Kidney images reveal how organ develops

Striking images reveal new insights into how the kidney develops from a group of cells into a complex organ.

The pictures are helping scientists to understand the early stages of development in mammals.

Researchers at the University of Edinburgh’s Roslin Institute used time-lapse imaging to capture mouse kidneys growing in the laboratory on camera.

Specialised structures

They identified a key molecule called beta-catenin that instructs cells to form specialised structures within the kidney. These structures - called nephrons - are responsible for filtering waste products from the blood to generate urine.

Image showing how the kidney grows specialised structures called nephrons that filter the blood and make urine

Molecular gradient

The images reveal that a gradient in the activity of beta-catenin forms along the growing nephron. It is the concentration of the molecule that instructs cells to form each particular part of the structure.

By changing the activity of beta-catenin in different places, the researchers learned that they could instruct cells to form different parts of the nephron.

Video of a mouse kidney growing in the laboratory

This is the first time we have been able to identify the molecular signals that instruct cells exactly how to form functional nephrons.

Dr Peter HohensteinSenior Research Fellow, The Roslin Institute

Lab studies

If nephrons do not work correctly, it can lead to a wide range of health problems — from abnormal water and salt loss, to dangerously high blood pressure. The findings will help scientists to grow nephrons in the lab that can be used to study how kidneys function.

By using time lapse imaging, we can get detailed information about the signals that control how kidneys form at different time-points in development. This means that we can use fewer animals and obtain much more information than normal imaging techniques.

Dr Nils LindstromPostdoctoral Research Fellow, Institute of Genetics and Molecular Medicine

The research is published today in the journal Elife and was funded by the National Centre for the Replacement, Refinement and Reduction of Animals in Research. The Roslin Institute receives strategic funding from the Biotechnology and Biological Sciences Research Council.