Desenvolvimento de vetores nanotecnológicos lipídicos do sistema CRISPR/Cas9 visando à terapia gênica para Mucopolissacaridose tipo I

Schuh, Roselena Silvestri

January 2017

A mucopolissacaridose tipo I (MPS I) é causada pela deficiência de alfa-L-iduronidase (IDUA), responsável pelo catabolismo de glicosaminoglicanos (GAGs), levando ao acúmulo multissistêmico de sulfato de heparano e dermatano. Este estudo tem por objetivo avaliar o potencial de sistemas lipídicos nanoestruturados como carreadores do plasmídeo do sistema CRISPR/Cas9 e um vetor doador da sequência do gene IDUA/Idua para edição gênica em fibroblastos de pacientes e em modelo murino de MPS I. Foram produzidos lipossomas (DOTAP, DOPE e DSPE-PEG) e nanoemulsões (e TCM) por homogeneização à alta pressão e microfluidização. O DNA foi associado às formulações por adsorção, ou por encapsulamento dos complexos pré-formados DNA/DOTAP no núcleo oleoso da nanoemulsão. A eficiência de transfecção dos complexos foi avaliada em fibroblastos de pacientes MPS I e ocorreu um aumento significativo da atividade de IDUA em 2, 15 e 30 dias após os tratamentos, que promoveu uma redução na quantidade de lisossomos nos fibroblastos tratados. A caracterização físico-química de formulações produzidas por microfluidização complexadas a somente um plasmídeo ou juntamente com um oligonucleotídeo foi verificada e pode-se afirmar que a capacidade de complexação e transfecção depende diretamente do tipo celular e da relação de cargas, e não há implicações quanto ao tamanho das sequências de ácidos nucleicos. Camundongos MPS I receberam os complexos lipossomais por injeção hidrodinâmica e sua biodistribuição foi detectada principalmente no pulmão, coração e fígado. A atividade sérica de IDUA normal aumentou em cerca de 6% e foi mantida por seis meses. A atividade aumentada no pulmão, coração, fígado e rim após eutanásia promoveu redução dos GAGs na urina e nos mesmos tecidos, corroborando com as análises histológicas. Em um estudo em andamento, foi realizada uma investigação mais aprofundada do efeito do tratamento lipossomal na morfologia óssea, sistemas cardiovascular e respiratório, e funções cerebrais dos animais tratados. A análise ecocardiográfica demonstrou uma melhora na hipertrofia e contratilidade do coração, porém não houve melhora na espessura das válvulas. O diâmetro da aorta foi similar ao de animais normais, porém as quebras de elastina ficaram entre o grupo normal e o não tratado. A morfologia facial dos animais tratados foi intermediária, assim como a espessura do osso zigomático. Entretanto, o osso femoral demonstrou espessura comparável ao normal. Já a resistência pulmonar apresentou uma tendência de redução nos animais tratados em relação aos animais MPS I. O conjunto de resultados demonstra o potencial das nanoestruturas lipídicas co-complexadas com o plasmídeo CRISPR/Cas9 e um vetor doador da sequência IDUA/Idua para terapia gênica da MPS I. / Mucopolysaccharidosis type I (MPS I) is caused by the deficiency of alpha-L-iduronidase (IDUA), responsible for the catabolism of glycosaminoglycans (GAGs), leading to multisystemic accumulation of heparan and dermatan sulfate. This study aims to evaluate the potential of lipid-based nanostructures as carriers of the CRISPR/Cas9 plasmid and a vector donor of the IDUA/Idua sequence for gene editing in patients’ fibroblasts and in a murine model of MPS I. Liposomes (DOTAP, DOPE, and DSPE-PEG) and nanoemulsions (also MCT) were produced through high-pressure homogenization or microfluidization. DNA was associated with liposomes and nanoemulsions by adsorption or by encapsulation of DNA/DOTAP preformed complexes in the oil core of nanoemulsions. The transfection efficiency of complexes was evaluated in fibroblasts from MPS I patients and a significant increase in IDUA activity was demonstrated at 2, 15, and 30 days after treatments. It was also possible to observe a significant reduction in lysosomal amount in treated fibroblasts. The physicochemical characterization of liposomes and nanoemulsions produced through microfluidization complexed with a single plasmid or along with an oligonucleotide has been verified and it can be stated that the complexing and transfection capacity of the complexes depends directly on the cell type and the charge ratio, and there are no implications of the size of the nucleic acid sequences. MPS I mice received the liposomal complexes by hydrodynamic injection and their immediate biodistribution was detected mainly in the lung, heart, and liver. An increase of about 6% in normal serum IDUA activity was maintained for six months, in addition to increased lung, heart, liver, and kidney activity after euthanasia. The enhanced enzymatic activity promoted a significant GAGs reduction in urine and in the same tissues, corroborating with histological analysis. In an ongoing study, a deeper investigation was carried out on the effect of liposomal treatment on bone morphology, cardiovascular and respiratory systems, and brain function. The echocardiographic analysis showed an improvement in the parameters of hypertrophy and contractility of the heart, but there was no improvement in heart valves. Aorta diameter was similar to that of normal animals, but elastin breaks were between the normal and untreated groups. Facial morphology of treated animals was intermediate, as well as the analysis of zygomatic bone thickness. However, femoral bone showed thickness comparable to normal animals. Lung resistance, on the other hand, showed a tendency to reduction in treated animals when compared to MPS I. The set of results demonstrates the potential of the co-complexed lipid nanostructures with the CRISPR/Cas9 plasmid and a donor vector of the IDUA/Idua sequence for MPS I gene therapy.

