三维培养中纤连蛋白分离的瓣膜间质细胞亚群的功能特性
Functional characterization of fibronectin-separated valve interstitial cell subpopulations in three-dimensional culture.
作者信息
Stephens Elizabeth H, Carroll Joshua L, Post Allison D, Kuo Joyce J, Grande-Allen K Jane
机构信息
Department of Bioengineering, Rice University, Houston, Texas 77251-1892, USA.
出版信息
J Heart Valve Dis. 2010 Nov;19(6):759-65.
BACKGROUND AND AIM OF THE STUDY
Myxomatous mitral valves (MVs) contain elevated proportions of myofibroblasts, a valve interstitial cell (VIC) subpopulation that may be important in disease pathogenesis. A novel technique was recently developed for the isolation of VIC myofibroblasts using time-dependent adhesion to fibronectin (FN). Cells that adhere rapidly to FN ('FAST') demonstrate myofibroblast cell phenotype markers, in contrast to cells that fail to adhere after a longer time ('SLOW'). The study aim was to characterize the functionality of these subpopulations using three-dimensional (3D) collagen constructs.
METHODS
The VICs were harvested from porcine mitral valve posterior leaflets. FAST and SLOW subpopulations, as well as unseparated VIC populations grown on FN and tissue culture plastic (TCP) (UNSEP FN, UNSEP TCP), were seeded within 3D collagen gels and cultured for three weeks. Collagen gel contraction was assessed throughout the culture duration; the mechanical properties of the resultant collagen constructs were assessed using uniaxial tensile testing.
RESULTS
FAST cells demonstrated a greater contraction of collagen gels compared to SLOW cells, particularly after 10 days (p < 0.05). Interestingly, the collagen gel contraction by both FN-separated VIC subpopulations (FAST and SLOW) was greater than for gels seeded with UNSEP TCP VICs (p < 0.05). Further, the contraction of UNSEP FN gels was greater than UNSEP TCP throughout the culture duration (p < OR = 0.002), suggesting that the subculture of VICs on FN potentiated these phenotypic changes. Finally, the collagen constructs seeded with FAST cells were stiffer than those seeded with SLOW, followed by UNSEP TCP (p < 0.001). The same pattern was found for failure stress (p = 0.006).
CONCLUSION
Time-dependent adhesion to FN produced a VIC subpopulation (FAST), the function of which in 3D culture was consistent with that of myofibroblasts; FN exposure alone also caused VICs to function similarly to myofibroblasts. This novel isolation method may prove valuable in future studies of myofibroblasts in valve disease.
研究背景与目的
黏液样二尖瓣(MV)中肌成纤维细胞比例升高,肌成纤维细胞作为瓣膜间质细胞(VIC)的一个亚群,可能在疾病发病机制中起重要作用。最近开发了一种新技术,利用对纤连蛋白(FN)的时间依赖性黏附来分离VIC肌成纤维细胞。与较长时间后仍未黏附的细胞(“慢黏附细胞”)相比,快速黏附于FN的细胞(“快黏附细胞”)表现出肌成纤维细胞表型标志物。本研究旨在使用三维(3D)胶原蛋白构建体来表征这些亚群的功能。
方法
从猪二尖瓣后叶中获取VIC。将快黏附细胞和慢黏附细胞亚群,以及在FN和组织培养塑料(TCP)上生长的未分离VIC群体(未分离FN组、未分离TCP组)接种到3D胶原蛋白凝胶中,并培养三周。在整个培养期间评估胶原蛋白凝胶的收缩情况;使用单轴拉伸试验评估所得胶原蛋白构建体的力学性能。
结果
与慢黏附细胞相比,快黏附细胞使胶原蛋白凝胶收缩更大,尤其是在10天后(p < 0.05)。有趣的是,两种经FN分离的VIC亚群(快黏附细胞和慢黏附细胞)引起的胶原蛋白凝胶收缩均大于接种未分离TCP VIC的凝胶(p < 0.05)。此外,在整个培养期间,未分离FN凝胶的收缩大于未分离TCP凝胶(p < 或 = 0.002),这表明VIC在FN上的传代培养增强了这些表型变化。最后,接种快黏附细胞的胶原蛋白构建体比接种慢黏附细胞的更硬,其次是未分离TCP组(p < 0.001)。在破坏应力方面也发现了相同的模式(p = 0.006)。
结论
对FN的时间依赖性黏附产生了一个VIC亚群(快黏附细胞),其在3D培养中的功能与肌成纤维细胞一致;单独暴露于FN也使VIC的功能类似于肌成纤维细胞。这种新的分离方法可能在未来瓣膜疾病中肌成纤维细胞的研究中具有重要价值。
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