JULY 17, 2024
by University of Geneva
Lack of hepatic GDH induces phase advance of the circadian rhythm of respiratory exchange ratio (RER), which is exacerbated by high protein diet. Credit: Journal of Biological Chemistry (2024). DOI: 10.1016/j.jbc.2024.107473
High-protein diets, known as paleolithic diets, are popular. Using mouse models, scientists at the University of Geneva (UNIGE) have studied their impact. While effective in regulating weight and stabilizing diabetes, these diets are not without risks.
Excess protein greatly increases ammonium production, overwhelming the liver. Excess ammonium can cause neurological disorders and, in severe cases, lead to coma. These results, published in the Journal of Biological Chemistry, suggest caution when following these diets.
Type 2 diabetes is a metabolic disease that is constantly increasing. Due to a sedentary lifestyle and an excessively rich diet, the damaged pancreas struggles to regulate blood sugar levels. While current treatments help control the progression of the disease, they do not cure diabetes. Losing weight is often an essential part of the treatment.
“Diets rich in animal and/or plant proteins, known as paleolithic diets, can be used to stabilize type 2 diabetes and regulate weight,” explains Pierre Maechler, full professor at the Department of Cell Physiology and Metabolism at the UNIGE Faculty of Medicine, who led this research.
These diets are inspired by the meat-based diets of pre-agricultural time. “But what impact do they have on the body? Are they harmless? That’s what we set out to find out.”
Liver under pressure
Ammonium is a normal waste product of protein breakdown, essentially eliminated in the liver by the enzyme glutamate dehydrogenase (GDH). In the event of protein overload, the GDH enzyme comes under pressure. To study the impact of high-protein diets, Pierre Maechler’s team fed healthy mice and mice lacking the GDH enzyme in their liver a diet with a protein content mimicking the so-called paleolithic diet.
Scientists observed that in healthy mice, although excess protein increased ammonium production, the liver managed this excess due to the action of the GDH enzyme, which detoxifies ammonium before it can cause damage.
“In contrast, in mice lacking the GDH enzyme, the liver is unable to eliminate the excess of toxic ammonium derived from proteins. No need to wait for weeks or months; a change of diet lasting a few days is enough to observe major consequences,” explains Karolina Luczkowska, a former Ph.D. student at the Department of Cell Physiology and Metabolism at the UNIGE Faculty of Medicine, and the study’s first author.
Caution is advised
These results suggest that in case of dysfunctional GDH enzyme, high-protein diets may cause a harmful excess of ammonium. Ammonium not eliminated by the liver can cause severe disorders, particularly neurological ones. A blood test could assess GDH activity to avoid overloading the metabolism with proteins in people whose GDH enzyme is deficient. “It is therefore important to be well informed before following a high-protein diet,” concludes Maechler.
More information: Karolina Luczkowska et al, Dietary protein load affects the energy and nitrogen balance requiring liver glutamate dehydrogenase to maintain physical activity, Journal of Biological Chemistry (2024). DOI: 10.1016/j.jbc.2024.107473
Journal information: Journal of Biological Chemistry
Provided by University of Geneva
Leave a Reply