequente tentativa de estabelecimento das linhagens mutantes. O sucesso no estabelecimento de um sistema de expressão de proteínas heterólogas com este padrão de glicosilação humano específico permitirá a obtenção e possível comercialização da GCase em sua forma terapêutica. Além disso, permitirá possíveis edições genômicas futuras para um padrão de maior complexidade de glicosilação humanizado, criando uma plataforma nacional para produção de outras glicoproteínas terapêuticas de interesse biotecnológico. / The production of therapeutic recombinant protein comprises complex and high valued molecules, including the glucocerebrosidase enzyme (GCase). Its deficiency results in Gaucher Disease, susceptible of treatment by enzymatic replacement therapy. The active form of recombinant GCase employed in therapy presents exposed terminal mannose residues in its glycosylation pattern. We hope to reproduce such pattern by constructing a Pichia pastoris strain with a specific human glycosylation pattern through the deletion of two genes involved in yeast glycosylation system, alg3 and och1, responsible for the final hyper-mannosylation characteristic of this organism. Therefore, the expression of GCase will be a case model for the development of the recombinant Pichia pastoris strain that could allow the expression of glycoproteins with a specific humanized glycosylation profile. Despite the establishment of the mutant strain using the CRISPR/Cas9 technique, we propose the construction of two control strains: one expressing the GCase protein for analysis of its wild type glycosylation pattern and another one expressing the Cas9 protein from Streptoccocus pyogenes (SpCas9). The P. pastoris/GCase strain was constructed testing two different secretion signal sequences: alkaline fosfatase (PHO1) and human albumin (Alb). Western blot results have shown GCase in cell lysate and in low expression levels in culture supernatant, being more expressed in the strain containing the PHO1 signal sequence. P. pastoris/SpCas9 strain was constructed and SpCas9 enzyme was detected via western blot in cell lysate after the induction with methanol. To produce the strain with the humanized glycosylation pattern, the deletion of alg3 and och1 genes was proposed along with the insertion, by homology directed repair pathway (HDR), of hygromycin and kanamycin antibiotics resistance marks. In order to do so, we have proposed the construction of two final expression vectors of the CRISPR/Cas9 system in P. pastoris, each one containing SpCas9 enzyme and the guide RNAs (gRNAs) for deletion of alg3 or och1, and also the construction of two fragments for HDR containing the antibiotics resistance gene flanked by 1Kb regions of homology with the deleted regions of alg3 or och1. Vectors and HDR fragments constructions were initially performed using classic cloning techniques. However, despite numerous tries, PCR and sequencing results have shown the failure of the constructions. Then, we moved on to the Gibson Assembly® technique, through which the two HDR fragments were built. Still, the expression vectors containing SpCas9 and the gRNAs presented difficulties in its assembly. Efforts continue to be made to successfully construct the remaining vectors and to establish the mutant lineage. Success in the establishment of a heterologous protein expression system with specific human glycosylation pattern will allow the obtainment and possible commercialization of the therapeutic form of GCase. Furthermore, it will also allow possible future genomic editing to a high complexity human glycosylation pattern, creating a national platform for the production of other therapeutic glycoproteins of biotechnological interest.

CRISPR-Cas9

Edição gênica

Glucocerebrosidase

Pichia pastoris

CRISPR-Cas9

Genome editing

Glucocerebrosidase

Pichia pastoris

Mechanisms and prevention of protein aggregation

Barber, Michael

January 2016

The deposition of amyloid in the central nervous system is associated with prevalent neurological disorders such as Alzheimer's and Parkinson's disease. This thesis studies the mechanisms and prevention of amyloid formation in vitro. We specifically focus on Parkinson's disease associated α-synuclein (α-syn). Using novel labeling methods we introduce NMR observable labels onto lysosomal protein glucocerebrosidase (GCase), a leading cause of Parkinson's disease. By introducing NMR active labels we are able to study GCase dynamics and screen potential drug therapeutics (chapter 3). Furthermore, we analyze the three way interaction between GCase, α-syn and lipids. We conclude that GCase is able to effectively chaperone α-syn under lysosomal conditions, both preventing amyloidogenesis and destabilizing mature amyloid fibrils (chapter 4). Additionally, a model chaperone-aggregate system is investigated to gain insight into the mechanisms of small heat shock protein chaperoning, and how such mechanisms prevent aggregation (chapter 5). Finally, a high resolution crystal structure of RNA editing enzyme Cid1 is presented, whilst not directly linked to aggregation, many of the techniques used in this thesis were first developed on Cid1 (chapter 7). Together, we utilize NMR, X-ray crystallography, electron microscopy and native mass spectrometry to elucidate aspects of protein aggregation mechanisms and prevention.

