Project description:Differentiation of pluripotent stem cells into lentoid bodies is important for the understanding of the lens development and investigating the processes critical for lens morphogenesis. This Study was initiated to investigate a comprehensive proteome profiling of the peripheral blood mononuclear cell (PBMC)-originated, induced pluripotent stem cell (iPSC)-derived lentoid bodies through mass spectrometry-based protein sequencing. Briefly, a small aliquot of blood sample was ascertained to collect PBMCs that were reprogrammed to iPSCs using the Sendai-virus delivery system. The PBMC-originated, iPSCs were differentiated into lentoid bodies employing the “fried egg” method using feeder-free conditions. The quantitative real-time PCR (qRT-PCR) confirmed the expression of lens-associated markers, which exhibited at least an order magnitude increased expression in lentoid bodies at differentiation day 35. Subsequently, the total cellular protein was extracted from lentoid bodies at day 35, digested with trypsin, fractionated into 96 fractions and subjected to an mass spectrometry-based label-free quantitative proteomics. mass spectrometry-based proteome profiling revealed 9,717 proteins in iPSC-derived lentoid bodies at differentiation day 35. In here, we report a comprehensive proteome of PBMC-originated, iPSC-derived lentoid bodies at day 35, which will help in better understanding processes critical for the development of the ocular lens.

Project description:Differentiation of pluripotent cells to generate lentoid bodies is important for the understanding of the lens development and investigating the processes critical for lens morphogenesis. This Study was initiated to investigate a comprehensive proteome profiling of the peripheral blood mononuclear cell (PBMC)-originated, induced pluripotent stem cell (iPSC)-derived lentoid bodies through mass spectrometry-based protein sequencing. Briefly, a small aliquot of blood sample was ascertained to collect PBMCs that were reprogrammed to iPSCs using the Sendai-virus delivery system. The PBMC-originated, iPSCs were differentiated into lentoid bodies employing the “fried egg” method using feeder-free conditions. The quantitative real-time PCR (qRT-PCR) confirmed the expression of lens-associated markers, which exhibited at least an order magnitude increased expression in lentoid bodies at differentiation day 25. Subsequently, the total cellular protein was extracted from lentoid bodies at day 25, digested with trypsin, fractionated into 24 fractions and subjected to an mass spectrometry-based label-free quantitative proteomics. mass spectrometry-based proteome profiling revealed 9,473 proteins in iPSC-derived lentoid bodies at differentiation day 25. In here, we report a comprehensive proteome of PBMC-originated, iPSC-derived lentoid bodies at day 25, which will help in better understanding processes critical for the development of the ocular lens.

Project description:Purpose: We previously reported the generation of corneal endothelial cells (CECs) using the human peripheral blood mononuclear cells (PBMC)-originated induced pluripotent stem cells (iPSCs). Herein, we extend our analysis through RNA-Seq based transcriptome profiling of H9 human embryonic stem cells (hESCs)- and iPSCs-derived CECs. Methods: The PBMC obtained from a healthy donor were subjected to generate iPSCs using Sendai-virus delivery system Cytotune 2.0 whereas the H9 hESCs were obtained commercially. Both hESCs and iPSCs were subjected to the 20-day procedure according to our previously published CECs generation method. The differentiated CECs were characterized by immunocytochemistry. Total RNA from hESCs- and iPSCs-derived CECs was used for the preparation of RNA-Seq libraries, which were sequenced on HiSeq 2500 system. The raw RNA-Seq reads were processed and analyzed using Lasergene Genomics Suite and the expression profiles were examined for differential expression using Spotfire DecisionSite with Functional Genomics. Results: The hESCs and iPSCs were differentiated into CECs through multipotent neural crest cells (NCCs) using a 20-day procedure. The differentiating CECs on day 20 (D20) exhibited a tightly packed hexagonal/polygonal shape, which expressed CECs-associated markers, zona occludens-1 and N-cadherin at the cell boundaries. A total of 180.18, and 179.01 million reads were obtained for hESCs- and iPSCs-derived CECs, respectively. Of these, >97% reads aligned to the human reference genome resulting in >250x sequence coverage for both hESCs- and iPSCs-derived CECs. Additional analysis identified expression (≥ 0.659 RPKM) of 13,561 and 13,551 genes in hESCs- and iPSCs-derived CECs, respectively, representing ~68% of the total human protein-coding transcriptome expressed in these CECs. Finally, a comparative analysis of both hESCs- and iPSCs-derived CECs transcriptomes identified >95% similarity at the gene level. Conclusion: These analyses reveal an overall similar transcriptional profile in both hESCs- and iPSCs-derived CECs.

