Bioconjugation of COL1 protein on liquid-like solid surfaces to study tumor invasion dynamics.

IF 1.6 4区 医学 Q4 BIOPHYSICS Biointerphases Pub Date : 2023-03-10 DOI:10.1116/6.0002083
D T Nguyen, D I Pedro, A Pepe, J G Rosa, J I Bowman, L Trachsel, G R Golde, I Suzuki, J M Lavrador, N T Y Nguyen, M A Kis, R A Smolchek, N Diodati, R Liu, S R Phillpot, A R Webber, P Castillo, E J Sayour, B S Sumerlin, W G Sawyer
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Abstract

Tumor invasion is likely driven by the product of intrinsic and extrinsic stresses, reduced intercellular adhesion, and reciprocal interactions between the cancer cells and the extracellular matrix (ECM). The ECM is a dynamic material system that is continuously evolving with the tumor microenvironment. Although it is widely reported that cancer cells degrade the ECM to create paths for migration using membrane-bound and soluble enzymes, other nonenzymatic mechanisms of invasion are less studied and not clearly understood. To explore tumor invasion that is independent of enzymatic degradation, we have created an open three-dimensional (3D) microchannel network using a novel bioconjugated liquid-like solid (LLS) medium to mimic both the tortuosity and the permeability of a loose capillary-like network. The LLS is made from an ensemble of soft granular microgels, which provides an accessible platform to investigate the 3D invasion of glioblastoma (GBM) tumor spheroids using in situ scanning confocal microscopy. The surface conjugation of the LLS microgels with type 1 collagen (COL1-LLS) enables cell adhesion and migration. In this model, invasive fronts of the GBM microtumor protruded into the proximal interstitial space and may have locally reorganized the surrounding COL1-LLS. Characterization of the invasive paths revealed a super-diffusive behavior of these fronts. Numerical simulations suggest that the interstitial space guided tumor invasion by restricting available paths, and this physical restriction is responsible for the super-diffusive behavior. This study also presents evidence that cancer cells utilize anchorage-dependent migration to explore their surroundings, and geometrical cues guide 3D tumor invasion along the accessible paths independent of proteolytic ability.

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COL1蛋白在类液体固体表面的生物偶联以研究肿瘤侵袭动力学。
肿瘤侵袭可能是由内在和外在压力、细胞间粘附减少以及癌症细胞与细胞外基质(ECM)之间相互作用的产物驱动的。ECM是一个随着肿瘤微环境不断发展的动态物质系统。尽管广泛报道癌症细胞利用膜结合和可溶性酶降解ECM以创建迁移路径,但其他非酶侵袭机制的研究较少,也不清楚。为了探索独立于酶降解的肿瘤侵袭,我们使用一种新型生物偶联类液体固体(LLS)介质创建了一个开放的三维(3D)微通道网络,以模拟松散类毛细管网络的曲折性和渗透性。LLS由软颗粒微凝胶组成,为使用原位扫描共聚焦显微镜研究胶质母细胞瘤(GBM)肿瘤球体的3D侵袭提供了一个可访问的平台。LLS微凝胶与1型胶原(COL1-LLS)的表面结合能够实现细胞粘附和迁移。在该模型中,GBM微肿瘤的侵袭性前部突出到近端间质间隙,并可能局部重组了周围的COL1-LLS。侵入路径的特征揭示了这些锋面的超扩散行为。数值模拟表明,间质间隙通过限制可用路径来引导肿瘤侵袭,而这种物理限制是导致超扩散行为的原因。这项研究还提供了证据,证明癌症细胞利用凤尾鱼依赖性迁移来探索周围环境,几何线索引导3D肿瘤沿着独立于蛋白水解能力的可到达路径侵袭。
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来源期刊
Biointerphases
Biointerphases 生物-材料科学:生物材料
自引率
0.00%
发文量
35
期刊介绍: Biointerphases emphasizes quantitative characterization of biomaterials and biological interfaces. As an interdisciplinary journal, a strong foundation of chemistry, physics, biology, engineering, theory, and/or modelling is incorporated into originated articles, reviews, and opinionated essays. In addition to regular submissions, the journal regularly features In Focus sections, targeted on specific topics and edited by experts in the field. Biointerphases is an international journal with excellence in scientific peer-review. Biointerphases is indexed in PubMed and the Science Citation Index (Clarivate Analytics). Accepted papers appear online immediately after proof processing and are uploaded to key citation sources daily. The journal is based on a mixed subscription and open-access model: Typically, authors can publish without any page charges but if the authors wish to publish open access, they can do so for a modest fee. Topics include: bio-surface modification nano-bio interface protein-surface interactions cell-surface interactions in vivo and in vitro systems biofilms / biofouling biosensors / biodiagnostics bio on a chip coatings interface spectroscopy biotribology / biorheology molecular recognition ambient diagnostic methods interface modelling adhesion phenomena.
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