TY - JOUR
T1 - Mechanisms of site-specific dephosphorylation and kinase opposition imposed by PP2A regulatory subunits
AU - Kruse, Thomas
AU - Gnosa, Sebastian Peter
AU - Nasa, Isha
AU - Garvanska, Dimitriya Hristoforova
AU - Hein, Jamin B.
AU - Nguyen, Hieu
AU - Samsøe-Petersen, Jacob
AU - Lopez-Mendez, Blanca
AU - Hertz, Emil Peter Thrane
AU - Schwarz, Jeanette
AU - Pena, Hanna Sofia
AU - Nikodemus, Denise
AU - Kveiborg, Marie
AU - Kettenbach, Arminja N.
AU - Nilsson, Jakob
PY - 2020
Y1 - 2020
N2 - PP2A is an essential protein phosphatase that regulates most cellular processes through the formation of holoenzymes containing distinct regulatory B-subunits. Only a limited number of PP2A-regulated phosphorylation sites are known. This hampers our understanding of the mechanisms of site-specific dephosphorylation and of its tumor suppressor functions. Here, we develop phosphoproteomic strategies for global substrate identification of PP2A-B56 and PP2A-B55 holoenzymes. Strikingly, we find that B-subunits directly affect the dephosphorylation site preference of the PP2A catalytic subunit, resulting in unique patterns of kinase opposition. For PP2A-B56, these patterns are further modulated by affinity and position of B56 binding motifs. Our screens identify phosphorylation sites in the cancer target ADAM17 that are regulated through a conserved B56 binding site. Binding of PP2A-B56 to ADAM17 protease decreases growth factor signaling and tumor development in mice. This work provides a roadmap for the identification of phosphatase substrates and reveals unexpected mechanisms governing PP2A dephosphorylation site specificity and tumor suppressor function.
AB - PP2A is an essential protein phosphatase that regulates most cellular processes through the formation of holoenzymes containing distinct regulatory B-subunits. Only a limited number of PP2A-regulated phosphorylation sites are known. This hampers our understanding of the mechanisms of site-specific dephosphorylation and of its tumor suppressor functions. Here, we develop phosphoproteomic strategies for global substrate identification of PP2A-B56 and PP2A-B55 holoenzymes. Strikingly, we find that B-subunits directly affect the dephosphorylation site preference of the PP2A catalytic subunit, resulting in unique patterns of kinase opposition. For PP2A-B56, these patterns are further modulated by affinity and position of B56 binding motifs. Our screens identify phosphorylation sites in the cancer target ADAM17 that are regulated through a conserved B56 binding site. Binding of PP2A-B56 to ADAM17 protease decreases growth factor signaling and tumor development in mice. This work provides a roadmap for the identification of phosphatase substrates and reveals unexpected mechanisms governing PP2A dephosphorylation site specificity and tumor suppressor function.
KW - ADAM17
KW - phosphoproteomics
KW - PP2A
KW - substrate specificity
KW - tumor suppressor
U2 - 10.15252/embj.2019103695
DO - 10.15252/embj.2019103695
M3 - Journal article
C2 - 32400009
AN - SCOPUS:85084413673
VL - 39
JO - E M B O Journal
JF - E M B O Journal
SN - 0261-4189
M1 - e103695
ER -