Lysosomální dědičná onemocnění: patobiochemie Gaucherovy choroby / Lysosomal inherited disorders - pathobiochemistry of the Gaucher disease

Illner, Jan

January 2011

Gaucher disease is one of the lysosomal storage disorders belonging to inherited defects of catabolism of sphingolipids. These defects are caused by mutation in genes of sphingolipid hydrolases or their protein activators. Subsequent storage of non-degraded sphingolipids leads to severe clinical phenotypes in patients. Gaucher disease is caused by deficiency of lysosomal β-glucocerebrosidase (GBA1) activity. Non-degraded glycosphingolipids are glucosylceramide (GlcCer) and glucosylpsychosine (lyso-GlcCer). Accumulation of these glycosphingolipids is related to Gaucher cells which are derived from macrophages and are abundant in spleen, liver or lung. The objective of the diploma thesis is pathobiochemistry of above mentioned glycosphingolipids. One of the topics of this work was optimization of mass spectrometry method for determination of activity of lysosomal β-glucocerebrosidase, using a natural substrate. The method was successfully optimized and can be effectively used for diagnostic purpose, instead of methods utilizing artificial substrates. In the next step, we performed analysis of pH profiles of lysosomal β-glucocerebrosidase activity focusing to search for non-lysosomal enzyme, which is able to degrade glucosylceramide. Evaluation of pH profiles did not confirm the existence of such an...

Viable neuronopathic Gaucher disease model in medaka (Oryzias latipes) displays axonal accumulation of alpha-synuclein / 生存可能な神経型ゴーシェ病モデルメダカは軸索にアルファシヌクレイン蓄積を示す

Uemura, Norihito

25 May 2015

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19178号 / 医博第4020号 / 新制||医||1010(附属図書館) / 32170 / 京都大学大学院医学研究科医学専攻 / (主査)教授 髙橋 淳, 教授 渡邉 大, 教授 村井 俊哉 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Parkinson's disease

Gaucher disease

alpha-synuclein

glucocerebrosidase

medaka

490

Vyšetření rekombinací mezi genem a pseudogenem pro β-glukocerebrosidasu vedoucích ke vzniku patogenních alel / Detection of β-glucocerebrosidase gene/pseudogene recombination events leading to pathogenic alleles

Peková, Barbora

January 2017

This diploma thesis provides an overview of gene conversion, its role in the pathogenesis of human diseases and the use of methods based on next-generation sequencing (NGS) for detection rare variants of DNA sequence. Labeling of target DNA molecules by random nucleotides in primer and NGS were used for detection point mutations arising de novo in the β-glucocerebrosidase gene by gene conversion between it and its pseudogene in meiotic and mitotic cells of control subjects. Primers specific for the active gene were used to selectively amplify the ninth and tenth exon of the gene where "recombinant" variants occur most frequently. Sequences generated from 20 genomic DNA samples on Illumina MiSeq platform were quality filtered, sorted by unique labels and consensus sequences were created from alignments of sequences carrying the same DNA tag. The number of potential point mutations in the samples ranged between 12 and 48. The mutations were manually re-evaluated from the alignments. The number of alignments with unique labeling was in the range of 7-15 thousand per sample. Only three samples carried possible recombinant mutations, suggesting a lower frequency of conversion in the region than reported by other techniques. Analysis of unique sequences in primer indicated possible ways to improve the...

