Although the human body is externally symmetric across the left-right axis, there are remarkable left-right asymmetries in the shape and positioning of most internal organs including the heart, lungs, liver, stomach, and brain.

Left-right asymmetry is known to be established during early embryogenesis by a small cluster of cells termed the left-right organizer. Within this organizer, motile cilia, hair-like structures on the cell surfaces, beat rapidly to create a leftward directional flow of extracellular fluid, which is the first outward sign of a left-right difference.

This early flow has been shown to be critical to the distinction of right from left; however, how this flow is sensed and translated into left-right asymmetry has been unknown.

In a new study, researchers now reveal that cilia in the organizer function as the creators of the flow – they also act as sensors for the biomechanical forces exerted by the flow to shape the left-right body plan of the developing embryo.

The findings were published in the journal Science.

“Nearly 25 years of work by numerous groups have shown that cilia and flow in the organizer are absolutely essential for establishing body left-right asymmetry”, says the senior author of the study. “But we haven’t had the right tools or techniques to definitively study how this all works.”

To overcome this challenge, the researchers utilized zebrafish as a model for left-right development and employed a novel optical toolkit consisting of custom-built microscopy and machine learning analysis.

Their approach was unique as they developed and deployed optical tweezers—a biophysical tool that uses light to hold and move microscopic objects similar to a tractor beam—that enabled precise delivery of mechanical force onto cilia in an intact, living animal for the first time.

Utilizing these tools, the researchers discovered that cilia are cell-surface mechanosensors that are important for left-right asymmetry of the developing body and organs such as the heart.

By using optical tweezers to apply mechanical force onto cilia in the left-right organizer of zebrafish, they showed that a subset of organizer cilia sense and translate flow forces into calcium signals that control left-right development in zebrafish.

Defects in left-right asymmetry are associated with numerous human disorders, including heterotaxy syndrome, primary ciliary dyskinesia and congenital heart disease.

“The knowledge gleaned from this study not only advances our understanding of the fundamental cellular processes that govern the development of the human body, they may also open new avenues for the development of novel diagnostics of these disorders,” says the author. “Additionally, this work may pave the way for targeted therapies on cilia signaling and mechanosensing to improve outcomes.”

The researchers continue to investigate the molecular mechanisms that govern cilia force sensing. They also continue to develop new strategies to visualize and manipulate cilia signaling, with the long-term goal of developing novel tools for the treatment of cilia-associated disorders.

“These results, and the tools that made it possible, have provided a new window into the developmental patterning of the embryo, and also opened Pandora’s box,” says a co-author on this study. “It reminds us that we have so much more to learn about how cilia signaling and mechanobiology impact development and disease.”

https://www.science.org/doi/10.1126/science.abq7317