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一个 RAW264.7 细胞的亚克隆通过增加 NFATc1 的从头表达和核易位形成破骨样细胞,能够比亲本 RAW264.7 更快地进行骨吸收。

A Sub-Clone of RAW264.7-Cells Form Osteoclast-Like Cells Capable of Bone Resorption Faster than Parental RAW264.7 through Increased De Novo Expression and Nuclear Translocation of NFATc1.

机构信息

Department of Laboratory Medicine, Division of Pathology, Karolinska Institutet, Alfred Nobels Allé, 8, SE-141 52 Stockholm, Sweden.

Musculoskeletal Group, Institute of Medical Sciences, University of Aberdeen, Aberdeen AB 252ZD, UK.

出版信息

Int J Mol Sci. 2020 Jan 14;21(2):538. doi: 10.3390/ijms21020538.

DOI:10.3390/ijms21020538
PMID:31947698
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7013577/
Abstract

The murine macrophage cell line RAW264.7 is extensively used as a progenitor to study osteoclast (OC) differentiation. RAW264.7 is a heterogeneous cell line, containing sub-clones with different abilities to form OCs. The aim of this study was to identify characteristics within the heterogeneous RAW264.7 cells that define sub-clones with an augmented ability to form bone-resorbing OCs (H9), as well as sub-clones representing non-OCs (J8). RAW264.7 sub-clones were isolated by single cell cloning. Selection was based on TRAP/cathepsin K expression in sub-clone cultures without added RANKL. Sub-clones before and after differentiation with RANKL were assayed for multiple OC-characteristics. Sub-clone H9 cells presented a higher expression of OC-markers in cultures without added RANKL compared to the parental RAW264.7. After 6 days of RANKL stimulation, sub-clone H9 cells had equal expression levels of OC-markers with RAW264.7 and formed OCs able to demineralize hydroxyapatite. However, sub-clone H9 cells displayed rapid differentiation of OC already at Day 2 compared to Day 4 from parental RAW264.7, and when cultured on plastic and on bone they were more efficient in resorption. This rapid differentiation was likely due to high initial expression/nuclear translocation of OC master transcription factor, NFATc1. In contrast to H9, J8 cells expressed initially very low levels of OC-markers, and they did not respond to RANKL-stimulation by developing OC-characteristics/OC-marker expression. Hence, H9 is an additional clone suitable for experimental setup requiring rapid differentiation of large numbers of OCs.

摘要

鼠源巨噬细胞 RAW264.7 细胞系被广泛用作研究破骨细胞 (OC) 分化的前体细胞。RAW264.7 是一个异质细胞系,包含具有不同形成 OC 能力的亚克隆。本研究的目的是确定异质 RAW264.7 细胞中的特征,这些特征定义了具有增强形成破骨细胞能力的亚克隆 (H9),以及代表非 OC 的亚克隆 (J8)。通过单细胞克隆分离 RAW264.7 亚克隆。选择基于在没有添加 RANKL 的亚克隆培养物中 TRAP/组织蛋白酶 K 的表达。在用 RANKL 分化前后,对亚克隆进行了多种 OC 特征的检测。与亲本 RAW264.7 相比,未经添加 RANKL 的培养物中 H9 亚克隆细胞的 OC 标志物表达更高。在用 RANKL 刺激 6 天后,H9 亚克隆细胞的 OC 标志物表达水平与 RAW264.7 相当,并形成能够脱矿羟基磷灰石的 OC。然而,与亲本 RAW264.7 相比,H9 亚克隆细胞在第 2 天就已经开始快速分化为 OC,而在第 4 天才开始分化,并且当在塑料和骨上培养时,其吸收能力更强。这种快速分化可能是由于 OC 主转录因子 NFATc1 的初始高表达/核易位。与 H9 相反,J8 细胞最初表达的 OC 标志物水平非常低,并且它们不会通过发展 OC 特征/OC 标志物表达对 RANKL 刺激做出反应。因此,H9 是一种适合需要快速分化大量 OC 的实验设置的额外克隆。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5ef7/7013577/44e1192b5714/ijms-21-00538-g006.jpg
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