Testing novel therapies for Choroideremia using patient-specific iPSc-derived Retinal Pigment Epithelium

Les dystrophies rétiniennes héréditaires (DRH) sont un groupe de maladies génétiquement et cliniquement hétérogènes, lesquelles se caractérisent par une perte progressive de la vision. La choroïdérémie (CHM) est une choriorétinopathie qui représente environ 3% des DRH. Elle se caractérise par une cécité nocturne durant l’enfance suivie par une perte du champ visuel périphérique lente et progressive. Cela aboutit à une cécité vers l’âge de 40 à 50 ans. Généralement, la vision centrale demeure préservée plus longtemps. Génétiquement, la maladie est causée par des mutations dans le gène CHM localisé dans le chromosome X qui code pour la Rab Escort Protein 1 (REP1).Cette protéine est impliquée dans la prénylation des Rab GTPasas qui régulent le trafic vésiculaire au sein de la cellule. La plupart des mutations responsables de la maladie sont des mutations pertes de fonction. La conséquence de ces mutations est l’absence de REP1 entrainant un défaut de prénylation des Rabs. Ce qui cause la dégénérescence des photorécepteurs, de l’épithélium pigmentaire rétinien (EPR) et de la choroïde. À ce jour, il n’existe pas de thérapie pour la CHM. Cependant, le diagnostic précoce de la maladie et son évolution lente donnent une fenêtre thérapeutique large et en font un candidat idéal pour la réussite d’un traitement.En raison de l’absence d’un modèle animal pertinent pour tester de nouvelles thérapies pour cette maladie, nous avons développé un modèle cellulaire humain d’EPR in vitro dérivé des cellules pluripotentes induites propres au patient. Ce tissu est morphologiquement et fonctionnellement représentatif de l’EPR in vivo et reproduit les défauts biochimiques de prénylation présents dans la CHM. De ce fait, il s’agit d’un modèle puissant pour évaluer l’efficacité de différentes approches thérapeutiques. Dans cette perspective, nous avons étudié une approche de thérapie génique par AAV2/5 afin de fournir le gène CHM dans le cas particulier de mutation faux sens et l’utilisation d’une translational read-through inducing drug (TRID) PTC124 pour le traitement des mutations non-sens.J’ai démontré pour la première fois la faisabilité de la thérapie génique pour la CHM dans le cas d’une expression résiduelle de REP1 muté, permettant de considérer les patients porteurs de mutations faux sens comme éligible à des essais cliniques de thérapie génique. De plus, j’ai démontré que l’efficacité de PTC124 peut être dépendante du type cellulaire. Dans l’ensemble, mes résultats suggèrent que l’efficacité de la molécule semblerait dépendre de la conservation de l’acide aminé muté et de sa localisation dans le domaine fonctionnel de REP1. Nous avons ainsi mis en valeur que le contexte génétique devrait être pris en compte dans la perspective d’une thérapie avec TRID pour cette maladie ainsi que d’autres pathologies.Pour conclure, j’ai souligné le potentiel prédictif du modèle d’EPR dérivé d’iPSc propre au patient pour évaluer de nouvelles approches thérapeutiques en l’absence d’un modèle animal approprié avant les essais cliniques.Inherited retinal dystrophies (IRDs) are a class of genetically and clinically heterogeneous diseases, which are characterized by a progressive loss of vision. Choroideremia (CHM) is a chorioretinopathy, which accounts for ~3% of all IRDs. It is characterized by night blindness in childhood, followed by slow and progressive loss of the peripheral visual field. This results in legal blindness by the fourth to fifth decade of life. Generally, central vision is preserved till late in life. Genetically, the disease is caused by mutations in the CHM gene located on the X chromosome and encoding the Rab Escort Protein 1 (REP1). This protein is involved in the prenylation of Rab GTPasas, which regulate vesicular cell trafficking. Most of the disease-causing mutations are loss-of-function and the absence of REP1 leads to a Rab prenylation defect and subsequent degeneration of photoreceptors, retinal pigment epithelium (RPE) and underlying choroid. To date, an established therapy is not available for CHM, but the early diagnosis and its slow evolution provide a large therapeutic window, that renders this disease a good candidate for successful treatment.In order to palliate the lack of a pertinent animal model for testing novel disease therapies, we developed a human cellular model using patient-specific induced pluripotent stem cells (iPSc)-derived RPE. This tissue is morphologically and functionally representative of the RPE in vivo, and reproduces the biochemical prenylation defect present in CHM. Therefore, it is a powerful model to evaluate the efficacy of different therapeutic approaches. Along this line, we investigated a gene augmentation approach, via AAV2/5 delivery of the CHM gene in the particular case of a CHM missense mutation, and the use of the translational read-through inducing drug (TRID) PTC124 for treating CHM nonsense mutations.I demonstrated for the first time the feasibility of gene augmentation therapy for CHM in the case of residual mutated REP1 expression, suggesting that missense-carrying patients can be considered for inclusion in clinical gene therapy trials. Moreover, I showed that the efficiency of PTC124 may be dependent on the cell type. In addition, my results suggest that drug efficiency likely depends on the conservation of the mutated amino acid residue and its localization with regards to REP1 functional domains. We thus highlight that genetic considerations should be taken into account when considering TRID therapy for this and other disorders.Taken together, I highlighted the predictive potential of the patient-specific iPSc-derived RPE model for screening of novel and varied therapeutic approaches in the absence of a suitable animal model prior to clinical translation

Pathogenicity of a novel missense variant associated with choroideremia and its impact on gene replacement therapy

