Beijing Key Laboratory of Molecular Pharmaceutics and New Drug Delivery Systems, School of Pharmaceutical Sciences, Peking University, Beijing, 100191, China.
State Key Laboratory of Natural and Biomimetic Drugs, School of Pharmaceutical Sciences, Peking University, Beijing 100191, China.
Nanoscale Horiz. 2022 Jun 27;7(7):779-789. doi: 10.1039/d2nh00067a.
Nano-tumor interactions are fundamental for cancer nanotherapy, and the cross-talk of nanomedicines with the extracellular matrix (ECM) is increasingly considered essential. Here, we specifically investigate the nano-ECM interactivity using drug-free nanoparticulates (NPs) and highly metastatic cancer cells as models. We discover with surprise that NPs closely bind to specific types of ECM components, namely, retraction fibers (RFs) and migrasomes, which are located at the rear of tumor cells during their migration. This interaction is observed to alter cell morphology, limit cell motion range and change cell adhesion. Importantly, NPs are demonstrated to inhibit tumor cell removal , and their anti-metastasis potential is preliminarily confirmed . Mechanically, the NPs are found to coat and form a rigid shell on the surface of migrasomes and retraction fibers interaction with lipid raft/caveolae substructures. In this way, NPs block the recognition, endocytosis and elimination of migrasomes by their surrounding tumor cells. Thereby, NPs interfere with the cell-ECM interaction and reduce the promotion effect of migrasomes on cell movement. Additionally, NPs trigger alteration of the expression of proteins related to cell-cell adhesion and cytoskeleton organization, which also restricts cell migration. In summary, all the findings here provide a potential target for anti-tumor metastasis nanomedicines.
纳米-肿瘤相互作用是癌症纳米治疗的基础,纳米药物与细胞外基质(ECM)的串扰越来越被认为是必不可少的。在这里,我们使用无药物纳米颗粒(NPs)和高转移性癌细胞作为模型,专门研究纳米-ECM 的相互作用。我们惊讶地发现, NPs 与特定类型的 ECM 成分(即收缩纤维(RFs)和迁移体)紧密结合,这些成分位于肿瘤细胞迁移过程中的后部。这种相互作用被观察到改变细胞形态,限制细胞运动范围并改变细胞黏附。重要的是,NPs 被证明可以抑制肿瘤细胞的去除,并且其抗转移潜力得到初步证实。从机械上讲,发现 NPs 在迁移体和收缩纤维表面涂覆并形成刚性壳,与脂筏/ caveolae 亚结构相互作用。通过这种方式,NPs 阻止了迁移体被周围肿瘤细胞的识别、内吞和消除。因此,NPs 干扰了细胞-ECM 相互作用,并降低了迁移体对细胞运动的促进作用。此外,NPs 触发与细胞间黏附和细胞骨架组织相关的蛋白表达的改变,这也限制了细胞迁移。总之,这里的所有发现为抗肿瘤转移纳米药物提供了一个潜在的靶点。
