Mutations causing DOK7 congenital myasthenia ablate functional motifs in Dok-7

Dok-7 is a cytoplasmic activator of muscle-specific receptor-tyrosine kinase (MuSK). Both Dok-7 and MuSK are required for neuromuscular synaptogenesis. Mutations in DOK7 underlie a congenital myasthenic syndrome (CMS) associated with small and simplified neuromuscular synapses likely due to impaired Dok-7/MuSK signaling. The overwhelming majority of patients with DOK7 CMS have at least one allele with a frameshift mutation that causes a truncation in the COOH-terminal region of Dok-7 and affects MuSK activation. Dok-7 has pleckstrin homology (PH) and phosphotyrosine binding (PTB) domains in the NH2-terminal moiety, both of which are indispensable for MuSK activation in myotubes, but little is known about additional functional elements. Here, we identify a chromosome region maintenance 1-dependent nuclear export signal (NES) in the COOH-terminal moiety and demonstrate that the NES-mediated cytoplasmic location of Dok-7 is essential for regulating the interaction with MuSK in myotubes. The NH2-terminal PH domain is responsible for the nuclear import of Dok-7. We also show that the Src homology 2 target motifs in the COOH-terminal moiety of Dok-7 are active and crucial for MuSK activation in myotubes. In addition, CMS-associated missense mutations found in the PH or PTB domain inactivate Dok-7. Together, these findings demonstrate that, in addition to the NH2-terminal PH and PTB domains, the COOH-terminal NES and Src homology 2 target motifs play key roles in Dok-7/MuSK signaling for neuromuscular synaptogenesis. Ablation or disruption of these functional elements in Dok-7 probably underlies the neuromuscular junction synaptopathy observed in DOK7 CMS.     

Intramolecular regulatory switch in ZAP-70: analogy with receptor tyrosine kinases

ZAP-70, a Syk family cytoplasmic protein tyrosine kinase (PTK), is required to couple the activated T-cell antigen receptor (TCR) to downstream signaling pathways. It contains two tandem SH2 domains that bind to phosphorylated TCR subunits and a C-terminal catalytic domain. The region connecting the SH2 domains with the kinase domain, termed interdomain B, has previously been shown to have striking regulatory effects on ZAP-70 function, presumed to be due to the recruitment of key substrates. Paradoxically, deletion of interdomain B preserves ZAP-70 function. Recent structural studies of several receptor tyrosine kinases (RTKs) revealed that their juxtamembrane regions negatively regulate their catalytic activities. In EphB2 and several other RTKs, this autoinhibition depends upon interaction between the kinase domain and tyrosine residues within the juxtamembrane region. Autoinhibition is released when these tyrosines become phosphorylated following receptor stimulation. Sequence homology suggested analogous regulation for ZAP-70. Based on mutagenesis analysis of ZAP-70 interdomain B, we find that this region downregulates ZAP-70 catalytic activity in a similar manner as the juxtamembrane region of EphB2. Similar regulation was also noted for the related Syk kinase. These findings suggest that a general autoinhibitory mechanism employed by RTKs is also used by some cytoplasmic tyrosine kinases.     

Crystal structure of the MuSK tyrosine kinase: insights into receptor autoregulation

Muscle-specific kinase (MuSK) is a receptor tyrosine kinase expressed selectively in skeletal muscle. During neuromuscular synapse formation, agrin released from motor neurons stimulates MuSK autophosphorylation in the kinase activation loop and in the juxtamembrane region, leading to clustering of acetylcholine receptors. We have determined the crystal structure of the cytoplasmic domain of unphosphorylated MuSK at 2.05 A resolution. The structure reveals an autoinhibited kinase domain in which the activation loop obstructs ATP and substrate binding. Steady-state kinetic analysis demonstrates that autophosphorylation results in a 200-fold increase in k(cat) and a 10-fold decrease in the K(m) for ATP. These studies provide a molecular basis for understanding the regulation of MuSK catalytic activity and suggest that an additional in vivo component may contribute to regulation via the juxtamembrane region.     