Project description:Here, we evaluate the efficacy of cryopreserved human embryonic stem cell (hESC)-derived corneal endothelial cells (CECs) to form a functional monolayer of corneal endothelium (CE) in mammals (rabbits) and non-human primates (monkeys). We injected cryopreserved hESC-derived CECs in rabbits and monkeys either immediately after removing 8 mm of the central portion of the CE or a few days later when corneal edema developed. All clinical models developed deturgesced and clear corneas 2-3 weeks following the CEC injection and remained comparable to the CE of the untreated eye. Confocal scanning microscopy confirmed an intact structure of hexagonal/polygonal cells and immunohistochemical analysis illustrated a monolayer expressing barrier and pump function proteins in the regenerated CE. The necropsy examination confirmed no remarkable change in multiple tissues examined for teratoma formation. In conclusion, our data demonstrate the efficacy of cryopreserved hESC-derived CECs to form a functional CE on the denuded Descemet’s membrane.

Project description:We report the miRNA profiling in MEF cells, ES cells and three Pluripotent Stem Cells obtained by three different reprogramming approaches from MEF cells based on Solexa sequencing. iPS cells are reprogrammed by four factors (OSKM) from MEF cells. NT-ESCs were established by reprogramming MEF cells into ESCs using nuclear transfer. NT-iPSCs were established to reflect the combination of nuclear transfer and iPS technologies. iPSCs, NT-ESCs, and NT-iPSCs were exactly derived from the same MEF cells. The results indicate NT-ESCs give expression to the unique miRNAs other than both ESCs and iPSCs while pluripotent cells acquire or retain the pluripotent specific miRNAs compared with MEF. Furthermore, the comparison of different reprogramming cells suggests that several miRNAs have key roles in distinctly developmental potential reprogrammine cells. Small RNA profiles of MEF, ES, iPS, NT-ES and NT-iPS cells were generated by Solexa sequencing. MEF and ES cells were performed in triplicate. iPS, NT-ES and NT-iPS cells were sequenced in duplicate.

Project description:Conventional embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) derived from primates resemble mouse epiblast stem cells, raising an intriguing question regarding whether the naïve pluripotent state resembling mouse embryonic stem cells (mESCs) exists in primates and how to capture it in vitro. Here we identified several specific signaling modulators that are sufficient to generate rhesus monkey fibroblast-derived iPSCs with the features of naïve pluripotency in terms of growth properties, gene expression profiles, self-renewal signaling, X-reactivation and the potential to generate cross-species chimeric embryos. Interestingly, together with recent reports of naïve human pluripotent stem cells, our findings suggest several conserved signaling pathways shared with rodents and specific to primates, providing significant insights for acquiring naïve pluripotency from other mammal species. In addition, the derivation of rhesus monkey naïve iPSCs also provides a valuable cell source for use in preclinical research and disease modeling. mRNA expression analysis of 4 rhesus monkey naive iPSC lines and 2 primed iPSC lines were examed.

