Staying in touch!

November 06, 2020

For our cells to assemble into tissues and whole organs, the extracellular ma-trix (ECM) as well as the integrins are required. The ECM forms a kind of extra-cellular protein meshwork, the integrins are surface proteins, which our cells use to attach to this extracellular support structure. How human cells balance attachment to versus detachment from the ECM is a yet unsolved question. The research team led by Professor Christof Hauck in the Department of Biolo-gy at the University of Konstanz, now identified a key enzyme, PPM1F, which regulates the integrins' detachment from the ECM. The results have been pub-lished in the online edition of the Journal of Cell Biologyhttps://doi.org/10.1083/jcb.202001057.

The ECM mainly consists of a network of protein fibres such as collagen and other filamentous extracellular proteins. In order to adhere to this meshwork, nearly every human cell possesses surface proteins termed integrins. Integrins operate like mo-lecular carabiners that lock the cells to the network of collagen fibres or other ECM proteins and thus provide a strong focal point of attachment for the cell. However, cells in our body do not always stay in place, but sometimes need to migrate over long distances to their final destination - just think of immune cells that have to travel from the lymph node to a skin wound. As a solution, nature provided integrins with special features.

Like a sailor in the ship's rigging

Integrins are peculiar, because they can be repeatedly folded over and extended: When folded over, integrins cannot connect to the ECM, as the carabiner is buried. Upon extension of the integrin, the carabiner is exposed and can lock the cell to the ECM. Interestingly, cells can extend integrins at the front end of the cell, while they fold over their integrins at the rear and detach from the ECM at these positions. Cy-cles of integrin-mediated "gripping and let loose" allow cells to move in the protein meshwork of the extracellular matrix like a sailor climbs in the ship's rigging. Integrins consist of two parts, the α- and the β-subunit. Both subunits traverse the cell mem-brane, so that a small part of the protein is inside the cell, but the larger portion, the actual carabiner, is outside of the cell. It has been known for some time that the ex-tension of the integrin is initiated by the integrin β-subunit: In particular, the protein talin initially binds to the intracellular part of the β-subunit and triggers integrin exten-sion and thus the activation of the carabiner.

Without phosphorylation the carabiner hook remains buried

Tanja Grimm and Nina Dierdorf, doctoral researchers at the Konstanz Research School Chemical Biology have discovered that the β-subunit is being marked for talin binding by a small chemical modification, a so-called phosphorylation. This phos-phorylation works like a switch: Upon phosphorylation, talin can bind and the integrin is extended. If phosphorylation does not take place or if this position in the integrin is mutated, talin does not associate and the carabiner remains buried. Consequently, the cells lose their grip. Moreover, the doctoral researchers now showed for the first time that a single enzyme is responsible for reversing the phosphorylation of the integrin β-subunit: the protein phosphatase PPM1F. This enzyme can remove the phosphorylation and thus trigger the integrins to fold over. The PPM1F-regulated "phosphorylation switch" in the integrin seems to be essential, because in the absence of PPM1F, embryonic development, when different cell types have to arrange themselves into functioning tissues, terminates prematurely. Isolated cells, in which the PPM1F gene is disrupted, show enhanced attachment to the extracellular matrix and can hardly move, as they are unable to release integrin-based matrix contacts.

Does less cell adhesion allow uncontrolled migration?

The researchers now hope that this knowledge can be used in the future to specifi-cally control PPM1F activity and thus the functionality of integrins. In some tumour cells, this phosphatase appears to be particularly abundant, and the resulting reduced adhesion of such tumour cells could be one of the reasons, why they are able to leave the primary tumour and form metastases at distant body sites.

"In the next step, we want to learn how to manipulate the phosphorylation switch and thus the function of integrins," says Tanja Grimm, first author of the study. "We might be able to specifically influence integrin-dependent processes in our body, from im-mune cell movement to tumour metastasis. With these novel findings we might help our cells to firmly stay in touch with their surrounding and prevent them straying away for the worse".

Key facts:
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Note to editors:

An image is available here:
https://cms.uni-konstanz.de/fileadmin/pi/fileserver/2020/Bilder/bloss_nicht.png

Caption:
The pictured cell originated from a malignant brain tumour. Upon removal of PPM1F, the cell can no longer detach from the ECM. It shows numerous matrix contacts, which contain the active, extended integrin carabiner (coloured in the yellow-green dots and the continuous ring). Because of the strong adhesion to the extracellular matrix, this cell can hardly move.
Image: Tanja Grimm, University of Konstanz

University of Konstanz

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