Rotational coupling of the transmembrane and kinase domains of the Neu receptor tyrosine kinase

Ligand binding to receptor tyrosine kinases (RTKs) regulates receptor dimerization and activation of the kinase domain. To examine the role of the transmembrane domain in regulation of RTK activation, we have exploited a simplified transmembrane motif, [VVVEVVV](n), previously shown to activate the Neu receptor. Here we demonstrate rotational linkage of the transmembrane domain with the kinase domain, as evidenced by a periodic activation of Neu as the dimerization motif is shifted across the transmembrane domain. These results indicate that activation requires a specific orientation of the kinase domains with respect to each other. Results obtained with platelet-derived growth factor receptor-beta suggest that this rotational linkage of the transmembrane domain to the kinase domain may be a general feature of RTKs. These observations suggest that activating mutations in RTK transmembrane and juxtamembrane domains will be limited to those residues that position the kinase domains in an allowed rotational conformation.     

Conformational regulation of the EGFR kinase core by the juxtamembrane and C-terminal tail: a molecular dynamics study

The catalytic domain of epidermal growth factor receptor (EGFR) is activated by dimerization, which requires allosteric coupling between distal dimerization and catalytic sites. Although crystal structures of EGFR kinases, solved in various conformational states, have provided important insights into EGFR activation by dimerization, the atomic details of how dimerization signals are dynamically coupled to catalytic regions of the kinase core are not fully understood. In this study, we have performed unrestrained and targeted molecular dynamics simulations on the active and inactive states of EGFR, followed by principal component analysis on the simulated trajectories, to identify correlated motions in the EGFR kinase domain upon dimerization. Our analysis reveals that the conformational changes associated with the catalytic functions of the kinase core are highly correlated with motions in the juxtamembrane (JM) and C-terminal tail, two flexible structural elements that play an active role in EGFR kinase activation and dimerization. In particular, the opening and closing of the ATP binding lobe relative to the substrate binding lobe is highly correlated with motions in the JM and C-terminal tail, suggesting that ATP and substrate binding can be coordinated with dimerization through conformational changes in the JM and C-terminal tail. Our study pinpoints key residues involved in this conformational coupling, and provides new insights into the role of the JM and C-terminal tail segments in EGFR kinase functions.     

Sorbs1 and -2 Interact with CrkL and Are Required for Acetylcholine Receptor Cluster Formation

Crk and CrkL are noncatalytic adaptor proteins necessary for the formation of neuromuscular synapses which function downstream of muscle-specific kinase (MuSK), a receptor tyrosine kinase expressed in skeletal muscle, and the MuSK binding protein Dok-7. How Crk/CrkL regulate neuromuscular endplate formation is not known. To better understand the roles of Crk/CrkL, we identified CrkL binding proteins using mass spectrometry and have identified Sorbs1 and Sorbs2 as two functionally redundant proteins that associate with the initiating MuSK/Dok-7/Crk/CrkL complex, regulate acetylcholine receptor (AChR) clustering in vitro, and are localized at synapses in vivo.     

Cytohesins are cytoplasmic ErbB receptor activators

Signaling by ErbB receptors requires the activation of their cytoplasmic kinase domains, which is initiated by ligand binding to the receptor ectodomains. Cytoplasmic factors contributing to the activation are unknown. Here we identify members of the cytohesin protein family as such factors. Cytohesin inhibition decreased ErbB receptor autophosphorylation and signaling, whereas cytohesin overexpression stimulated receptor activation. Monitoring epidermal growth factor receptor (EGFR) conformation by anisotropy microscopy together with cell-free reconstitution of cytohesin-dependent receptor autophosphorylation indicate that cytohesins facilitate conformational rearrangements in the intracellular domains of dimerized receptors. Consistent with cytohesins playing a prominent role in ErbB receptor signaling, we found that cytohesin overexpression correlated with EGF signaling pathway activation in human lung adenocarcinomas. Chemical inhibition of cytohesins resulted in reduced proliferation of EGFR-dependent lung cancer cells in?vitro and in?vivo. Our results establish cytohesins as cytoplasmic conformational activators of ErbB receptors that are of pathophysiological relevance.     

