Research story

Unlocking the mystery of brain asymmetry

Brain asymmetry, the differences between the left and right sides of the brain, is present across the entire animal kingdom. But why it exists is a mystery. Professor Stephen Wilson and Professor Isaac Bianco are leading a research team to find answers – with the help of zebrafish.

The habenular nucleus of a zebrafish embryo four days post-fertilisation. The left side of the habenular nucleus is slightly bigger compared to the right, highlighting asymmetry.
Credit:

Ana Faro, Tom Hawkins and Dr Steve Wilson / Wellcome Collection

Licence: Attribution CC BY

The habenular nucleus of a zebrafish embryo four days post-fertilisation. The habenular nucleus is a part of the epithalamus, which connects the limbic system (responsible for instinct and mood) to other regions of the brain.

Jane Bracher

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Unlocking the mystery of brain asymmetry
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Why does brain asymmetry exist? What factors produce asymmetry between the left and right sides of the brain? What might happen if that asymmetry was lost? 

These are just some of the questions Professor Stephen Wilson and Professor Isaac Bianco from University College London hope to answer through their research, ‘Understanding brain asymmetry: from genes and developmental mechanisms to circuits and behaviour’. 

With support from our Discovery Research Awards, they are using zebrafish as their animal model system to try and shed light on brain asymmetry at a fundamental level and potentially transform our understanding of this phenomenon.    

Understanding brain asymmetry 

The brain and how it works has long been a point of curiosity in science. We know a lot about how neurons and brain circuits work but not so much about how the brain functions as a whole unit. 

We’ve gained knowledge about the development and function of structures in different parts of the brain. But why there’s a difference between the left and right sides and how that difference comes about is still one of the brain’s mysteries. 

“Brain asymmetries are present across the entire animal kingdom,” says Bianco.   

“People have been fascinated by them for many years, but it's really not clear how such asymmetries come about and what purpose they serve.” 

Wilson and Bianco’s project will gather data across multiple domains in their goal to gain a deeper understanding of the brain’s right and left hemispheres.  

They will look at the genes and molecular processes that lead to some neurons on the left side of the brain becoming different to the neurons on the right side. They’ll also investigate asymmetric circuits across the brain and the behavioural consequences of brain asymmetry. 

Wilson explains: “The first step of the project is to try to understand the developmental mechanisms that give rise to the differences between left and right sides – what are the genes and signalling pathways?   

“The second part of the project is to ask what is the asymmetry good for? Suppose asymmetry is lost, what's the consequence of that upon the functioning of the brain? And so our work really addresses very fundamental mechanisms of understanding the organisation, the structure and the function of the brain.”  

If this research project is able to provide that crucial information, it could lead to a much deeper understanding of the brain. In turn, that might offer valuable insights into what happens when the brain is not functioning properly in various neurological conditions.

Researching with zebrafish 

Small, striped zebrafish swimming inside a transparent tank.

Zebrafish is a small tropical freshwater vertebrate known for its transparent embryos.

Credit:

Patrick Shepherd / Wellcome

A crucial aspect of Wilson and Bianco’s research is the involvement of zebrafish, a small tropical freshwater vertebrate known for its transparent embryos. They’re using these fish as their main animal model system.

Zebrafish, which also show sleep, social, hunting and other complex behaviours, are particularly suited to the research required to study brain asymmetry.  

“One of the main advantages of zebrafish for this type of work is that they have a tiny and optically transparent brain, and this allows us to use advanced light microscopy techniques to look at the structure of the brain, but also its activity in behaving animals,” Bianco explains.  

“We can record these patterns of activity and understand how the brain is processing information really at single cell resolution.”  

The team have already started studying different behaviours elicited by visual stimuli with the help of the zebrafish. These studies will help them understand how mutating genes involved in the development of asymmetry impact visually driven behaviours. 

“It's very easy for us to alter gene function in zebrafish and look at the consequences of those altered gene functions upon the development of the asymmetries that we're interested in,” Wilson says.

Transparent zebrafish embryo seen through a microscope.

The tiny and optically transparent brain of zebrafish means researchers can observe the structure and activity of their brains and how they process information using advanced light microscopy techniques.

Credit:

Patrick Shepherd / Wellcome

Following the science with discovery research 

The work Wilson and Bianco are doing is transformative research that’s driven by curiosity. They don’t know exactly where it will go but they’re eager to let the science lead them. 

“Discovery research allows the investigator to follow wherever the science is taking them,” Wilson says. “So, we find unexpected results all over the place. That allows us to pursue different lines of investigation depending upon the results of our previous experiments.” 

This is the kind of research we support through our Discovery Research programme, where we give researchers the space to pursue knowledge in unexpected places and make breakthroughs that could have major implications for our health.  

Their project can serve as a vital contribution to understanding not just brain asymmetry but the brain itself and potentially have major repercussions for neuroscience. 

"The brain is probably the most complicated object in the universe,” Bianco says, “and I think questions about how this remarkable organ that's responsible for all of our thoughts, feelings and cognition, how it's put together, and how it functions, are fascinating.” 

  • Stephen Wilson

    Professor of Developmental Biology

    University College London

    Stephen Wilson is a Professor of Developmental Biology in the Cell and Developmental Biology department at UCL Division of Biosciences. Wilson's research focuses on brain development using zebrafish as a model system. Wilson studies the mechanisms underlying vertebrate brain development, such as how the left and right sides of the brain become different and how the eyes take shape.

  • Isaac Bianco

    Professorial Research Fellow

    University College London

    Isaac Bianco is a Professorial Research Fellow at the UCL Research Department of Neuroscience, Physiology and Pharmacology. Bianco's research on brain asymmetry aims is to understand fundamental aspects of the structure and operation of the neural circuits that process sensory information to control animal behaviour. Bianco works with larval zebrafish with its tiny, optically transparent brain that enables the use of advanced light microscopy techniques to monitor neural activity.