Cookies on this website

We use cookies to ensure that we give you the best experience on our website. If you click 'Accept all cookies' we'll assume that you are happy to receive all cookies and you won't see this message again. If you click 'Reject all non-essential cookies' only necessary cookies providing core functionality such as security, network management, and accessibility will be enabled. Click 'Find out more' for information on how to change your cookie settings.

A research team led by Prof Alison Simmons at MRC HIU used single-cell technology to identify new players in the gut epithelial barrier.

Inflammatory Bowel Disease (IBD) is a disease that affects at least 300,000 people in the UK alone. Its incidence is increasing worldwide, in particular in industrial-urbanised societies. There is no cure for IBD, and while many patients can manage the symptoms with appropriate care, approximately 40% of patients do not respond to available therapies.

Diseases such as IBD develop when the symbiotic relationship between the cells lining the surface of the gut wall and the trillions of bacteria that live inside the gut lumen breaks down. Normally these bacteria are beneficial to our bodies, helping to digest food, training the immune system or preventing harmful bacteria from taking hold. However, in diseases such as IBD, the barrier cell layer that keeps these microorganisms inside the gut lumen breaks down, leading to emergence of harmful bacteria and subsequent inflammation.

 

A detailed look at the gut

Mouse gutTo understand why this protective barrier breaks down, the research team led by Professor Alison Simmons at the MRC Human Immunology Unit compared gut biopsies from healthy individuals and patients with IBD.

Rather than looking at these biopsies as a whole, inferring the average behaviour of different types of cell in each sample, the researchers were interested in examining each cell individually, to understand how each one is changed in disease. The team took advantage of the state of the art single cell facility at the MRC Weatherall Institute of Molecular Medicine to assemble a cell-by-cell map of the gut lining in health and IBD, in a paper published today in the journal Nature.

 

pH sensor

Using this careful analysis, researchers were able to identify a previously unknown sensor cell, that can detect the level of acidity in the gut lumen. They showed that these cells are located at the tip of the folds on the surface layer of the gut and secrete a hormone, uroguanylin, which regulates proliferation, metabolism and barrier function in the intestine on binding its ligand at acid pH. Surprisingly, these sensor cells were depleted in both IBD and colon cancer.

 

Protective mucus

The researchers also examined the behaviour of barrier goblet cells. These cells play a pivotal role secreting protective mucus over the colon surface to act as block to invasion of lumen bacteria. Their analysis found several previously unknown subtypes of goblet cell, each with their own important function. The subtype that changed most dramatically in IBD normally produces an anti-bacterial substance.. In IBD, this goblet cell type was damaged to such an extent, that it was unable to produce this anti-bacterial substance, leading to bacterial invasion and inflammation of the colon.  These results reveal a mechanism by which the gut stops being able to protect itself from luminal bacteria in patients with IBD.

 

Future research

This detailed analysis of the changes that happen to in the gut in IBD opens new research opportunities, as it provides the first insight, at single cell level, of how the protective barrier of the gut keeps harmful bacteria at bay, and also how this barrier is disrupted in IBD.

“By identifying new colonic epithelial cell types and uncovering fundamental determinants of barrier breakdown in IBD we open up avenues to restore the protective mucus layer pharmaceutically” said Prof Alison Simmons, Professor of Gastroenterology in the Nuffield Department of Medicine “Our work is also the first time that we are able to understand how individual, single cells lining our gut change in inflammation and lose their ability to protect against the harmful effects of luminal microbes in IBD”.

 

This work was funded by the Medical Research Council, The Wellcome Trust, NIHR and the Oxford NIHR Biomedical Research Centre.