Intestinal surface cells pull rather than push

(Press-News.org) Cells on the inner surface of the intestine are replaced every few days. But, how does this work? It was always assumed that cells leave the intestinal surface because excess cells are pushed out. In a recent publication in the journal Science, researchers of the Hubrecht Institute and AMOLF show that this is not correct. In reality, the situation is exactly the opposite: the cells do not push, but pull at each other. These pulling forces lead to the removal of the weakest cells. This insight gives a new perspective on how a malfunctioning intestine can lead to disease or infection.

Pulling rather than pushing

The general idea was as follows: old and malfunctioning cells in the intestinal surface move to the exit like packages on a conveyor belt in a distribution center. Cells push each other out as they accumulate.

It turns out to be different. Researchers Daniel Krueger and Kasper Spoelstra show that the cells are not under pressure, but under tension. This tension arises from cells pulling at each other. This is comparable to a game of tug of war, but then played by cells and their neighbors. This tug of war game turns out to be essential to determine which cells are the weakest, and therefore need to leave the intestine.

Organoids

To get to these new insights, the research groups of Hans Clevers (Hubrecht Insitute), Sander Tans (AMOLF) and Jeroen van Zon (AMOLF) work with so-called intestinal organoids. These are miniature versions of the intestine grown in the lab. One of the advantages of these organoids is that the researchers can easily manipulate and study them under a microscope.  

Weak cells are out

Pulling forces exerted by cells on one another are essential for proper intestinal function. Cells that cannot generate sufficient pulling forces are removed from the intestine. These cells form a risk of improper closure of the barrier between the inside and outside of the intestines, which can lead to inflammation.

Experiments

Researchers Daniel and Kasper influenced the tug of war game played by cells in the organoids in different ways. Firstly, they conducted a series of experiments making cells weaker or stronger by manipulating them with light or by genetic manipulation. Whenever they combined stronger and weaker cells in one organoid, they noticed that weaker cells disappeared much more often from the organoid than stronger cells. Secondly, they conducted experiments weakening individual cells with a laser. Cells weakened in this manner tended to be extruded within one hour. Both experiments show that whenever cells are weaker than their neighbors – and are therefore losing the tug of war game – they are quickly removed from the intestine.

A closer look at intestinal diseases

Pulling forces between cells in the intestinal surface also have medical consequences. The researchers also studied organoids with a genetic abnormality for the disease congenital tufting enteropathy. This disease has a negative effect on the development of the intestinal surface in newborns, sometimes leading to irreparable damage to the intestine. The researchers demonstrated that cells with this particular genetic abnormality show a disrupted tug of war behavior; they are exerting too much pulling force on each other.

Now that it is clear that cells leave the intestinal surface because of their ability to exert pulling forces, the researchers expect that follow-up studies will be conducted using tissue from patients with intestinal abnormalities, and also on forces between cells in other organs.  

This research was a collaboration between the Hubrecht Institute, AMOLF and the Institute of Human Biology.

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About Hans Clevers
Hans Clevers is distinguished group leader at the Hubrecht Institute. He is group leader at the Princess Máxima Center for Pediatric Oncology, professor in Molecular Genetics at Utrecht University and Investigator at Oncode Institute. Hans Clevers was the Head of pharma Research and Early Development (pRED) at Roche from 2022 to 2025. He previously held directorship/President positions at the Hubrecht Institute, the Royal Netherlands Academy of Arts and Sciences and the Princess Máxima Center for pediatric oncology.

About the Hubrecht Institute
The Hubrecht Institute is a research institute focused on molecular and developmental biology. Because of the dynamic character of the research, the institute has a variable number of research groups, around 20, that do fundamental, multidisciplinary research on healthy and diseased cells, tissues and organisms. The Hubrecht Institute is a research institute of the Royal Netherlands Academy of Arts and Sciences (KNAW), situated on Utrecht Science Park. Since 2008, the institute is affiliated with the UMC Utrecht, advancing the translation of research to the clinic. The Hubrecht Institute has a partnership with the European Molecular Biology Laboratory (EMBL). For more information, visit www.hubrecht.eu. 

About AMOLF
AMOLF is a research institute located in Amsterdam, the Netherlands. AMOLF’s mission is to initiate and perform leading fundamental research on the physics of complex forms of matter, and to create new functional materials, in partnership with academia and industry. AMOLF is part of the institutes organisation of NWO. For more information, visit www.amolf.nl.

 

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