Ribosomal S6 kinases (RSKs) are the major functional components in mitogen-activated protein kinase (MAPK) pathway, and these are activated by upstream Extracellular signal-regulated kinase. Upon activation, RSKs activate a number of substrate molecules involved in transcription, translation and cell-cycle regulation. But how cellular binding partners are engaged in the MAPK pathways and regulate the molecular mechanisms have not been explored. Considering the importance of protein-protein interactions in cell signalling and folding pattern of native protein, functional C-terminal kinase domain of RSK3 has been characterized using in vitro, in silico and biophysical approaches. RSKs discharge different functions by binding to downstream kinase partners. Hence, depending upon cellular binding partners, RSKs translocate between cytoplasm and nucleus. In our study, it has been observed that the refolded C-terminal Kinase domain (CTKD) of RSK 3 has a compact domain structure which is predominantly α-helical in nature by burying the tryptophans deep into the core, which was confirmed by CD, Fluorescence spectroscopy and limited proteolysis assay. Our study also revealed that RSK 3 CTKD was found to be a homotrimer from DLS experiments. A model was also built for RSK 3 CTKD and was further validated using PROCHECK and ProSA webservers.
Keywords: CD spectroscopy; Dynamic light scattering; Fluorescence spectroscopy; In silico modelling; Inclusion bodies; MAPK/ERK and RSK.