Quantitation of Human 14-3-3ζ Dimerization and the Effect of Phosphorylation on Dimer-monomer Equilibria.

14-3-3 proteins are universal regulatory proteins and their function depends on their oligomeric form which may alter between the monomeric, homodimeric and heterodimeric states. The populations of individual oligomeric forms are controlled by Kd values of the dimer-monomer equilibria between the involved isoforms. This complex picture is extended by post-translational modifications, e.g. phosphorylation. In this work, we describe the equilibria between monomers, homo- and heterodimers of the 14-3-3ζ isoform in the unmodified and phosphorylated form. To cover a wide range of dimerization affinities, we combined solution NMR, microscale thermophoresis, native PAGE, and a set of novel fluorescence assays. Using a FRET based assay, we also determined the kinetic parameters of dimerization. We found that phosphorylation of 14-3-3ζ at Ser58 increases its homodimeric Kd value by 6 orders of magnitude. The presented assays allow to efficiently monitor 14-3-3ζ dimerization as a function of external factors, such as temperature, salt concentration, and client protein binding. For instance, we obtained values of both transient and equilibrium thermodynamic constants for the dimerization, and observed a substantial decrease of 14-3-3ζ dimer dissociation rate upon binding to the doubly phosphorylated regulatory domain of tyrosine hydroxylase. In summary, our work provides a conceptual framework to characterise the isoform exchanges of homo- and heterodimers which can significantly deepen our knowledge about the regulatory function of 14-3-3 proteins.

Protein environment affects the water-tryptophan binding mode. MD, QM/MM, and NMR studies of engrailed homeodomain mutants.

Water molecules can interact with aromatic moieties using either their O-H bonds or their lone-pairs of electrons. In proteins, water-π interactions have been reported to occur with tryptophan and histidine residues, and dynamic exchange between O-Hπ hydrogen bonding and lone-pairπ interactions was suggested to take place, based on ab initio calculations. Here we used classical and QM/MM molecular dynamics simulations, complemented with an NMR study, to examine a specific water-indole interaction observed in the engrailed homeodomain and in its mutants. Our simulations indicate that the binding mode between water and indole can adapt to the potential created by the surrounding amino acids (and by the residues at the DNA surface in protein-DNA complexes), and support the model of dynamic switching between the O-Hπ hydrogen bonding and lone-pairπ binding modes.

Free energy calculations on the stability of the 14-3-3ζ protein.

Mutations of cysteine are often introduced to e.g. avoid formation of non-physiological inter-molecular disulfide bridges in in-vitro experiments, or to maintain specificity in labeling experiments. Alanine or serine is typically preferred, which usually do not alter the overall protein stability, when the original cysteine was surface exposed. However, selecting the optimal mutation for cysteines in the hydrophobic core of the protein is more challenging. In this work, the stability of selected Cys mutants of 14-3-3ζ was predicted by free-energy calculations and the obtained data were compared with experimentally determined stabilities. Both the computational predictions as well as the experimental validation point at a significant destabilization of mutants C94A and C94S. This destabilization could be attributed to the formation of hydrophobic cavities and a polar solvation of a hydrophilic side chain. A L12E, M78K double mutant was further studied in terms of its reduced dimerization propensity. In contrast to naïve expectations, this double mutant did not lead to the formation of strong salt bridges, which was rationalized in terms of a preferred solvation of the ionic species. Again, experiments agreed with the calculations by confirming the monomerization of the double mutants. Overall, the simulation data is in good agreement with experiments and offers additional insight into the stability and dimerization of this important family of regulatory proteins.

Quantitative mapping of microtubule-associated protein 2c (MAP2c) phosphorylation and regulatory protein 14-3-3ζ-binding sites reveals key differences between MAP2c and its homolog Tau.

Microtubule-associated protein 2c (MAP2c) is involved in neuronal development and is less characterized than its homolog Tau, which has various roles in neurodegeneration. Using NMR methods providing single-residue resolution and quantitative comparison, we investigated molecular interactions important for the regulatory roles of MAP2c in microtubule dynamics. We found that MAP2c and Tau significantly differ in the position and kinetics of sites that are phosphorylated by cAMP-dependent protein kinase (PKA), even in highly homologous regions. We determined the binding sites of unphosphorylated and phosphorylated MAP2c responsible for interactions with the regulatory protein 14-3-3ζ. Differences in phosphorylation and in charge distribution between MAP2c and Tau suggested that both MAP2c and Tau respond to the same signal (phosphorylation by PKA) but have different downstream effects, indicating a signaling branch point for controlling microtubule stability. Although the interactions of phosphorylated Tau with 14-3-3ζ are supposed to be a major factor in microtubule destabilization, the binding of 14-3-3ζ to MAP2c enhanced by PKA-mediated phosphorylation is likely to influence microtubule-MAP2c binding much less, in agreement with the results of our tubulin co-sedimentation measurements. The specific location of the major MAP2c phosphorylation site in a region homologous to the muscarinic receptor-binding site of Tau suggests that MAP2c also may regulate processes other than microtubule dynamics.