SUMMARY In several growth factor receptors, the intracellular juxtamembrane (JM) region participates in autoinhibitory interactions that must be disrupted for tyrosine kinase activation. Using alanine scanning mutagenesis and crystallographic approaches, we define a domain within the JM region of the epidermal growth factor receptor (EGFR) that instead plays an activating – rather than autoinhibitory – role. Mutations in the C-terminal 19 residues of the EGFR JM region abolish EGFR activation. In a crystal structure of an asymmetric dimer of the tyrosine kinase domain, the JM region of an acceptor monomer makes extensive contacts with the C-lobe of a donor monomer, thus stabilizing the dimer. We describe how an uncharacterized lung cancer mutation in this JM activation domain (V665M) constitutively activates EGFR by augmenting its capacity to act as an acceptor in the asymmetric dimer. This JM mutant promotes cellular transformation by EGFR in vitro and is tumorigenic in a xenograft assay.
Cytokinesis requires coordination of actomyosin ring (AMR) contraction with rearrangements of the plasma membrane and extracellular matrix. In Saccharomyces cerevisiae, new membrane, the chitin synthase Chs2 (which forms the primary septum [PS]), and the protein Inn1 are all delivered to the division site upon mitotic exit even when the AMR is absent. Inn1 is essential for PS formation but not for Chs2 localization. The Inn1 C-terminal region is necessary for localization, and distinct PXXP motifs in this region mediate functionally important interactions with SH3 domains in the cytokinesis proteins Hof1 (an F-BAR protein) and Cyk3 (whose overexpression can restore PS formation in inn1Δ cells). The Inn1 N terminus resembles C2 domains but does not appear to bind phospholipids; nonetheless, when overexpressed or fused to Hof1, it can provide Inn1 function even in the absence of the AMR. Thus, Inn1 and Cyk3 appear to cooperate in activating Chs2 for PS formation, which allows coordination of AMR contraction with ingression of the cleavage furrow.
SUMMARY Phospholipid-binding modules such as PH, C1, and C2 domains play crucial roles in location-dependent regulation of many protein kinases. Here, we identify the KA1 domain (kinase associated-1 domain), found at the C-terminus of yeast septin-associated kinases (Kcc4p, Gin4p and Hsl1p) and human MARK/PAR1 kinases, as a membrane association domain that binds acidic phospholipids. Membrane localization of isolated KA1 domains depends on phosphatidylserine. Using X-ray crystallography, we identified a structurally conserved binding site for anionic phospholipids in KA1 domains from Kcc4p and MARK1. Mutating this site impairs membrane association of both KA1 domains and intact proteins, and reveals the importance of phosphatidylserine for bud neck localization of yeast Kcc4p. Our data suggest that KA1 domains contribute to “coincidence detection”, allowing kinases to bind other regulators (such as septins) only at the membrane surface. These findings have important implications for understanding MARK/PAR1 kinases, which are implicated in Alzheimer’s disease, cancer, and autism.
Summary Regulated relocalization of signaling and trafficking proteins is crucial for the control of many cellular processes, and is driven by a series of domains that respond to alterations at membrane surfaces. The first examples of these domains – conditional peripheral membrane proteins – included C1, C2, PH, PX, and FYVE domains, which specifically recognize single tightly regulated membrane components such as diacylglycerol or phosphoinositides. The structural basis for this recognition is now well understood. Efforts to identify additional domains with similar functions that bind other targets (or participate in unexplained cellular processes) have not yielded many more examples of specific phospholipid-binding domains. Instead, most of the recently discovered conditional peripheral membrane proteins bind multiple targets (each with limited specificity), relying on coincidence detection, and/or recognizing broader physical properties of the membrane such as charge or curvature. This broader range of recognition modes presents significant methodological challenges for a full structural understanding.
The response of eukaryotic cells to DNA damage includes the activation of phosphatidylinositol-3 kinase-related kinases (PIKK), such as ATM, ATR, and DNA-dependent protein kinase (DNA-PK). These three kinases have very similar substrate specificities in vitro, but in vivo, their substrates overlap only partially. Several in vivo substrates of ATM and ATR have been identified and almost all of them are involved in DNA damageinduced cell cycle arrest and/or apoptosis. In contrast, few in vivo substrates of DNA-PK have been identified. These include histone H2AX and DNA-PK itself. We identify here valosin-containing protein (VCP) as a novel substrate of DNA-PK and other PIKK family members. VCP is phosphorylated at Ser 784 within its COOH terminus, a region previously shown to target VCP to specific intracellular compartments. Furthermore, VCP phosphorylated at Ser 784 accumulated at sites of DNA double-strand breaks (DSBs). VCP is a protein chaperone that unfolds and translocates proteins. Its phosphorylation in response to DNA damage and its recruitment to sites of DNA DSBs could indicate a role of VCP in DNA repair. (Cancer Res 2005; 65(17): 7533-40)
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