Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Wood, A.K.; Sun, Heyuan; Jones, Max; Percival, Hannah; Braodberry, Eleanor; Zindy, Egor; Lawless, Craig; Swift, Joe; Brennan, Keith; Gilmore, Andrew

doi:10.1101/2020.10.06.327726

2020

DOI: 10.1101/2020.10.06.327726

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Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

A.K. Wood

Heyuan Sun

Max Jones

et al.

Abstract: SummaryMicroenvironmental stiffness regulates the behaviour of both normal and cancer cells. In breast tissue, high mammographic density (HMD), which reflects greater organisation and stiffness of the periductal collagen, represents a significant risk factor for cancer. However, the mechanistic link between extracellular matrix (ECM) stiffness and increased risk of breast tumour initiation remains unclear. In particular, how increased ECM stiffness might promote genomic damage, leading to the acquisition of tr… Show more

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The role of physics in multiomics and cancer evolution

Gourmet

Walker‐Samuel

2023

Front. Oncol.

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Complex interactions between the physical environment and phenotype of a tumour, and genomics, transcriptomics, proteomics and epigenomics, are increasingly known to have a significant influence on cancer development, progression and evolution. For example, mechanical stress can alter both genome maintenance and histone modifications, which consequently affect transcription and the epigenome. Increased stiffness has been linked to genetic heterogeneity and is responsible for heterochromatin accumulations. Stiffness thereby leads to deregulation in gene expression, disrupts the proteome and can impact angiogenesis. Several studies have shown how the physics of cancer can influence diverse cancer hallmarks such as resistance to cell death, angiogenesis and evasion from immune destruction. In this review, we will explain the role that physics of cancer plays in cancer evolution and explore how multiomics are being used to elucidate the mechanisms underpinning them.

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The role of physics in multiomics and cancer evolution

Gourmet

Walker‐Samuel

2023

Front. Oncol.

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Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Cited by 1 publication

References 55 publications

The role of physics in multiomics and cancer evolution

The role of physics in multiomics and cancer evolution

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