摘要
Mechanical cues present in the stem cell niche resulting from intracellular processes or external force sources significantly affect the basic functions of stem cells such as self-renewal and differentiation.Creation of artificial cellular matrices exhibiting intrinsic mechanical cues generated by mechanical movements remains scarce.Herein,we reported on mechanically dynamic hydrogel matrices undergoing photo-induced directional domain sliding movement and their role in regulating embryonic stem cell(ESC)differentiation.The mechanically dynamic hydrogels were prepared via the self-assembly of an alternating hydrophilic and hydrophobic peptide with a photocaged cysteine residue.Upon light irradiation,the assemblies of the caged peptide were converted to non-equilibrated non-caged peptide bilayers that underwent the directional domain sliding motion induced by the thermodynamically favorable hydrophobic collapse transition.Culturing murine ESCs on the mechanically dynamic hydrogels resulted in biased differentiation toward the ectodermal lineage.We further showed that the mechanically dynamic hydrogels stimulated the translocation of a mechanotransduction protein Yes-associated protein(YAP)into the nucleus,implicating a potential mechanotransduction mechanism for the biased differentiation of ESCs.The finding of the biased ectodermal differentiation of ESCs induced by the mechanically dynamic hydrogels implies the great potency of the mechanically dynamic hydrogels as biomaterials for disease therapy and tissue regeneration in the future.
由细胞内行为或外源力引起的干细胞龛中存在的机械信号对干细胞的自我恢复和分化等基本功能具有重要影响.然而,关于具有分子机械运动产生的内在机械信号的人工细胞外基质鲜有报道.在此,我们报道了含光诱导片段定向滑动的机械动态水凝胶的合成及其作为人工细胞外基质在调节胚胎干细胞(ESC)分化中的功能.通过引入光笼蔽的半胱氨酸残基调控亲疏水交替多肽的自组装制备机械动态水凝胶.光笼蔽多肽组装体在光照射下转化为热力学非平衡的非笼蔽多肽双分子层,其进一步发生热力学有利的疏水性塌陷转变诱导的片段定向滑动.在机械动态水凝胶上培养鼠胚胎干细胞,该片段定向滑动诱导干细胞向外胚层谱系定向分化.进一步揭示了机械动态水凝胶促进机械转导蛋白YAP进入细胞核,表明其用于ESCs定向分化的潜在机械转导机制.细胞定向分化结果表明了机械动态水凝胶作为潜在的生物材料,有望用于疾病治疗和组织再生.
作者
Zhifei Cheng
Shanshan Nai
Shuxin Song
Lingyi Chen
Zhilin Yu
程志非;能姗姗;宋树鑫;陈凌懿;余志林(Key Laboratory of Functional Polymer Materials,Ministry of Education,State Key Laboratory of Medicinal Chemical Biology,Institute of Polymer Chemistry,College of Chemistry,Nankai University,Tianjin 300071,China;State Key Laboratory of Medicinal Chemical Biology,Tianjin Key Laboratory of Protein Sciences,National Demonstration Center for Experimental Biology Education and College of Life Sciences,Nankai University,Tianjin 300071,China)
基金
supported by the National Key R&D Program of China (2018YFC1313003)
the Fundamental Research Funds for the Central Universities
the National Natural Science Foundation of China (21774065 and 31622038)
the Natural Science Foundation of Tianjin (18JCQNJC14100 and 18JCJQJC48400)
