APA
Martínez, Natalia & Gragera Alía, Teresa & de Lucas, María Pilar & Cámara, Ana Belén & Ballester, Alicia & Anta, Berta & Fernández Medarde, Alberto & López Briones, Tania & Ortega, Judith & Peña Jimenez, Daniel & Barbáchano, Antonio & Montero Calle, Ana & Cordero, Víctor & Barderas, Rodrigo & Iglesias, Teresa & Yunta González, Mónica & Oliva, José Luís & Muñoz, Alberto & Santos, Eugenio & Zarich, Natasha & Rojas Cabañero, José M. (2023-04 ) .PKD phosphorylation and COP9/Signalosome modulate intracellular Spry2 protein stability.
ISO 690
Martínez, Natalia & Gragera Alía, Teresa & de Lucas, María Pilar & Cámara, Ana Belén & Ballester, Alicia & Anta, Berta & Fernández Medarde, Alberto & López Briones, Tania & Ortega, Judith & Peña Jimenez, Daniel & Barbáchano, Antonio & Montero Calle, Ana & Cordero, Víctor & Barderas, Rodrigo & Iglesias, Teresa & Yunta González, Mónica & Oliva, José Luís & Muñoz, Alberto & Santos, Eugenio & Zarich, Natasha & Rojas Cabañero, José M.. 2023-04 .PKD phosphorylation and COP9/Signalosome modulate intracellular Spry2 protein stability.
https://hdl.handle.net/20.500.12080/39619
Résumé:
Spry2 is a molecular modulator of tyrosine kinase receptor signaling pathways that has cancer-type-specific effects. Mammalian
Spry2 protein undergoes tyrosine and serine phosphorylation in response to growth factor stimulation. Spry2 expression is
distinctly altered in various cancer types. Inhibition of the proteasome functionality results in reduced intracellular Spry2
degradation. Using in vitro and in vivo assays, we show that protein kinase D (PKD) phosphorylates Spry2 at serine 112 and
interacts in vivo with the C-terminal half of this protein. Importantly, missense mutation of Ser112 decreases the rate of Spry2
intracellular protein degradation. Either knocking down the expression of all three mammalian PKD isoforms or blocking their
kinase activity with a specific inhibitor contributes to the stabilization of Spry2 wild-type protein. Downregulation of CSN3, a
component of the COP9/Signalosome that binds PKD, significantly increases the half-life of Spry2 wild-type protein but does not
affect the stability of a Spry2 after mutating Ser112 to the non-phosphorylatable residue alanine. Our data demonstrate that both
PKD and the COP9/Signalosome play a significant role in control of Spry2 intracellular stability and support the consideration of the
PKD/COP9 complex as a potential therapeutic target in tumors where Spry2 expression is reduced.