Lingard Eliana, Dong Siyuan, Hoyle Anna, Appleton Ellen, Hales Alis, Skaria Eldhose, Lawless Craig, Taylor-Hearn Isobel, Saadati Simon, Chu Qixun, Miller Aline F, Domingos Marco, Saiani Alberto, Swift Joe, Gilmore Andrew P
Wellcome Centre for Cell-Matrix Research, Oxford Road, Manchester M13 9PT, UK; Division of Cancer Sciences, School of Medical Sciences, Faculty of Biology, Medicine and Health, Manchester Academic Health Science Centre, University of Manchester, Manchester, M13 9PL, UK.
School of Materials, Faculty of Science and Engineering, The University of Manchester, Oxford Road, Manchester, UK.
Biomater Adv. 2024 Jun;160:213847. doi: 10.1016/j.bioadv.2024.213847. Epub 2024 Mar 28.
Three-dimensional (3D) organoid models have been instrumental in understanding molecular mechanisms responsible for many cellular processes and diseases. However, established organic biomaterial scaffolds used for 3D hydrogel cultures, such as Matrigel, are biochemically complex and display significant batch variability, limiting reproducibility in experiments. Recently, there has been significant progress in the development of synthetic hydrogels for in vitro cell culture that are reproducible, mechanically tuneable, and biocompatible. Self-assembling peptide hydrogels (SAPHs) are synthetic biomaterials that can be engineered to be compatible with 3D cell culture. Here we investigate the ability of PeptiGel® SAPHs to model the mammary epithelial cell (MEC) microenvironment in vitro. The positively charged PeptiGel®Alpha4 supported MEC viability, but did not promote formation of polarised acini. Modifying the stiffness of PeptiGel® Alpha4 stimulated changes in MEC viability and changes in protein expression associated with altered MEC function, but did not fully recapitulate the morphologies of MECs grown in Matrigel. To supply the appropriate biochemical signals for MEC organoids, we supplemented PeptiGels® with laminin. Laminin was found to require negatively charged PeptiGel® Alpha7 for functionality, but was then able to provide appropriate signals for correct MEC polarisation and expression of characteristic proteins. Thus, optimisation of SAPH composition and mechanics allows tuning to support tissue-specific organoids.
三维(3D)类器官模型有助于理解许多细胞过程和疾病背后的分子机制。然而,用于3D水凝胶培养的成熟有机生物材料支架,如基质胶,在生化方面较为复杂,且批次间差异显著,限制了实验的可重复性。最近,用于体外细胞培养的合成水凝胶在开发方面取得了重大进展,这些水凝胶具有可重复性、机械可调性和生物相容性。自组装肽水凝胶(SAPHs)是一种合成生物材料,可设计成与3D细胞培养兼容。在此,我们研究了PeptiGel® SAPHs在体外模拟乳腺上皮细胞(MEC)微环境的能力。带正电荷的PeptiGel®Alpha4支持MEC的活力,但不促进极化腺泡的形成。改变PeptiGel® Alpha4的硬度会刺激MEC活力的变化以及与MEC功能改变相关的蛋白质表达变化,但不能完全重现基质胶中生长的MEC的形态。为了为MEC类器官提供适当的生化信号,我们在PeptiGels®中添加了层粘连蛋白。发现层粘连蛋白需要带负电荷的PeptiGel® Alpha7才能发挥功能,但随后能够为正确的MEC极化和特征性蛋白质的表达提供适当的信号。因此,优化SAPH的组成和力学性能可进行调整以支持组织特异性类器官。
