WPI Nano Life Science Institute (WPI-Nano LSI), Kanazawa University, Kakuma-machi, Kanazawa 920-1192, Japan.
Nanoscale. 2021 Apr 7;13(13):6661-6677. doi: 10.1039/d0nr09178b. Epub 2021 Mar 29.
Exosomes have recently gained interest as mediators of cell-to-cell communication and as potential biomarkers for cancer and other diseases. They also have potential as nanocarriers for drug delivery systems. Therefore, detailed structural, molecular, and biomechanical characterization of exosomes is of great importance for developing methods to detect and identify the changes associated with the presence of cancer and other diseases. Here, we employed three-dimensional atomic force microscopy (3D-AFM) to reveal the structural and nanomechanical properties of exosomes at high spatial resolution in physiologically relevant conditions. The substructural details of exosomes released from three different cell types were determined based on 3D-AFM force mapping. The resulting analysis revealed the presence of distinct local domains bulging out from the exosome surfaces, which were associated with the exosomal membrane proteins present on the outer surface. The nanomechanical properties of individual exosomes were determined from the 3D-force maps. We found a considerably high elastic modulus, ranging from 50 to 350 MPa, as compared to that obtained for synthetic liposomes. Moreover, malignancy-dependent changes in the exosome mechanical properties were revealed by comparing metastatic and nonmetastatic tumor cell-derived exosomes. We found a clear difference in their Young's modulus values, suggesting differences in their protein profiles and other exosomal contents. Exosomes derived from a highly aggressive and metastatic k-ras-activated human osteosarcoma (OS) cell line (143B) showed a higher Young's modulus than that derived from a nonaggressive and nonmetastatic k-ras-wildtype human OS cell line (HOS). The increased elastic modulus of the 143B cell-derived exosomes was ascribed to the presence of abundant specific proteins responsible for elastic fiber formation as determined by mass spectroscopy and confirmed by western blotting and ELISA. Therefore, we conclude that exosomes derived from metastatic tumor cells carry an exclusive protein content that differs from their nonmetastatic counterparts, and thus they exhibit different mechanical characteristics. Discrimination between metastatic and nonmetastatic malignant cell-derived exosomes would be of great importance for studying exosome biological functions and using them as diagnostic biomarkers for various tumor types. Our findings further suggest that metastatic tumor cells release exosomes that express increased levels of elastic fiber-associated proteins to preserve their softness.
外泌体作为细胞间通讯的介质和癌症及其他疾病的潜在生物标志物,最近引起了人们的兴趣。它们也有可能作为药物传递系统的纳米载体。因此,详细的结构、分子和生物力学特征对于开发检测和识别与癌症和其他疾病存在相关变化的方法非常重要。在这里,我们采用三维原子力显微镜(3D-AFM)在生理相关条件下以高空间分辨率揭示外泌体的结构和纳机械特性。基于 3D-AFM 力映射确定了来自三种不同细胞类型的外泌体的亚结构细节。分析结果表明,外泌体表面存在明显的局部凸起区域,与外泌体表面存在的膜蛋白有关。通过 3D-力图谱确定了单个外泌体的纳米力学特性。我们发现,与合成脂质体相比,外泌体的弹性模量相当高,范围从 50 到 350MPa。此外,通过比较转移性和非转移性肿瘤细胞衍生的外泌体,揭示了外泌体机械特性与恶性肿瘤的依赖性变化。我们发现它们的杨氏模量值有明显差异,这表明它们的蛋白质谱和其他外泌体内容存在差异。源自高度侵袭性和转移性 k-ras 激活的人骨肉瘤(OS)细胞系(143B)的外泌体比源自非侵袭性和非转移性 k-ras 野生型人 OS 细胞系(HOS)的外泌体表现出更高的杨氏模量。143B 细胞衍生的外泌体弹性模量的增加归因于大量特定的弹性纤维形成蛋白的存在,这是通过质谱确定的,并通过 Western 印迹和 ELISA 进行了确认。因此,我们得出结论,源自转移性肿瘤细胞的外泌体携带独特的蛋白质含量,与非转移性肿瘤细胞不同,因此它们表现出不同的机械特性。区分转移性和非转移性恶性细胞衍生的外泌体对于研究外泌体的生物学功能以及将其用作各种肿瘤类型的诊断生物标志物非常重要。我们的研究结果进一步表明,转移性肿瘤细胞释放表达高水平弹性纤维相关蛋白的外泌体,以保持其柔软度。
