Matrix stiffening promotes a tumor vasculature phenotype

Bordeleau, François; Mason, Brooke N.; Lollis, Emmanuel Macklin; Mazzola, Michael; Zanotelli, Matthew R.; Somasegar, Sahana; Califano, Joseph P.; Montague, Christine R; LaValley, Danielle J.; Huynh, John; Mencia-Trinchant, Nuria; Abril, Yashira L. Negrón; Hassane, Duane C.; Bonassar, Lawrence J.; Butcher, Jonathan T.; Weiss, Robert S.; Reinhart‐King, Cynthia A.

doi:10.1073/pnas.1613855114

Cited by 324 publications

(352 citation statements)

References 59 publications

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“…Accordingly, we observed a lower QPOL signal in tumor sections from mice treated with BAPN compared to the untreated control (Figure E). These results are consistent with the reduced stiffness and contractility of tumor tissue observed in BAPN treated mice . Of particular relevance, the quantification of the retardance revealed that we could distinguish between soft and stiff tumors (Figure F).…”

Section: Resultsmentioning

confidence: 99%

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Quantitative assessment of cell contractility using polarized light microscopy

Wang

Miller

Pannullo

et al. 2018

Journal of Biophotonics

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Cell contractility regulates multiple cell behaviors which contribute to both normal and pathological processes. However, measuring cell contractility remains a technical challenge in complex biological samples. The current state of the art technologies employed to measure cell contractility have inherent limitations that greatly limit the experimental conditions under which they can be used. Here, we use quantitative polarization microscopy to extract information about cell contractility. We show that the optical retardance signal measured from the cell body is proportional to cell contractility in 2-dimensional and 3-dimensional platforms, and as such can be used as a straightforward, tractable methodology to assess cell contractility in a variety of systems. This label-free optical method provides a novel and flexible way to assess cellular forces of single cells and monolayers in several cell types, fixed or live, in addition to cells present in situ in mouse tumor tissue samples. This easily implementable and experimentally versatile method will significantly contribute to the cell mechanics field.

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Section: Resultsmentioning

confidence: 99%

“…Type I collagen was isolated from rat‐tail tendons and extracted in 0.1% sterile acetic acid at 4°C as described previously . Stiffness of the collagen scaffolds was controlled either by changing the collagen density or by increasing collagen crosslinking through non‐enzymatic glycation.…”

Section: Methodsmentioning

confidence: 99%

Quantitative assessment of cell contractility using polarized light microscopy

Wang

Miller

Pannullo

et al. 2018

Journal of Biophotonics

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“…Briefly, the ratio of acrylamide (40% w/v; Bio-Rad, Hercules, CA) and bis-acrylamide (2% w/v; Bio-Rad) was varied to tune gel stiffness from 1 to 10 kPa to mimic vascular and tumorous tissue as described previously [22,26,39]. Gels were coated with either 0.1 mg/ml collagen type I (BD Biosciences, San Jose, CA) or fibronectin (Thermo Fisher Scientific, Waltham, MA).…”

Section: Methodsmentioning

confidence: 99%

Matrix stiffness enhances VEGFR-2 internalization, signaling, and proliferation in endothelial cells

LaValley

Zanotelli

Bordeleau

et al. 2017

Converg. Sci. Phys. Oncol.

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Vascular endothelial growth factor (VEGF) can mediate endothelial cell migration, proliferation, and angiogenesis. During cancer progression, VEGF production is often increased to stimulate the growth of new blood vessels to supply growing tumors with the additional oxygen and nutrients they require. Extracellular matrix stiffening also occurs during tumor progression, however, the crosstalk between tumor mechanics and VEGF signaling remains poorly understood. Here, we show that matrix stiffness heightens downstream endothelial cell response to VEGF by altering VEGF receptor-2 (VEGFR-2) internalization, and this effect is influenced by cell confluency. In sub-confluent endothelial monolayers, VEGFR-2 levels, but not VEGFR-2 phosphorylation, are influenced by matrix rigidity. Interestingly, more compliant matrices correlated with increased expression and clustering of VEGFR-2; however, stiffer matrices induced increased VEGFR-2 internalization. These effects are most likely due to actin-mediated contractility, as inhibiting ROCK on stiff substrates increased VEGFR-2 clustering and decreased internalization. Additionally, increasing matrix stiffness elevates ERK 1/2 phosphorylation, resulting in increased cell proliferation. Moreover, cells on stiff matrices generate more actin stress fibers than on compliant substrates, and the addition of VEGF stimulates an increase in fiber formation regardless of stiffness. In contrast, once endothelial cells reached confluency, stiffness-enhanced VEGF signaling was no longer observed. Together, these data show a complex effect of VEGF and matrix mechanics on VEGF-induced signaling, receptor dynamics, and cell proliferation that is mediated by cell confluency.

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“…Enhanced ECM density and rigidity facilitates liver and breast cancer detection via , and may indicate risk factors for tumour progression and therapeutic response 53,54 . ECM changes alter mechanotransduction 55,56 and promote malignant behaviour by disrupting epithelial morphogenesis 57 , growth factor secretion and signalling 58 , invasive phenotype 59,60 and stem cell differentiation 61 , as well as angiogenesis and vessel permeability 62 . As such, efforts have focused on characterizing altered ECM and how it contributes to tumour progression, with the goal of normalizing ECM for therapy 3,63 (FIG.…”

Section: Physical Microenvironment Of the Tumourmentioning

confidence: 99%

Engineering and physical sciences in oncology: challenges and opportunities

2017

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The principles of engineering and physics have been applied to oncology for nearly 50 years. Engineers and physical scientists have made contributions to all aspects of cancer biology, from quantitative understanding of tumour growth and progression to improved detection and treatment of cancer. Many early efforts focused on experimental and computational modelling of drug distribution, cell cycle kinetics and tumour growth dynamics. In the past decade, we have witnessed exponential growth at the interface of engineering, physics and oncology that has been fuelled by advances in fields including materials science, microfabrication, nanomedicine, microfluidics, imaging, and catalysed by new programmes at the National Institutes of Health (NIH), including the National Institute of Biomedical Imaging and Bioengineering (NIBIB), Physical Sciences in Oncology, and the National Cancer Institute (NCI) Alliance for Nanotechnology. Here, we review the advances made at the interface of engineering and physical sciences and oncology in four important areas: the physical microenvironment of the tumour and technological advances in drug delivery; cellular and molecular imaging; and microfluidics and microfabrication. We discussthe research advances, opportunities and challenges for integrating engineering and physical sciences with oncology to develop new methods to study, detect and treat cancer, and we also describe the future outlook for these emerging areas.

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Matrix stiffening promotes a tumor vasculature phenotype

Cited by 324 publications

References 59 publications

Quantitative assessment of cell contractility using polarized light microscopy

Quantitative assessment of cell contractility using polarized light microscopy

Matrix stiffness enhances VEGFR-2 internalization, signaling, and proliferation in endothelial cells

Engineering and physical sciences in oncology: challenges and opportunities

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