Project description:Patients with recessive dystrophic epidermolysis bullosa (RDEB) lack functional Type VII collagen and suffer severe blistering and chronic wounds that ultimately lead to infection and development of lethal squamous cell carcinoma (SCC). The discovery of induced pluripotent stem cells (iPSCs) and the ability to edit the genome bring the possibility to provide definitive genetic therapy through corrected autologous tissues. We have formed a multidisciplinary team with the ultimate goal to develop an iPSC-based therapy for RDEB. Here, we present a clinical protocol that generates autologous, corrected epithelial keratinocyte sheets with the COL7A1 gene mutation corrected for grafting on to patients. We demonstrate the utility of sequential reprogramming and novel adenovirus-associated viral genome editing to generate corrected iPSC banks. iPSC-derived keratinocytes were produced with minimal heterogeneity and secreted wild-type collagen VII, resulting in stratified epidermis in vitro and in vivo in mice. Sequencing of corrected cell lines prior to tissue formation revealed heterogeneity of SCC-predisposing mutations, allowing us to select COL7A1 corrected banks with minimal mutational burden for downstream epidermis production. Our results provide a first clinical platform to use iPSCs in the treatment of debilitating genodermatoses. Microarray analysis of iPS-derived keratinocytes from two RDEB patients (iPS-K1 and iPS-K3), corresponding patient keratinocytes (AHK1 and AHK2), normal human keratinocytes (NHK), as well as H9 human embryonic stem cells (hESC - H9). All samples were analyzed in duplicate and differential gene expression was measured relative to H9.

Project description:Complex tissues contain multiple cell types that are hierarchically organized within morphologically and functionally distinct compartments. Construction of engineered tissues with optimized tissue architecture has been limited by tissue fabrication techniques, which do not enable versatile microscale organization of multiple cell types in tissues of size adequate for physiologic studies and tissue therapies. Here, we present an ‘Intaglio-Void/Embed-Relief Topographic (InVERT) molding’ method for microscale organization of many cell types, including induced pluripotent stem cell (iPS)-derived progeny, within a variety of synthetic and natural extracellular matrices and across tissues of sizes appropriate for in vitro, pre-clinical, and clinical biologic studies. We demonstrate that compartmental placement of non-parenchymal cells relative to primary or iPS-derived hepatocytes and hepatic compartment microstructure and cellular composition modulate hepatic functions. Configurations found to be optimal in vitro also result in superior survival and function after transplantation into mice, demonstrating the importance of architectural optimization prior to implantation. Two replicates of iPS-Hepatocytes cultured alone for 1 day or co-cultured with mouse J2 stromal cells for 1 day. One replicate of a mixture of iPS-Hepatocytes cultured alone for 1 day and then combined with J2 stromal cell RNA after RNA purification. Pure J2 stromal cell RNA was also hybridized to they Human chips but those hybridizations did not produce usable data and have not been included in this study.

Project description:Gene-corrected patient-specific induced pluripotent stem (iPS) cells offer a novel approach to gene therapy. Yet it is unknown whether selective pressures during prolonged culture and multiple clonal events would introduce a mutational load incompatible with therapeutic use. Here we begin to assess whether the mutational load of gene-corrected iPS cells is compatible with use in the treatment of genetic causes of retinal degenerative disease. We isolated iPS cells free of transgene sequences from a patient with gyrate atrophy caused by a point mutation in the gene encoding ornithine-δ-aminotransferase (OAT) and used homologous recombination to correct the genetic defect. Cytogenetic analysis, array comparative genomic hybridization (aCGH), and exome sequencing were performed to assess the genomic integrity of an iPS cell line after three sequential clonal events: initial reprogramming, gene targeting, and subsequent removal of a selection cassette. No abnormalities were detected following standard G-band metaphase analysis. However, aCGH and exome sequencing identified two deletions, one amplification, and nine point mutations in protein-coding regions in the initial iPS cell clone. Except for the targeted correction of the single nucleotide in the OAT locus and a single synonymous base pair change, no additional mutations or copy number variation were identified in iPS cells following the two subsequent clonal events. These findings confirm that iPS cells themselves may carry a significant mutational load at initial isolation, but that the clonal events and prolonged cultured required for correction of a genetic defect can be accomplished without a substantial increase in mutational burden.

