技术资料

Magnesium (Mg) is a promising conductive metallic biomaterial due to its desirable mechanical properties for load bearing and biodegradability in human body. Controlling the rapid degradation of Mg in physiological environment continues to be the key challenge toward clinical translation. In this study,we investigated the effects of conductive poly(3,4-ethylenedioxythiophene) (PEDOT) coating on the degradation behavior of Mg substrates and their cytocompatibility. Human embryonic stem cells (hESCs) were used as the in vitro model system to study cellular responses to Mg degradation because they are sensitive and can potentially differentiate into many cell types of interest (e.g.,neurons) for regenerative medicine. The PEDOT was deposited on Mg substrates using electrochemical deposition. The greater number of cyclic voltammetry (CV) cycles yielded thicker PEDOT coatings on Mg substrates. Specifically,the coatings produced by 2,5,and 10 CV cycles (denoted as 2×-PEDOT-Mg,5×-PEDOT-Mg,and 10×-PEDOT-Mg) had an average thickness of 31,63,and 78 µm,respectively. Compared with non-coated Mg samples,all PEDOT coated Mg samples showed slower degradation rates,as indicated by Tafel test results and Mg ion concentrations in the post-culture media. The 5×-PEDOT-Mg showed the best coating adhesion and slowest Mg degradation among the tested samples. Moreover,hESCs survived for the longest period when cultured with the 5×-PEDOT-Mg samples compared with the non-coated Mg and 2×-PEDOT-Mg. Overall,the results of this study showed promise in using PEDOT coating on biodegradable Mg-based implants for potential neural recording,stimulation and tissue engineering applications,thus encouraging further research. View Publication

It has been suggested that the isolation of scalable populations of limbal stem cells may lead to radical changes in ocular therapy. In particular,the derivation and transplantation of corneal stem cells from these populations may result in therapies providing clinical normality of the diseased or damaged cornea. Although feasible in theory,the lack of donor material in sufficient quantity and quality currently limits such a strategy. A potential scalable source of corneal cells could be derived from pluripotent stem cells (PSCs). We developed an in vitro and serum-free corneal differentiation model which displays significant promise. Our stepwise differentiation model was designed with reference to development and gave rise to cells which displayed similarities to epithelial progenitor cells which can be specified to cells displaying a corneal epithelial phenotype. We believe our approach is novel,provides a robust model of human development and in the future,may facilitate the generation of corneal epithelial cells that are suitable for clinical use. Additionally,we demonstrate that following continued cell culture,stem cell-derived corneal epithelial cells undergo transdifferentiation and exhibit squamous metaplasia and therefore,also offer an in vitro model of disease. View Publication

Vascular smooth muscle cells (SMCs) arise from diverse developmental origins. Regional distribution of vascular diseases may,in part,be attributed to this inherent heterogeneity in SMC lineage. Therefore,systems for generating human SMC subtypes of distinct embryonic origins would represent useful platforms for studying the influence of SMC lineage on the spatial specificity of vascular disease. Here we describe how human pluripotent stem cells can be differentiated into distinct populations of SMC subtypes under chemically defined conditions. The initial stage (days 0-5 or 0-7) begins with the induction of three intermediate lineages: neuroectoderm,lateral plate mesoderm and paraxial mesoderm. Subsequently,these precursor lineages are differentiated into contractile SMCs (days 5-19+). At key stages,the emergence of lineage-specific markers confirms recapitulation of embryonic developmental pathways and generation of functionally distinct SMC subtypes. The ability to derive an unlimited supply of human SMCs will accelerate applications in regenerative medicine and disease modeling. View Publication

Under appropriate conditions in culture,embryonic stem cells will differentiate and form embryoid bodies that have been shown to contain cells of the hematopoietic,endothelial,muscle and neuronal lineages. Many aspects of the lineage-specific differentiation programs observed within the embryoid bodies reflect those found in the embryo,indicating that this model system provides access to early cell populations that develop in a normal fashion. Recent studies involving the differentiation of genetically altered embryonic stem cells highlight the potential of this in vitro differentiation system for defining the function of genes in early development. View Publication

