技术资料

Human embryonic stem cell-derived cardiovascular progenitor cells (hESC-CVPCs) hold great promise for cell-based therapies of heart diseases. However,little is known about their niche microenvironment and in particular the required extracellular matrix (ECM) components. Here we screened combinations of surface-immobilized ECM proteins to identify substrates that support the attachment and survival of hESC-CVPCs. Covalent immobilization of ECM proteins laminin (Lm),fibronectin (Fn),collagen I (CI),collagen III (CIII),and collagen IV (CIV) in multiple combinations and concentrations was achieved by reductive amination on transparent acetaldehyde plasma polymer (AAPP) interlayer coatings. We identified that CI,CIII,CIV,and Fn and their combinations were important for hESC-CVPC attachment and survival,while Lm was dispensable. Moreover,for coatings displaying single ECM proteins,CI and CIII performed better than CIV and Fn,while coatings displaying the combined ECM proteins CIII + CIV and Fn + CIII + CIV at 100 µg/mL were comparable to Matrigel in regard to supporting hESC-CVPC attachment and viability. Our results identify ECM proteins required for hESC-CVPCs and demonstrate that coatings displaying multiple immobilized ECM proteins offer a suitable microenvironment for the attachment and survival of hESC-CVPCs. This knowledge contributes to the development of approaches for maintaining hESC-CVPCs and therefore to advances in cardiovascular regeneration. textcopyright 2017 Wiley Periodicals,Inc. J Biomed Mater Res Part A: 105A: 1094-1104,2017. View Publication

As multiple sclerosis research progresses,it is pertinent to continue to develop suitable paradigms to allow for ever more sophisticated investigations. Animal models of multiple sclerosis,despite their continuing contributions to the field,may not be the most prudent for every experiment. Indeed,such may be either insufficient to reflect the functional impact of human genetic variations or unsuitable for drug screenings. Thus,we have established a cell- and patient-specific paradigm to provide an in vitro model within which to perform future genetic investigations. Renal proximal tubule epithelial cells were isolated from multiple sclerosis patients' urine and transfected with pluripotency-inducing episomal factors. Subsequent induced pluripotent stem cells were formed into embryoid bodies selective for ectodermal lineage,resulting in neural tube-like rosettes and eventually neural progenitor cells. Differentiation of these precursors into primary neurons was achieved through a regimen of neurotrophic and other factors. These patient-specific primary neurons displayed typical morphology and functionality,also staining positive for mature neuronal markers. The development of such a non-invasive procedure devoid of permanent genetic manipulation during the course of differentiation,in the context of multiple sclerosis,provides an avenue for studies with a greater cell- and human-specific focus,specifically in the context of genetic contributions to neurodegeneration and drug discovery. View Publication

The physiologic function of BUBR1,a key component of the spindle checkpoint,was examined by generating BUBR1-mutant mice. BUBR1(-/-) embryos failed to survive beyond day 8.5 in utero as a result of extensive apoptosis. Whereas BUBR1(+/-) blastocysts grew relatively normally in vitro,BUBR1(-/-) blastocysts exhibited impaired proliferation and atrophied. Adult BUBR1(+/-) mice manifested splenomegaly and abnormal megakaryopoiesis. BUBR1 haploinsufficiency resulted in an increase in the number of splenic megakaryocytes,which was correlated with an increase in megakaryocytic,but a decrease in erythroid,progenitors in bone marrow cells. RNA interference-mediated down-regulation of BUBR1 also caused an increase in polyploidy formation in murine embryonic fibroblast cells and enhanced megakaryopoiesis in bone marrow progenitor cells. However,enhanced megakaryopoiesis in BUBR1(+/-) mice was not correlated with a significant increase in platelets in peripheral blood,which was at least partly due to a defect in the formation of proplatelet-producing megakaryocytes. Together,these results indicate that BUBR1 is essential for early embryonic development and normal hematopoiesis. View Publication

Neural progenitor cells (NPCs) can be induced from somatic cells by defined factors. Here we report that NPCs can be generated from mouse embryonic fibroblasts by a chemical cocktail,namely VCR (V,VPA,an inhibitor of HDACs; C,CHIR99021,an inhibitor of GSK-3 kinases and R,Repsox,an inhibitor of TGF-β pathways),under a physiological hypoxic condition. These chemical-induced NPCs (ciNPCs) resemble mouse brain-derived NPCs re- garding their proliferative and self-renewing abilities,gene expression profiles,and multipotency for different neu- roectodermal lineages in vitro and in vivo. Further experiments reveal that alternative cocktails with inhibitors of histone deacetylation,glycogen synthase kinase,and TGF-β pathways show similar efficacies for ciNPC induction. Moreover,ciNPCs can also be induced from mouse tail-tip fibroblasts and human urinary cells with the same chemi- cal cocktail VCR. Thus our study demonstrates that lineage-specific conversion of somatic cells to NPCs could be achieved by chemical cocktails without introducing exogenous factors. View Publication

