技术资料

Mitochondrial diseases display pathological phenotypes according to the mixture of mutant versus wild-type mitochondrial DNA (mtDNA),known as heteroplasmy. We herein examined the impact of nuclear reprogramming and clonal isolation of induced pluripotent stem cells (iPSC) on mitochondrial heteroplasmy. Patient-derived dermal fibroblasts with a prototypical mitochondrial deficiency diagnosed as MELAS demonstrated mitochondrial dysfunction with reduced oxidative reserve due to heteroplasmy at position G13513A in the ND5 subunit of complex I. Bioengineered iPSC clones acquired pluripotency with multi-lineage differentiation capacity and demonstrated reduction in mitochondrial density and oxygen consumption distinguishing them from the somatic source. Consistent with the cellular mosaicism of the original patient-derived fibroblasts,the MELAS-iPSC clones contained a similar range of mtDNA heteroplasmy of the disease-causing mutation with identical profiles in the remaining mtDNA. High-heteroplasmy iPSC clones were used to demonstrate that extended stem cell passaging was sufficient to purge mutant mtDNA,resulting in isogenic iPSC subclones with various degrees of disease-causing genotypes. Upon comparative differentiation of iPSC clones,improved cardiogenic yield was associated with iPSC clones containing lower heteroplasmy compared to isogenic clones with high heteroplasmy. Thus,mtDNA heteroplasmic segregation within patient-derived stem cell lines enables direct comparison of genotype/phenotype relationships in progenitor cells and lineage-restricted progeny,and indicates that cell fate decisions are regulated as a function of mtDNA mutation load. The novel nuclear reprogramming-based model system introduces a disease-in-a-dish tool to examine the impact of mutant genotypes for MELAS patients in bioengineered tissues and a cellular probe for molecular features of individual mitochondrial diseases. View Publication

Organs-on-chips are microengineered in vitro tissue structures that can be used as platforms for physiological and pathological research. They provide tissue-like microenvironments in which different cell types can be co-cultured in a controlled manner to create synthetic organ mimics. Blood vessels are an integral part of all tissues in the human body. Development of vascular structures is therefore an important research topic for advancing the field of organs-on-chips since generated tissues will require a blood or nutrient supply. Here,we have engineered three-dimensional constructs of vascular tissue inside microchannels by injecting a mixture of human umbilical vein endothelial cells,human embryonic stem cell-derived pericytes (the precursors of vascular smooth muscle cells) and rat tail collagen I into a polydimethylsiloxane microfluidic channel with dimensions 500 μm × 120 μm × 1 cm (w × h × l). Over the course of 12 h,the cells organized themselves into a single long tube resembling a blood vessel that followed the contours of the channel. Detailed examination of tube morphology by confocal microscopy revealed a mature endothelial monolayer with complete PECAM-1 staining at cell–cell contacts and pericytes incorporated inside the tubular structures. We also demonstrated that tube formation was disrupted in the presence of a neutralizing antibody against transforming growth factor-beta (TGF-β). The TGF-β signaling pathway is essential for normal vascular development; deletion of any of its components in mouse development results in defective vasculogenesis and angiogenesis and mutations in humans have been linked to multiple vascular genetic diseases. In the engineered microvessels,inhibition of TGF-β signaling resulted in tubes with smaller diameters and higher tortuosity,highly reminiscent of the abnormal vessels observed in patients with one particular vascular disease known as hereditary hemorrhagic telangiectasia (HHT). In summary,we have developed microengineered three-dimensional vascular structures that can be used as a model to test the effects of drugs and study the interaction between different human vascular cell types. In the future,the model may be integrated into larger tissue constructs to advance the development of organs-on-chips. View Publication

