活体三次谐波显微镜观察黑色素瘤细胞侵袭:界面引导和微泡动力学原理。

IntraVital Pub Date : 2012-07-01 eCollection Date: 2012-01-01 DOI:10.4161/intv.21223
Bettina Weigelin, Gert-Jan Bakker, Peter Friedl
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引用次数: 284

摘要

癌细胞的侵袭是基于细胞自身的特性进行个体或集体迁移,并对所遇到的组织结构进行适应,起到屏障或引导作用的适应性过程。尽管癌症侵袭的分子和物理机制在体外3D模型中得到了很好的研究,但它们在体内与间质组织的地形相关性、分类和验证仍然不完整。利用活体肿瘤的活体三次谐波和二次谐波合成(THG, SHG)和三通道荧光显微镜,我们绘制了B16F10黑色素瘤侵入真皮的图谱,穿透深度可达600µm,并重建了入侵模式和组织轨迹,以建立入侵途径和结果。B16F10细胞优先沿着复杂的多界面地形预先形成的轨迹发展适应性入侵模式,结合单细胞和集体迁移模式,不会立即对解剖组织进行重塑或破坏。这些数据表明,组织界面的维数(1D, 2D, 3D)决定了肿瘤细胞入侵的微观解剖结构,强调沿微通道耦合接触引导的非破坏性迁移是关键的入侵机制。THG成像进一步以亚微米分辨率检测肿瘤相关微颗粒的存在和间质动力学,揭示肿瘤施加的微环境条件。这些地形研究结果建立了THG、SHG和荧光显微镜在活体肿瘤生物学中的联合应用,并为合理的体外模型开发和依赖于环境的入侵模式和途径的分子分类提供了模板。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Intravital third harmonic generation microscopy of collective melanoma cell invasion: Principles of interface guidance and microvesicle dynamics.

Cancer cell invasion is an adaptive process based on cell-intrinsic properties to migrate individually or collectively, and their adaptation to encountered tissue structure acting as barrier or providing guidance. Whereas molecular and physical mechanisms of cancer invasion are well-studied in 3D in vitro models, their topographic relevance, classification and validation toward interstitial tissue organization in vivo remain incomplete. Using combined intravital third and second harmonic generation (THG, SHG), and three-channel fluorescence microscopy in live tumors, we here map B16F10 melanoma invasion into the dermis with up to 600 µm penetration depth and reconstruct both invasion mode and tissue tracks to establish invasion routes and outcome. B16F10 cells preferentially develop adaptive invasion patterns along preformed tracks of complex, multi-interface topography, combining single-cell and collective migration modes, without immediate anatomic tissue remodeling or destruction. The data suggest that the dimensionality (1D, 2D, 3D) of tissue interfaces determines the microanatomy exploited by invading tumor cells, emphasizing non-destructive migration along microchannels coupled to contact guidance as key invasion mechanisms. THG imaging further detected the presence and interstitial dynamics of tumor-associated microparticles with submicron resolution, revealing tumor-imposed conditioning of the microenvironment. These topographic findings establish combined THG, SHG and fluorescence microscopy in intravital tumor biology and provide a template for rational in vitro model development and context-dependent molecular classification of invasion modes and routes.

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