人类间充质干细胞在严重免疫缺陷小鼠体内的移植。

Yuko Kato, Yusuke Ohno, Ryoji Ito, Takeshi Taketani, Yumi Matsuzaki, Satoru Miyagi
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引用次数: 0

摘要

移植人类间充质基质/干细胞(hMSCs)具有治疗先天性骨骼疾病的潜力。然而,间充质干细胞的自我更新和分化能力存在明显差异。因此,在将 hMSCs 用于临床之前,我们对其细胞增殖和三系分化能力进行了体外测试,以确定其特征。然而,目前仍不清楚 hMSCs 在体外的能力是否能准确预测其在活体动物体内的能力。异种移植模型是验证临床间充质干细胞的另一种方法。尽管如此,该方法仍需改进,而且临床使用的经培养扩增的 hMSCs 在移植环境中是否仍能保留其吞噬和分化成成脂、成骨和软骨系细胞的能力也有待确定。在本研究中,为了建立稳健的间充质干细胞异种移植模型,我们研究了 hMSCs 的输送途径和受体的免疫状态。将 hMSCs 经动脉内注射到经 X 射线照射(IR)的 NOG(一种严重免疫缺陷的小鼠)体内可获得最高的接种率,但无法维持长期接种。我们证实,移植物细胞定位在胶原酶释放部分(CR),内源性集落形成细胞就存在于该部分。我们还发现,存在于 CR 部分的 Pdgfrα+Sca1+ 间充质干细胞(PαS)可抵抗 IR。这些结果表明,我们的方案能使 hMSCs 在短期内实现在小鼠骨髓中的高水平移植。与此相反,由于内源性间充质干细胞对红外有抵抗力,长期重建至少部分受到了限制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Engraftment of human mesenchymal stem cells in a severely immunodeficient mouse.

The transplantation of human mesenchymal stromal/stem cells (hMSCs) has potential as a curative and permanent therapy for congenital skeletal diseases. However, the self-renewal and differentiation capacities of hMSCs markedly vary. Therefore, cell proliferation and trilineage differentiation capacities were tested in vitro to characterize hMSCs before their clinical use. However, it remains unclear whether the ability of hMSCs in vitro accurately predicts that in living animals. The xenograft model is an alternative method for validating clinical MSCs. Nevertheless, the protocol still needs refinement, and it has yet to be established whether hMSCs, which are expanded in culture for clinical use, retain the ability to engraft and differentiate into adipogenic, osteogenic, and chondrogenic lineage cells in transplantation settings. In the present study, to establish a robust xenograft model of MSCs, we examined the delivery routes of hMSCs and the immunological state of recipients. The intra-arterial injection of hMSCs into X-ray-irradiated (IR) NOG, a severely immunodeficient mouse, achieved the highest engraftment but failed to sustain long-term engraftment. We demonstrated that graft cells localized to a collagenase-released fraction (CR), in which endogenous colony-forming cells reside. We also showed that Pdgfrα+Sca1+ MSCs (PαS), which reside in the CR fraction, resisted IR. These results show that our protocol enables hMSCs to fulfill a high level of engraftment in mouse bone marrow in the short term. In contrast, long-term reconstitution was restricted, at least partially, because of IR-resistant endogenous MSCs.

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