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Article Abstract
Kinase domains are often flanked by flexible tails and intrinsically disordered regions (IDRs) that contain conserved motifs. The coordinated action and interplay of IDRs and folded kinase domains is necessary for the proper function of kinases and kinase complexes. Characterization of full length kinases and complexes is often challenging due to the flexible nature of flanking IDRs, yet necessary to fully understand their function and regulation. The p90 ribosomal S6 kinase (RSK) family is an unique kinase family with two distinct, functional kinase domains (NTK and CTK) flanked by flexible tails and a linker. RSK2 forms a stable complex with its activating kinase, ERK2, and here, we use multiple complementary techniques, HDXMS, cryoEM, and Alphafold modeling to study the full length RSK2:ERK2 complex. We find that broadly, ERK2 is more solvent protected than the NTK/CTK. The NTK N-lobe has quite high deuterium uptake, and analysis of published NTK crystal structures suggests that the NTK N-lobe is dynamic and can adopt a wide range of conformations. CryoEM reveals that the RSK2:ERK2 complex adopts a compact shape, and this is consistent with AlphaFold model of the complex hints at a possible additional interface between the NTK and ERK2. Collectively, our approach demonstrates that employing multiple complementary techniques can provide insight into the structure and biophysical characteristics of this challenging to study kinase complex.
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