Cell tension, matrix mechanics, and cancer development

Sui Huang, Donald E Ingber

extracellular matrix cancer cytoskeleton mechanotransduction

Key takeaways

01Tumors are physically stiffer than healthy tissue
02This stiffness can activate cancer-promoting signals
03Cells pull on their surroundings, increasing stiffness
04This can create a mechanical feedback loop for cancer growth

Increased tissue stiffness can create a feedback loop that promotes cancerous cell behavior and further tissue stiffening.

Abstract

Oncologists often diagnose cancer based on a change of tissue stiffness sensed by palpation, yet cancer researchers generally focus on biochemical signaling mechanisms. Tumors are more rigid because they have a stiffer extracellular matrix. A new study shows that this alteration of matrix mechanics activates integrins, which not only promotes mitogenic signaling through Erk but also cell contractility through Rho, which can further increase matrix stiffness. This establishes a positive feedback loop that switches on the malignant phenotype in mammary epithelial cells. This mechanical "autocrine loop" brings solid-state mechanotransduction on a par with oncogenic signaling pathways in malignant transformation.

Cite this study

APA: Sui Huang, & Donald E Ingber (2005). Cell tension, matrix mechanics, and cancer development. https://fasciaresearchdatabase.com/cell-tension-matrix-mechanics-and-cancer-development/
MLA: Sui Huang, and Donald E Ingber. "Cell tension, matrix mechanics, and cancer development." 2005, https://fasciaresearchdatabase.com/cell-tension-matrix-mechanics-and-cancer-development/.
Chicago: Sui Huang, Donald E Ingber. 2005. "Cell tension, matrix mechanics, and cancer development.". https://fasciaresearchdatabase.com/cell-tension-matrix-mechanics-and-cancer-development/