| Differentiation of Human Induced Pluripotent Stem Cells (hiPSCs) into Osteoclasts
|
|
Author:
Date:
2020-12-20
[Abstract] Defects in bone resorption by osteoclasts result in numerous rare genetic bone disorders as well as in some common diseases such as osteoporosis or osteopetrosis. The use of hiPSC-differentiated osteoclasts opens new avenues in this research field by providing an unlimited cell source and overcoming obstacles such as unavailability of human specimens and suitable animal models. Generation of hiPSCs is well established but efficient differentiation of hiPSCs into osteoclasts has been challenging. Published hiPSC-osteoclast differentiation protocols use a hiPSC-OP9 co-culture system or ...
[摘要] [摘要]破骨细胞引起的骨吸收缺陷导致许多罕见的遗传性骨疾病以及某些常见的疾病,例如骨质疏松症或骨质疏松症。采用的hiPSC -分化破骨细胞通过提供无限的细胞来源和克服障碍,如人体标本和合适的动物模型的可用性打开了该领域的新途径。hiPSC的生成已被公认,但是将hiPSC高效分化为破骨细胞一直具有挑战性。发布的hiPSC -osteoclast分化协议使用的hiPSC-OP9共培养体系或hiPSC细胞来源的胚状 具有多种细胞因子的机体(EB)。我们的三阶段协议包含:1)中胚层EB分化,2)的扩张骨髓单核细胞和3)的成熟的hiPSC -osteoclasts。我们通过在Nunclon Sphera微孔板上培养Accutase分离的hiPSCs来产生大小均一的EB,并在4天的细胞因子混合物中促进EB中胚层分化。对于第2阶段,将EBs转移至明胶包被的平板中,并用hM -CSF和hIL-3培养,以扩增骨髓单核细胞群。通过与维生素d,补充hTGF β,HM -CSF和hRANKL ,在第2阶段结束时收集的细胞的diff erentiated成成熟破骨细胞(第3阶段)。与其他技术相比,我们的协议不需要共培养系统。诱导EBs分化为中胚层 均匀的方式; 使用较少的细胞因子进行分化;只需要很短的时间就可以使破骨细胞成熟,并产生足够数量的破骨细胞用于后续的分子分析。
图形摘要: ...
|
|
|
| In vitro Time-lapse Imaging of Primary Cilium in Migrating Neuroblasts
|
|
Author:
Date:
2020-11-20
[Abstract] Neuronal migration is a critical step for the development of neuronal circuits in the brain. Immature new neurons (neuroblasts) generated in the postnatal ventricular-subventricular zone (V-SVZ) show a remarkable potential to migrate for a long distance at a high speed in the postnatal mammalian brain, and are thus a powerful model to analyze the molecular and cellular mechanisms of neuronal migration. Here we describe a methodology for in vitro time-lapse imaging of the primary cilium and its related structures in migrating V-SVZ-derived neuroblasts using confocal or superresolution ...
[摘要] [摘要]神经元迁移是大脑中神经元回路发展的关键步骤。产后心室-脑室下区(V-SVZ)中产生的未成熟新神经元(神经母细胞)显示出巨大的潜力,可以在产后哺乳动物脑中高速长距离迁移,因此是分析分子和神经元的强大模型。神经元迁移的细胞机制。在这里,我们描述了一种使用共聚焦或超分辨率激光扫描显微镜对V-SVZ衍生的成神经细胞进行迁移的初级纤毛及其相关结构的体外延时成像方法。从出生后的第0-1天(P0-1)小鼠脑中解剖V-SVZ组织,并通过胰蛋白酶消化和温和的移液将其分离成单个细胞。然后用编码目的基因的质粒转导这些细胞,通过离心聚集,并在Matrigel中培养2天。通过共聚焦或超分辨率激光扫描显微镜获取培养的神经母细胞及其睫状结构(包括睫状膜和基体)迁移行为的时移图像。该方法提供了有关成神经细胞形态和睫状结构时空动态的信息,并且广泛适用于各种物种中各种类型的迁移神经元和非神经元细胞。
[背景]在出生后的大脑中,神经干细胞驻留在侧脑室侧壁内衬的心室-心室下区(V-SVZ)中,并不断生成未成熟的新神经元(神经母细胞)(Obernier和Alvarez-Buylla,2019)。这些成神经细胞形成链状细胞聚集体,并通过鼻尖迁移流(RMS)彼此迁移至嗅球(OB)(Luskin,1993; Lois and Alvarez-Buylla,1994; Lois et ...
|
|
|
| Isolation, Culture, and Differentiation of Primary Myoblasts Derived from Muscle Satellite Cells
|
|
Author:
Date:
2020-07-20
[Abstract] The skeletal muscle is key for body mobility and motor performance, but aging and diseases often lead to progressive loss of muscle mass due to wasting or degeneration of muscle cells. Muscle satellite cells (MuSCs) represent a population of tissue stem cells residing in the skeletal muscles and are responsible for homeostatic maintenance and regeneration of skeletal muscles. Growth, injury, and degenerative signals activate MuSCs, which then proliferate (proliferating MuSCs are called myoblasts), differentiate and fuse with existing multinuclear muscle cells (myofibers) to mediate muscle ...
[摘要] [摘要] 骨骼肌是身体活动和运动表现的关键,但是衰老和疾病通常会由于肌肉细胞的浪费或变性而导致肌肉质量的逐步丧失。肌卫星细胞(MuSCs)代表的组织STE群体米细胞小号居住在骨骼肌和负责骨骼肌的体内平衡维持和再生。生长,损伤和变性信号激活MuSC,然后增殖(增殖的MuSC被称为成肌细胞),分化并与现有的多核肌肉细胞(肌纤维)融合,以介导肌肉的生长和修复。在这里,我们描述了从小鼠骨骼肌中分离MuSC的体外实验方案分析。此外,我们提供了有关如何将原代成肌细胞培养和分化成肌管的详细协议,以及用于表征细胞的免疫荧光染色程序。这些方法对于在体外模拟再生肌生成以了解MuSC 的动力学,功能和分子调控至关重要。
[背景] 通过多种细胞功能维持肌肉的动态平衡,对于保持肌肉的完整性至关重要。组织特异性成体干细胞能够在整个生命中连续不断地再生局部组织。在成年骨骼肌中,称为肌肉卫星细胞(MuSC)的干细胞群具有强大的再生能力,这是肌肉动态平衡的关键(Yin 等人,2013; Dumont 等人,2016)。静态MuSC位于与肌肉纤维并列的基底层下方的壁iche中,负责肌肉的生长和再生(Yin 等人,2013; Dumont 等人,2016)。
...
|
|
|