Metabolic requirements vary during development, and our understanding of how metabolic activity influences cell specialization is incomplete. Here, we describe a switch from glutamine catabolism to synthesis required for erythroid cell maturation. Glutamine synthetase (GS), one of the oldest functioning genes in evolution, is activated during erythroid maturation to detoxify ammonium generated from heme biosynthesis, which is up-regulated to support hemoglobin production. Loss of GS in mouse erythroid precursors caused ammonium accumulation and oxidative stress, impairing erythroid maturation and recovery from anemia. In β-thalassemia, GS activity is inhibited by protein oxidation, leading to glutamate and ammonium accumulation, whereas enhancing GS activity alleviates the metabolic and pathological defects. Our findings identify an evolutionarily conserved metabolic adaptation that could potentially be leveraged to treat common red blood cell disorders.
A glutamine metabolic switch supports erythropoiesis / J. Lyu, Z. Gu, Y. Zhang, H.S. Vu, C. Lechauve, F. Cai, H. Cao, J. Keith, V. Brancaleoni, F. Granata, I. Motta, M.D. Cappellini, L.J. Huang, R.J. Deberardinis, M.J. Weiss, M. Ni, J. Xu. - In: SCIENCE. - ISSN 0036-8075. - 386:6723(2024 Nov 15), pp. eadh9215.1-eadh9215.15. [10.1126/science.adh9215]
A glutamine metabolic switch supports erythropoiesis
I. Motta;M.D. Cappellini;
2024
Abstract
Metabolic requirements vary during development, and our understanding of how metabolic activity influences cell specialization is incomplete. Here, we describe a switch from glutamine catabolism to synthesis required for erythroid cell maturation. Glutamine synthetase (GS), one of the oldest functioning genes in evolution, is activated during erythroid maturation to detoxify ammonium generated from heme biosynthesis, which is up-regulated to support hemoglobin production. Loss of GS in mouse erythroid precursors caused ammonium accumulation and oxidative stress, impairing erythroid maturation and recovery from anemia. In β-thalassemia, GS activity is inhibited by protein oxidation, leading to glutamate and ammonium accumulation, whereas enhancing GS activity alleviates the metabolic and pathological defects. Our findings identify an evolutionarily conserved metabolic adaptation that could potentially be leveraged to treat common red blood cell disorders.
| File | Dimensione | Formato | |
|---|---|---|---|
|
science.adh9215.pdf
accesso riservato
Descrizione: Research Article
Tipologia:
Publisher's version/PDF
Dimensione
2.64 MB
Formato
Adobe PDF
|
2.64 MB | Adobe PDF | Visualizza/Apri Richiedi una copia |
Pubblicazioni consigliate
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
