CNRS researchers at the Institut Curie have recently shown that cancer cells use a membrane protein that has been known for several decades to internalise iron. Published in Nature Chemistry (August 3rd, 2020), this work shows that the absorbed iron allows cancer cells to acquire metastatic properties.
Biologists knew CD44 well, but didn’t know the major biological function that it fulfils. CD44 is a glycoprotein found on the surface of many cells, in various organs, that is also involved in several biological processes: immune response, inflammation and cancer, among others. For the first time, a research team has shown that it participated in these phenomena by allowing iron to enter cells through endocytosis.
Scientists at the Laboratoire Chimie et Biologie de la Cellule (CNRS/INSERM/Institut Curie) and their colleagues1 reached this conclusion by studying CD44’s activity in cancer cells, and the resulting changes to metabolism and genetic expression.
Their results show that CD44 can internalise iron bound to hyaluronic acid. For cancer cells, the iron then fulfils two roles: it supplies the mitochondria so that it can produce metabolites necessary for the cell to pass into a metastatic state and epigenetically “unlocks” certain genes that are also necessary to the metastatic process. In that state, CD44 even becomes the main pathway for iron to enter cells.
These observations explain why CD44 was already known for its association with the appearance of metastases and relapses. But they are also surprising because until now biologists thought that a different mechanism was involved in iron endocytosis, involving transferrin and its TfR1 receptor. The research team now hopes to develop molecules capable of blocking cellular iron traffic to eliminate cells with high metastatic potential.
This research received financial support from ERC Consolidator and labelling from the Ligue Contre le Cancer and Fondation Charles Defforey – Institut de France.
CD44 regulates epigenetic plasticity by mediating iron endocytosis, Sebastian Müller, Fabien Sindikubwabo, Tatiana Cañeque, Anne Lafon, Antoine Versini, Bérangère Lombard, Damarys Loew, Ting-Di Wu, Christophe Ginestier, Emmanuelle Charafe-Jauffret, Adeline Durand, Céline Vallot, Sylvain Baulande, Nicolas Servant, Raphaël Rodriguez. Nature Chemistry, 3 August 2020. DOI:10.1038/s41557-020-0513-5
Notes
1. Researchers at the Centre de Recherche en Cancérologie de Marseille (CNRS/INSERM/Institut Paoli Calmettes/Aix-Marseille Université), the Laboratoire Dynamique de l'Information Génétique: Bases Fondamentales et Cancer (CNRS/Sorbonne Université/Institut Curie), the Laboratoire Cancer et Génome: Bioinformatique, Biostatistiques et Epidémiologie des Systèmes Complexes (INSERM/Mines Paristech/Institut Curie), the Plateforme de Séquençage Haut Débit ICGex (Institut Curie) and the Laboratoire de Spectrométrie de Masse et Protéomique (Institut Curie) also participated in this work.
Source: CNRS