Mechanical constraints organize 3D tissues and orchestrate muscle differentiation
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Biological tissues achieve proper shape and ordered structures during development through responses to internal and external signals, with mechanical cues playing a crucial role. These forces guide cellular organization, leading to complex self-organizing structures that are foundational to embryonic patterns. Emerging theories and experiments suggest that “topological morphogens” drive these processes. Despite the predominance of three-dimensional (3D) structures in biology, studying 3D tissues remains challenging due to limited model systems and the complexity of modeling. Here, we address these challenges by using self-organized cellular aggregates, specifically spindle-shaped C2C12 myoblasts, subjected to controlled mechanical stretching. Our findings reveal that these cells form a multilayered, actin-oriented tissue structure, where mechanical forces drive long-range 3D organization and muscle differentiation. Notably, tissue surface emerges as a hotspot for differentiation, correlating with directional order as shown by single molecule fluorescent in situ hybridization.
We explore how cells work together to form complex structures, particularly in 3D, using muscle precursors cells (C2C12 myoblasts) as a model. By applying controlled stretching forces, we found that these cells self-organize into layered tissues that guide their transformation into muscle. This research highlights the critical role of physical forces in shaping tissues, suggesting that the way cells are physically arranged and stretched in three dimensions can significantly influence their behavior and function. Our findings offer new insights into how tissues develop and could have implications for tissue engineering, where creating the right 3D environment is key to successful tissue growth and repair.