The spinal cord consists of multiple neuronal cell types that are critical to motor control and arise from distinct progenitor domains in the developing neural tube. Excitatory V2a interneurons in particular are an integral component of central pattern generators that control respiration and locomotion; however,the lack of a robust source of human V2a interneurons limits the ability to molecularly profile these cells and examine their therapeutic potential to treat spinal cord injury (SCI). Here,we report the directed differentiation of CHX10(+) V2a interneurons from human pluripotent stem cells (hPSCs). Signaling pathways (retinoic acid,sonic hedgehog,and Notch) that pattern the neural tube were sequentially perturbed to identify an optimized combination of small molecules that yielded ∼25% CHX10(+) cells in four hPSC lines. Differentiated cultures expressed much higher levels of V2a phenotypic markers (CHX10 and SOX14) than other neural lineage markers. Over time,CHX10(+) cells expressed neuronal markers [neurofilament,NeuN,and vesicular glutamate transporter 2 (VGlut2)],and cultures exhibited increased action potential frequency. Single-cell RNAseq analysis confirmed CHX10(+) cells within the differentiated population,which consisted primarily of neurons with some glial and neural progenitor cells. At 2 wk after transplantation into the spinal cord of mice,hPSC-derived V2a cultures survived at the site of injection,coexpressed NeuN and VGlut2,extended neurites textgreater5 mm,and formed putative synapses with host neurons. These results provide a description of V2a interneurons differentiated from hPSCs that may be used to model central nervous system development and serve as a potential cell therapy for SCI. View Publication

The authors surveyed whole-exome and RNA-sequencing data from 252 unique pluripotent stem cell lines,some of which are in the pipeline for clinical use,and found that approximately 5{\%} of cell lines had acquired mutations in the TP53 gene that allow mutant cells to rapidly outcompete non-mutant cells,but do not prevent differentiation. View Publication

Exosomes are cell-derived nanovesicles that hold promise as living vehicles for intracellular delivery of therapeutics to mammalian cells. This potential,however,is undermined by the lack of effective methods to load exosomes with therapeutic proteins and to facilitate their uptake by target cells. Here,we demonstrate how a vesicular stomatitis virus glycoprotein (VSVG) can both load protein cargo onto exosomes and increase their delivery ability via a pseudotyping mechanism. By fusing a set of fluorescent and luminescent reporters with VSVG,we show the successful targeting and incorporation of VSVG fusions into exosomes by gene transfection and fluorescence tracking. We subsequently validate our system by live cell imaging of VSVG and its participation in endosomes/exosomes that are ultimately released from transfected HEK293 cells. We show that VSVG pseudotyping of exosomes does not affect the size or distributions of the exosomes,and both the full-length VSVG and the VSVG without the ectodomain are shown to integrate into the exosomal membrane,suggesting that the ectodomain is not required for protein loading. Finally,exosomes pseudotyped with full-length VSVG are internalized by multiple-recipient cell types to a greater degree compared to exosomes loaded with VSVG without the ectodomain,confirming a role of the ectodomain in cell tropism. In summary,our work introduces a new genetically encoded pseudotyping platform to load and enhance the intracellular delivery of therapeutic proteins via exosome-based vehicles to target cells. View Publication

