Mechanical Characterization of Aortic Valve Interstitial Cells and their Nuclei using Atomic Force Microscopy

Liu, Haijiao

20 November 2012

The cellular mechanical environment, including the elasticity of the extracellular matrix, profoundly affects cellular mechanical and biological responses. This responsiveness depends on and may influence the inherent mechanical properties of the cell and the nucleus. In this thesis, the local and global elastic moduli of valve interstitial cells (VICs) cultured on substrates of varying stiffness were characterized using atomic force microscopy (AFM). A novel AFM technique used to directly determine nuclear elastic moduli in situ was also tested and preliminary results for VIC nuclear elasticity and isolated VIC nuclei elasticity were presented. This study confirmed that both local and global elasticity of VICs were sensitive to substrate compliance, and demonstrated that the nucleus was consistently two to four times stiffer than the cytoplasm and that isolated VIC nuclei were significantly softer than the intact nuclei in situ. It also provides practical guidelines for efficient AFM-based measurement of cell mechanical properties.

Atomic force microscopy

cell mechanics

nuclear mechanics

heart valve

0541

0548

Mechanical Characterization of Aortic Valve Interstitial Cells and their Nuclei using Atomic Force Microscopy

Liu, Haijiao

20 November 2012

The cellular mechanical environment, including the elasticity of the extracellular matrix, profoundly affects cellular mechanical and biological responses. This responsiveness depends on and may influence the inherent mechanical properties of the cell and the nucleus. In this thesis, the local and global elastic moduli of valve interstitial cells (VICs) cultured on substrates of varying stiffness were characterized using atomic force microscopy (AFM). A novel AFM technique used to directly determine nuclear elastic moduli in situ was also tested and preliminary results for VIC nuclear elasticity and isolated VIC nuclei elasticity were presented. This study confirmed that both local and global elasticity of VICs were sensitive to substrate compliance, and demonstrated that the nucleus was consistently two to four times stiffer than the cytoplasm and that isolated VIC nuclei were significantly softer than the intact nuclei in situ. It also provides practical guidelines for efficient AFM-based measurement of cell mechanical properties.

Atomic force microscopy

cell mechanics

nuclear mechanics

heart valve

0541

0548

Mechanics and Mechanotransduction of Adherent Cells: A Compendium of Atomic Force Microscopy Studies

Haase, Kristina M.

January 2014

Mechanical cues have been recognized to be critically important in the regulation of cells. A myriad of cellular processes including differentiation, proliferation, and gene expression are all affected by physical forces from the extra- and intra-cellular microenvironments. Despite recent advances in nano-technologies, many questions still surround how cells sense and respond to forces. Through a series of studies, we demonstrate how both the structure and inherent mechanical properties of the cell affect their response to mechanical cues. We first develop a methodology to mechanically manipulate cells while simultaneously characterizing their deformations. Using combined atomic force and confocal microscopy techniques and through systematic examination we demonstrate the role of the cytoskeleton and nucleus in the deformability and shape change of epithelial cells. Mechanical properties have been used in recent years to identify diseased states, including cancer. With this in mind, we used HeLa cells as a model and characterized significant deformability of their plasma membrane and underlying cortex. Importantly, we demonstrate and characterize their ability to recover from large shape changes, which we also observed in other epithelial cells. Shape recovery is shown to be rapid and reliant upon the actin cytoskeleton and intracellular fluid flow. Although the nucleus does not contribute significantly to the deformation and recovery of HeLa cells, the importance of nuclear mechanics cannot be forgone. In vitro studies have shown that mechanical forces transmitted through the cell’s cytoskeleton critically affect nuclear mechanics and gene transcription processes. Many others have used simple models and isolated nuclei in an attempt to characterize nuclear properties. Thus, in a subsequent study, we examine the nucleus within intact cells. Nuclear shape change, in response to force, is shown to be complex and cannot be well-characterized by isotropic mechanical properties. Characterization of the mechanics of the cell, as demonstrated through our findings, is crucial in the field of biological physics. The aforementioned studies, written as scientific articles, are presented in the body of this thesis (Chapters 2-5). A review article that focuses on mechanotransduction and relevant examples using AFM as a tool for its examination acts as an introductory chapter.

Cell mechanics

Atomic Force Microscopy

Mechanotransduction

Nuclear mechanics

Plasma membrane

Cytoskeleton

Effect of Nuclear Stiffness on Cell Mechanics and Migration of Human Breast Cancer Cells

Fischer, Tony, Hayn, Alexander, Mierke, Claudia Tanja

03 April 2023

The migration and invasion of cancer cells through 3D confined extracellular matrices is coupled to cell mechanics and the mechanics of the extracellular matrix. Cell mechanics is mainly determined by both the mechanics of the largest organelle in the cell, the nucleus, and the cytoskeletal architecture of the cell. Hence, cytoskeletal and nuclear mechanics are the major contributors to cell mechanics. Among other factors, steric hindrances of the extracellular matrix confinement are supposed to affect nuclear mechanics and thus also influence cell mechanics. Therefore, we propose that the percentage of invasive cells and their invasion depths into loose and dense 3D extracellular matrices is regulated by both nuclear and cytoskeletal mechanics. In order to investigate the effect of both nuclear and cytoskeletal mechanics on the overall cell mechanics, we firstly altered nuclear mechanics by the chromatin de-condensing reagent Trichostatin A (TSA) and secondly altered cytoskeletal mechanics by addition of actin polymerization inhibitor Latrunculin A and the myosin inhibitor Blebbistatin. In fact, we found that TSA-treated MDA-MB-231 human breast cancer cells increased their invasion depth in dense 3D extracellular matrices, whereas the invasion depths in loose matrices were decreased. Similarly, the invasion depths of TSA-treated MCF- 7 human breast cancer cells in dense matrices were significantly increased compared to loose matrices, where the invasion depths were decreased. These results are also valid in the presence of a matrix-metalloproteinase inhibitor GM6001. Using atomic force microscopy (AFM), we found that the nuclear stiffnesses of both MDA-MB- 231 and MCF-7 breast cancer cells were pronouncedly higher than their cytoskeletal stiffness, whereas the stiffness of the nucleus of human mammary epithelial cells was decreased compared to their cytoskeleton. TSA treatment reduced cytoskeletal and nuclear stiffness of MCF-7 cells, as expected. However, a softening of the nucleus by TSA treatment may induce a stiffening of the cytoskeleton of MDA-MB-231 cells and subsequently an apparent stiffening of the nucleus. Inhibiting actin polymerization using Latrunculin A revealed a softer nucleus of MDA-MB-231 cells under TSA treatment. This indicates that the actin-dependent cytoskeletal stiffness seems to be influenced by the TSA-induced nuclear stiffness changes. Finally, the combined treatment with TSA and Latrunculin A further justifies the hypothesis of apparent nuclear stiffening, indicating that cytoskeletal mechanics seem to be regulated by nuclear mechanics.

info:eu-repo/classification/ddc/570

ddc:570