Organotypic 3D Cell-Architecture Impacts the Expression Pattern of miRNAs–mRNAs Network in Breast Cancer SKBR3 Cells

IF 3.6 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Non-Coding RNA Pub Date : 2023-10-26 DOI:10.3390/ncrna9060066

María de los Ángeles Gastélum-López, Maribel Aguilar-Medina, Cristina García Mata, Jorge López-Gutiérrez, Geovanni Romero-Quintana, Mercedes Bermúdez, Mariana Avendaño-Felix, César López-Camarillo, Carlos Pérez-Plascencia, Adriana S Beltrán, Rosalío Ramos-Payán

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引用次数: 0

Abstract

Background. Currently, most of the research on breast cancer has been carried out in conventional two-dimensional (2D) cell cultures due to its practical benefits, however, the three-dimensional (3D) cell culture is becoming the model of choice in cancer research because it allows cell–cell and cell–extracellular matrix (ECM) interactions, mimicking the native microenvironment of tumors in vivo. Methods. In this work, we evaluated the effect of 3D cell organization on the expression pattern of miRNAs (by Small-RNAseq) and mRNAs (by microarrays) in the breast cancer SKBR3 cell line and analyzed the biological processes and signaling pathways regulated by the differentially expressed protein-coding genes (DE-mRNAs) and miRNAs (DE-microRNAs) found in the organoids. Results. We obtained well-defined cell-aggregated organoids with a grape cluster-like morphology with a size up to 9.2 × 105 μm3. The transcriptomic assays showed that cell growth in organoids significantly affected (all p < 0.01) the gene expression patterns of both miRNAs, and mRNAs, finding 20 upregulated and 19 downregulated DE-microRNAs, as well as 49 upregulated and 123 downregulated DE-mRNAs. In silico analysis showed that a subset of 11 upregulated DE-microRNAs target 70 downregulated DE-mRNAs. These genes are involved in 150 gene ontology (GO) biological processes such as regulation of cell morphogenesis, regulation of cell shape, regulation of canonical Wnt signaling pathway, morphogenesis of epithelium, regulation of cytoskeleton organization, as well as in the MAPK and AGE–RAGE signaling KEGG-pathways. Interestingly, hsa-mir-122-5p (Fold Change (FC) = 15.4), hsa-mir-369-3p (FC = 11.4), and hsa-mir-10b-5p (FC = 20.1) regulated up to 81% of the 70 downregulated DE-mRNAs. Conclusion. The organotypic 3D cell-organization architecture of breast cancer SKBR3 cells impacts the expression pattern of the miRNAs–mRNAs network mainly through overexpression of hsa-mir-122-5p, hsa-mir-369-3p, and hsa-mir-10b-5p. All these findings suggest that the interaction between cell–cell and cell–ECM as well as the change in the culture architecture impacts gene expression, and, therefore, support the pertinence of migrating breast cancer research from conventional cultures to 3D models.

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器官型3D细胞结构对乳腺癌SKBR3细胞mirna - mrna网络表达模式的影响

背景。目前，大多数乳腺癌研究都是在传统的二维(2D)细胞培养中进行的，因为它具有实际的好处，然而，三维(3D)细胞培养正成为癌症研究的首选模型，因为它允许细胞间和细胞外基质(ECM)相互作用，模拟肿瘤在体内的原生微环境。方法。在这项工作中，我们评估了3D细胞组织对乳腺癌SKBR3细胞系中miRNAs(通过Small-RNAseq)和mrna(通过微阵列)表达模式的影响，并分析了类器官中发现的差异表达蛋白编码基因(de - mrna)和miRNAs (DE-microRNAs)调控的生物学过程和信号通路。结果。我们获得了定义明确的细胞聚集类器官，具有葡萄簇状形态，大小可达9.2 × 105 μm3。转录组学分析显示，类器官的细胞生长显著影响(p <0.01)，发现20个de - microrna上调，19个下调，49个de - mrna上调，123个mrna下调。计算机分析显示，11个上调的de - microrna的一个子集靶向70个下调的de - mrna。这些基因参与了150个基因本体(GO)生物学过程，如细胞形态发生的调控、细胞形状的调控、典型Wnt信号通路的调控、上皮形态发生的调控、细胞骨架组织的调控，以及MAPK和AGE-RAGE信号通路kegg -通路。有趣的是，hsa-mir-122-5p (Fold Change (FC) = 15.4)、hsa-mir-369-3p (FC = 11.4)和hsa-mir-10b-5p (FC = 20.1)调节了70个下调的de - mrna中的81%。结论。乳腺癌SKBR3细胞的器官型三维细胞组织结构主要通过过表达hsa-mir-122-5p、hsa-mir-369-3p和hsa-mir-10b-5p来影响mirnas - mrna网络的表达模式。所有这些发现都表明，细胞-细胞和细胞- ecm之间的相互作用以及培养结构的变化会影响基因表达，因此，支持将乳腺癌研究从传统培养转移到3D模型的针对性。

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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来源期刊

Non-Coding RNA Biochemistry, Genetics and Molecular Biology-Genetics

CiteScore

6.70

自引率

4.70%

发文量

审稿时长

10 weeks

期刊介绍： Functional studies dealing with identification, structure-function relationships or biological activity of: small regulatory RNAs (miRNAs, siRNAs and piRNAs) associated with the RNA interference pathway small nuclear RNAs, small nucleolar and tRNAs derived small RNAs other types of small RNAs, such as those associated with splice junctions and transcription start sites long non-coding RNAs, including antisense RNAs, long ''intergenic'' RNAs, intronic RNAs and ''enhancer'' RNAs other classes of RNAs such as vault RNAs, scaRNAs, circular RNAs, 7SL RNAs, telomeric and centromeric RNAs regulatory functions of mRNAs and UTR-derived RNAs catalytic and allosteric (riboswitch) RNAs viral, transposon and repeat-derived RNAs bacterial regulatory RNAs, including CRISPR RNAS Analysis of RNA processing, RNA binding proteins, RNA signaling and RNA interaction pathways: DICER AGO, PIWI and PIWI-like proteins other classes of RNA binding and RNA transport proteins RNA interactions with chromatin-modifying complexes RNA interactions with DNA and other RNAs the role of RNA in the formation and function of specialized subnuclear organelles and other aspects of cell biology intercellular and intergenerational RNA signaling RNA processing structure-function relationships in RNA complexes RNA analyses, informatics, tools and technologies: transcriptomic analyses and technologies development of tools and technologies for RNA biology and therapeutics Translational studies involving long and short non-coding RNAs: identification of biomarkers development of new therapies involving microRNAs and other ncRNAs clinical studies involving microRNAs and other ncRNAs.