The future of safe cell-based therapy rests on overcoming teratoma/tumor formation,in particular when using human pluripotent stem cells (hPSCs),such as human embryonic stem cells (hESCs) and human induced pluripotent stem cells (hiPSCs). Because the presence of a few remaining undifferentiated hPSCs can cause undesirable teratomas after transplantation,complete removal of these cells with no/minimal damage to differentiated cells is a prerequisite for clinical application of hPSC-based therapy. Having identified a unique hESC signature of pro- and antiapoptotic gene expression profile,we hypothesized that targeting hPSC-specific antiapoptotic factor(s) (i.e.,survivin or Bcl10) represents an efficient strategy to selectively eliminate pluripotent cells with teratoma potential. Here we report the successful identification of small molecules that can effectively inhibit these antiapoptotic factors,leading to selective and efficient removal of pluripotent stem cells through apoptotic cell death. In particular,a single treatment of hESC-derived mixed population with chemical inhibitors of survivin (e.g.,quercetin or YM155) induced selective and complete cell death of undifferentiated hPSCs. In contrast,differentiated cell types (e.g.,dopamine neurons and smooth-muscle cells) derived from hPSCs survived well and maintained their functionality. We found that quercetin-induced selective cell death is caused by mitochondrial accumulation of p53 and is sufficient to prevent teratoma formation after transplantation of hESC- or hiPSC-derived cells. Taken together,these results provide the proof of concept" that small-molecule targeting of hPSC-specific antiapoptotic pathway(s) is a viable strategy to prevent tumor formation by selectively eliminating remaining undifferentiated pluripotent cells for safe hPSC-based therapy." View Publication

Human embryonic stem (ES) cells can be maintained in an undifferentiated state if the culture medium is first conditioned on a layer of mouse embryonic fibroblast (MEF) feeder cells. Here we show that human ES cell proliferation is coordinated by MEF-secreted heparan sulfate proteoglycans (HSPG) in conditioned medium (CM). These HSPG and other heparinoids can stabilize basic fibroblast growth factor (FGF2) in unconditioned medium at levels comparable to those observed in CM. They also directly mediate binding of FGF2 to the human ES cell surface,and their removal from CM impairs proliferation. Finally,we have developed a purification scheme for MEF-secreted HSPG in CM. Using column chromatography,immunoblotting,and mass spectrometry-based proteomic analysis,we have identified multiple HSPG species in CM. The results demonstrate that HSPG are key signaling cofactors in CM-based human ES cell culture. View Publication

Self-renewal of human embryonic stem cells (ESCs) is promoted by FGF and TGFbeta/Activin signaling,and differentiation is promoted by BMP signaling,but how these signals regulate genes critical to the maintenance of pluripotency has been unclear. Using a defined medium,we show here that both TGFbeta and FGF signals synergize to inhibit BMP signaling; sustain expression of pluripotency-associated genes such as NANOG,OCT4,and SOX2; and promote long-term undifferentiated proliferation of human ESCs. We also show that both TGFbeta- and BMP-responsive SMADs can bind with the NANOG proximal promoter. NANOG promoter activity is enhanced by TGFbeta/Activin and FGF signaling and is decreased by BMP signaling. Mutation of putative SMAD binding elements reduces NANOG promoter activity to basal levels and makes NANOG unresponsive to BMP and TGFbeta signaling. These results suggest that direct binding of TGFbeta/Activin-responsive SMADs to the NANOG promoter plays an essential role in sustaining human ESC self-renewal. View Publication

Murine embryonic stem (mES) cells are self-renewing pluripotent cells that bear the capacity to differentiate into ectoderm-,endoderm-,and mesoderm-derived tissues. In suspension culture,embryonic stem (ES) cells grow into spherical embryoid bodies (EBs) and are useful for the study of specific gene products in the development and function of various tissue types. Osteoclasts are hematopoietic stem cell-derived cells that participate in bone turnover by secreting resorptive molecules such as hydrochloric acid and acidic proteases,which degrade the bone extracellular matrix. Aberrant osteoclast function leads to dysplastic,erosive,and sclerosing bone diseases. Previous studies have reported the derivation of osteoclasts from mES cells; however,most of these protocols require coculture with stromal cell lines. We describe two simplified,novel methods of stromal cell-independent ES cell-derived osteoclast development. View Publication

