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骨髓来源的细胞在伤口愈合过程中有助于上皮细胞的植入。

Bone marrow-derived cells contribute to epithelial engraftment during wound healing.

作者信息

Borue Xenia, Lee Sean, Grove Joanna, Herzog Erica L, Harris Robert, Diflo Thomas, Glusac Earl, Hyman Kevin, Theise Neil D, Krause Diane S

机构信息

Department of Laboratory Medicine, Yale University School of Medicine, 333 Cedar Street, P.O. Box 208035, New Haven, CT 06520-8035, USA.

出版信息

Am J Pathol. 2004 Nov;165(5):1767-72. doi: 10.1016/S0002-9440(10)63431-1.

DOI:10.1016/S0002-9440(10)63431-1
PMID:15509544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1618655/
Abstract

Recent findings suggest that bone marrow-derived cells (BMDC) may contribute to tissue maintenance throughout the body. However, it is not yet known whether marrow-derived epithelial cells are capable of undergoing proliferation. Our laboratory has shown that BMDC engraft as keratinocytes in the skin at low levels (</= 1%) in the absence of injury. Here we show that skin damage affects the degree of engraftment of BMDC as keratinocytes and that the keratinocytes are actively cycling. Female mice reconstituted with sex-mismatched BM were wounded by punch biopsy and incision. At the wound site, engraftment of BMDC as epidermal cells increased within 1 day, and continued to increase to approximately 4% by 3 weeks after injury. Using a Cre-lox system, fusion of BMDC with epithelial cells was ruled out. BMDC-derived epithelial cells at the wound edges expressed Ki67, a marker for actively cycling cells, and this proliferation correlated with an increase in the number of donor-derived cells within the wound. Donor-derived cytokeratin 5-expressing cells were rare, suggesting that BMDC do not engraft as epidermal stem cells, and the level of engraftment peaked and then decreased over time, further suggesting that BMDC may assist in early wound healing by engrafting as transit-amplifying cells, which then differentiate into keratinocytes.

摘要

最近的研究结果表明,骨髓来源的细胞(BMDC)可能有助于维持全身组织。然而,骨髓来源的上皮细胞是否能够增殖尚不清楚。我们实验室已经表明,在没有损伤的情况下,BMDC以低水平(≤1%)作为角质形成细胞植入皮肤。在这里,我们表明皮肤损伤会影响BMDC作为角质形成细胞的植入程度,并且角质形成细胞处于活跃的细胞周期。用性别不匹配的骨髓重建的雌性小鼠通过打孔活检和切口进行创伤。在伤口部位,BMDC作为表皮细胞的植入在1天内增加,并在损伤后3周持续增加至约4%。使用Cre-lox系统排除了BMDC与上皮细胞的融合。伤口边缘的BMDC来源的上皮细胞表达Ki67,这是一种活跃细胞周期的标志物,这种增殖与伤口内供体来源细胞数量的增加相关。供体来源的表达细胞角蛋白5的细胞很少见,这表明BMDC不是作为表皮干细胞植入的,并且植入水平达到峰值后随时间下降,这进一步表明BMDC可能通过作为过渡增殖细胞植入来协助早期伤口愈合,然后这些细胞分化为角质形成细胞。

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