Terapia gênica

Mucopolissacaridose I

Lipossomos

Nanoemulsões

CRISPR/Cas9

Nonviral vectors

Mucopolysaccharidosis,

Gene therapy

Desenvolvimento de vetores nanotecnológicos lipídicos do sistema CRISPR/Cas9 visando à terapia gênica para Mucopolissacaridose tipo I

Schuh, Roselena Silvestri

January 2017

A mucopolissacaridose tipo I (MPS I) é causada pela deficiência de alfa-L-iduronidase (IDUA), responsável pelo catabolismo de glicosaminoglicanos (GAGs), levando ao acúmulo multissistêmico de sulfato de heparano e dermatano. Este estudo tem por objetivo avaliar o potencial de sistemas lipídicos nanoestruturados como carreadores do plasmídeo do sistema CRISPR/Cas9 e um vetor doador da sequência do gene IDUA/Idua para edição gênica em fibroblastos de pacientes e em modelo murino de MPS I. Foram produzidos lipossomas (DOTAP, DOPE e DSPE-PEG) e nanoemulsões (e TCM) por homogeneização à alta pressão e microfluidização. O DNA foi associado às formulações por adsorção, ou por encapsulamento dos complexos pré-formados DNA/DOTAP no núcleo oleoso da nanoemulsão. A eficiência de transfecção dos complexos foi avaliada em fibroblastos de pacientes MPS I e ocorreu um aumento significativo da atividade de IDUA em 2, 15 e 30 dias após os tratamentos, que promoveu uma redução na quantidade de lisossomos nos fibroblastos tratados. A caracterização físico-química de formulações produzidas por microfluidização complexadas a somente um plasmídeo ou juntamente com um oligonucleotídeo foi verificada e pode-se afirmar que a capacidade de complexação e transfecção depende diretamente do tipo celular e da relação de cargas, e não há implicações quanto ao tamanho das sequências de ácidos nucleicos. Camundongos MPS I receberam os complexos lipossomais por injeção hidrodinâmica e sua biodistribuição foi detectada principalmente no pulmão, coração e fígado. A atividade sérica de IDUA normal aumentou em cerca de 6% e foi mantida por seis meses. A atividade aumentada no pulmão, coração, fígado e rim após eutanásia promoveu redução dos GAGs na urina e nos mesmos tecidos, corroborando com as análises histológicas. Em um estudo em andamento, foi realizada uma investigação mais aprofundada do efeito do tratamento lipossomal na morfologia óssea, sistemas cardiovascular e respiratório, e funções cerebrais dos animais tratados. A análise ecocardiográfica demonstrou uma melhora na hipertrofia e contratilidade do coração, porém não houve melhora na espessura das válvulas. O diâmetro da aorta foi similar ao de animais normais, porém as quebras de elastina ficaram entre o grupo normal e o não tratado. A morfologia facial dos animais tratados foi intermediária, assim como a espessura do osso zigomático. Entretanto, o osso femoral demonstrou espessura comparável ao normal. Já a resistência pulmonar apresentou uma tendência de redução nos animais tratados em relação aos animais MPS I. O conjunto de resultados demonstra o potencial das nanoestruturas lipídicas co-complexadas com o plasmídeo CRISPR/Cas9 e um vetor doador da sequência IDUA/Idua para terapia gênica da MPS I. / Mucopolysaccharidosis type I (MPS I) is caused by the deficiency of alpha-L-iduronidase (IDUA), responsible for the catabolism of glycosaminoglycans (GAGs), leading to multisystemic accumulation of heparan and dermatan sulfate. This study aims to evaluate the potential of lipid-based nanostructures as carriers of the CRISPR/Cas9 plasmid and a vector donor of the IDUA/Idua sequence for gene editing in patients’ fibroblasts and in a murine model of MPS I. Liposomes (DOTAP, DOPE, and DSPE-PEG) and nanoemulsions (also MCT) were produced through high-pressure homogenization or microfluidization. DNA was associated with liposomes and nanoemulsions by adsorption or by encapsulation of DNA/DOTAP preformed complexes in the oil core of nanoemulsions. The transfection efficiency of complexes was evaluated in fibroblasts from MPS I patients and a significant increase in IDUA activity was demonstrated at 2, 15, and 30 days after treatments. It was also possible