Project description:The establishment of induced pluripotent stem (iPS) cells methodologies has widened the possibilities of stem cell related clinical therapies. However, safety concerns over current reprogramming technologies as well as lack of efficient protocols for differentiation raise serious questions over their usage in clinical settings. Direct lineage conversion may represent a safer technology for cell-therapy. Here, we identify Sox2 as a factor able to transdetermine human mesenchymal stem cells (MSCs) to hematopoietic progenitor cells (HPCs), recapitulating the molecular events during in vivo hematopoiesis. This technology offers an efficiency of up to 70% HPC generation in less than 8 days under feeder-free conditions. With the goal of devising ways for transplantation into diseased patients we developed two different methodologies that avoid exogenous DNA integration or viral infections. The first, by transduction of recombinant Sox2 protein, and the second by functional replacement of Sox2 by inhibition of TGFß signaling. The DNA integration-, virus-, and feeder-free transdetermination system here described may complement and enhance current approaches for autologous as well as heterologous HPC transplantation in humans. Mesenchymal Stem Cells were transdifferentiated towards the hematopoietic lineage.

Project description:Patients with dyskeratosis congenita (DC) and related telomeropathies resulting from premature telomere dysfunction suffer from multi-organ failure. In the liver, DC patients present with nodular hyperplasia and cirrhosis. We model DC liver pathologies using isogenic human induced pluripotent stem (iPS) cells harboring a causal DC mutation in DKC1, or a clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9-corrected control allele. Differentiation of these iPS cells into hepatocytes or hepatic stellate cells reveals a dominant phenotype in the parenchyma. Generation of genotype admixed hepatostellate organoids indicates that DC hepatocytes elicit a pathogenic hyperplastic response in stellate cells independent of stellate cell genotype. Phenotypic rescue was achieved via suppression of AKT activity, a central regulator of mTORC1, MYC, and DC hepatocyte-driven hyperplasia. Thus, isogenic, iPS-derived admixed hepatostellate organoids offer insight into the liver pathologies in telomeropathies and provide a framework for evaluating emerging therapies.

Project description:Gene-corrected patient-specific induced pluripotent stem (iPS) cells offer a novel approach to gene therapy. Yet it is unknown whether selective pressures during prolonged culture and multiple clonal events would introduce a mutational load incompatible with therapeutic use. Here we begin to assess whether the mutational load of gene-corrected iPS cells is compatible with use in the treatment of genetic causes of retinal degenerative disease. We isolated iPS cells free of transgene sequences from a patient with gyrate atrophy caused by a point mutation in the gene encoding ornithine-δ-aminotransferase (OAT) and used homologous recombination to correct the genetic defect. Cytogenetic analysis, array comparative genomic hybridization (aCGH), and exome sequencing were performed to assess the genomic integrity of an iPS cell line after three sequential clonal events: initial reprogramming, gene targeting, and subsequent removal of a selection cassette. No abnormalities were detected following standard G-band metaphase analysis. However, aCGH and exome sequencing identified two deletions, one amplification, and nine point mutations in protein-coding regions in the initial iPS cell clone. Except for the targeted correction of the single nucleotide in the OAT locus and a single synonymous base pair change, no additional mutations or copy number variation were identified in iPS cells following the two subsequent clonal events. These findings confirm that iPS cells themselves may carry a significant mutational load at initial isolation, but that the clonal events and prolonged cultured required for correction of a genetic defect can be accomplished without a substantial increase in mutational burden. Array comparative genomic hybridization (aCGH) were performed to assess the genomic integrity of an iPS cell line after three sequential clonal events: initial reprogramming, gene targeting, and subsequent removal of a selection cassette. Human CGH 2.1M Whole-Genome Tiling v2.0D Array plus 4633 custom-designed probes which cover the gene targeting construct and the reprogramming plasmid vectors. Comparison of patient iPS cell with full skin fibroblast cells was performed on this design.

