β-adrenergic signalling activates cAMP-dependent protein kinase (PKA), which regulates the activity of L-type voltage-gated calcium channels such as CaV1.2. Several PKA target sites in the C-terminal tail of CaV1.2 have been identified, and their phosphorylation has been suggested to increase currents in specific tissues or heterologous expression systems. However, augmentation of CaV1.2 currents in the heart is instead mediated by phosphorylation of Rad, a small GTPase that can inhibit CaV1.2. It is unclear how each of the proposed target sites in CaV1.2 and Rad rank towards their recognition by PKA, which could reveal a preferential phosphorylation. Here we used quantitative assays on three CaV1.2 and four Rad sites. Isothermal titration calorimetry (ITC) and enzyme kinetics show that there are two Tiers of targets, with CaV1.2 residue Ser1981 and Rad residues Ser25 and Ser272 forming Tier 1 substrates for PKA. These share a common feature with two Arginine residues at specific positions that can anchor the peptide into the substrate binding cleft of PKA. In contrast, PKA shows minimal activity for the other, Tier 2 substrates, characterized by low kcat values and undetectable binding via ITC. The existence of two Tiers suggests that PKA regulation of the CaV1.2 complex may occur in a graded fashion. We report crystal structures of the PKA catalytic subunit with and without a CaV1.2 and test the importance of several anchoring residues via mutagenesis. Different target sites utilize different anchors, highlighting the plasticity of PKAc to recognize substrates.
Keywords: GTP binding protein; X‐ray crystallography; beta-adrenergic signaling; cAMP-depending protein kinase; cardiac muscle; diabetes; enzyme kinetics; isothermal titration calorimetry; synaptic plasticity; voltage gated calcium channel.
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