EasySep™小鼠TIL(CD45)正选试剂盒
产品号 #73202_C
神经分化诱导剂
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总览
ISX-9是小分子诱导剂,可在体外和体内诱导成体神经干细胞分化(Schneider等人)。已证明其作用机制通过钙离子激活的信号通路,依赖肌细胞增强因子2(MEF2)介导的基因表达发挥作用(Schneider 等人;Petrik 等人)。
重编程
·结合CHIR99021、Forskolin、SB431542和I-BET151,将成纤维细胞直接重编程为成熟神经元(Li等人)。
分化
·诱导成年大鼠HCN海马神经干/祖细胞系、成年小鼠全脑或脑室下区神经祖细胞和P19胚胎癌细胞的神经元分化(Schneider等人)。
·改善小鼠的海马神经发生和功能(Petrik等人)。
·刺激成年小鼠心肌的心肌基因表达和细胞周期活性(Russell等人)。
·恶性星形胶质细胞中,阻断肿瘤细胞增殖,诱导神经元基因表达(Zhang等人)。
·人原代胰岛培养物中,改善β细胞功能,增强促进 β 细胞分化的转录因子表达,增加细胞内胰岛素含量(Dioum等人)。
细胞类型
癌细胞及细胞系,心肌细胞,PSC衍生,神经干/祖细胞,神经元,胰腺细胞
种属
人,小鼠,非人灵长类,其它细胞系,大鼠
应用
分化,重编程
研究领域
癌症,上皮细胞研究,神经科学,干细胞生物学
CAS 编号
832115-62-5
化学式
C₁₁H₁₀N₂O₂S
纯度
≥ 95 %
产品说明书及文档
请在《产品说明书》中查找相关支持信息和使用说明,或浏览下方更多实验方案。
应用领域
本产品专为以下研究领域设计,适用于工作流程中的高亮阶段。探索这些工作流程,了解更多我们为各研究领域提供的其他配套产品。
相关材料与文献
技术资料 (1)
文献 (6)
Small-Molecule-Driven Direct Reprogramming of Mouse Fibroblasts into Functional Neurons. Cell stem cell 2015 AUG
Abstract
Recently, direct reprogramming between divergent lineages has been achieved by the introduction of regulatory transcription factors. This approach may provide alternative cell resources for drug discovery and regenerative medicine, but applications could be limited by the genetic manipulation involved. Here, we show that mouse fibroblasts can be directly converted into neuronal cells using only a cocktail of small molecules, with a yield of up to textgreater90% being TUJ1-positive after 16 days of induction. After a further maturation stage, these chemically induced neurons (CiNs) possessed neuron-specific expression patterns, generated action potentials, and formed functional synapses. Mechanistically, we found that a BET family bromodomain inhibitor, I-BET151, disrupted the fibroblast-specific program, while the neurogenesis inducer ISX9 was necessary to activate neuron-specific genes. Overall, our findings provide a proof of principle" for chemically induced direct reprogramming of somatic cell fates across germ layers without genetic manipulation�
Functional and mechanistic exploration of an adult neurogenesis-promoting small molecule. FASEB journal : official publication of the Federation of American Societies for Experimental Biology 2012
Abstract
Adult neurogenesis occurs throughout life in the mammalian hippocampus and is essential for memory and mood control. There is significant interest in identifying ways to promote neurogenesis and ensure maintenance of these hippocampal functions. Previous work with a synthetic small molecule, isoxazole 9 (Isx-9), highlighted its neuronal-differentiating properties in vitro. However, the ability of Isx-9 to drive neurogenesis in vivo or improve hippocampal function was unknown. Here we show that Isx-9 promotes neurogenesis in vivo, enhancing the proliferation and differentiation of hippocampal subgranular zone (SGZ) neuroblasts, and the dendritic arborization of adult-generated dentate gyrus neurons. Isx-9 also improves hippocampal function, enhancing memory in the Morris water maze. Notably, Isx-9 enhances neurogenesis and memory without detectable increases in cellular or animal activity or vascularization. Molecular exploration of Isx-9-induced regulation of neurogenesis (via FACS and microarray of SGZ stem and progenitor cells) suggested the involvement of the myocyte-enhancer family of proteins (Mef2). Indeed, transgenic-mediated inducible knockout of all brain-enriched Mef2 isoforms (Mef2a/c/d) specifically from neural stem cells and their progeny confirmed Mef2's requirement for Isx-9-induced increase in hippocampal neurogenesis. Thus, Isx-9 enhances hippocampal neurogenesis and memory in vivo, and its effects are reliant on Mef2, revealing a novel cell-intrinsic molecular pathway regulating adult neurogenesis.
Targeting native adult heart progenitors with cardiogenic small molecules. ACS chemical biology 2012
Abstract
Targeting native progenitors with small molecule pharmaceuticals that direct cell fate decisions is an attractive approach for regenerative medicine. Here, we show that 3,5-disubstituted isoxazoles (Isx), stem cell-modulator small molecules originally recovered in a P19 embryonal carcinoma cell-based screen, directed cardiac muscle gene expression in vivo in target tissues of adult transgenic reporter mice. Isx also stimulated adult mouse myocardial cell cycle activity. Narrowing our focus onto one target cardiac-resident progenitor population, Isx directed muscle transcriptional programs in vivo in multipotent Notch-activated epicardium-derived cells (NECs), generating Notch-activated adult cardiomyocyte-like precursors. Myocardial infarction (MI) preemptively differentiated NECs toward fibroblast lineages, overriding Isx's cardiogenic influence in this cell population. Isx dysregulated gene expression in vivo in Notch-activated repair fibroblasts, driving distinctive (pro-angiogenesis) gene programs, but failed to mitigate fibrosis or avert ventricular functional decline after MI. In NECs in vitro, Isx directed partial muscle differentiation, which included biosynthesis and assembly of sarcomeric α-actinin premyofibrils, beaded structures pathognomonic of early developing cardiomyocytes. Thus, although Isx small molecules have promising in vivo efficacy at the level of cardiac muscle gene expression in native multipotent progenitors and are first in class in this regard, a greater understanding of the dynamic interplay between fibrosis and cardiogenic small molecule signals will be required to pharmacologically enable regenerative repair of the heart.
更多信息
| 种属 | Human, Mouse, Non-Human Primate, Other, Rat |
|---|---|
| Cas Number | 832115-62-5 |
| Chemical Formula | C₁₁H₁₀N₂O₂S |
| 纯度 | ≥ 95% |
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