技术资料

$$-Thalassemia ($$-Thal) is one of the most common genetic diseases in the world. The generation of patient-specific $$-Thal-induced pluripotent stem cells (iPSCs),correction of the disease-causing mutations in those cells,and then differentiation into hematopoietic stem cells offers a new therapeutic strategy for this disease. Here,we designed a CRISPR/Cas9 to specifically target the Homo sapiens hemoglobin $$ (HBB) gene CD41/42(-CTTT) mutation. We demonstrated that the combination of single strand oligodeoxynucleotides with CRISPR/Cas9 was capable of correcting the HBB gene CD41/42 mutation in $$-Thal iPSCs. After applying a correction-specific PCR assay to purify the corrected clones followed by sequencing to confirm mutation correction,we verified that the purified clones retained full pluripotency and exhibited normal karyotyping. Additionally,whole-exome sequencing showed that the mutation load to the exomes was minimal after CRISPR/Cas9 targeting. Furthermore,the corrected iPSCs were selected for erythroblast differentiation and restored the expression of HBB protein compared with the parental iPSCs. This method provides an efficient and safe strategy to correct the HBB gene mutation in $$-Thal iPSCs. View Publication

Generating human podocytes in vitro could offer a unique opportunity to study human diseases. Here,we describe a simple and efficient protocol for obtaining functional podocytes in vitro from human induced pluripotent stem cells. Cells were exposed to a three-step protocol,which induced their differentiation into intermediate mesoderm,then into nephron progenitors and,finally,into mature podocytes. After differentiation,cells expressed the main podocyte markers,such as synaptopodin,WT1,α-Actinin-4,P-cadherin and nephrin at the protein and mRNA level,and showed the low proliferation rate typical of mature podocytes. Exposure to Angiotensin II significantly decreased the expression of podocyte genes and cells underwent cytoskeleton rearrangement. Cells were able to internalize albumin and self-assembled into chimeric 3D structures in combination with dissociated embryonic mouse kidney cells. Overall,these findings demonstrate the establishment of a robust protocol that,mimicking developmental stages,makes it possible to derive functional podocytes in vitro. View Publication

Neural rosettes derived from human induced pluripotent stem cells (iPSCs) have been claimed to be a highly robust in vitro cellular model for biomedical application. They are able to propagate in vitro in the presence of mitogens,including basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF). However,these two mitogens are also involved in anterior-posterior patterning in a gradient dependent manner along the neural tube axis. Here,we compared the regional identity of neural rosette cells and specific neural subtypes of their progeny propagated with low and high concentrations of bFGF and EGF. We observed that low concentrations of bFGF and EGF in the culturing system were able to induce forebrain identity of the neural rosettes and promote subsequent cortical neuronal differentiation. On the contrary,high concentrations of these mitogens stimulate a mid-hindbrain fate of the neural rosettes,resulting in subsequent cholinergic neuron differentiation. Thus,our results indicate that different concentrations of bFGF and EGF supplemented during propagation of neural rosettes are involved in altering the identity of the resultant neural cells. View Publication

In Wilson disease (WD),functional loss of ATPase copper-transporting $$ (ATP7B) impairs biliary copper excretion,leading to excessive copper accumulation in the liver and fulminant hepatitis. Current US Food and Drug Administration- and European Medicines Agency-approved pharmacological treatments usually fail to restore copper homeostasis in patients with WD who have progressed to acute liver failure,leaving liver transplantation as the only viable treatment option. Here,we investigated the therapeutic utility of methanobactin (MB),a peptide produced by Methylosinus trichosporium OB3b,which has an exceptionally high affinity for copper. We demonstrated that ATP7B-deficient rats recapitulate WD-associated phenotypes,including hepatic copper accumulation,liver damage,and mitochondrial impairment. Short-term treatment of these rats with MB efficiently reversed mitochondrial impairment and liver damage in the acute stages of liver copper accumulation compared with that seen in untreated ATP7B-deficient rats. This beneficial effect was associated with depletion of copper from hepatocyte mitochondria. Moreover,MB treatment prevented hepatocyte death,subsequent liver failure,and death in the rodent model. These results suggest that MB has potential as a therapeutic agent for the treatment of acute WD. View Publication

