New findings about human metabolic processes

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See text for image caption. Source: Anna Köttgen/University of Freiburg
See text for image caption. Source: Anna Köttgen/University of Freiburg
Freiburg researchers discover numerous undescribed metabolic processes and their genes by comparing metabolic products in urine and blood

Researchers at the Faculty of Medicine at the University of Freiburg have gained significant new insights into metabolic processes in the kidney. The scientists from the Institute of Genetic Epidemiology at the Medical Center - University of Freiburg measured tiny molecules, so-called metabolites, which occur in blood and urine and reflect our metabolism, in samples from more than 5,000 study participants. They compared these with the genome of the test persons and were able to identify 1,299 genetic changes that are associated with metabolites and contribute to their production, degradation or transport. The findings provide a better understanding of processes throughout the body and particularly in the kidney, which produces urine from blood plasma. These discoveries, which appeared June 5, 2023, in the journal Nature Genetics, could lead to a better understanding of diseases and new approaches to their treatment. For example, a new class of therapies for treating diabetes, called SGLT2 inhibitors, work by inhibiting a metabolite transporter in the kidney.

"This study opens up new insights into metabolism and its links to health. It provides valuable information that could help us to better understand diseases and thus provide a basis for new treatment options," says Anna Köttgen , Director of the Institute of Genetic Epidemiology at the Medical Center - University of Freiburg and spokesperson of the Collaborative Research Center 1453 "Nephrogenetics" at the University of Freiburg, which supported the study’s research. Köttgen is also a member of the Cluster of Excellence CIBSS - Centre for Integrative Biological Signalling Studies at the University of Freiburg.

Integration of blood plasma and urine analyses yielded important findings

Conducting such a large-scale association study presented special challenges. The researchers had to analyse large amounts of data and understand complex genetic relationships. First author Dr. Pascal Schlosser from the Faculty of Medicine at the University of Freiburg and the Institute of Genetic Epidemiology at the Medical Center - University of Freiburg explains: "In particular, the comparison of metabolites from plasma and urine samples and their genetic basis, which is known as multi-matrix analysis, is very time-consuming. However, it offers the possibility of distinguishing whether certain metabolic changes occur primarily in the kidney itself or are distributed throughout the body. Moreover, in this way we were able to observe a much larger part of human metabolic processes than from the mere study of blood."

Kidney enzyme also relevant in hypertension and osteoarthritis

Among other things, the researchers were able to show that the enzyme DPEP1 not only has important functions in the kidney, but is also operating in different parts of the body. For example, increased activity of DPEP1 was associated with a higher risk of osteoarthritis, but at the same time with a lower risk of hypertension. "Our findings may therefore help us to consider potential side effects of new drugs already during their development process," says first author Nora Scherer , also from the Institute of Genetic Epidemiology at the Medical Center - University of Freiburg.

Overview of facts:

Original publication: Schlosser, Pascal, Scherer, Nora, et al.: Genetic studies of paired metabolomes reveal enzymatic and transport processes at the interface of plasma and urine. In: Nature Genetics, June 2023 DOI: 10.1038/s41588’023 -01409-8

Anna Köttgen heads the Institute für Genetic Epidemiology at the Medical Center - University of Freiburg and is spokesperson for the Collaborative Research Center 1453 "Nephrogenetics" at the University of Freiburg that supported the study’s research.

Using genome-wide analysis, the researchers identified 1,299 genetic alterations that impact on metabolites in blood plasma and urine. Shown here are the 282 gene locations where enzymes and transporter proteins that influence metabolism are located. Image: Anna Köttgen/Universität Freiburg