New insights into the mechanisms behind Crohn's disease point to potential therapeutic target

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BOSTON – The structure of chromatin—the mixture of DNA and proteins that form chromosomes—can affect gene expression, and certain chromatin “readers” are important for monitoring this structure often in response to environmental cues.

everse intestinal abnormalities in mice with inflammation characteristic of Crohn’s disease

BOSTON – The structure of chromatin—the mixture of DNA and proteins that form chromosomes—can affect gene expression, and certain chromatin “readers” are important for monitoring this structure often in response to environmental cues.

Mutations within one such reader, called Speckled Protein 140 (SP140), are associated with an increased risk of certain immune diseases, including Crohn’s disease, a type of inflammatory bowel disease.

New research led by investigators at Massachusetts General Hospital (MGH) and published in Cell provides insights into the mechanisms behind this link, pointing to potential therapeutic targets.

SP140 expression is uniquely restricted to immune cells such as macrophages, which surround and kill microorganisms, remove dead cells, and stimulate the action of other immune cells.

Protein analyses by Kate L. Jeffrey, PhD, a principal investigator of immunology at MGH and an associate professor of medicine at Harvard Medical School, and her colleagues revealed that SP140 represses topoisomerases (TOP), which are enzymes that help DNA untangle during replication.

The team also found that in humans and mice, SP140 loss resulted in unleashed TOP activity, ultimately leading to defective gene expression and bacterial killing by macrophages that caused intestinal abnormalities. Inhibiting TOP rescued these defects in mice with inflammation characteristic of Crohn’s disease, a condition that remains incurable by surgical or therapeutic interventions.

“Applying a combination of human genetics, proteomics, biochemistry, utilization of primary immune cells from Crohn’s disease individuals, and in vivo animal studies, our study highlights the power of examining human disease associated genetic mutations to advance mechanistic understanding of disease,” says Jeffrey. “The work broadens our understanding of epigenetics in health—or the physical changes in cells’ DNA structure that affect the expression of genes in response to environmental cues. Importantly though, it revealed how dysregulation of epigenetic factors drive diseases such as Crohn’s that are rising in incidence because of the complex interplay of genes plus environment.”

Several TOP inhibitors are approved for the treatment of certain cancers, and many in the drug class are being tested in ongoing cancer clinical trials. These latest findings indicate that clinical trials should also test their effectiveness against Crohn’s disease.

Additional co-authors include Hajera Amatullah, Isabella Fraschilla, Sreehaas Digumarthi, Julie Huang, Fatemeh Adiliaghdam, Gracia Bonilla, Lai Ping Wong, Marie-Eve Rivard, Claudine Beauchamp, Virginie Mercier, Philippe Goyette, Ruslan I. Sadreyev, Robert M. Anthony, and John Rioux.

This study was supported by the Canadian Institutes of Health Research, the Canada Foundation for Innovation, the National Institutes of Health and the MGH Research Scholar Program. Dr. Jeffrey is a John Lawrence MGH Research Scholar 2020-2025.

About the Massachusetts General Hospital

Massachusetts General Hospital, founded in 1811, is the original and largest teaching hospital of Harvard Medical School. The Mass General Research Institute conducts the largest hospital-based research program in the nation, with annual research operations of more than $1 billion and comprises more than 9,500 researchers working across more than 30 institutes, centers and departments. In July 2022, Mass General was named #8 in the U.S. News & World Report list of “America’s Best Hospitals.” MGH is a founding member of the Mass General Brigham healthcare system.