to observe a significant reduction in lysosomal amount in treated fibroblasts. The physicochemical characterization of liposomes and nanoemulsions produced through microfluidization complexed with a single plasmid or along with an oligonucleotide has been verified and it can be stated that the complexing and transfection capacity of the complexes depends directly on the cell type and the charge ratio, and there are no implications of the size of the nucleic acid sequences. MPS I mice received the liposomal complexes by hydrodynamic injection and their immediate biodistribution was detected mainly in the lung, heart, and liver. An increase of about 6% in normal serum IDUA activity was maintained for six months, in addition to increased lung, heart, liver, and kidney activity after euthanasia. The enhanced enzymatic activity promoted a significant GAGs reduction in urine and in the same tissues, corroborating with histological analysis. In an ongoing study, a deeper investigation was carried out on the effect of liposomal treatment on bone morphology, cardiovascular and respiratory systems, and brain function. The echocardiographic analysis showed an improvement in the parameters of hypertrophy and contractility of the heart, but there was no improvement in heart valves. Aorta diameter was similar to that of normal animals, but elastin breaks were between the normal and untreated groups. Facial morphology of treated animals was intermediate, as well as the analysis of zygomatic bone thickness. However, femoral bone showed thickness comparable to normal animals. Lung resistance, on the other hand, showed a tendency to reduction in treated animals when compared to MPS I. The set of results demonstrates the potential of the co-complexed lipid nanostructures with the CRISPR/Cas9 plasmid and a donor vector of the IDUA/Idua sequence for MPS I gene therapy.

Terapia gênica

Mucopolissacaridose I

Lipossomos

Nanoemulsões

CRISPR/Cas9

Nonviral vectors

Mucopolysaccharidosis,

Gene therapy

Identification and characterization of causal genes for LDL cholesterol levels and downstream effects on atherosclerosis

Mazzaferro, Eugenia

January 2017

Coronary artery disease is the leading cause of death worldwide and results from progression of atherosclerosis, which is triggered in part by elevated plasma concentrations of LDL cholesterol. Genome-wide association studies have identified many loci that are associated with circulating lipid levels and bioinformatics tools have been implemented to prioritize positional candidate genes. This project aims to better understand the genetics underlying the regulation of plasma LDL levels and their effect of atherosclerosis using a zebrafish (Danio rerio) model system. A multiplex line with the genes abcg5, abcg8, myrf, col4a3bpa, col4a3bpb, st3gal3, ywhaqa and ywhaqb targeted by CRISPR/Cas9 technique was established using zebrafish with fluorescently labeled macrophages (Tg[mpeg1:mCherry]) and neutrophils (Tg[mpo:EGFP]). Monodansylpentane cadaverase was used to visualize lipids droplets, together with macrophages and neutrophils, in 384 overfed larvae, allowing the visualization and quantification of vascular atherogenic traits at 10 days post-fertilization. Euthanized larvae were homogenized for the quantification of triglycerides, total cholesterol, LDL, HDL, glucose and protein levels. DNA was extracted and larvae were paired-end sequenced for the CRISPR-targeted sites. Linear regression analysis to compare the wild-type larvae against homozygous mutants and additive models for orthologous genes were performed. The lower accumulation of lipids and the lower co-localization of macrophages and neutrophils in the vasculature suggested that the larvae with mutations in the gene abcg5, abcg8, col4a3bpb, and ywhaqb resulted in larvae more protected against atherosclerotic phenotype. The study suggested that loss of function of the targeted genes was associated with atherogenic traits, helping to understand the pathophysiology of atherosclerosis.

