Centre for Experimental Medicine, School of Medicine, Dentistry, and Biomedical Science, Queen's University Belfast, Belfast, United Kingdom.
Regenerative Medicine Institute (REMEDI), National Centre for Biomedical Engineering Science.
Stem Cells. 2018 Jun;36(6):834-843. doi: 10.1002/stem.2810. Epub 2018 Mar 9.
Myeloid angiogenic cells (MACs) promote revascularization through the paracrine release of angiogenic factors and have been harnessed as therapeutic cells for many ischemic diseases. However, their proangiogenic properties have been suggested to be diminished in diabetes. This study investigates how the diabetic milieu affects the immunophenotype and function of MACs. Both MACs isolated from diabetic conditions and healthy cells exposed to a diabetic environment were used to determine the potential of MACs as a cell therapy for diabetic-related ischemia. MACs were isolated from human peripheral blood and characterized alongside proinflammatory macrophages M (LPS + IFNγ) and proangiogenic macrophages M (IL4). Functional changes in MACs in response to high-d-glucose were assessed using an in vitro 3D-tubulogenesis assay. Phenotypic changes were determined by gene and protein expression analysis. Additionally, MACs from type 1 diabetic (T1D) patients and corresponding controls were isolated and characterized. Our evidence demonstrates MACs identity as a distinct macrophage subtype that shares M2 proangiogenic characteristics, but can be distinguished by CD163 expression. High-d-glucose treatment significantly reduced MACs proangiogenic capacity, which was associated with a significant increase in IL1β mRNA and protein expression. Inhibition of IL1β abrogated the antiangiogenic effect induced by high-d-glucose. IL1β was also significantly upregulated in MACs isolated from T1D patients with microvascular complications compared to T1D patients without microvascular complications or nondiabetic volunteers. This study demonstrates that Type 1 diabetes and diabetic-like conditions impair the proangiogenic and regenerative capacity of MACs, and this response is mediated by IL-1β. Stem Cells 2018;36:834-843.
骨髓源性血管生成细胞 (MACs) 通过旁分泌释放血管生成因子促进血管新生,并已被用作多种缺血性疾病的治疗细胞。然而,有人提出糖尿病会降低其促血管生成特性。本研究探讨了糖尿病微环境如何影响 MACs 的免疫表型和功能。通过比较从糖尿病条件下分离的 MACs 和暴露于糖尿病环境的健康细胞,确定了 MACs 作为治疗糖尿病相关缺血的细胞疗法的潜力。MACs 从人外周血中分离出来,并与促炎巨噬细胞 M(LPS+IFNγ)和促血管生成巨噬细胞 M(IL4)一起进行了特征描述。使用体外 3D 管状发生测定法评估了高葡萄糖对 MACs 功能的影响。通过基因和蛋白质表达分析确定了 MACs 表型的变化。此外,还分离并表征了 1 型糖尿病 (T1D) 患者和相应对照者的 MACs。我们的证据表明,MACs 是一种独特的巨噬细胞亚型,具有 M2 促血管生成特征,但可以通过 CD163 表达来区分。高葡萄糖处理显著降低了 MACs 的促血管生成能力,这与 IL1β mRNA 和蛋白表达的显著增加有关。IL1β 抑制剂阻断了高葡萄糖诱导的抗血管生成作用。与没有微血管并发症或非糖尿病志愿者的 T1D 患者相比,患有微血管并发症的 T1D 患者的 MACs 中 IL1β 的表达也显著上调。本研究表明,1 型糖尿病和类似糖尿病的条件会损害 MACs 的促血管生成和再生能力,而这种反应是由 IL-1β 介导的。Stem Cells 2018;36:834-843.
