Researchers at the Francis Crick Institute, working with UCL and Imperial College London, have discovered a new biological pathway that is a principal driver of inflammatory bowel disease (IBD) and related conditions, and which can be targeted using existing drugs.

About 5% of the world’s population, and one in ten people in the UK1, are currently affected by an autoimmune disease, such as IBD, the umbrella term for Crohn’s disease and ulcerative colitis. These diseases are also becoming more common, with over half a million people living with IBD in the UK as of 2022, nearly double the 300,000 previously estimated2.

Despite increasing prevalence, current treatments do not work in every patient and attempts to develop new drugs often fail due to our incomplete understanding of what causes IBD.

In research published in Nature, scientists at the Crick journeyed into a ‘gene desert’ — an area of DNA that doesn’t code for proteins — which has previously been linked to IBD and several other autoimmune diseases3.

They found that this gene desert contains an ‘enhancer’, a section of DNA that is like a volume dial for nearby genes, able to crank up the amount of proteins they make. The team discovered that this particular enhancer was only active in macrophages, a type of immune cell known to be important in IBD, and boosted a gene called ETS2, with higher levels correlating with a higher risk of disease.

Using genetic editing, the scientists showed that ETS2 was essential for almost all inflammatory functions in macrophages, including several that directly contribute to tissue damage in IBD. Strikingly, simply increasing the amount of ETS2 in resting macrophages turned them into inflammatory cells that closely resembled those from IBD patients.

The team also discovered that many other genes previously linked to IBD are part of the ETS2 pathway, providing further evidence that it is a major cause of IBD.

ETS2 as a treatment target

Specific drugs that block ETS2 don’t exist, so the team searched for drugs that might indirectly reduce its activity. They found that MEK inhibitors, drugs already prescribed for other non-inflammatory conditions, were predicted to switch off the inflammatory effects of ETS2.

The researchers then put this to the test, and discovered that these drugs not only reduced inflammation in macrophages, but also in gut samples from patients with IBD.

As MEK inhibitors can have side effects in other organs, the researchers are now working with LifeArc to find ways to deliver MEK inhibitors directly to macrophages.

James Lee, Group Leader of the Genetic Mechanisms of Disease Laboratory at the Crick, and Consultant Gastroenterologist at the Royal Free Hospital and UCL, who led the research, said: “IBD usually develops in young people and can cause severe symptoms that disrupt education, relationships, family life and employment. Better treatments are urgently needed.

“Using genetics as a starting point, we’ve uncovered a pathway that appears to play a major role in IBD and other inflammatory diseases. Excitingly, we’ve shown that this can be targeted therapeutically, and we’re now working on how to ensure this approach is safe and effective for treating people in the future.”

Christina Stankey, PhD student at the Crick, and first author along with Christophe Bourges and Lea-Maxie Haag, said: “IBD and other autoimmune conditions are really complex, with multiple genetic and environmental risk factors, so to find one of the central pathways, and show how this can be switched off with an existing drug, is a massive step forwards.”

Volunteer participants from the NIHR BioResource, with and without IBD, provided blood samples that contributed to this research. The research was funded by Crohn’s and Colitis UK, the Wellcome Trust, MRC and Cancer Research UK, and the researchers worked with collaborators across the UK and Europe.

Ruth Wakeman, Director of Services, Advocacy and Evidence at Crohn’s & Colitis UK said: “Every year, more than 25,000 people are told that they have Inflammatory Bowel Disease. Crohn’s and Colitis are complex, lifelong conditions for which there is no cure, but research like this is helping us to answer some of the big questions about what causes them. The more we can understand about Inflammatory Bowel Disease, the more likely we are to be able to help patients live well with these conditions. This research is a really exciting step towards the possibility of a world free from Crohn’s and Colitis one day.”

Lauren Golightly is 27 years old and was diagnosed with Crohn’s Disease in 2018 after experiencing stomach cramps, blood in her poo and irregular bowel habits.

She said: “Crohn’s has had a huge impact on my life. I’ve had a rocky road since diagnosis, with many hospital admissions, several different medications and even surgery to have a temporary stoma bag. One of the hardest things about having Inflammatory Bowel Disease ( IBD) is the uncertainty around it. I still experience flare-ups and can still spend quite a bit of time in hospital. Learning about this research is so exciting and encouraging. I am hopeful this could potentially make a difference for myself and so many other hundreds of thousands of people living with IBD.”



Source link

Leave a Reply

Your email address will not be published. Required fields are marked *

Before you post, please prove you are sentient.

What color is a typical spring leaf?

Explore More

Microbiome science may help doctors deliver more effective, personalized treatment to children with irritable bowel syndrome

To improve the treatment of children with irritable bowel syndrome (IBS), investigators have developed a sophisticated way to analyze the microbial and metabolic contents of the gut. A report in

Mapping 1.6 million gut cells to find new ways treat disease

The most comprehensive cell map of the human gut to date has been created by combining spatial and single-cell data from 1.6 million cells. Mapping the cells of the gut

Stress-tolerant cells drive tumor initiation in pancreatic cancer

Researchers at University of California San Diego School of Medicine have discovered a molecular pathway critical to the initiation of pancreatic tumors. The mechanism could also contribute to the disease’s