Information for Our Community

Whether you are part of our community or are interested in joining us, we welcome you to Washington University School of Medicine.

close  


Visit the News Hub

Scientists find timekeepers of gut’s immune system

Targeting such cells may lead to treatments for digestive ailments

by Tamara BhandariOctober 4, 2019

Qianli Wang

As people go through their daily and nightly routines, their digestive tracts follow a routine, too: digesting food and absorbing nutrients during waking hours, and replenishing worn-out cells during sleep. Shift work and jet lag can knock sleep schedules and digestive rhythms out of whack. Such disruptions have been linked to increased risk of intestinal infections, obesity, inflammatory bowel disease and colorectal cancer, among others.

Now, researchers at Washington University School of Medicine in St. Louis have identified a type of immune cell that helps keep time in the gut. Such cells, known as type 3 innate lymphoid cells (ILC3), are responsible for keeping the intestine operating in a normal, healthy manner. The researchers found that so-called clock genes are highly active in such cells and that the cells’ production of immune molecules track with the activity of the clock genes. When the researchers eliminated a key clock gene from mice, the animals failed to produce a subset of ILC3 cells and struggled to control a bacterial infection in the gut.

The findings, published Oct. 4 in Science Immunology, help explain why disruptions to circadian rhythms are linked to gastrointestinal problems. Further, they suggest that targeting clock genes could affect immune cells and help counter the negative effects of erratic sleep schedules associated with intestinal illnesses.

“It’s become increasingly clear that the disruptions of circadian rhythms so common in modern life – shift work, jet lag, chronic sleep deprivation – have harmful effects on people’s health, but we still don’t know a lot about how exactly sleep disruptions cause these problems,” said senior author Marco Colonna, MD, the Robert Rock Belliveau MD Professor of Pathology and a professor of medicine. “What we’ve found here is that circadian rhythms directly affect the function of immune cells in the gut, which could help explain some of the health issues we see, such as inflammatory bowel disease and metabolic syndrome.”

ILC3 cells maintain equilibrium in the gut by fortifying the barrier between the trillions of bacteria that normally live inside the gut and the cells that make up the intestine itself. They also produce immune molecules that help the gut’s immune system avoid overreacting to harmless microbes and food particles, while preserving its ability to combat disease-causing micro-organisms.

Colonna and colleagues have studied ILC3 cells for years, but it wasn’t until first author Qianli Wang and second author Michelle Robinette, MD, PhD – both graduate students in Colonna’s lab at the time – noticed that clock genes were highly activated in ILC3 cells that they began to wonder whether the cells could link circadian rhythms to the gut’s immune system.

“If ILC3 cells are attuned to circadian rhythms, they can anticipate when nutrition is going to arrive in the intestine, which is also when dangerous bacteria might accidentally be consumed and arrive in the gut, too,” Wang said. “For optimal functioning, the gut needs to be prepared for these daily rhythms, and these cells play a pivotal role in that process.”

By studying ILC3 cells taken from mouse intestines at six-hour intervals, the researchers found that the activity of clock genes varied in a predictable pattern over the course of a day, and that the activity of genes for immune molecules tracked with the clock genes. When they put some mice on a schedule similar to one experienced by a shift worker – an eight-hour change in the light-dark cycle every two days – the ILC3 cells no longer functioned normally. They produced low levels of immune molecules when stimulated to respond to an infection. Further, when mice were genetically modified to lack the clock protein REV-ERB alpha, the animals failed to develop normal quantities of ILC3 cells.

“I think it’s fair to say that ILC3 is under circadian rhythm regulation and certain key circadian genes are crucial for ILC3 cells to develop and function,” Wang said.

Wang and Colonna suspected that a paucity of ILC3 cells or a change in ILC3 behavior could affect the body’s ability to fight intestinal infections. Using mice that lack the clock protein – as well as healthy mice for comparison – the researchers studied the effect of infection with the bacterium Clostridium difficile, which can cause severe diarrhea in people. The mice without the clock protein failed to mount an effective defense: Their ILC3 cells produced more of a damaging immune molecule and less of a protective immune molecule, and the bacteria spread more widely in their bodies.

“The equilibrium of the gut is upset by disruptions to circadian rhythms,” Wang said. “ILC3 cells are so important to gut equilibrium that we may be able to counter some of these disruptions by targeting clock genes in ILC3 cells.”

The researchers are continuing to study the role of circadian rhythms on the digestive tract.

“The emerging relevance of the circadian regulation in gut health is likely to impact medical and hospital practice,” Colonna said. “I think we will have to start taking circadian rhythms of the gut cells into consideration when choosing optimal timing for nutritional and pharmacological interventions.”

Wang Q, Robinette ML, Billon C, Collins PL, Bando JK, Fachi JL, Sécca C, Porter SI, Saini A, Gilfillan S, Solt LA, Musiek ES, Oltz EM, Burris TP, Colonna M. Circadian rhythm–dependent and circadian rhythm–independent impacts of the molecular clock on type 3 innate lymphoid cells. Science Immunology. Oct. 4, 2019. DOI: 10.1126/sciimmunol.aay7501

This study was supported by the National Institutes of Health (NIH), grant numbers AI095542, DE025884, AI134236, AI134035, MH092769, K99 DK118110, and T32 GM007200; Pfizer; Crohn’s & Colitis Foundation; and anonymous donors.

Washington University School of Medicine’s 1,500 faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is a leader in medical research, teaching and patient care, ranking among the top 10 medical schools in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.

Tamara covers infectious diseases, molecular microbiology, neurology, neuroscience, surgery, the Institute for Informatics, the Division of Physician-Scientists and the MSTP program. She holds a double bachelor's degree in molecular biophysics & biochemistry and in sociology from Yale University, a master's in public health from the University of California, Berkeley, and a PhD in biomedical science from the University of California, San Diego. She joined WashU Medicine Marketing & Communications in 2016. She has received three Robert G. Fenley writing awards from the American Association of Medical Colleges: a bronze in 2020 for "Mind’s quality control center found in long-ignored brain area," a silver in 2022 for "Mice with hallucination-like behaviors reveal insight into psychotic illness," and a bronze in 2023 for "Race of people given Alzheimer’s blood tests may affect interpretation of results." Since January of 2024, Tamara has been writing under the name Tamara Schneider.