Activating PRKACB somatic mutation in cortisol-producing adenomas
Stéphanie Espiard, … , Constantine A. Stratakis, Jérôme Bertherat
Stéphanie Espiard, … , Constantine A. Stratakis, Jérôme Bertherat
Published April 19, 2018
Citation Information: JCI Insight. 2018;3(8):e98296. https://doi.org/10.1172/jci.insight.98296.
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Research Article Endocrinology Genetics

Activating PRKACB somatic mutation in cortisol-producing adenomas

Abstract

Mutations in the gene encoding the protein kinase A (PKA) catalytic subunit α have been found to be responsible for cortisol-producing adenomas (CPAs). In this study, we identified by whole-exome sequencing the somatic mutation p.S54L in the PRKACB gene, encoding the catalytic subunit β (Cβ) of PKA, in a CPA from a patient with severe Cushing syndrome. Bioluminescence resonance energy transfer and surface plasmon resonance assays revealed that the mutation hampers formation of type I holoenzymes and that these holoenzymes were highly sensitive to cAMP. PKA activity, measured both in cell lysates and with recombinant proteins, based on phosphorylation of a synthetic substrate, was higher under basal conditions for the mutant enzyme compared with the WT, while maximal activity was lower. These data suggest that at baseline the PRKACB p.S54L mutant drove the adenoma cells to higher cAMP signaling activity, probably contributing to their autonomous growth. Although the role of PRKACB in tumorigenesis has been suggested, we demonstrated for the first time to our knowledge that a PRKACB mutation can lead to an adrenal tumor. Moreover, this observation describes another mechanism of PKA pathway activation in CPAs and highlights the particular role of residue Ser54 for the function of PKA.

Authors

Stéphanie Espiard, Matthias J. Knape, Kerstin Bathon, Guillaume Assié, Marthe Rizk-Rabin, Simon Faillot, Windy Luscap-Rondof, Daniel Abid, Laurence Guignat, Davide Calebiro, Friedrich W. Herberg, Constantine A. Stratakis, Jérôme Bertherat

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Figure 3

Binding of PKA-Cβ to physiological pseudosubstrate inhibitors.

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Binding of PKA-Cβ to physiological pseudosubstrate inhibitors. Binding a...
Binding affinity of Cβ-WT (A and C) or Cβ-S54L (B and D) was determined using surface plasmon resonance (SPR). For this, recombinant RIα subunit (A and B) or the protein kinase inhibitor α (PKIα) (C and D) were captured on a sensor chip. Recombinant Cβ-WT (A and C) or Cβ-S54L (B and D) were injected for 300 seconds at different concentrations (association). Dissociation of the complex was monitored for 300 seconds. Equilibrium binding constants and rate constants were determined using a Langmuir 1:1 binding model (curve fits are depicted as red dashed lines in representative plots) and are summarized in Tables 1 and 2. The reduced affinities for RIα and PKIα determined for the mutant Cβ-S54L compared with the WT protein are mainly due to faster complex dissociation (see Tables 1 and 2 for dissociation rates). RU, response units.