Cellular transporter protein essential for nutrient absorption in pathogenic fungi may offer new treatment approaches
They are the cell's "gatekeepers": specialized proteins, known as transporters, selectively control which substances enter a cell and which do not. Researchers at the University of Münster and the National and Kapodistrian University of Athens have investigated these transporters in a specific case: the UapA transporter of the model fungus Aspergillus nidulans. The findings are not only relevant to cell biology but could also offer new approaches to treating fungal infections.
These transporters are essential for pathogenic fungal species to bring important nutrients into the cell. Of particular relevance is the fact that homologous transporters are found in humans. These are responsible for the co-transport of vitamin C and sodium ions. Research into the UapA transporter of the model fungus can therefore also provide insights into the structure and function of human transporters.
It is also important to note that several Aspergillus species are pathogens capable of causing severe, life-threatening infections in immunocompromised individuals. "Investigating and understanding these transport processes is therefore of particular biomedical significance," emphasizes Prof. Christos Gatsogiannis, who is leading the research at the University of Münster with his team.
Their research findings, published in the Proceedings of the National Academy of Sciences, suggest that UapA functions via a specialized "elevator-type" transport mechanism. In this mechanism, the protein consists of a relatively rigid scaffold domain (the "shaft"), which is embedded in the membrane, and a mobile transport domain (the "elevator"), which binds the substrate. During transport, this "elevator" moves along the scaffold, carrying the substrate from the outside of the cell into the cytoplasm.
This process requires precise coordination with membrane lipids and surrounding water molecules. Until now, the molecular basis of this process was poorly understood due to a lack of structural information.
With its new study, the research team has made a significant advance in elucidating this transport mechanism. The research group led by Prof. Gatsogiannis at the Institute of Medical Physics and Biophysics and the Center for Soft Nanoscience at the University of Münster achieved a decisive breakthrough: Using state-of-the-art cryo-electron microscopy, they succeeded in imaging UapA in two different states.
The structures were determined at an exceptional resolution of 2.05 Å—one of the highest resolutions ever achieved for a eukaryotic membrane transporter. This level of detail allows the visualization of the protein's architecture, as well as individual water molecules and the surrounding membrane lipids.
One of the most striking findings concerns the N-terminal region of the protein: Until now, it was assumed that this region had no fixed structure. However, the new data show that the region fulfills a dual function: It helps the transporter fold correctly and reach the cell surface. It also plays a role in regulating how the transporter functions.
The findings are fully consistent with genetic and functional studies carried out by the research group led by Prof. George Diallinas at the Institute of Biology, National and Kapodistrian University of Athens. They thus expand our understanding of how UapA functions. Antifungal drugs—that is, medicines used to treat fungal infections—can use transporters such as UapA to enter fungal cells. A deeper understanding of their structure and function could therefore contribute to the development of new therapeutic strategies against fungal infections.
Publication details
George Broutzakis et al, Cryo-EM of the eukaryotic purine transporter UapA demonstrates intramolecular and lipid regulation of transport, Proceedings of the National Academy of Sciences (2026). DOI: 10.1073/pnas.2513585123
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Citation: Cellular transporter protein essential for nutrient absorption in pathogenic fungi may offer new treatment approaches (2026, July 16) retrieved 16 July 2026 from https://phys.org/news/2026-07-cellular-protein-essential-nutrient-absorption.html
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