Sickle cell disease (SCD) is the most common human genetic disease which is caused by a single mutation of human β-globin (HBB) gene. The lack of long-term treatment makes the development of reliable cell and gene therapies highly desirable. Disease-specific patient-derived human induced pluripotent stem cells (hiPSCs) have great potential for developing novel cell and gene therapies. With the disease-causing mutations corrected in situ,patient-derived hiPSCs can restore normal cell functions and serve as a renewable autologous cell source for the treatment of genetic disorders. Here we successfully utilized transcription activator-like effector nucleases (TALENs),a recently emerged novel genome editing tool,to correct the SCD mutation in patient-derived hiPSCs. The TALENs we have engineered are highly specific and generate minimal off-target effects. In combination with piggyBac transposon,TALEN-mediated gene targeting leaves no residual ectopic sequences at the site of correction and the corrected hiPSCs retain full pluripotency and a normal karyotype. Our study demonstrates an important first step of using TALENs for the treatment of genetic diseases such as SCD,which represents a significant advance toward hiPSC-based cell and gene therapies. View Publication

INTRODUCTION: Ischemic stroke is a leading cause of death and disability,but treatment options are severely limited. Cell therapy offers an attractive strategy for regenerating lost tissues and enhancing the endogenous healing process. In this study,we investigated the use of human embryonic stem cell-derived neural precursors as a cell therapy in a murine stroke model.backslashnbackslashnMETHODS: Neural precursors were derived from human embryonic stem cells by using a fully adherent SMAD inhibition protocol employing small molecules. The efficiency of neural induction and the ability of these cells to further differentiate into neurons were assessed by using immunocytochemistry. Whole-cell patch-clamp recording was used to demonstrate the electrophysiological activity of human embryonic stem cell-derived neurons. Neural precursors were transplanted into the core and penumbra regions of a focal ischemic stroke in the barrel cortex of mice. Animals received injections of bromodeoxyuridine to track regeneration. Neural differentiation of the transplanted cells and regenerative markers were measured by using immunohistochemistry. The adhesive removal test was used to determine functional improvement after stroke and intervention.backslashnbackslashnRESULTS: After 11 days of neural induction by using the small-molecule protocol,over 95% of human embryonic stem-derived cells expressed at least one neural marker. Further in vitro differentiation yielded cells that stained for mature neuronal markers and exhibited high-amplitude,repetitive action potentials in response to depolarization. Neuronal differentiation also occurred after transplantation into the ischemic cortex. A greater level of bromodeoxyuridine co-localization with neurons was observed in the penumbra region of animals receiving cell transplantation. Transplantation also improved sensory recovery in transplant animals over that in control animals.backslashnbackslashnCONCLUSIONS: Human embryonic stem cell-derived neural precursors derived by using a highly efficient small-molecule SMAD inhibition protocol can differentiate into electrophysiologically functional neurons in vitro. These cells also differentiate into neurons in vivo,enhance regenerative activities,and improve sensory recovery after ischemic stroke. View Publication

Development of therapeutics for genetically complex neurodegenerative diseases such as sporadic amyotrophic lateral sclerosis (ALS) has largely been hampered by lack of relevant disease models. Reprogramming of sporadic ALS patients' fibroblasts into induced pluripotent stem cells (iPSC) and differentiation into affected neurons that show a disease phenotype could provide a cellular model for disease mechanism studies and drug discovery. Here we report the reprogramming to pluripotency of fibroblasts from a large cohort of healthy controls and ALS patients and their differentiation into motor neurons. We demonstrate that motor neurons derived from three sALS patients show de novo TDP-43 aggregation and that the aggregates recapitulate pathology in postmortem tissue from one of the same patients from which the iPSC were derived. We configured a high-content chemical screen using the TDP-43 aggregate endpoint both in lower motor neurons and upper motor neuron like cells and identified FDA-approved small molecule modulators including Digoxin demonstrating the feasibility of patient-derived iPSC-based disease modeling for drug screening. View Publication

Neural crest (NC) cells contribute to the development of many complex tissues of all three germ layers during embryogenesis,and its abnormal development accounts for several congenital birth defects. Generating NC cells-including specific subpopulations such as cranial,cardiac,and trunk NC cells-from human pluripotent stem cells will provide a valuable model system to study human development and disease. Here,we describe a rapid and robust NC differentiation method called LSB-short" that is based on dual SMAD pathway inhibition. This protocol yields high percentages of NC cell populations from multiple human induced pluripotent stem and human embryonic stem cell lines in 8 days. The resulting cells can be propagated easily� View Publication