We have previously demonstrated that mouse embryonic stem (ES) cells differentiated on three-dimensional (3D),highly porous,tantalum-based scaffolds (Cytomatrixtrade mark) have significantly higher hematopoietic differentiation efficiency than those cultured under conventional two-dimensional (2D) tissue culture conditions. In addition,ES cell-seeded scaffolds cultured inside spinner bioreactors showed further enhancement in hematopoiesis compared to static conditions. In the present study,we evaluated how these various biomaterial-based culture conditions,e.g. 2D vs. 3D scaffolds and static vs. dynamic,influence the global gene expression profile of differentiated ES cells. We report that compared to 2D tissue culture plates,cells differentiated on porous,Cytomatrixtrade mark scaffolds possess significantly higher expression levels of extracellular matrix (ECM)-related genes,as well as genes that regulate cell growth,proliferation and differentiation. In addition,these differences in gene expression were more pronounced in 3D dynamic culture compared to 3D static culture. We report specific genes that are either uniquely expressed under each condition or are quantitatively regulated,i.e. over expressed or inhibited by a specific culture environment. We conclude that that biomaterial-based 3D cultures,especially under dynamic conditions,might favor efficient hematopoietic differentiation of ES cells by stimulating increased expression of specific ECM proteins,growth factors and cell adhesion related genes while significantly down-regulating genes that act to inhibit expression of these molecules. View Publication

Multigene delivery and subsequent cellular expression is emerging as a key technology required in diverse research fields including,synthetic and structural biology,cellular reprogramming and functional pharmaceutical screening. Current viral delivery systems such as retro- and adenoviruses suffer from limited DNA cargo capacity,thus impeding unrestricted multigene expression. We developed MultiPrime,a modular,non-cytotoxic,non-integrating,baculovirus-based vector system expediting highly efficient transient multigene expression from a variety of promoters. MultiPrime viruses efficiently transduce a wide range of cell types,including non-dividing primary neurons and induced-pluripotent stem cells (iPS). We show that MultiPrime can be used for reprogramming,and for genome editing and engineering by CRISPR/Cas9. Moreover,we implemented dual-host-specific cassettes enabling multiprotein expression in insect and mammalian cells using a single reagent. Our experiments establish MultiPrime as a powerful and highly efficient tool,to deliver multiple genes for a wide range of applications in primary and established mammalian cells. View Publication

Genome editing with engineered site-specific endonucleases involves nonhomologous end-joining,leading to reading frame disruption. The approach is applicable to dominant negative disorders,which can be treated simply by knocking out the mutant allele,while leaving the normal allele intact. We applied this strategy to dominant dystrophic epidermolysis bullosa (DDEB),which is caused by a dominant negative mutation in the COL7A1 gene encoding type VII collagen (COL7). We performed genome editing with TALENs and CRISPR/Cas9 targeting the mutation,c.80688084delinsGA. We then cotransfected Cas9 and guide RNA expression vectors expressed with GFP and DsRed,respectively,into induced pluripotent stem cells (iPSCs) generated from DDEB fibroblasts. After sorting,90% of the iPSCs were edited,and we selected four gene-edited iPSC lines for further study. These iPSCs were differentiated into keratinocytes and fibroblasts secreting COL7. RT-PCR and Western blot analyses revealed gene-edited COL7 with frameshift mutations degraded at the protein level. In addition,we confirmed that the gene-edited truncated COL7 could neither associate with normal COL7 nor undergo triple helix formation. Our data establish the feasibility of mutation site-specific genome editing in dominant negative disorders. View Publication

The aryl hydrocarbon receptor (AHR) is a ligand activated transcription factor that increases the expression of detoxifying enzymes upon ligand stimulation. Recent studies now suggest that novel endogenous roles of the AHR exist throughout development. In an effort to create an optimized model system for the study of AHR signaling in several cellular lineages,we have employed a CRISPR/CAS9 genome editing strategy in induced pluripotent stem cells (iPSCs) to incorporate a reporter cassette at the transcription start site of one of its canonical targets,cytochrome P450 1A1 (CYP1A1). This cell line faithfully reports on CYP1A1 expression,with luciferase levels as its functional readout,when treated with an endogenous AHR ligand (FICZ) at escalating doses. iPSC-derived fibroblast-like cells respond to acute exposure to environmental and endogenous AHR ligands,and iPSC-derived hepatocytes increase CYP1A1 in a similar manner to primary hepatocytes. This cell line is an important innovation that can be used to map AHR activity in discrete cellular subsets throughout developmental ontogeny. As further endogenous ligands are proposed,this line can be used to screen for safety and efficacy and can report on the ability of small molecules to regulate critical cellular processes by modulating the activity of the AHR. View Publication

