模拟微重力条件下的球状体形成及肌腱细胞特异性基因表达的调节
Spheroid formation and modulation of tenocyte-specific gene expression under simulated microgravity.
作者信息
Kraus Armin, Luetzenberg Ronald, Abuagela Nauras, Hollenberg Siri, Infanger Manfred
机构信息
Department of Plastic, Aesthetic and Hand Surgery, Otto-von-Guericke University, Magdeburg, Germany.
出版信息
Muscles Ligaments Tendons J. 2018 Jan 10;7(3):411-417. doi: 10.11138/mltj/2017.7.3.411. eCollection 2017 Jul-Sep.
BACKGROUND
For tendon tissue engineering, tenocyte-seeded scaffolds are a promising approach. Under conventional 2D culture however, tenocytes show rapid senescene and phenotype loss. We hypothesized that phenotype loss could be counteracted by simulated microgravity conditions.
METHODS
Human tenocytes were exposed to microgravity for 9 days on a Random Positioning Machine (RPM). Formation of 3D-structures (spheroids) was observed under light microscopy, gene expression was measured by real-time PCR. Cells under conventional 2D-culture served as control group.
RESULTS
Simulated microgravity reached a value of as low as 0.003g. Spheroid formation was observed after 4 days, and spheroids showed stable existance to the end of the observation period. After 9 days, spheroids showed a significantly higher gene expression of collagen 1 compared to adherent cells under microgravity (4.4x, p=0.04) and compared to the control group (5.6x, p=0.02). Gene expression of collagen 3 () was significantly increased in spheroids compared to the control group (2.3x, p=0.03). Gene expressions of the extracellular matrix genes und were increased in adherent cells under microgravity compared to the 1g-control group, not reaching statistical significance (p=0.1 and p=0.3). For the gene expression of vimentin, no significant alteration was observed both in the adherent cells and in the spheroids compared to the 1g control group. Gene expression of the tenocyte-specific transcription factor scleraxis () was significantly increased in spheroids compared to the control group (3.7x, p=0.03).
CONCLUSION
Simulated microgravity could counteract tenocyte senescence and serve as a promising model for scaffold-free 3D cell culturing and tissue engineering.
LEVEL OF EVIDENCE
V (laboratory study).
背景
对于肌腱组织工程而言,接种肌腱细胞的支架是一种很有前景的方法。然而,在传统的二维培养条件下,肌腱细胞会迅速衰老并丧失表型。我们推测模拟微重力条件可以抵消表型丧失。
方法
将人肌腱细胞在随机定位机(RPM)上暴露于微重力环境9天。在光学显微镜下观察三维结构(球体)的形成,通过实时PCR测量基因表达。将传统二维培养条件下的细胞作为对照组。
结果
模拟微重力达到了低至0.003g的值。4天后观察到球体形成,并且球体在观察期结束时保持稳定存在。9天后,与微重力条件下的贴壁细胞相比,球体中胶原蛋白1的基因表达显著更高(4.4倍,p = 0.04),与对照组相比(5.6倍,p = 0.02)。与对照组相比,球体中胶原蛋白3的基因表达显著增加(2.3倍,p = 0.03)。与1g对照组相比,微重力条件下贴壁细胞中细胞外基质基因和的基因表达增加,但未达到统计学显著性(p = 0.1和p = 0.3)。与1g对照组相比,在贴壁细胞和球体中波形蛋白的基因表达均未观察到显著变化。与对照组相比,球体中肌腱细胞特异性转录因子硬骨素的基因表达显著增加(3.7倍,p = 0.03)。
结论
模拟微重力可以抵消肌腱细胞衰老,并作为无支架三维细胞培养和组织工程的一种有前景的模型。
证据水平
V(实验室研究)。
Zotero 插件