3D environment favors persistent changes in cell functions and altered morphology, wrinkling, and biomechanical signature of the nucleus

The interplay between cells and their surrounding microenvironment drives multiple cellular functions, including migration, proliferation, and cell fate transitions. The nucleus is a mechanosensitive organelle; however, the morphological and functional changes of the nucleus induced by a three-dimensional (3D) extracellular environment remain unclear. Here, we report that leukemia Jurkat cells selected after 3D growth conditions retain persistent nuclear changes even after being released from confinement. These altered cells showed aberrant nuclear wrinkling, visualized by the lamin B1 distribution and mediated by disrupted actin dynamics and protein kinase C (PKC)β signaling. Moreover, these cells presented changes in chromatin compaction, transcription, apoptosis, and in vivo dissemination. By combining biomechanical techniques and single-nucleus analysis, we have determined that these cells exhibit a distinct nuclear mechanical behavior and biophysical signature compared with control cells. Together, these findings demonstrate that 3D microenvironments alter leukemia cell biology by promoting persistent changes in chromatin organization, morphology, and mechanical response of the nucleus.