Vascularization of engineered human skin constructs is crucial for recapitulation of systemic drug delivery and for their long-term survival,functionality,and viable engraftment. In this study,the latest microfabrication techniques are used and a novel bioengineering approach is established to micropattern spatially controlled and perfusable vascular networks in 3D human skin equivalents using both primary and induced pluripotent stem cell (iPSC)-derived endothelial cells. Using 3D printing technology makes it possible to control the geometry of the micropatterned vascular networks. It is verified that vascularized human skin equivalents (vHSEs) can form a robust epidermis and establish an endothelial barrier function,which allows for the recapitulation of both topical and systemic delivery of drugs. In addition,the therapeutic potential of vHSEs for cutaneous wounds on immunodeficient mice is examined and it is demonstrated that vHSEs can both promote and guide neovascularization during wound healing. Overall,this innovative bioengineering approach can enable in vitro evaluation of topical and systemic drug delivery as well as improve the potential of engineered skin constructs to be used as a potential therapeutic option for the treatment of cutaneous wounds. View Publication

The high proliferation rate of embryonic stem cells (ESCs) is thought to arise partly from very low expression of p21. However,how p21 is suppressed in ESCs has been unclear. We found that p53 binds to the p21 promoter in human ESCs (hESCs) as efficiently as in differentiated human mesenchymal stem cells,however it does not promote p21 transcription in hESCs. We observed an enrichment for both the repressive histone H3K27me3 and activating histone H3K4me3 chromatin marks at the p21 locus in hESCs,suggesting it is a suppressed,bivalent domain which overrides activation by p53. Reducing H3K27me3 methylation in hESCs rescued p21 expression,and ectopic expression of p21 in hESCs triggered their differentiation. Further,we uncovered a subset of bivalent promoters bound by p53 in hESCs that are similarly induced upon differentiation in a p53-dependent manner,whereas p53 promotes the transcription of other target genes which do not show an enrichment of H3K27me3 in ESCs. Our studies reveal a unique epigenetic strategy used by ESCs to poise undesired p53 target genes,thus balancing the maintenance of pluripotency in the undifferentiated state with a robust response to differentiation signals,while utilizing p53 activity to maintain genomic stability and homeostasis in ESCs. View Publication

Induced pluripotent stem cells (iPSCs) have the ability to differentiate in any specialized somatic cell type,which makes them an attractive tool for a wide variety of scientific approaches,including regenerative medicine. However,their pluripotent state and their growth in compact colonies render them difficult to access and,therefore,restrict delivery of specific agents for cell manipulation. Thus,our investigation focus was set on the evaluation of the capability of Layer-by-Layer (LbL) designed microcarriers to serve as a potential drug delivery system to iPSCs,as they offer several appealing advantages. Most notably,these carriers allow for the transport of active agents in a protected environment and for a rather specific delivery through surface modifications. As we could show,charge and mode of LbL carrier application as well as the size of the iPSC colonies determine the interaction with and the uptake rate by iPSCs. None of the examined conditions had an influence on iPSC colony properties such as colony morphology and size or maintenance of pluripotent properties. An overall interaction rate of LbL carriers with iPSCs of up to 20 % was achieved. Those data emphasize the applicability of LbL carriers for stem cell research. Additionally,the potential use of LbL carriers as a promising delivery tool for iPSCs was contrasted to viral particles and liposomes. The identified differences among those delivery tools have substantiated our major conclusion that LbL carrier uptake rate is influenced by characteristic features of the iPSC colonies (most notably colony size) in addition to their surface charges. View Publication

Rett syndrome (RTT) is a postnatal neurodevelopmental disorder that primarily affects girls. Mutations in the methyl-CpG-binding protein 2 (MECP2) gene account for approximately 95 % of all RTT cases. To model RTT in vitro,we generated induced pluripotent stem cells (iPSCs) from fibroblasts of two RTT patients with different mutations (MECP2 (R306C) and MECP2 (1155$$32)) in their MECP2 gene. We found that these iPSCs were capable of differentiating into functional neurons. Compared to control neurons,the RTT iPSC-derived cells had reduced soma size and a decreased amount of synaptic input,evident both as fewer Synapsin 1-positive puncta and a lower frequency of spontaneous excitatory postsynaptic currents. Supplementation of the culture media with choline rescued all of these defects. Choline supplementation may act through changes in the expression of choline acetyltransferase,an important enzyme in cholinergic signaling,and also through alterations in the lipid metabolite profiles of the RTT neurons. Our study elucidates the possible mechanistic pathways for the effect of choline on human RTT cell models,thereby illustrating the potential for using choline as a nutraceutical to treat RTT. View Publication

