Computational Methods for Structure-to-Function Analysis of Diet-Derived Catechins-Mediated Targeting of In Vitro Vasculogenic Mimicry.

IF 2.4 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Cancer Informatics Pub Date : 2021-04-09 eCollection Date: 2021-01-01 DOI:10.1177/11769351211009229

Abicumaran Uthamacumaran, Narjara Gonzalez Suarez, Abdoulaye Baniré Diallo, Borhane Annabi

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Abstract

Background: Vasculogenic mimicry (VM) is an adaptive biological phenomenon wherein cancer cells spontaneously self-organize into 3-dimensional (3D) branching network structures. This emergent behavior is considered central in promoting an invasive, metastatic, and therapy resistance molecular signature to cancer cells. The quantitative analysis of such complex phenotypic systems could require the use of computational approaches including machine learning algorithms originating from complexity science.

Procedures: In vitro 3D VM was performed with SKOV3 and ES2 ovarian cancer cells cultured on Matrigel. Diet-derived catechins disruption of VM was monitored at 24 hours with pictures taken with an inverted microscope. Three computational algorithms for complex feature extraction relevant for 3D VM, including 2D wavelet analysis, fractal dimension, and percolation clustering scores were assessed coupled with machine learning classifiers.

Results: These algorithms demonstrated the structure-to-function galloyl moiety impact on VM for each of the gallated catechin tested, and shown applicable in quantifying the drug-mediated structural changes in VM processes.

Conclusions: Our study provides evidence of how appropriate 3D VM compression and feature extractors coupled with classification/regression methods could be efficient to study in vitro drug-induced perturbation of complex processes. Such approaches could be exploited in the development and characterization of drugs targeting VM.

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饮食来源儿茶素介导的体外血管生成模拟的结构-功能分析的计算方法。

背景:血管生成模仿(VM)是一种适应性生物学现象，其中癌细胞自发地自组织成三维(3D)分支网络结构。这种突发性行为被认为是促进癌细胞侵袭性、转移性和治疗抗性分子特征的核心。这种复杂表型系统的定量分析可能需要使用计算方法，包括源自复杂性科学的机器学习算法。方法:采用Matrigel培养的SKOV3和ES2卵巢癌细胞进行体外3D VM。24小时用倒置显微镜拍照监测VM的饮食源性儿茶素破坏。结合机器学习分类器，评估了三维虚拟机复杂特征提取的三种计算算法，包括二维小波分析、分形维数和渗透聚类得分。结果:这些算法证明了每一种没食子儿茶素对VM的结构-功能影响，并证明了在VM过程中药物介导的结构变化的量化适用。结论:我们的研究提供了适当的3D VM压缩和特征提取器结合分类/回归方法可以有效研究体外药物诱导的复杂过程扰动的证据。这些方法可以用于针对VM的药物的开发和表征。

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来源期刊

Cancer Informatics Medicine-Oncology

CiteScore

3.00

自引率

5.00%

发文量

审稿时长

8 weeks

期刊介绍： The field of cancer research relies on advances in many other disciplines, including omics technology, mass spectrometry, radio imaging, computer science, and biostatistics. Cancer Informatics provides open access to peer-reviewed high-quality manuscripts reporting bioinformatics analysis of molecular genetics and/or clinical data pertaining to cancer, emphasizing the use of machine learning, artificial intelligence, statistical algorithms, advanced imaging techniques, data visualization, and high-throughput technologies. As the leading journal dedicated exclusively to the report of the use of computational methods in cancer research and practice, Cancer Informatics leverages methodological improvements in systems biology, genomics, proteomics, metabolomics, and molecular biochemistry into the fields of cancer detection, treatment, classification, risk-prediction, prevention, outcome, and modeling.