SLC25A51 regulates the transport of the coenzyme NAD into the mitochondria
For their growth, cells need various nutrients and vitamins. So-called solute carriers (SLC), proteins that can transport such substances across the boundaries of cellular membranes, play a central role in metabolism. Scientists in Giulio Superti-Furga’s research group at the CeMM have now discovered that the previously uncharacterised protein SLC25A51 acts as a transporter into the mitochondria for the coenzyme NAD. The results of this study not only open up new possibilities to study the biological role of NAD but also potentially provide the basis for new therapeutic approaches. The work has now been published in the journal Nature Communications.
Solute carriers (SLC) are proteins that act as transporters and enable the entry and exit of nutrients and waste products into and from the cell and its organelles. Many of these transporter proteins are still relatively poorly studied and the question of how some nutrients enter and leave cells often remains unanswered. So far, it has not yet been clarified how mitochondria gain access to an important cofactor of our metabolism, the so-called NAD (nicotinamide adenine dinucleotide). In scientific literature, there were only references to mitochondrial NAD transporters in plants and yeast. Lead author Enrico Girardi and the research group of CeMM Scientific Director Giulio Superti-Furga, in cooperation with scientists from the University of Bari (Italy), have now identified the protein responsible for the important transport of NAD into mitochondria: SLC25A51.
Measurement of nutrient pathways provided evidence
For their studies, the scientists used a specially created cell line library, which allows investigating pairwise genetic interactions of two SLCs. Their genes are deactivated both individually and in pairs; the effects of these interventions on cell growth can then be measured. Among the combination-related large number of interactions measured, some around the previously uncharacterised gene SLC25A51 stood out. The other interacting SLCs transport various nutrients, but all of them could be associated with NAD via known metabolic processes. “By accurately quantitatively measuring certain nutrients in the cells, we found that the presence of SLC25A51 correlated with the amount of NAD and that cells lacking SLC25A51 had extremely low levels of this molecule in their mitochondria,” explains senior author Giulio Superti-Furga. “In our study we also show that the already known NAD transporter in yeast and SLC25A51 play a similar role in the human cell.”
Important part of the scientific puzzle
The question of the existence of a mitochondrial NAD transporter in humans has been discussed for some time. Giulio Superti-Furga also explains: “The results of our research, which have also been confirmed in two other independent studies by US laboratories, provide an important answer to this question and open up the opportunity of influencing the NAD content in this key organelle. NAD is associated with many physiological and pathological processes such as ageing, neurological diseases and the metabolism of cancer cells. Our study therefore represents an important contribution to understanding the biological role of this molecule. At the same time, we also see the enormous therapeutic potential arising from the possibility of a possible modulation of the NAD content in mitochondria by the transporter SLC25A51.”
Attached pictures: Last author Giulio Superti-Furga and first author Enrico Girardi (© Klaus Pichler / CeMM);
The study „Epistasis-driven identification of SLC25A51 as a regulator of human mitochondrial NAD import“ was published in Nature Communications on 1 December 2020. DOI: 10.1038/s41467-020-19871-x
Authors: Enrico Girardi, Gennaro Agrimi, Ulrich Goldmann, Giuseppe Fiume, Sabrina Lindinger, Vitaly Sedlyarov, Ismet Srndic, Bettina Gürtl, Benedikt Agerer, Felix Kartnig, Pasquale Scarcia, Maria Antonietta Di Noia, Eva Liñeiro, Manuele Rebsamen, Tabea Wiedmer, Andreas Bergthaler, Luigi Palmieri, Giulio Superti-Furga
Funding: The study was funded with support by the Austrian Academy of Sciences, the European Research Council (ERC) (AdG 695214, StG 677006) and the Austrian Science Fund (FWF P29250-B30, FWF DK W1212)
Giulio Superti-Furga is Scientific Director of CeMM, and Professor of Medical Systems Biology at the Medical University of Vienna. He was trained as a molecular biologist at the University of Zurich, Genentech, IMP Vienna and EMBL Heidelberg. He obtained four grants from the European Research Council, is a member of five scientific academies, and has published more than 200 papers. CeMM, which he has been directing since 2005, is located in the middle of the large general hospital campus in Vienna, where, together with some 180 scientists and medical doctors, he brings genomic and systems views close to the clinical world with a view to improving medical practice. For CeMM, he promoted a unique mode of super-cooperation, connecting biology with medicine, experiments with computation, discovery with translation, and science with society and the arts. Recent interests include ways to create functional precision medicine approaches and the role of the human transportome in pathophysiology and drug discovery. He is the scientific coordinator of the Innovative Medicine Initiative consortium “RESOLUTE”, dedicated to the deorphanization of SLC transporters.
The mission of CeMM Research Center for Molecular Medicine of the Austrian Academy of Sciences is to achieve maximum scientific innovation in molecular medicine to improve healthcare. At CeMM, an international and creative team of scientists and medical doctors pursues free-minded basic life science research in a large and vibrant hospital environment of outstanding medical tradition and practice. CeMM’s research is based on post-genomic technologies and focuses on societally important diseases, such as immune disorders and infections, cancer and metabolic disorders. CeMM operates in a unique mode of super-cooperation, connecting biology with medicine, experiments with computation, discovery with translation, and science with society and the arts. The goal of CeMM is to pioneer the science that nurtures the precise, personalized, predictive and preventive medicine of the future. CeMM trains a modern blend of biomedical scientists and is located at the campus of the General Hospital and the Medical University of Vienna. www.cemm.oeaw.ac.at
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The study “Epistasis-driven identification of SLC25A51 as a regulator of human mitochondrial NAD import” was published in Nature Communications on 1 December 2020. DOI: 10.1038/s41467-020-19871-x