RESUMO
Mutations of the human leucine-rich repeat kinase 2 (LRRK2) have been associated with both, idiopathic and familial Parkinson's disease (PD). Most of these pathogenic mutations are located in the kinase domain (KD) or GTPase domain of LRRK2. In this study we describe a mechanism in which protein kinase activity can be modulated by reversible oxidation or reduction, involving a unique pair of adjacent cysteines, the "CC" motif. Among all human protein kinases, only LRRK2 contains this "CC" motif (C2024 and C2025) in the Activation Segment (AS) of the kinase domain. In an approach combining site-directed mutagenesis, biochemical analyses, cell-based assays, and Gaussian accelerated Molecular Dynamics (GaMD) simulations we could attribute a role for each of those cysteines. We employed reducing and oxidizing agents with potential clinical relevance to investigate effects on kinase activity and microtubule docking. We find that each cysteine gives a distinct contribution: the first cysteine, C2024, is essential for LRRK2 protein kinase activity, while the adjacent cysteine, C2025, contributes significantly to redox sensitivity. Implementing thiolates (R-S-) in GaMD simulations allowed us to analyse how each of the cysteines in the "CC" motif interacts with its surrounding residues depending on its oxidation state. From our studies we conclude that oxidizing agents can downregulate kinase activity of hyperactive LRRK2 PD mutations and may provide promising tools for therapeutic strategies.
RESUMO
Mutations in LRRK2, a large multi-domain protein kinase, create risk factors for Parkinson's Disease (PD). LRRK2 has seven well-folded domains that include three N-terminal scaffold domains (NtDs) and four C-terminal domains (CtDs). In full-length inactive LRRK2 there is an additional well-folded motif, the LRR-ROC Linker, that lies between the NtDs and the CtDs. This motif, which is stabilized by hydrophobic residues in the LRR and ROC/COR-A domains, is anchored to the C-Lobe of the kinase domain. The LRR-ROC Linker becomes disordered when the NtDs are unleashed from the CtDs following activation by Rab29 or by various PD mutations. A key residue within the LRR-ROC Linker, W1295, sterically blocks access of substrate proteins. The W1295A mutant blocks cis-autophosphorylation of S1292 and reduces phosphorylation of heterologous Rab substrates. GaMD simulations show that the LRR-Linker motif, P + 1 loop and the inhibitory helix in the DYGψ motif are very stable. Finally, in full-length inactive LRRK2 ATP is bound to the kinase domain and GDP:Mg to the GTPase/ROC domain. The fundamentally different mechanisms for binding nucleotide (G-Loop vs P-Loop) are captured by these GaMD simulations. In this model, where ATP binds with low affinity (µM range) to N-Lobe capping residues, the known auto-phosphorylation sites are located in the space that is sampled by the flexible phosphates thus providing a potential mechanism for cis-autophosphorylation.