Recent studies using defined transcription factors to convert skin fibroblasts into chondrocytes have raised the question of whether osteo-chondroprogenitors expressing SOX9 and RUNX2 could also be generated during the course of the reprogramming process. Here,we demonstrated that doxycycline-inducible expression of reprogramming factors (KLF4 [K] and c-MYC [M]) for 6 days were sufficient to convert murine fibroblasts into SOX9(+)/RUNX2(+) cellular aggregates and together with SOX9 (S) promoted the conversion efficiency when cultured in a defined stem cell medium,mTeSR. KMS-reprogrammed cells possess gene expression profiles akin to those of native osteo-chondroprogenitors with elevated osteogenic properties and can differentiate into osteoblasts and chondrocytes in vitro,but form bone tissue upon transplantation under the skin and in the fracture site of mouse tibia. Altogether,we provide a reprogramming strategy to enable efficient derivation of osteo-chondrogenic cells that may hold promise for cell replacement therapy not limited to cartilage but also for bone tissues. View Publication

Genome-wide association studies (GWASs) have identified many disease-associated variant alleles,but understanding whether and how different genes/loci interact requires a platform for probing how the variant alleles act mechanistically. Isogenic mutant human embryonic stem cells (hESCs) provide an unlimited resource to derive and study human disease-relevant cells. Here,we focused on CDKAL1,linked by GWASs to diabetes. Through transcript profiling,we find that expression of the metallothionein (MT) gene family,also linked by GWASs to diabetes,is significantly downregulated in CDKAL1(-/-) cells that have been differentiated to insulin-expressing pancreatic beta-like cells. Forced MT1E expression rescues both hypersensitivity of CDKAL1 mutant cells to glycolipotoxicity and pancreatic beta-cell dysfunction in vitro and in vivo. MT1E functions at least in part through relief of ER stress. This study establishes an isogenic hESC-based platform to study the interaction of GWAS-identified diabetes gene variants and illuminate the molecular network impacting disease progression. View Publication

Fibrodysplasia ossificans progressiva (FOP) is a rare and intractable disease characterized by extraskeletal bone formation through endochondral ossification. Patients with FOP harbor point mutations in ACVR1,a type I receptor for BMPs. Although mutated ACVR1 (FOP-ACVR1) has been shown to render hyperactivity in BMP signaling,we and others have uncovered a mechanism by which FOP-ACVR1 mistransduces BMP signaling in response to Activin-A,a molecule that normally transduces TGF-β signaling. Although Activin-A evokes enhanced chondrogenesis in vitro and heterotopic ossification (HO) in vivo,the underlying mechanisms have yet to be revealed. To this end,we developed a high-throughput screening (HTS) system using FOP patient-derived induced pluripotent stem cells (FOP-iPSCs) to identify pivotal pathways in enhanced chondrogenesis that are initiated by Activin-A. In a screen of 6,809 small-molecule compounds,we identified mTOR signaling as a critical pathway for the aberrant chondrogenesis of mesenchymal stromal cells derived from FOP-iPSCs (FOP-iMSCs). Two different HO mouse models,an FOP model mouse expressing FOP-ACVR1 and an FOP-iPSC-based HO model mouse,revealed critical roles for mTOR signaling in vivo. Moreover,we identified ENPP2,an enzyme that generates lysophosphatidic acid,as a linker of FOP-ACVR1 and mTOR signaling in chondrogenesis. These results uncovered the crucial role of the Activin-A/FOP-ACVR1/ENPP2/mTOR axis in FOP pathogenesis. View Publication

This report describes the establishment directly from normal preimplantation mouse embryos of a cell line that forms teratocarcinomas when injected into mice. The pluripotency of these embryonic stem cells was demonstrated conclusively by the observation that subclonal cultures,derived from isolated single cells,can differentiate into a wide variety of cell types. Such embryonic stem cells were isolated from inner cell masses of late blastocysts cultured in medium conditioned by an established teratocarcinoma stem cell line. This suggests that such conditioned medium might contain a growth factor that stimulates the proliferation or inhibits the differentiation of normal pluripotent embryonic cells,or both. This method of obtaining embryonic stem cells makes feasible the isolation of pluripotent cells lines from various types of noninbred embryo,including those carrying mutant genes. The availability of such cell lines should made possible new approaches to the study of early mammalian development. View Publication