Project description:Purpose: To investigate the transcriptomes of H9 human embryonic stem cells (hESCs)- and peripheral blood mononuclear cells (PBMC) originated induced pluripotent stem cells (iPSCs)-derived early stage lentoid bodies at day 24 through RNA-Seq based whole transcriptome sequencing. Methods: The PBMC obtained from a healthy donor were subjected to generate iPSCs using Sendai-virus delivery system Cytotune 2.0 whereas the H9 hESCs were obtained commercially. Both hESCs and iPSCs were differentiated into lentoid bodies using “fried egg” method with feeder-free conditions as described previously. The differentiating lentoid bodies were examined for the expression of lens-specific and pluripotency markers at days 0, 6, 10, 15 and 24 by quantitative real-time PCR (qRT-PCR). Briefly, four biological replicates for each hESCs- and iPSC-derived lentoid bodies at day 24 were used for the RNA-Seq library preparation followed by sequencing on a single lane of HiSeq 2500. The raw reads were processed and analyzed using Lasergene Genomics Suite and the expression profiles were examined for differential expression using Spotfire DecisionSite with Functional Genomics. Results: The differentiating lentoid bodies at day 24 revealed transparent lens like morphological features with an increased expression of lens-specific markers including CRYGC. A total of 193.41, and 170.00 million reads were obtained for hESCs- and iPSCs-derived lentoid bodies, respectively. Of these, >96% reads aligned to the human reference genome resulting in >200x sequence coverage for both hESCs- and iPSCs-derived lentoid bodies. Additional analysis identified expression (≥ 0.659 RPKM) of 13,991 and 14,018 genes in hESCs- and iPSCs-derived lentoid bodies, respectively, representing ~70% of the total human protein-coding transcriptome expressed in lentoid bodies. Finally, a comparative analysis of both hESCs- and iPSCs-derived lentoid bodies transcriptomes identified >96% similarity at the gene level. Conclusion: The transcriptome analysis revealed an overall similar transcriptional profile in both hESCs- and iPSCs-derived lentoid bodies during differentiation at day 24.

Project description:Orangutans are an endangered species whose natural habitats are restricted to the Southeast Asian islands of Borneo and Sumatra. For potential species conservation and functional genomics studies, we derived induced pluripotent stem cells (iPSCs) from cryopreserved skin fibroblasts obtained from captive orangutans. We report the gene expression profiles of iPSCs and skin fibroblasts derived from orangtuans. The overall goal was to evaluate gene expression biomarkers of pluripotency in iPSCs and skin fibroblasts derived from PBD-ZSD patients and healthy controls. Dermal fibroblast cultures from 2 orangutans were reprogrammed into iPSCs by transfection with retroviruses designed to express the human OCT4, SOX2, KLF4 and c-MYC cDNA. Fibroblasts and iPSCs were cultured in 1:1 ratio of DMEM:F12 medium supplemented with 20% KOSR (knock-out serum replacement) at 37°C with 5% CO2 until confluence for RNA extraction. The overall goal was to evaluate gene expression biomarkers of pluripotency in iPSCs and original fibroblast cultures.

Project description:RNA-seq samples from 3 species across a differentiation from induced pluripotent stem cells to neural progenitor cells were generated to study gene expression evolution. Briefly, previously generated urinary stem cell derived iPSCs of 3 human (Homo sapiens) individuals (3 clones), 1 gorilla (Gorilla gorilla) individual and fibroblast derived cynomolgus macaque (Macaca fascicularis) iPSCs of 2 individuals (4 clones) (Geuder et al. 2021) were differentiated to neural progenitor cells via dual-SMAD inhibition as three-dimensional aggregation culture (Chambers et al. 2009; Ohnuki et al. 2014). Bulk RNA-seq libraries of iPSCs and NPCs were generated using prime-seq protocol (Janjic et al. 2022).

Project description:We performed RNA-seq experiments on two samples (cortical neurons and spinal motor neurons) from normal induced pluripotent stem cells (iPSCs), and another two samples (cortical neurons and spinal motor neurons) derived from SPG3A (an early onset form of hereditary spastic paraplegia) iPSCs. This initial experiment is to test the system and set up a baseline for future studies. Cortical projection neurons and spinal motor neurons were differentiated from same batch of iPSCs in parallel to minimize variations. The differentiation of cortical neurons and spinal motor neurons are based on protocols well-established in our group.