CRISPR/Cas9

Zebrafish

Atherosclerosis

LDL cholesterol

Natural Sciences

Naturvetenskap

Medical Biotechnology

Medicinsk bioteknologi

Expanding the Tribolium toolkit : CRISPR-based techniques to investigate cell fates in a short germ embryo / Extension de la boîte à outils de Tribolium : technique basée sur CRISPR pour étudier le destin de cellules dans un embryon de type "short germ"

Gilles, Anna Friederike

30 November 2016

Un objectif important de la biologie du développement est de comprendre la base cellulaire de la morphogenèse, notamment le destin des différentes cellules souches dans l'embryon en développement. En décrivant la morphogenèse des espèces représentatives des différents groupes ou embranchements, on fournit une base solide pour comparer les processus similaires dans les différents organismes, et pour tirer des conclusions sur l'évolution des plans d'organisation des animaux. À cette fin, les scientifiques développent des techniques chez des espèces sélectionnées - celles-ci comprennent la manipulation de la fonction des gènes, le marquage et le suivi des populations distinctes de cellules, et l'imagerie in vivo.Dans cette thèse, je présente mes efforts pour améliorer la boîte à outils génomique du coléoptère Tribolium castaneum. J'utilise une technique d'édition du génome récemment découverte, CRISPR/Cas, pour introduire des modifications précises dans le génome de Tribolium, y compris l'introduction de grands fragments par recombinaison homologue. Je montre que l'expression de tous les composants de CRISPR/Cas est induite de manière efficace par des promoteurs endogènes de Tribolium. En me basant sur ces résultats, je développe VALCYRIE, une approche transgénique pourmarquer des clones de cellules uniques dans l'embryon de Tribolium.Ce travail me permet d'enquêter sur le devenir des cellules dans la région terminale postérieure du blastoderme de Tribolium. En utilisant une approche de marquage clonal, je montre que ces cellules donnent naissance à des cellules germinales primordiales et aumésoderme postérieur. Avec la même méthode, je montre que l'intestin postérieur de Tribolium se développe à partir d'une population distincte de cellules au début de la bandelette germinale. En utilisant une technique de microscopie timelapse haute résolution, je décris le sort de cellules individuelles dans le blastoderme de Triboliumet je fais la lumière sur le plan de développement des segments gnathal et thoracique de l'embryon à ce stade. En outre, je montre que l'amnios de Tribolium augmente considérablement au cours du développement précoce. En me basant sur des données d'imagerie, je passe en revue la cartographie du devenir de la bandelette germinale en ce qui concerne l'amnios et l'ectoderme embryonnaire / An important objective of developmental biology is to understand the cellular basis of morphogenesis, including fates of distinct progenitor cells in the developing embryo. Describing morphogenesis in representative species of different groups or phyla provides a solid basis for comparing similar processes in different organisms, and for drawing conclusions about the evolution of animal body plans. To this end, scientists develop techniques in selected species - these include manipulation of gene function, marking and tracking of distinct populations of cells, and in vivo imaging.In this thesis, I present my efforts to enhance the genomic toolkit of the beetle Tribolium castaneum. I use a recently discovered genome editing technique, CRISPR/Cas, to introduce precise alterations in the Tribolium genome, including the introduction of large fragments by homologous recombination. I show that all CRISPR/Cas components are driven efficiently by endogenous Tribolium promoters. Based on these results, I develop VALCYRIE, a transgenic approach to mark single cell clones in developing Tribolium embryos.This work allows me to investigate the fates of the cells in the posterior terminal region of the Tribolium blastoderm. Using a clonal labeling approach, I demonstrate that these cells give rise to primordial germ cells and posterior mesoderm. With the same technique, I demonstrate that the hindgut of Tribolium develops from a distinct cell population in the early germband. Using high-resolution time lapse microscopy, I describe the fates of single cells in the Triboliumblastodermand shed new light on the fatemap of gnathal and thoracic segments of the embryo at this stage. Furthermore, Ishow that the amnion of Tribolium expands greatly during early development. Based on imaging data, I review the fate map of the early germ band with regard to the amnion and the embryonic ectoderm