Human induced pluripotent stem cells (iPSCs) can be derived from various types of somatic cells by transient overexpression of 4 Yamanaka factors (OCT4,SOX2,C-MYC,and KLF4). Patient-specific iPSC derivatives (e.g.,neuronal,cardiac,hepatic,muscular,and endothelial cells [ECs]) hold great promise in drug discovery and regenerative medicine. In this study,we aimed to evaluate whether the cellular origin can affect the differentiation,in vivo behavior,and single-cell gene expression signatures of human iPSC-derived ECs. We derived human iPSCs from 3 types of somatic cells of the same individuals: fibroblasts (FB-iPSCs),ECs (EC-iPSCs),and cardiac progenitor cells (CPC-iPSCs). We then differentiated them into ECs by sequential administration of Activin,BMP4,bFGF,and VEGF. EC-iPSCs at early passage (10 textless P textless 20) showed higher EC differentiation propensity and gene expression of EC-specific markers (PECAM1 and NOS3) than FB-iPSCs and CPC-iPSCs. In vivo transplanted EC-iPSC-ECs were recovered with a higher percentage of CD31(+) population and expressed higher EC-specific gene expression markers (PECAM1,KDR,and ICAM) as revealed by microfluidic single-cell quantitative PCR (qPCR). In vitro EC-iPSC-ECs maintained a higher CD31(+) population than FB-iPSC-ECs and CPC-iPSC-ECs with long-term culturing and passaging. These results indicate that cellular origin may influence lineage differentiation propensity of human iPSCs; hence,the somatic memory carried by early passage iPSCs should be carefully considered before clinical translation. View Publication

Photoreceptor degeneration due to retinitis pigmentosa (RP) is a primary cause of inherited retinal blindness. Photoreceptor cell-replacement may hold the potential for repair in a completely degenerate retina by reinstating light sensitive cells to form connections that relay information to downstream retinal layers. This study assessed the therapeutic potential of photoreceptor progenitors derived from human embryonic and induced pluripotent stem cells (ESCs and iPSCs) using a protocol that is suitable for future clinical trials. ESCs and iPSCs were cultured in four specific stages under defined conditions,resulting in generation of a near-homogeneous population of photoreceptor-like progenitors. Following transplantation into mice with end-stage retinal degeneration,these cells differentiated into photoreceptors and formed a cell layer connected with host retinal neurons. Visual function was partially restored in treated animals,as evidenced by two visual behavioral tests. Furthermore,the magnitude of functional improvement was positively correlated with the number of engrafted cells. Similar efficacy was observed using either ESCs or iPSCs as source material. These data validate the potential of human pluripotent stem cells for photoreceptor replacement therapies aimed at photoreceptor regeneration in retinal disease. View Publication

Reliable,scalable and time-efficient culture methods are required to fully realize the clinical and industrial applications of human pluripotent stem (hPS) cells. Here we present a completely defined,xeno-free medium that supports long-term propagation of hPS cells on uncoated tissue culture plastic. The medium consists of the Essential 8 (E8) formulation supplemented with inter-α-inhibitor (IαI),a human serum-derived protein,recently demonstrated to activate key pluripotency pathways in mouse PS cells. IαI efficiently induces attachment and long-term growth of both embryonic and induced hPS cell lines when added as a soluble protein to the medium at seeding. IαI supplementation efficiently supports adaptation of feeder-dependent hPS cells to xeno-free conditions,clonal growth as well as single-cell survival in the absence of Rho-associated kinase inhibitor (ROCKi). This time-efficient and simplified culture method paves the way for large-scale,high-throughput hPS cell culture,and will be valuable for both basic research and commercial applications. View Publication

PAIRED (PRD)-like homeobox genes belong to a class of predicted transcription factor genes. Several of these PRD-like homeobox genes have been predicted in silico from genomic sequence but until recently had no evidence of transcript expression. We found recently that nine PRD-like homeobox genes,ARGFX,CPHX1,CPHX2,DPRX,DUXA,DUXB,NOBOX,TPRX1 and TPRX2,were expressed in human preimplantation embryos. In the current study we characterized these PRD-like homeobox genes in depth and studied their functions as transcription factors. We cloned multiple transcript variants from human embryos and showed that the expression of these genes is specific to embryos and pluripotent stem cells. Overexpression of the genes in human embryonic stem cells confirmed their roles as transcription factors as either activators (CPHX1,CPHX2,ARGFX) or repressors (DPRX,DUXA,TPRX2) with distinct targets that could be explained by the amino acid sequence in homeodomain. Some PRD-like homeodomain transcription factors had high concordance of target genes and showed enrichment for both developmentally important gene sets and a 36 bp DNA recognition motif implicated in Embryo Genome Activation (EGA). Our data implicate a role for these previously uncharacterized PRD-like homeodomain proteins in the regulation of human embryo genome activation and preimplantation embryo development. View Publication