Mousumi Akter, Hossein Moghimianavval, Gary D Luker, Allen P Liu
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引用次数: 0
摘要
合成细胞具有模块化设计和模拟生物传感、细胞间通信和新陈代谢等细胞过程的能力,为应对生物医学和环境挑战提供了一个多功能平台。构建具有刺激响应分泌能力的合成细胞对于靶向给药和生物传感器开发中的应用至关重要。以前对合成细胞分泌工程的尝试仅限于通过膜孔释放非特异性货物,从而限制了选择性分泌所需的时空精确性和特异性。在这里,我们设计并构建了一个基于蛋白质的平台,称为 TEV 蛋白酶介导的可释放肌动蛋白结合蛋白(TRAP),用于在合成细胞中进行选择性、快速和可触发的分泌。TRAP 可与重组肌动蛋白网络紧密结合,并通过蛋白水解从结合的肌动蛋白中释放出来,然后通过细胞穿透肽膜转运进行分泌。我们证明了 TRAP 在促进荧光蛋白和发光蛋白的光激活分泌方面的功效。通过为合成细胞配备可控分泌机制,TRAP 为开发刺激响应型生物材料、基于合成细胞的多功能生物传感系统,以及通过将合成细胞与活细胞整合以靶向输送蛋白质治疗药物的治疗应用铺平了道路。
Light-triggered protease-mediated release of actin-bound cargo from synthetic cells
Synthetic cells offer a versatile platform for addressing biomedical and environmental challenges, due to their modular design and capability to mimic cellular processes such as biosensing, intercellular communication, and metabolism. Constructing synthetic cells capable of stimuli-responsive secretion is vital for applications in targeted drug delivery and biosensor development. Previous attempts at engineering secretion for synthetic cells have been confined to non-specific cargo release via membrane pores, limiting the spatiotemporal precision and specificity necessary for selective secretion. Here, we designed and constructed a protein-based platform termed TEV Protease-mediated Releasable Actin-binding protein (TRAP) for selective, rapid, and triggerable secretion in synthetic cells. TRAP is designed to bind tightly to reconstituted actin networks and is proteolytically released from bound actin, followed by secretion via cell-penetrating peptide membrane translocation. We demonstrated TRAP's efficacy in facilitating light-activated secretion of both fluorescent and luminescent proteins. By equipping synthetic cells with a controlled secretion mechanism, TRAP paves the way for the development of stimuli-responsive biomaterials, versatile synthetic cell-based biosensing systems, and therapeutic applications through the integration of synthetic cells with living cells for targeted delivery of protein therapeutics.