Details

Autor(en) / Beteiligte

• Mattè, Alessandro
• Lupo, Francesca
• Tibaldi, Elena
• Di Paolo, Maria Luisa
• Federti, Enrica
• Carpentieri, Andrea
• Pucci, Piero
• Brunati, Anna Maria
• Cesaro, Luca
• Turrini, Francesco
• Gomez Manzo, Saul
• Choi, Soo Young
• Marcial Quino, Jaime
• Kim, Dae Won
• Pantaleo, Antonella
• Xiuli, An
• Iatcenko, Iana
• Cappellini, Maria Domenica
• Forni, Gian Luca
• De Franceschi, Lucia

Titel

Fyn specifically Regulates the activity of red cell glucose-6-phosphate-dehydrogenase

Ist Teil von

• Redox biology, 2020-09, Vol.36, p.101639, Article 101639

Ort / Verlag

Netherlands: Elsevier B.V

Erscheinungsjahr

2020

Link zum Volltext

Quelle

MEDLINE

Beschreibungen/Notizen

• Fyn is a tyrosine kinase belonging to the Src family (Src-Family-Kinase, SFK), ubiquitously expressed. Previously, we report that Fyn is important in stress erythropoiesis. Here, we show that in red cells Fyn specifically stimulates G6PD activity, resulting in a 3-fold increase enzyme catalytic activity (kcat) by phosphorylating tyrosine (Tyr)-401. We found Tyr-401 on G6PD as functional target of Fyn in normal human red blood cells (RBC), being undetectable in G6PD deficient RBCs (G6PD-Mediterranean and G6PD-Genova). Indeed, Tyr-401 is located to a region of the G6PD molecule critical for the formation of the enzymatically active dimer. Amino acid replacements in this region are mostly associated with a chronic hemolysis phenotype. Using mutagenesis approach, we demonstrated that the phosphorylation status of Tyr401 modulates the interaction of G6PD with G6P and stabilizes G6PD in a catalytically more efficient conformation. RBCs from Fyn-/−mice are defective in G6PD activity, resulting in increased susceptibility to primaquine-induced intravascular hemolysis. This negatively affected the recycling of reduced Prx2 in response to oxidative stress, indicating that defective G6PD phosphorylation impairs defense against oxidation. In human RBCs, we confirm the involvement of the thioredoxin/Prx2 system in the increase vulnerability of G6PD deficient RBCs to oxidation. In conclusion, our data suggest that Fyn is an oxidative radical sensor, and that Fyn-mediated Tyr-401 phosphorylation, by increasing G6PD activity, plays an important role in the physiology of RBCs. Failure of G6PD activation by this mechanism may be a major limiting factor in the ability of G6PD deficient RBCs to withstand oxidative stress. [Display omitted] •In red cells, Fyn acts as an oxidative sensor.•Fyn specifically stimulates G6PD activity by phosphorylating tyrosine (Tyr)-401.•In Fyn-/-mice, failure of G6PD activation increases red cell vulnerability against oxidation.•Fyn targeting G6PD protects Prx2 recycling, which is required to remove peroxides.