International audienceChoroideremia (CHM) is an inherited retinal dystrophy characterised by progressive degeneration of photoreceptors, retinal pigment epithelium (RPE) and underlying choroid. It is caused by loss-of-function mutations in CHM, which has an X-linked inheritance, and is thus an ideal candidate for gene replacement strategies. CHM encodes REP1, which plays a key role in the prenylation of Rab GTPases. We recently showed that an induced pluripotent stem cell (iPSc)-derived RPE model for CHM is fully functional and reproduces the underlying prenylation defect. This criterion can thus be used for testing the pathogenic nature of novel variants. Until recently, missense variants were not associated with CHM. Currently, at least nine such variants have been reported but only two have been shown to be pathogenic. We report here the characterisation of the third pathogenic missense CHM variant, p.Leu457Pro. Clinically, the associated phenotype is indistinguishable from that of loss-of-function mutations. By contrast, this missense variant results in wild type CHM expression levels and detectable levels of mutant protein. The prenylation status of patient-specific fibroblasts and iPSc-derived RPE is within the range observed for loss-of-function mutations, consistent with the clinical phenotype. Lastly, considering the current climate of CHM gene therapy, we assayed whether the presence of mutant REP1 could interfere with a gene replacement strategy by testing the prenylation status of patient-specific iPSc-derived RPE following AAV-mediated gene transfer. Our results show that correction of the functional defect is possible and highlight the predictive value of these models for therapy screening prior to inclusion in clinical trials

Pathogenicity of novel atypical variants leading to choroideremia as determined by functional analyses

International audienceChoroideremia is a monogenic X-linked recessive chorioretinal disease linked to pathogenic variants in the CHM gene. These variants are commonly base-pair changes, frameshifts, or large deletions. However, a few rare or unusual events comprising large duplications, a retrotransposon insertion, a pseudo-exon activation, and two c-98 promoter substitutions have also been described. Following an exhaustive molecular diagnosis, we identified and characterized three novel atypical disease-causing variants in three unrelated male patients. One is a first-ever reported Alu insertion within CHM and the other two are nucleotide substitutions, c.-90C>G and c.-108A>G, affecting highly conserved promoter positions. RNA analysis combined with western blot and functional assays of patient cells established the pathogenicity of the Alu insertion and the c.-90C>G alteration. Furthermore, luciferase reporter assays suggested a CHM transcription defect associated with the c.-90C>G and c.-108A>G variants. These findings broaden our knowledge of the mutational spectrum and the transcriptional regulation of the CHM gene

The effect of PTC124 on choroideremia fibroblasts and iPSC-derived RPE raises considerations for therapy

International audienceInherited retinal dystrophies (IRDs) are caused by mutations in over 200 genes, resulting in a range of therapeutic options. Translational read-through inducing drugs (TRIDs) offer the possibility of treating multiple IRDs regardless of the causative gene. TRIDs promote ribosomal misreading of premature stop codons, which results in the incorporation of a near-cognate amino acid to produce a full-length protein. The IRD choroideremia (CHM) is a pertinent candidate for TRID therapy, as nonsense variants cause 30% of cases. Recently, treatment of the UAA nonsense-carrying CHM zebrafish model with the TRID PTC124 corrected the underlying biochemical defect and improved retinal phenotype. To be clinically relevant, we studied PTC124 efficiency in UAA nonsense-carrying human fibroblasts and induced pluripotent stem cell-derived retinal pigment epithelium, as well as in a UAA-mutated CHM overexpression system. We showed that PTC124 treatment induces a non-significant trend for functional rescue, which could not be improved by nonsense-mediated decay inhibition. Furthermore, it does not produce a detectable CHM-encoded protein even when coupled with a proteasome inhibitor. We suggest that drug efficiency may depend upon on the target amino acid and its evolutionary conservation, and argue that patient cells should be screened in vitro prior to inclusion in a clinical trial

A Novel Chromosomal Translocation Identified due to Complex Genetic Instability in iPSC Generated for Choroideremia

International audienceInduced pluripotent stem cells (iPSCs) have revolutionized the study of human diseases as they can renew indefinitely, undergo multi-lineage differentiation, and generate disease-specific models. However, the difficulty of working with iPSCs is that they are prone to genetic instability. Furthermore, genetically unstable iPSCs are often discarded, as they can have unforeseen consequences on pathophysiological or therapeutic read-outs. We generated iPSCs from two brothers of a previously unstudied family affected with the inherited retinal dystrophy choroideremia. We detected complex rearrangements involving chromosomes 12, 20 and/or 5 in the generated iPSCs. Suspecting an underlying chromosomal aberration, we performed karyotype analysis of the original fibroblasts, and of blood cells from additional family members. We identified a novel chromosomal translocation t(12;20)(q24.3;q11.2) segregating in this family. We determined that the translocation was balanced and did not impact subsequent retinal differentiation. We show for the first time that an undetected genetic instability in somatic cells can breed further instability upon reprogramming. Therefore, the detection of chromosomal aberrations in iPSCs should not be disregarded, as they may reveal rearrangements segregating in families. Furthermore, as such rearrangements are often associated with reproductive failure or birth defects, this in turn has important consequences for genetic counseling of family members

Mutational spectrum of CHM characterized families.

<p>Mutational spectrum of CHM characterized families.</p

Molecular strategy followed up for the diagnosis of CHM families.

<p>Molecular strategy followed up for the diagnosis of CHM families.</p

Clinical findings identified in affected individuals carrying mutations in the <i>CHM</i> gene.

<p>Clinical findings identified in affected individuals carrying mutations in the <i>CHM</i> gene.</p