INTRODUCTION: The reprogramming of a patient's somatic cells back into induced pluripotent stem cells (iPSCs) holds significant promise for future autologous cellular therapeutics. The continued presence of potentially oncogenic transgenic elements following reprogramming,however,represents a safety concern that should be addressed prior to clinical applications. The polycistronic stem cell cassette (STEMCCA),an excisable lentiviral reprogramming vector,provides,in our hands,the most consistent reprogramming approach that addresses this safety concern. Nevertheless,most viral integrations occur in genes,and exactly how the integration,epigenetic reprogramming,and excision of the STEMCCA reprogramming vector influences those genes and whether these cells still have clinical potential are not yet known. METHODS: In this study,we used both microarray and sensitive real-time PCR to investigate gene expression changes following both intron-based reprogramming and excision of the STEMCCA cassette during the generation of human iPSCs from adult human dermal fibroblasts. Integration site analysis was conducted using nonrestrictive linear amplification PCR. Transgene-free iPSCs were fully characterized via immunocytochemistry,karyotyping and teratoma formation,and current protocols were implemented for guided differentiation. We also utilized current good manufacturing practice guidelines and manufacturing facilities for conversion of our iPSCs into putative clinical grade conditions. RESULTS: We found that a STEMCCA-derived iPSC line that contains a single integration,found to be located in an intronic location in an actively transcribed gene,PRPF39,displays significantly increased expression when compared with post-excised stem cells. STEMCCA excision via Cre recombinase returned basal expression levels of PRPF39. These cells were also shown to have proper splicing patterns and PRPF39 gene sequences. We also fully characterized the post-excision iPSCs,differentiated them into multiple clinically relevant cell types (including oligodendrocytes,hepatocytes,and cardiomyocytes),and converted them to putative clinical-grade conditions using the same approach previously approved by the US Food and Drug Administration for the conversion of human embryonic stem cells from research-grade to clinical-grade status. CONCLUSION: For the first time,these studies provide a proof-of-principle for the generation of fully characterized transgene-free human iPSCs and,in light of the limited availability of current good manufacturing practice cellular manufacturing facilities,highlight an attractive potential mechanism for converting research-grade cell lines into putatively clinical-grade biologics for personalized cellular therapeutics. View Publication

Spinocerebellar ataxia type 2 (SCA2) is caused by triple nucleotidebackslashnrepeat (CAG) expansion in the coding region of the ATAXN2 gene onbackslashnchromosome 12,which produces an elongated,toxic polyglutamine tract,backslashnleading to Purkinje cell loss. There is currently no effective therapy.backslashnOne of the main obstacles that hampers therapeutic development is lackbackslashnof an ideal disease model. In this study,we have generated andbackslashncharacterized SCA2-induced pluripotent stem (iPS) cell lines as an inbackslashnvitro cell model. Dermal fibroblasts (FBs) were harvested from primarybackslashncultures of skin explants obtained from a SCA2 subject and a healthybackslashnsubject. For reprogramming,hOct4,hSox2,hKlf4,and hc-Myc werebackslashntransduced to passage-3 FBs by retroviral infection. Both SCA2 iPS andbackslashncontrol iPS cells were successfully generated and showed typical stembackslashncell growth patterns with normal karyotype. All iPS cell lines expressedbackslashnstem cell markers and differentiated in vitro into cells from threebackslashnembryonic germ layers. Upon in vitro neural differentiation,SCA2 iPSbackslashncells showed abnormality in neural rosette formation but successfullybackslashndifferentiated into neural stem cells (NSCs) and subsequent neuralbackslashncells. SCA2 and normal FBs showed a comparable level of ataxin-2backslashnexpression; whereas SCA2 NSCs showed less ataxin-2 expression thanbackslashnnormal NSCs and SCA2 FBs. Within the neural lineage,neurons had thebackslashnmost abundant expression of ataxin-2. Time-lapsed neural growth assaybackslashnindicated terminally differentiated SCA2 neural cells were short-livedbackslashncompared with control neural cells. The expanded CAG repeats of SCA2backslashnwere stable throughout reprogramming and neural differentiation. Inbackslashnconclusion,we have established the first disease-specific human SCA2backslashniPS cell line. These mutant iPS cells have the potential for neuralbackslashndifferentiation. These differentiated neural cells harboring mutationsbackslashnare invaluable for the study of SCA2 pathogenesis and therapeutic drugbackslashndevelopment. View Publication