Microchip construction for migration assays: investigating the impact of physical confinement on cell morphology and motility during vaccinia virus infection.

IF 3.8 2区 化学 Q1 BIOCHEMICAL RESEARCH METHODS
Analytical and Bioanalytical Chemistry Pub Date : 2024-11-01 Epub Date: 2024-08-19 DOI:10.1007/s00216-024-05485-5
Cheng Wang, Yueyue Huangfu, Ji Wang, Xiaofeng Lu, Dong Liu, Zhi-Ling Zhang
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引用次数: 0

Abstract

Vaccinia virus (VACV)-induced cell migration is thought to be closely related to the rapid transmission of viral infection in the body. The limited studies are mainly based on scratch assay using traditional cell culture techniques, which inevitably ignores the influences of extracellular microenvironment. Physical confinement, inherently presenting in vivo, has proven to be a critical extern cue in modulating migration behaviors of multiple cells, while its impacts on VACV-induced cell motility remain unclear. Herein, we developed a migration assay microchip featuring confined microchannel array to investigate the effect of physical confinement on infected cell morphology and motility during VACV infection. Results showed that different from the random cell migration observed in traditional scratch assay on planar substrate, VACV-infected cells exhibited accelerated directionally persistent migration under confinement microenvironment. Moreover, single-directed elongated dominant lamella appeared to contrast distinctly with multiple protrusions stretched in random directions under unconfined condition. Additionally, the Golgi complex tended to relocate behind the nucleus confined within the microchannel axis compared to the classical reorientation pattern. These differences in characteristic subcellular architecture and organelle reorientation of migrating cells revealed cell biological mechanisms underlying altered migration behavior. Collectively, our study demonstrates that physical confinement acting as a guidance cue has profound impacts on VACV-induced migration behaviors, which provides new insight into cell migration behavior and viral rapid spread during VACV infection.

Abstract Image

用于迁移试验的微芯片构建:研究疫苗病毒感染过程中物理限制对细胞形态和运动的影响。
疫苗病毒(VACV)诱导的细胞迁移被认为与病毒感染在体内的快速传播密切相关。有限的研究主要基于传统细胞培养技术的划痕试验,这不可避免地忽略了细胞外微环境的影响。体内固有的物理限制已被证明是调节多种细胞迁移行为的关键外部线索,但其对 VACV 诱导的细胞运动的影响仍不清楚。在此,我们开发了一种具有封闭微通道阵列的迁移检测芯片,以研究物理封闭对 VACV 感染过程中受感染细胞形态和运动的影响。结果表明,与传统的平面基底划痕实验中观察到的细胞随机迁移不同,VACV 感染细胞在封闭微环境下表现出加速的定向持续迁移。此外,在无限制条件下,单向伸长的优势薄片与随机方向伸展的多个突起形成鲜明对比。此外,与经典的重新定向模式相比,高尔基复合体倾向于重新定向到限制在微通道轴内的细胞核后面。迁移细胞特有的亚细胞结构和细胞器重新定向的这些差异揭示了迁移行为发生改变的细胞生物学机制。总之,我们的研究表明,物理限制作为一种引导线索对 VACV 诱导的迁移行为有深远影响,这为 VACV 感染过程中的细胞迁移行为和病毒快速传播提供了新的视角。
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来源期刊
CiteScore
8.00
自引率
4.70%
发文量
638
审稿时长
2.1 months
期刊介绍: Analytical and Bioanalytical Chemistry’s mission is the rapid publication of excellent and high-impact research articles on fundamental and applied topics of analytical and bioanalytical measurement science. Its scope is broad, and ranges from novel measurement platforms and their characterization to multidisciplinary approaches that effectively address important scientific problems. The Editors encourage submissions presenting innovative analytical research in concept, instrumentation, methods, and/or applications, including: mass spectrometry, spectroscopy, and electroanalysis; advanced separations; analytical strategies in “-omics” and imaging, bioanalysis, and sampling; miniaturized devices, medical diagnostics, sensors; analytical characterization of nano- and biomaterials; chemometrics and advanced data analysis.
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