Hacettepe University, Graduate School of Health Sciences, Department of Stem Cell Sciences, Ankara, Turkey; Hacettepe University, Center for Stem Cell Research and Development, Ankara, Turkey.
Hacettepe University, Center for Stem Cell Research and Development, Ankara, Turkey; Hemosoft IT and Training Services, Hacettepe Teknokent, Ankara, Turkey.
Cytokine. 2021 Mar;139:155407. doi: 10.1016/j.cyto.2020.155407. Epub 2020 Dec 28.
Although G-CSF mobilized peripheral blood stem cell (PBSC) transplantation is commonly used in adults, bone marrow (BM) is still the preferred stem cell source in pediatric stem cell transplantation. Despite the fact that G-CSF is increasingly being used to enhance the hematopoietic stem/progenitor cell (HSPC) yield in BM transplantation (G-BM), the direct effects of G-CSF on the pediatric BM microenvironment have never been investigated. The BM hematopoietic niche provides the physical space where the HSPCs reside. This BM niche regulates HSPC quiescence and proliferation through direct interactions with other niche cells, including Mesenchymal Stromal Cells (MSCs). These cells have been shown to secrete a wide range of hematopoietic cytokines (CKs) and growth factors (GFs) involved in differentiation, retention and homing of hematopoietic cells. Here, we assessed changes in the BM microenvironment by measuring levels of 48 different CKs and GFs in G-BM and control BM (C-BM) plasma from pediatric donors. In addition, the effect of G-CSF on cell numbers and characteristics of HSPCs and MSCs was assessed. IL-16, SCGF-b, MIP-1b (all >1000 pg/mL) and RANTES (>10.000 pg/mL) were highly expressed in healthy donor pediatric BM plasma. Levels of IL-3, IL-18, GROa, MCP-3 (p<0.05) were increased in G-BM, whereas levels of RANTES (p<0.001) decreased after G-CSF treatment. We found a negative correlation with increasing age for IL2-Ra and LIF (p<0.05). In addition, a concomitant increase in the number of both hematopoietic and fibroblast colony forming units was observed, indicating that G-CSF affects both HSPC and MSC numbers. In conclusion, G-CSF treatment of healthy pediatric donors affects the hematopoietic BM microenvironment by expansion of HSPC and MSC numbers and modifying local CK and GF levels.
虽然粒细胞集落刺激因子(G-CSF)动员外周血造血干细胞(PBSC)移植在成人中被广泛应用,但骨髓(BM)仍然是儿科干细胞移植中首选的干细胞来源。尽管 G-CSF 越来越多地被用于提高骨髓移植(G-BM)中的造血干细胞/祖细胞(HSPC)产量,但 G-CSF 对儿科 BM 微环境的直接影响从未被研究过。BM 造血龛位为 HSPC 提供了栖息的物理空间。这个 BM 龛位通过与其他龛位细胞(包括间充质基质细胞(MSCs))的直接相互作用,调节 HSPC 的静止和增殖。这些细胞已被证明分泌广泛的造血细胞因子(CKs)和生长因子(GFs),参与造血细胞的分化、保留和归巢。在这里,我们通过测量儿科供体 G-BM 和对照 BM(C-BM)血浆中的 48 种不同 CK 和 GFs 的水平来评估 BM 微环境的变化。此外,还评估了 G-CSF 对 HSPCs 和 MSCs 数量和特征的影响。白细胞介素-16(IL-16)、干细胞生长因子-β(SCGF-b)、巨噬细胞炎性蛋白-1b(MIP-1b)(均>1000pg/mL)和 RANTES(>10.000pg/mL)在健康供体儿科 BM 血浆中高表达。G-BM 中白细胞介素-3(IL-3)、白细胞介素-18(IL-18)、GROa、单核细胞趋化蛋白-3(MCP-3)的水平升高(p<0.05),而 G-CSF 治疗后 RANTES 的水平降低(p<0.001)。我们发现,随着年龄的增长,白细胞介素 2 受体-α(IL2-Ra)和白血病抑制因子(LIF)的水平呈负相关(p<0.05)。此外,还观察到造血和成纤维细胞集落形成单位的数量同时增加,这表明 G-CSF 影响 HSPC 和 MSC 的数量。总之,G-CSF 治疗健康儿科供体通过增加 HSPC 和 MSC 的数量并改变局部 CK 和 GF 水平来影响造血 BM 微环境。
