Scaffold proteins contribute to the spatiotemporal control of MAPK signaling and KSR1 is an ERK cascade scaffold that localizes to the plasma membrane in response to growth factor treatment. To better understand the molecular mechanisms of KSR1 function, we examined the interaction of KSR1 with each of the ERK cascade components, Raf, MEK, and ERK. Here, we identify a hydrophobic motif within the proline-rich sequence (PRS) of MEK1 and MEK2 that is required for constitutive binding to KSR1 and find that MEK binding and residues in the KSR1 CA1 region enable KSR1 to form a ternary complex with B-Raf and MEK following growth factor treatment that enhances MEK activation. We also find that docking of active ERK to the KSR1 scaffold allows ERK to phosphorylate KSR1 and B-Raf on feedback S/TP sites. Strikingly, feedback phosphorylation of KSR1 and B-Raf promote their dissociation and result in the release of KSR1 from the plasma membrane. Together, these findings provide unique insight into the signaling dynamics of the KSR1 scaffold and reveal that through regulated interactions with Raf and ERK, KSR1 acts to both potentiate and attenuate ERK cascade activation, thus regulating the intensity and duration of ERK cascade signaling emanating from the plasma membrane during growth factor signaling.ERK cascade ͉ protein scaffolds ͉ signal tranduction C ells respond to a diverse array of signal inputs and ensuring that the correct biological response is achieved requires that the appropriate signaling pathways are engaged and that mechanisms are in place to regulate the strength, duration, and location of pathway activation. Receptor tyrosine kinases (RTKs) serve as entry points for many extracellular cues, relaying signals that control cell proliferation and differentiation, promote cell migration and survival, and modulate cellular metabolism. RTK pathways are intricate signaling networks, containing modules of multiprotein complexes that assemble at various intracellular compartments to process, integrate, and transmit information that will ultimately specify a particular biological response (1).An essential effector cascade required for most RTK function is the ERK cascade composed of the Raf, MEK, and ERK kinases (2). The critical link that allows RTKs to signal to ERK is the RasGTPase. Through the recruitment of guanine nucleotide exchange factors to the cell surface, activated RTKs stimulate the GTPloading of Ras, which allows Ras to interact directly with its target effectors, one of which is the Raf kinase family. Binding to Ras recruits the cytosolic Raf kinases to the plasma membrane where they are activated, thus initiating the phosphorylation cascade that results in MEK and ERK activation.In addition to the enzymatic components of the ERK cascade, protein scaffolds have also been found to play an important role in ERK cascade activation and signaling (3, 4). The Ste5 protein in yeast is the prototypical scaffold for MAPK signaling cascades, and studies characterizing Ste5 have revealed that by interacting wit...