CRISPR/Cas

Tribolium castaneum

Développement des insectes

CRISPR/Cas9

Tribolium castaneum

Insect development

570

Molecular techniques for therapeutic and diagnostic applications in Mucopolysaccharidosis IIIB and Gaucher disease

Christensen, Chloe L.

22 December 2020

There is an unmet need to develop and test treatments for rare lysosomal disease (LD). Most LDs are present in childhood and do not currently have approved therapies. Rare diseases individually are uncommon but taken together account for a population prevalence of 3.5-5.9% worldwide. Due to their rarity, it often takes significant time and effort to diagnose rare diseases. New diagnostic tools, especially for early detection, will offer an advantage in avoiding this diagnostic odyssey. This dissertation is focused on investigating novel diagnostic and treatment methods in vitro for two neurodegenerative LDs: Gaucher disease (GD) and mucopolysaccharidosis IIIB (MPS IIIB). Mutations in NAGLU and GBA1, the genes that encode for lysosomal hydrolases required for degradation of heparan sulfate and glucocerebrosides, lead to the observed pathogenesis in MPS IIIB and GD, respectively. Since many LDs, including MPS IIIB and some forms of GD, are neurodegenerative, cell and gene-based therapeutic strategies are of significant interest. Therapeutics that offer some symptom mitigation in other LDs, such as enzyme replacement or substrate reduction therapies, do not offer appreciable disease mitigation in MPS IIIB or neurodegenerative GD. Here, a novel compound heterozygous mutation, NAGLUY140C/R297X, that results in approximately 50% residual NAGLU protein and 0.6% NAGLU enzyme activity is reported in NAGLU. Furthermore, a RFLP and site-directed mutagenesis strategy was developed to identify the presence of the relatively common p.R297X mutation in patient cell samples, in addition to two other novel molecular assays for the detection of the p.E153K mutation in NAGLU and p.N370S mutation in GBA1. MPS IIIB and GD human skin fibroblasts were reprogrammed to iPSCs using non-integrating Sendai viral vectors with a reprogramming efficiency of 0.2% and 0.3%, respectively. Resulting iPS cell lines were confirmed as being pluripotent through a barrage of analyses for markers of pluripotency and differentiation. Intriguingly, early passage MPS IIIB iPSCs were found to exhibit increased cell death and spontaneous differentiation to embryoid body-like structures, which was hypothesized to be caused by fibroblast growth factor 2 (FGF2) sequestration or degradation due to inherent heparan sulfate dysregulation. Supplemental FGF2 (100 ng/mL) was found to significantly increase confluency of MPS IIIB iPSCs after 48 hours (n = 5, p ≤ 0.05) and persisting to 96 hrs (n = 5, p ≤ 0.05), thus providing evidence for an important role of FGF2-heparan sulfate interactions in the maintenance of stem cell pluripotency. These findings highlight the importance of considering inherent disease pathology when developing disease models. Three genome editing strategies, CRISPR-Cas9, base and prime editing, are addressed throughout this dissertation. Genome editing outcomes in NAGLU and GBA1, as well as a control gene, HPRT1, are reported in HEK293 cells, human skin fibroblasts, and induced pluripotent stem cells (iPSCs). Although CRISPR-HDR failed to yield mutation correction, base editing of the common p.N370S (c.1226 A>G) in GD skin fibroblasts using with 42% efficiency is reported. Base editing of HPRT1 in HEK293 cells with an overall editing efficiency of 6 ± 0.5% (n = 3), but interestingly, when base editing at the centered nucleotide was analyzed, the editing efficiency increases to 27 ± 4.3% (n = 3). These findings align with other reports of a centered nucleotide preference for base editors and will help direct genome editing strategies in the future. This dissertation describes the first genome editing in NAGLU, and the first base editing in GBA1, and underscores the importance of optimizing genome editing strategies when targeting disease-causing mutations in patient-derived cells. The findings reported here will direct future genome editing strategies for developing cell and gene-based therapies for MPS IIIB and GD. / Graduate / 2021-12-15

