Project description:Versatile human cardiac tissues engineered with perfusable heart extracellular microenvironment for biomedical applications

Project description:3-dimensional (3D) human induced pluripotent stem cell-derived engineered cardiac tissues (hiPSC-ECTs) have emerged as a promising alternative to 2-dimensional hiPSC-cardiomyocyte monolayer systems because hiPSC-ECTs are a closer representation of endogenous cardiac tissues and more faithfully reflect the relevant cardiac pathophysiology. The ability to perform functional and molecular assessments using the same hiPSC-ECT construct would allow for more reliable correlation between observed functional performance and underlying molecular events, and thus is critically needed. Herein, for the first time, we have established an integrated method that permits sequential assessment of functional properties and top-down proteomics from the same single hiPSC-ECT construct. We quantitatively determined the differences in isometric twitch force and the sarcomeric proteoforms between two groups of hiPSC-ECTs that differed in the duration of time of 3D-ECT culture. Importantly, by using this integrated method we discovered a new and strong correlation between the measured contractile parameters and the phosphorylation levels of alpha-tropomyosin between the two groups of hiPSC-ECTs. The integration of functional assessments together with molecular characterization by top-down proteomics in the same hiPSC-ECT construct enables a holistic analysis of hiPSC-ECTs to accelerate their applications in disease modeling, cardiotoxicity, and drug discovery.

Project description:Efficient generation of functional cardiomyocytes from human induced pluripotent stem cells (hiPSC-CMs) is critical for their use in regenerative medicine and other applications. In this study, we evaluated the effect of space microgravity (µg) on the differentiation of hiPSC-derived cardiac progenitors compared with parallel 1g condition on the International Space Station. Cryopreserved 3D cardiac progenitors derived from hiPSCs were cultured for 3 weeks. Compared with 1g culture, the µg culture had larger sphere sizes, increased expression of proliferation markers, higher counts of nuclei, and higher cell viability. Highly enriched cardiomyocytes generated in µg had appropriate gene expression and cardiac structure as well as improved function including contractility and Ca2+ handling. RNA-seq analysis of 3-day cultures revealed that short-term exposure of cardiac progenitor spheres to space microgravity upregulated genes involved in cell proliferation, cardiac differentiation, and contraction. These results indicate that space microgravity increased survival and proliferation of hiPSC-CMs and improved their structures and functions.

Project description:Human embryonic stem cells (hESCs) are isolated from the inner cell mass of the blastocysts. The pluripotent properties of hESCs enable the derivation of cell-types or tissues of different lineages for potential applications such as therapeutics discovery and regenerative medicine. Even though hESCs are pluripotent, differences have been observed when compared to the native pluripotent epiblast cells of the blastocyst. We use a chemical approach (3iL: 3 small molecule inhibitor and cytokine) to induce an expression signature that more closely resembles native pluripotent cells. This experiment is STAT3 binding data in 3iL hESCs.

Project description:Human embryonic stem cells (hESCs) are isolated from the inner cell mass of the blastocysts. The pluripotent properties of hESCs enable the derivation of cell-types or tissues of different lineages for potential applications such as therapeutics discovery and regenerative medicine. Even though hESCs are pluripotent, differences have been observed when compared to the native pluripotent epiblast cells of the blastocyst. We use a chemical approach (3iL: 3 small molecule inhibitor and cytokine) to induce an expression signature that more closely resembles native pluripotent cells. This experiment is the epigenetic data of the study.

Project description:The ability of induced pluripotent stem cells (iPSCs) to differentiate into all adult cell types makes them attractive for basic research and regenerative medicine applications, but it remains unknown when and how this hallmark of the pluripotent state is established. Here, we pinpoint the acquisition of developmental pluripotency in a suitable reprogramming system and show that nascent iPSCs abruptly and without extensive maturation period in culture become capable of generating all tissues upon injection into preimplantation embryos. Strikingly, the developmental potential of nascent iPSCs is comparable to or even surpasses that of high-quality established pluripotent cells. Further functional assays as well as genome-wide transcriptional and chromatin analyses suggest that cells acquiring developmental pluripotency exhibit a unique combination of molecular and functional properties that distinguish them from canonical pluripotency states. These include reduced clonal self-renewal potential and the elevated expression of transcriptional regulators of postimplantation development. Our observations close an important gap in our understanding of induced pluripotency and provide an improved roadmap of cellular reprogramming with ramifications for the biomedical use of iPSCs.

Project description:The ability of induced pluripotent stem cells (iPSCs) to differentiate into all adult cell types makes them attractive for basic research and regenerative medicine applications, but it remains unknown when and how this hallmark of the pluripotent state is established. Here, we pinpoint the acquisition of developmental pluripotency in a suitable reprogramming system and show that nascent iPSCs abruptly and without extensive maturation period in culture become capable of generating all tissues upon injection into preimplantation embryos. Strikingly, the developmental potential of nascent iPSCs is comparable to or even surpasses that of high-quality established pluripotent cells. Further functional assays as well as genome-wide transcriptional and chromatin analyses suggest that cells acquiring developmental pluripotency exhibit a unique combination of molecular and functional properties that distinguish them from canonical pluripotency states. These include reduced clonal self-renewal potential and the elevated expression of transcriptional regulators of postimplantation development. Our observations close an important gap in our understanding of induced pluripotency and provide an improved roadmap of cellular reprogramming with ramifications for the biomedical use of iPSCs.

Project description:Human embryonic stem cells (hESCs) are isolated from the inner cell mass of the blastocysts. The pluripotent properties of hESCs enable the derivation of cell-types or tissues of different lineages for potential applications such as therapeutics discovery and regenerative medicine. Even though hESCs are pluripotent, differences have been observed when compared to the native pluripotent epiblast cells of the blastocyst. We use a chemical approach (3iL: 3 small molecule inhibitor and cytokine) to induce an expression signature that more closely resembles native pluripotent cells. This experiment is the transcription factor binding data of the study.

Project description:Extended pluripotent stem (EPS) cells have shown great applicative potentials in generating synthetic embryos, directed differentiation and disease modeling. However, the lack of a xenofree culture condition has significantly limited their wide applications. We developed a chemically defined and xeno-free culture condition for culturing and deriving human EPS cells, which can be long-term stably propagated in vitro, as well as preserve their embryonic and extraembryonic developmental potentials.

Project description:Extended pluripotent stem (EPS) cells have shown great applicative potentials in generating synthetic embryos, directed differentiation and disease modeling. However, the lack of a xenofree culture condition has significantly limited their wide applications. We developed a chemically defined and xeno-free culture condition for culturing and deriving human EPS cells, which can be long-term stably propagated in vitro, as well as preserve their embryonic and extraembryonic developmental potentials.