Kent Olivia, Casey Eleanor R, Brown Max, Bell Steven, Ehrman Matthew C, Flagler Michael J, Määttä Arto, Benham Adam M, Hawkins Timothy J
Department of Biosciences, Durham University, South Road, Durham, DH1 3LE, UK.
The Procter & Gamble Company, Newcastle Innovation Centre, Newcastle-Upon-Tyne, NE12 9TS, UK.
Sci Rep. 2025 Apr 21;15(1):13764. doi: 10.1038/s41598-025-96280-4.
Although light microscopy has been used to examine the early trafficking of collagen within the cell, much of our understanding of the detailed organisation of cell deposited collagen is from static electron microscopy studies. To understand the dynamics of live cell collagen deposition and fibril organisation, we generated a bright photostable mNGCol1α2 fusion protein and employed a range of microscopy techniques to follow its intracellular transport and elucidate extracellular fibril formation. Our findings reveal the dynamics of fibril growth and the dynamic nature of collagen network interactions at the cellular level. Notably we observed molecular events that build network organisation, including fibril bundling, bifurcation, directionality along existing fibrils, and looping/intertwining behaviours. Strikingly, mNGCol1α2 fluorescence intensity maxima can mark a fibril before another growing collagen fibril intersects at this location. Real-time, high-resolution imaging of collagen has enabled fibrillogenesis and organisational dynamics to be visualised together in an actively secreting cellular system. We also show that the N-terminal protease site is not an absolute requirement for collagen fibril incorporation. This approach paves the way for assessing the dynamic organisation and assembly of collagen into the extracellular matrix in skin models and other tissues during health, ageing and disease.
尽管光学显微镜已被用于研究胶原蛋白在细胞内的早期运输,但我们对细胞沉积胶原蛋白详细组织结构的了解大多来自静态电子显微镜研究。为了了解活细胞胶原蛋白沉积和纤维组织的动态过程,我们生成了一种明亮的光稳定mNGCol1α2融合蛋白,并采用了一系列显微镜技术来追踪其细胞内运输过程,并阐明细胞外纤维的形成。我们的研究结果揭示了纤维生长的动态过程以及细胞水平上胶原蛋白网络相互作用的动态性质。值得注意的是,我们观察到了构建网络组织的分子事件,包括纤维束集、分叉、沿现有纤维的方向性以及环化/缠绕行为。令人惊讶的是,在另一条正在生长的胶原蛋白纤维在此位置相交之前,mNGCol1α2荧光强度最大值可以标记一条纤维。胶原蛋白的实时、高分辨率成像使得在一个活跃分泌的细胞系统中能够同时观察到纤维形成和组织动态过程。我们还表明,N端蛋白酶位点并非胶原蛋白纤维掺入的绝对必要条件。这种方法为评估健康、衰老和疾病过程中皮肤模型及其他组织中胶原蛋白向细胞外基质的动态组织和组装铺平了道路。