iPSCs

Regenerative medicine

Lysosomal disease

MPS IIIB

Gaucher disease

CRISPR-Cas9

The therapeutic potential of the CRISPR-Cas9 system for treating Duchenne muscular dystrophy

Rubin, David Sweeney

05 November 2016

The CRISPR-Cas9 gene editing system gives researchers the ability to manipulate and edit DNA with unprecedented ease and precision. It was discovered in bacteria as part of their adaptive immune system, but has been reengineered to target any double stranded DNA. This burgeoning molecular tool has created great excitement as scientists are rapidly adopting it to study fields including human gene therapy, disease modeling, agriculture, gene drive in mosquitos, and many others. This paper will explore the potential impact of CRISPR-Cas9 in human therapeutics. Specifically, the potential of CRISPR-Cas9 to treat Duchenne Muscular Dystrophy will be examined. In several ways, this debilitating degenerative disease is an ideal candidate for gene-editing with CRISPR-Cas9. Recent progress in the lab has demonstrated the gene editing system’s ability to rescue dystrophin protein levels in vivo. Although CRISPR-Cas9 holds great promise for previously incurable diseases, there are still many limitations that must be overcome before the gene editing system can be used in patients. This paper will discuss these barriers as well as recent advancements to overcome them.

Genetics

Cas9

CRISPR

CRISPR-Cas9

Dystrophin

Duchenne muscular dystrophy

Gene editing

Recapitulating the human segmentation clock with pluripotent stem cells / 多能性幹細胞を用いたヒト分節時計の再現

Yamanaka, Yoshihiro

27 July 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第22699号 / 医科博第114号 / 新制||医科||8(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 影山 龍一郎, 教授 妻木 範行, 教授 長船 健二 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

pluripotent stem cells

stepwise induction

mesoderm development

somitogenesis

segmentation clock

CRISPR/Cas9

disease modeling

491

Un modèle macrophagique humain pour étudier la dynamique d’activation de l’inflammasome

Marchitto, Lorie

04 1900

Les inflammasomes sont des complexes protéiques impliqués dans l’immunité innée, qui sont activés par de multiples signaux de danger. Des mutations héréditaires des protéines de l’inflammasome peuvent être responsables de son activation excessive et in fine de la survenue de pathologies auto-inflammatoires chez l’être humain. À l’heure actuelle, aucun modèle cellulaire ne permet d’étudier spécifiquement la dynamique d’activation des inflammasomes et de préciser les conséquences des mutations activatrices sur celles-ci. J’ai donc généré un modèle humain macrophagique exprimant une protéine recombinante FLAG3x-ASC endogène, commune aux différents inflammasomes dans la lignée cellulaire humaine monocytaire/macrophagique THP-1. Cette lignée a été générée par édition génique par la technologie CRISPR-Cas9 en utilisant un substrat de recombinaison permettant d’insérer la séquence codant pour le FLAG3X in frame du locus PYCARD codant pour ASC. J’ai pu générer 6 clones FLAG3x-ASC dans la lignée THP-1. Les clones générés ont été validés en confirmant l’expression et la fonctionnalité de la protéine recombinante FLAG3x-ASC et en vérifiant l’absence de mutations indésirables hors-cible générée par la nucléase Cas9. Une fois ce modèle généré, j’ai pu également reproduire un variant génétique du gène NLRC4, protéine sensor de l’inflammasome du même nom, retrouvé chez un patient présentant une maladie auto-inflammatoire. La validation des clones mutant pour NLRC4 est en cours. Ce projet permettra la caractérisation de la dynamique d’activation de l’inflammasome dans un modèle physiologique et pathologique. Ceci permettra une avancée importante dans la compréhension de l’inflammasome et son agrégation ainsi que la régulation de ce complexe face aux signaux de danger. / Inflammasomes are multiproteic complexes that are involved in innate immunity and are activated by multiple signals of dangers. Hereditary mutations in inflammasome components lead to its excessive activation that is responsible for human auto-inflammatory disease. While these mutations are supposed to alter the dynamic of inflammasome activation, there is no current human model allowing the dynamic study of this complex. I generated a human cellular model expressing an endogenous FLAG3x ASC protein, an adaptator protein common to several inflammasomes, in the human monocytic/macrophagic THP-1 cell line. This model was created through CRISPR-Cas9 genome engineering using a recombination template allowing the in frame integration of the sequence encoding the FLAG3X peptide at the PYCARD locus encoding ASC. I generated and validated the expression and the functionality of 6 FLAG3x-ASC THP-1 cell lines. Furthermore, these cell lines are devoided of CRISPR-Cas9 off-target effect. In this model, I further reproduced a genetic variant of the inflammasome component NLRC4 observed in a patient presenting with autoinflammatory manifestation. The functional validation of the FLAG3x-ASC THP-1 harboring the NLRC4 variant is on-going. This project will allow to study the dynamic of the activation of the inflammasome in healthy and pathological conditions. Those results will help refine our comprehension of inflammasome complexation and regulation in response to danger signals.