Modulating Protein Homeostasis to Ameliorate Lysosomal Storage Disorders

Wang, Fan

06 September 2012

The goal of this project has been to develop therapeutic strategies for protein misfolding diseases caused by excessive degradation of misfolded proteins and loss of protein function. The focus for this work is lysosomal storage disorders (LSDs), a group of more than 50 known inherited metabolic diseases characterized by deficiency in hydrolytic enzymes and consequent buildup of lysosomal macromolecules. Gaucher’s Disease (GD) is used as a representative of the family of LSDs in this study. GD is caused by mutations in the gene encoding lysosomal glucocerebrosidase (GC) and consequent accumulation of the GC substrate, glucocerebroside. The most prevalent mutations among GD patients are single amino acid substitutions that do not directly impair GC activity, but rather destabilize its native folding. GC normally folds in the ER and trafficks through the secretory pathway to the lysosomes. GC variants containing destabilizing mutations misfold and are retrotranslocated to the cytoplasm for ER-associated degradation (ERAD). However, evidence shows that if misfolding-prone, mutated GC variants are forced to fold into their 3D native structure, they retain catalytic activity. This study describes strategies to remodel the network of cellular pathways that maintain protein homeostasis and to create a folding environment favorable to the folding of unstable, degradation-prone lysosomal enzyme variants. We demonstrated that folding and trafficking of mutated GC variants can be achieved by modulating the protein folding network in fibroblasts derived from patients with GD to i) upregulate the expression of ER luminal chaperones, ii) inhibit the ERAD pathway, and iii) enhance the pool of mutated GC in the ER amenable to folding rescue. We also demonstrated that the same cell engineering strategies that proved successful in rescuing the folding and activity of mutated GC enable rescue of mutated enzyme variants in fibroblasts derived from patients with Tay-Sachs disease, a LSD caused by deficiency of lysosomal hexosaminidase A activity. As a result, the current study provides insights for the development of therapeutic strategies for GD based on the modulation of general cellular pathways that maintain protein homeostasis that could in principle be applied to the treatment of multiple LSDs.

Gaucher's Disease

Lysosomal Storage Disorders

Glucocerebrosidase

Proteostasis

Protein folding

Calcium homeostasis

Molecular chaperone

ER-associated degradation

The Role of Neutral Sphingolipids in the Pathogenesis of Parkinson Disease and Dementia with Lewy Bodies

Singh, Priyanka

19 April 2013

The molecular mechanisms underlying the association between mutations in GBA1 and risk of developing the ‘synucleinopathy’ disorders Parkinson’s disease (PD) and dementia with Lewy bodies (DLB) remain elusive. To better understand the precise molecular cascade that connects GBA1 mutations with α-synuclein dysregulation, a modified lipid extraction and HPTLC protocol was optimized to detect changes in levels of neutral sphingolipids (SLs) from neural cells and tissue expressing wild-type (WT) GBA1, mutant GBA1, or both. We demonstrate that mutant GBA1 does not confer a dominant-negative effect on WT GBA1-mediated activity; however, bona fide loss-of-enzymatic function mutation events led to the accumulation of lipid substrates in neural cells and tissue, and enhance α- synuclein/ubiquitin reactivity in brain tissue of mutant gba1 mice. Our HPLC-MS/MS data are consistent with other studies demonstrating that heterozygous GBA1 mutations do not lead to lipid accumulation, but may alter α-synuclein degradation through a yet-to-be defined novel gain-of-toxic function event.

Parkinson Disease

Dementia with Lewy bodies

Synucleinopathy

Glucocerebrosidase

GBA1

Sphingolipids

Glucosylceramide

Glucosylsphingosine

Alpha-synuclein

The Role of Neutral Sphingolipids in the Pathogenesis of Parkinson Disease and Dementia with Lewy Bodies

Singh, Priyanka

January 2013

The molecular mechanisms underlying the association between mutations in GBA1 and risk of developing the ‘synucleinopathy’ disorders Parkinson’s disease (PD) and dementia with Lewy bodies (DLB) remain elusive. To better understand the precise molecular cascade that connects GBA1 mutations with α-synuclein dysregulation, a modified lipid extraction and HPTLC protocol was optimized to detect changes in levels of neutral sphingolipids (SLs) from neural cells and tissue expressing wild-type (WT) GBA1, mutant GBA1, or both. We demonstrate that mutant GBA1 does not confer a dominant-negative effect on WT GBA1-mediated activity; however, bona fide loss-of-enzymatic function mutation events led to the accumulation of lipid substrates in neural cells and tissue, and enhance α- synuclein/ubiquitin reactivity in brain tissue of mutant gba1 mice. Our HPLC-MS/MS data are consistent with other studies demonstrating that heterozygous GBA1 mutations do not lead to lipid accumulation, but may alter α-synuclein degradation through a yet-to-be defined novel gain-of-toxic function event.

Parkinson Disease

Dementia with Lewy bodies

Synucleinopathy

Glucocerebrosidase

GBA1

Sphingolipids

Glucosylceramide

Glucosylsphingosine

Alpha-synuclein