In the present study,we combined stem cell technology with a non-absorbable biomaterial for the reconstruction of the ruptured ACL. Towards this purpose,multipotential stromal cells derived either from subcutaneous human adipose tissue (hAT-MSCs) or from induced pluripotent stem cells (iPSCs) generated from human foreskin fibroblasts (hiPSC-MSCs) were cultured on the biomaterial for 21days in vitro to generate a 3D bioartifical ACL graft. Stem cell differentiation towards bone and ligament at the ends and central part of the biomaterial was selectively induced using either BMP-2/FGF-2 or TGF-β/FGF-2 combinations,respectively. The bioartificial ACL graft was subsequently implanted in a swine ACL rupture model in place of the surgically removed normal ACL. Four months post-implantation,the tissue engineered ACL graft generated an ACL-like tissue exhibiting morphological and biochemical characteristics resembling those of normal ACL. View Publication

We report generation of induced pluripotent stem cell (iPSC) lines from ten Parkinson's disease (PD) patients carrying SNCA,PARK2,LRRK2,and GBA mutations,and one age-matched control. After validation of pluripotency,long-term genome stability,and integration-free reprogramming,eight of these lines (one of each SNCA,LRRK2 and GBA,four PARK2 lines,and the control) were differentiated into neural stem cells (NSC) and subsequently to dopaminergic cultures. We did not observe significant differences in the timeline of neural induction and NSC derivation between the patient and control line,nor amongst the patient lines,although we report considerable variability in the efficiency of dopaminergic differentiation among patient lines. We performed whole genome expression analyses of the lines at each stage of differentiation (fibroblast,iPSC,NSC,and dopaminergic culture) in an attempt to identify alterations by large-scale evaluation. While gene expression profiling clearly distinguished cells at different stages of differentiation,no mutation-specific clustering or difference was observed,though consistent changes in patient lines were detected in genes associated mitochondrial biology. We further examined gene expression in a stress model (MPTP-induced dopaminergic neuronal death) using two clones from the SNCA triplication line,and detected changes in genes associated with mitophagy. Our data suggested that even a well-characterized line of a monogenic disease may not be sufficient to determine the cause or mechanism of the disease,and highlights the need to use more focused strategies for large-scale data analysis. View Publication

Mucopolysaccharidosis type II (MPS II) is an X-linked lysosomal storage disorder resulting from deficiency of iduronate-2-sulphatase activity. The disease manifests almost exclusively in males; only 16 symptomatic heterozygote girls have been reported so far. We describe the results of X-chromosome inactivation analysis in a 5-year-old girl with clinically severe disease and heterozygous mutation p.Arg468Gln in the IDS gene. X inactivation analysed at three X-chromosome loci showed extreme skewing (96/4 to 99/1) in two patient's cell types. This finding correlated with exclusive expression of the mutated allele. Induced pluripotent stem cells (iPSC) generated from the patient's peripheral blood demonstrated characteristic pluripotency markers,deficiency of enzyme activity,and mutation in the IDS gene. These cells were capable of differentiation into other cell types (cardiomyocytes,neurons). In MPS II iPSC clones,the X inactivation ratio remained highly skewed in culture conditions that led to partial X inactivation reset in Fabry disease iPSC clones. Our data,in accordance with the literature,suggest that extremely skewed X inactivation favouring the mutated allele is a crucial condition for manifestation of MPS II in females. This suggests that the X inactivation status and enzyme activity have a prognostic value and should be used to evaluate MPS II in females. For the first time,we show generation of iPSC from a symptomatic MPS II female patient that can serve as a cellular model for further research of the pathogenesis and treatment of this disease. View Publication

Disturbances in neuronal differentiation and function are an underlying factor of many brain disorders. Zinc homeostasis and signaling are important mediators for a normal brain development and function,given that zinc deficiency was shown to result in cognitive and emotional deficits in animal models that might be associated with neurodevelopmental disorders. One underlying mechanism of the observed detrimental effects of zinc deficiency on the brain might be impaired proliferation and differentiation of stem cells participating in neurogenesis. Thus,to examine the molecular mechanisms regulating zinc metabolism and signaling in differentiating neurons,using a protocol for motor neuron differentiation,we characterized the expression of zinc homeostasis genes during neurogenesis using human induced pluripotent stem cells (hiPSCs) and evaluated the influence of altered zinc levels on the expression of zinc homeostasis genes,cell survival,cell fate,and neuronal function. Our results show that zinc transporters are highly regulated genes during neuronal differentiation and that low zinc levels are associated with decreased cell survival,altered neuronal differentiation,and,in particular,synaptic function. We conclude that zinc deficiency in a critical time window during brain development might influence brain function by modulating neuronal differentiation. View Publication