Inflammasome

NLRC4

ASC

CRISPR-Cas9

Monocytes/Macrophages

Genetic modification in CPVT patient specific induced pluripotent stem cells with CRISPR/Cas9

Zimmermann, Maximilian

02 December 2019

No description available.

610

iPSC

CPVT

CRISPR/Cas9

stem cell

cardiology

Ryanodine receptor 2

pluripotency

Medizin (PPN619874732)

Edition du génome humain :Une perspective transhumaniste ?Enjeux éthiques et philosophiques de la technologie CRISPR

Ngaketcha Njafang, Armand

21 May 2021

La technologie d’édition CRISPR peut être définie comme un outil biologique qui par son efficacité, son extrême précision et la facilité de sa modélisation, permet aujourd’hui de modifier le génome des organismes vivants en général et celui de l’homme en particulier. Sa découverte en 2012 par les chercheuses française et américaine, E. Charpentier et J. Doudna, récompensées par le Prix Nobel de chimie 2020, permet des applications thérapeutiques, au niveau germinal, pour des maladies à transmission autosomique dominante. Jusqu’ici, aucune technologie antérieure d’édition génomique, ni aucun diagnostic anténatal (DPI, DPN), n’avait été capable de prévenir ces maladies. En novembre 2018, le chercheur chinois Hé Jiankui annonce avoir utilisé la technologie CRISPR pour éditer des embryons humains viables. Selon Jiankui cette tentative consiste à modifier génétiquement des embryons humains en FIV afin de prévenir « définitivement » l’infection au VIH des futurs bébés. Cette modification génétique est ainsi transmissible à leur descendance. A partir de là, il s’est ouvert un tournant décisif de l’édition du génome humain héritable. Celui-ci s’apparente, dans notre contexte marqué par la convergence des NBIC, à une perspective transhumaniste. Car à la vérité, CRISPR n’aurait pas fait que prévenir l’infection au VIH chez ces bébés, il aurait surtout amélioré un caractère génétique conférant à ces derniers une immunité à vie contre le VIH-SIDA, avec pour principal corollaire, que de telles modifications sont héritables. Cette application non thérapeutique controversée, nous a conduit à nous demander successivement s’il est souhaitable de se servir de la technologie d’édition du génome CRISPR-Cas9, pour corriger au niveau germinal ou embryonnaire, une anomalie génétique afin de préserver le futur enfant de certains handicaps qui pourraient mettre en péril sa santé ou alourdir sa vie ?Jusqu’où de telles modifications pourraient être jugées comme bénéfiques ou à risque pour l’enfant et qui en aurait l’ultime légitimité d’en juger ?Peut-on alors affirmer, qu’en regard de l’extrême étroitesse qui existe entre la finalité thérapeutique d’une modification génomique germinale ou embryonnaire et l’amélioration/l’augmentation génétique, le risque d’altération de la nature humaine et de fait, la sortie hors de l’espèce humaine devient inéluctable ? / Doctorat en Philosophie / info:eu-repo/semantics/nonPublished

Sciences humaines