New study maps cellular mechanisms driving fibrosis in Crohn's Disease

As inflamed regions of the gut form scar tissue, the space within the gut lumen becomes smaller and more restricted, leading to symptoms of gut obstruction. There is currently no drug treatment available for this complication – eventually as fibrosis worsens, surgery becomes the only option.

Researchers from the Institute of Genetics and Cancer, together with colleagues at the Earlham Institute and Heriot-Watt University, discovered that the biggest build up of scar tissue takes place in the submucosa (a layer of tissue beneath the inner lining of the bowel). This indicates that the submucosa could be the starting point where the scarring begins.

Inflammation, the hallmark of Crohn’s Disease, brings clusters or aggregates of immune cells into the submucosa. Using single-cell RNA sequencing (scRNA-seq) to study fibrosis in Crohn's Disease, the researchers uncovered an unusual clustering of endothelial cells - cells which usually line blood vessels - around these groups of immune cells (known as Crohn’s lymphoid aggregates or CLAs). These clusters of blood vessel cells signal to scar building cells (fibroblasts/myofibroblasts) either directly or through macrophages, to start producing excessive collagen or scar tissue. This suggests that these Crohn’s lymphoid aggregates may have a significant role in driving the process of fibrosis. 

This study demonstrates the value of single-cell transcriptomics to complement histological analysis of clinical samples. By linking tissue pathology to cell and signalling mechanisms researchers can gain greater resolution of disease-associated sub-populations of cells which are typically challenging to separate morphologically. 

The paper is generated from an international consortium of researchers collaborating to create a ‘gut cell atlas’ - a research tool that identifies and characterises gut cells - enabling greater insight and faster resolution for diseases impacting the digestive system.

At Earlham Institute, scientists in the Papatheodorou Group are combining their computational expertise in single-cell genomics with cutting-edge data science and AI to develop tools and methodology needed to integrate data, standardise metadata, build cell atlases, and analyse these atlases across different species.

Further analysis is needed to confirm these interactions and the next steps for this research will involve increasing the number of gut samples analysed using the same methodology.

Funded by The Leona M. and Harry B. Helmsley Charitable Trust, the largest private philanthropy focused on Crohn’s Disease, this research is vital for the discovery of new therapeutic targets to find better treatments for the hundreds of thousands of Crohn’s Disease patients suffering from this painful complication – severely impacting their quality of life.