Project description:Primary Hyperoxaluria Type 1 (PH1) is a rare inherited metabolic disorder characterized by oxalate overproduction in the liver, resulting in renal damage. It is caused by mutations in the AGXT gene. Combined liver and kidney transplantation is currently the only permanent curative treatment. We combined locus-specific gene correction and hepatic direct cell reprogramming to generate autologous healthy induced hepatocytes (iHeps) from PH1 patient-derived fibroblasts. First, site-specific AGXT corrected cells were obtained by homology directed repair (HDR) assisted by CRISPR/Cas9, following two different strategies: accurate point mutation (c.853T>C) correction or knock-in of an enhanced version of AGXT cDNA. Then, iHeps were generated, by overexpression of hepatic transcription factors. Generated AGXT-corrected iHeps showed hepatic gene expression profile and exhibited in vitro reversion of oxalate accumulation compared to non-edited PH1-derived iHeps. This strategy set up a potential alternative cellular source for liver cell replacement therapy and a personalized PH1 in vitro disease model.

Project description:Transplantation of genetically corrected hepatocytes is an attractive alternative to liver transplantation but is hampered by the low amplification potential of these cells in vitro. Here, we describe a method for generating proliferative hepatic progenitor cells (iHPC) from human hepatocytes as an expandable cell source for liver therapy. Dedifferentiation of primary hepatocytes to iHPC was achieved in less than 7 days by culturing the cells in medium with a cocktail of growth factors and small molecules. In culture, iHPC expressed a combination of endoderm hepatic progenitor and mesenchymal stem cell markers and proliferated vigorously, allowing for their expansion by at least 104 times. RNA sequencing of iHPC demonstrated that they displayed far more subtle changes in both transcriptome and transposcriptome, compared to hepatocyte-derived iPSC. Finally, transplantation of iHPC into the liver of immuno-deficient mice showed iHPC differentiation potential in vivo, without triggering detectable tumor development.

Project description:Transplantation of genetically corrected hepatocytes is an attractive alternative to liver transplantation but is hampered by the low amplification potential of these cells in vitro. Here, we describe a method for generating proliferative hepatic progenitor cells (iHPC) from human hepatocytes as an expandable cell source for liver therapy. Dedifferentiation of primary hepatocytes to iHPC was achieved in less than 7 days by culturing the cells in medium with a cocktail of growth factors and small molecules. In culture, iHPC expressed a combination of endoderm hepatic progenitor and mesenchymal stem cell markers and proliferated vigorously, allowing for their expansion by at least 104 times. RNA sequencing of iHPC demonstrated that they displayed far more subtle changes in both transcriptome and transposcriptome, compared to hepatocyte-derived iPSC. Finally, transplantation of iHPC into the liver of immuno-deficient mice showed iHPC differentiation potential in vivo, without triggering detectable tumor development.

Project description:Complex tissues contain multiple cell types that are hierarchically organized within morphologically and functionally distinct compartments. Construction of engineered tissues with optimized tissue architecture has been limited by tissue fabrication techniques, which do not enable versatile microscale organization of multiple cell types in tissues of size adequate for physiologic studies and tissue therapies. Here, we present an ‘Intaglio-Void/Embed-Relief Topographic (InVERT) molding’ method for microscale organization of many cell types, including induced pluripotent stem cell (iPS)-derived progeny, within a variety of synthetic and natural extracellular matrices and across tissues of sizes appropriate for in vitro, pre-clinical, and clinical biologic studies. We demonstrate that compartmental placement of non-parenchymal cells relative to primary or iPS-derived hepatocytes and hepatic compartment microstructure and cellular composition modulate hepatic functions. Configurations found to be optimal in vitro also result in superior survival and function after transplantation into mice, demonstrating the importance of architectural optimization prior to implantation.