Dedifferentiation Alters Chondrocyte Nuclear Mechanics During In vitro Culture and Expansion

Overview

Journal Biophys J

Publisher Cell Press

Specialty Biophysics

Date 2021 Nov 20

PMID 34800469

Citations 15

Authors

Soham Ghosh

Adrienne K Scott

Benjamin Seelbinder

Jeanne E Barthold

Brittany M St Martin

Samantha Kaonis

Stephanie E Schneider

Jonathan T Henderson

Corey P Neu

Affiliations

Soon will be listed here.

Abstract

The biophysical features of a cell can provide global insights into diverse molecular changes, especially in processes like the dedifferentiation of chondrocytes. Key biophysical markers of chondrocyte dedifferentiation include flattened cellular morphology and increased stress-fiber formation. During cartilage regeneration procedures, dedifferentiation of chondrocytes during in vitro expansion presents a critical limitation to the successful repair of cartilage tissue. Our study investigates how biophysical changes of chondrocytes during dedifferentiation influence the nuclear mechanics and gene expression of structural proteins located at the nuclear envelope. Through an experimental model of cell stretching and a detailed spatial intranuclear strain quantification, we identified that strain is amplified and the distribution of strain within the chromatin is altered under tensile loading in the dedifferentiated state. Further, using a confocal microscopy image-based finite element model and simulation of cell stretching, we found that the cell shape is the primary determinant of the strain amplification inside the chondrocyte nucleus in the dedifferentiated state. Additionally, we found that nuclear envelope proteins have lower gene expression in the dedifferentiated state. This study highlights the role of cell shape in nuclear mechanics and lays the groundwork to design biophysical strategies for the maintenance and enhancement of the chondrocyte phenotype during cell expansion with a goal of successful cartilage tissue engineering.

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