Hickey Kassondra N, Grassi Shannon M, Caplan Michael R, Stabenfeldt Sarah E
School of Biological and Health Systems Engineering, Arizona State University, PO Box 879709, Tempe, AZ 85287-9709 USA.
Phoenix Country Day School, Upper School Faculty, Paradise Valley, AZ USA.
Cell Mol Bioeng. 2020 Aug 7;14(1):75-87. doi: 10.1007/s12195-020-00643-y. eCollection 2021 Feb.
Stromal cell derived factor-1a (SDF-1a) and its receptor CXCR4 modulate stem cell recruitment to neural injury sites. SDF-1a gradients originating from injury sites contribute to chemotactic cellular recruitment. To capitalize on this injury-induced cell recruitment, further investigation of SDF-1a/CXCR4 signaling dynamics are warranted. Here, we studied how exogenous SDF-1a delivery strategies impact spatiotemporal SDF-1a levels and the role autocrine/paracrine signaling plays.
We first assessed total SDF-1a and CXCR4 levels over the course of 7 days following intracortical injection of either bolus SDF-1a or SDF-1a loaded nanoparticles in CXCR4-EGFP mice. We then investigated cellular contributors to SDF-1a autocrine/paracrine signaling time course measurements of SDF-1a and CXCR4 gene expression following exogenous SDF-1a application. Lastly, we created mathematical models that could recapitulate our observations.
, we found sustained total SDF-1a levels beyond 3 days post injection, indicating endogenous SDF-1a production. We confirmed that microglia, astrocytes, and brain endothelial cells significantly change SDF-1a and CXCR4 expression after exposure. We found that diffusion-only based mathematical models were unable to capture SDF-1a spatial distribution. Adding autocrine/paracrine mechanisms to the model allowed for SDF-1a temporal trends to be modeled accurately, indicating it plays an essential role in SDF-1a sustainment.
We conclude that autocrine/paracrine dynamics play a role in endogenous SDF-1a levels in the brain following exogenous delivery. Implementation of these dynamics are necessary to improving SDF-1a delivery strategies. Further, mathematical models introduced here may be utilized in predicting future outcomes based upon new biomaterial designs.
基质细胞衍生因子-1a(SDF-1a)及其受体CXCR4调节干细胞向神经损伤部位的募集。源自损伤部位的SDF-1a梯度有助于趋化性细胞募集。为了利用这种损伤诱导的细胞募集,有必要进一步研究SDF-1a/CXCR4信号动力学。在此,我们研究了外源性SDF-1a递送策略如何影响时空SDF-1a水平以及自分泌/旁分泌信号所起的作用。
我们首先在CXCR4-EGFP小鼠的皮质内注射大剂量SDF-1a或负载SDF-1a的纳米颗粒后,评估7天内的总SDF-1a和CXCR4水平。然后,我们在外源性应用SDF-1a后,通过测量SDF-1a和CXCR4基因表达的时间进程,研究了参与SDF-1a自分泌/旁分泌信号的细胞。最后,我们创建了能够概括我们观察结果的数学模型。
我们发现注射后3天以上总SDF-1a水平持续存在,表明内源性SDF-1a产生。我们证实,小胶质细胞、星形胶质细胞和脑内皮细胞在暴露后会显著改变SDF-1a和CXCR4的表达。我们发现仅基于扩散的数学模型无法捕捉SDF-1a的空间分布。在模型中加入自分泌/旁分泌机制可以准确模拟SDF-1a的时间趋势,表明其在SDF-1a维持中起重要作用。
我们得出结论,自分泌/旁分泌动力学在外源性递送后大脑内源性SDF-1a水平中起作用。实施这些动力学对于改进SDF-1a递送策略是必要的。此外,这里介绍的数学模型可用于基于新的生物材料设计预测未来结果。
