Document Type
Article
Publication Title
Biology Open
Publication Date
2026
Keywords
C. elegans, sarcomere, muscle plasticity, locomotion, mechanotransduction, activity-dependent remodeling
Abstract
Muscle structure is dynamically shaped by mechanical use, yet how distinct locomotor behaviors influence sarcomere organization remains poorly understood. In Caenorhabditis elegans, crawling and swimming constitute discrete gaits that differ in curvature, frequency, and mechanical load, providing a tractable model for studying activity-dependent remodeling. Using confocal imaging of phalloidin-stained body-wall myocytes, we quantified myocyte geometry, sarcomere length, and sarcomere number across anterior, mid-body, and posterior regions in animals reared exclusively under crawling or swimming conditions. Quantification and hypothesis testing used linear mixed models that accounted for repeated myocyte measurements within animals, with interaction terms testing region-specific effects of locomotor condition after interquartile range (IQR)-based outlier removal. Swimming produced characteristic remodeling of body-wall muscles. Myocytes elongated globally, while selectively thinning in the mid-body, reducing cell area by ∼13% relative to crawlers. Shape metrics confirmed this shift: circularity declined at mid- and tail-regions and anisotropy increased by ∼2–3 units. Sarcomere architecture exhibited parallel remodeling. Average sarcomere length shortened across the body (−0.19 µm in head, −0.35 µm in mid-body, −0.20 µm in tail), while sarcomere number increased in anterior and mid-body regions (+0.77 and +0.65 sarcomeres per myocyte). The mid-body region also showed a significant rise in sarcomere density, indicating tighter serial packing. These adaptations mirror functional compartmentalization predicted from gait kinematics and parallel fast-fiber remodeling observed in vertebrate muscles. The results indicate that C. elegans muscles adapt their contractile lattice to sustained mechanical demand, linking neural gait selection and mechanosensitive signaling to long-term structural plasticity. This work establishes C. elegans as a model for dissecting the conserved pathways that couple muscle use to cellular architecture and provides a foundation for future comparisons of healthy and diseased muscle remodeling.
Funding Source
Some strains were provided by the CGC, which is funded by NIH Office of Research Infrastructure Programs (P40 OD010440). This article was published Open Access thanks to a transformative agreement between Milner Library and Company of Biologists.
Recommended Citation
Adina Fazyl, Akash Anbu, Sabrina Kollbaum, Andrés G. Vidal-Gadea; Activity-dependent remodeling of muscle architecture during distinct locomotor behaviors in Caenorhabditis elegans. Biol Open 15 January 2026; 15 (1): bio062371. doi: https://doi.org/10.1242/bio.062371
Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.
DOI
10.1242/bio.062371
Comments
First published in Biology Open (2026): https://doi.org/10.1242/bio.062371