Francis Crick Institute press release
Under strict embargo: 16:00hrs BST Wednesday 6 August 2025
Peer reviewed
Experimental study
Animals (zebrafish)
Early heartbeats direct the heart’s own development and growth
Researchers at the Francis Crick Institute have discovered that the heart’s own contractions trigger biological signals that guide the formation of a functional beating heart.
Their study in zebrafish highlights the heart’s ability to remodel and adapt to physiological demands and could also reveal what goes wrong during congenital heart conditions.
The heart is one of the first organs to form so that it can supply a developing embryo with the oxygen and nutrients critical to grow and survive. However, how the heart transforms from a simple tube into a complex, three-dimensional pump is still not fully understood.
As part of their study, published today in Developmental Cell, the research team followed the early development of the heart’s muscular structures, called trabeculae, in zebrafish. Zebrafish hearts share key structural and genetic features with human hearts, but with the added advantage of transparency, making it possible to see the heart grow at minute details in real time.
They used live 4D imaging of the zebrafish hearts to study biological processes at different scales, from individual cell behaviours to changes in organ shape and size.
They observed that trabeculae don’t grow and develop by cell division, as previously thought. Instead, neighbouring cells are recruited to build trabecular complexity, thus increasing heart’s muscle mass and contractile efficiency.
Setting the right pace
The team also uncovered a feedback mechanism between heart contraction and its own development. As the trabeculae develop and the heart contracts more strongly, this initiates mechanical signal that makes cells ‘softer’ enabling them to stretch and increase their size. This allows the heart to expand its volume by 90% and maximise its blood filling capacity.
Crucially, this feedback systems dictates a healthy pace of growth, because as heart cells stretch, they lose their ability to get recruited, thereby stabilising trabecular growth.
Toby Andrews, postdoctoral fellow and first author of the study, said: “The heartbeat is synonymous with life, and although we’ve observed its structure for centuries, how it grows to the right shape and size is still mysterious. What we’re uncovering is that the heart’s structure isn’t hardwired, instead it intelligently adapts to changes in animal physiology. Understanding the biology behind this flexibility could form the basis of future treatments for heart disease.”
The team now plans to delve deeper into trabeculae development, as it transforms into an ever more complex sponge-like 3D mesh of muscular ridges. They hope to identify how trabecular ridges regulate blood flow and which cellular processes and molecular mechanisms shape these complex structures.
Rashmi Priya, head of the Crick’s Organ Morphodynamics Lab, said, “Although we’ve made progress in understanding the molecular pathways involved in heart diseases or ‘cardiomyopathies’, we still know very little about how trabeculae form and how defects in these structures affect heart function. This underscores the importance of dissecting the developmental mechanisms that sculpt these structures and give rise to one of nature’s most efficient pumps—the heart.”
This work is funded by the British Heart Foundation.
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For further information, contact: press@crick.ac.uk or +44 (0)20 3796 5252
Notes to Editors
Reference: Andrews et al. (2025) Mechanochemical coupling of cell shape and organ function optimizes heart size and contractile efficiency in zebrafish. Developmental Cell.
The Francis Crick Institute is a biomedical discovery institute with the mission of understanding the fundamental biology underlying health and disease. Its work helps improve our understanding of why disease develops which promotes discoveries into new ways to prevent, diagnose and treat disease.
An independent organisation, its founding partners are the Medical Research Council (MRC), Cancer Research UK, Wellcome, UCL (University College London), Imperial College London and King’s College London.
The Crick was formed in 2015, and in 2016 it moved into a brand new state-of-the-art building in central London which brings together 1500 scientists and support staff working collaboratively across disciplines, making it the biggest biomedical research facility under a single roof in Europe.
Journal
Developmental Cell