Ligand-induced EGF receptor oligomerization is kinase-dependent and enhances internalization

The current activation model of the EGF receptor (EGFR) predicts that binding of EGF results in dimerization and oligomerization of the EGFR, leading to the allosteric activation of the intracellular tyrosine kinase. Little is known about the regulatory mechanism of receptor oligomerization. In this study, we have employed FRET between identical fluorophores (homo-FRET) to monitor the dimerization and oligomerization state of the EGFR before and after receptor activation. Our data show that, in the absence of ligand, ～40% of the EGFR molecules were present as inactive dimers or predimers. The monomer/predimer ratio was not affected by deletion of the intracellular domain. Ligand binding induced the formation of receptor oligomers, which were found in both the plasma membrane and intracellular structures. Ligand-induced oligomerization required tyrosine kinase activity and nine different tyrosine kinase substrate residues. This indicates that the binding of signaling molecules to activated EGFRs results in EGFR oligomerization. Induction of EGFR predimers or pre-oligomers using the EGFR fused to the FK506-binding protein did not affect signaling but was found to enhance EGF-induced receptor internalization. Our data show that EGFR oligomerization is the result of EGFR signaling and enhances EGFR internalization.     

A basic peptide within the juxtamembrane region is required for EGF receptor dimerization

The epidermal growth factor receptor (EGFR) is fundamental for normal cell growth and organ development, but has also been implicated in various pathologies, notably tumors of epithelial origin. We have previously shown that the initial 13 amino acids (P13) within the intracellular juxtamembrane region (R645-R657) are involved in the interaction with calmodulin, thus indicating an important role for this region in EGFR function. Here we show that P13 is required for proper dimerization of the receptor. We expressed either the intracellular domain of EGFR (TKJM) or the intracellular domain lacking P13 (DeltaTKJM) in COS-7 cells that express endogenous EGFR. Only TKJM was immunoprecipitated with an antibody directed against the extracellular part of EGFR, and only TKJM was tyrosine phosphorylated by endogenous EGFR. Using SK-N-MC cells, which do not express endogenous EGFR, that were stably transfected with either wild-type EGFR or recombinant full-length EGFR lacking P13 demonstrated that P13 is required for appropriate receptor dimerization. Furthermore, mutant EGFR lacking P13 failed to be autophosphorylated. P13 is rich in basic amino acids and in silico modeling of the EGFR in conjunction with our results suggests a novel role for the juxtamembrane domain (JM) of EGFR in mediating intracellular dimerization and thus receptor kinase activation and function.     

Molecular Mechanisms of SH2- and PTB-Domain-Containing Proteins in Receptor Tyrosine Kinase Signaling

Intracellular signaling is mediated by reversible posttranslational modifications (PTMs) that include phosphorylation, ubiquitination, and acetylation, among others. In response to extracellular stimuli such as growth factors, receptor tyrosine kinases (RTKs) typically dimerize and initiate signaling through phosphorylation of their cytoplasmic tails and downstream scaffolds. Signaling effectors are recruited to these phosphotyrosine (pTyr) sites primarily through Src homology 2 (SH2) domains and pTyr-binding (PTB) domains. This review describes how these conserved domains specifically recognize pTyr residues and play a major role in mediating precise downstream signaling events.Receptor tyrosine kinase (RTK) signaling is initiated on binding of soluble growth factors to growth factor receptors such as the insulin receptor (IR) or epidermal growth factor receptor (EGFR), or on binding of membrane-bound ephrins, as is the case for Eph receptors. Intracellular signaling is then propagated through PTMs, which commonly serve to regulate protein function by acting as docking sites for recruitment of modular protein interaction domains. Phosphorylation is the best studied PTM, and is a principle mechanism regulating intracellular signaling.A common element in RTK signaling involves autophosphorylation of the intracellular portion of the receptor (Fig. 1). RTKs become activated as a result of ligand-stabilized dimerization or oligomerization. For instance, in the EGFR subfamily (which includes ErbB and EGF receptors), the formation of homo- or heterodimers is initiated by ligand binding and subsequent exposure of a dimerization domain (Hynes and Lane 2005). Dimerization of the RTKs allows autophosphorylation of the RTKs; EGFR is exceptional in that an allosteric interaction between the kinase domains of adjacent monomers is responsible for the receptor activation (Zhang et al. 2006). However, in the majority of cases dimerization enhances RTK catalytic activity through phosphorylation of the kinase activation loop, and in some instances the juxtamembrane region, and recruits signaling effectors through the creation of pTyr docking sites. The specific interaction of signaling proteins with these pTyr-binding motifs activates signaling pathways, such as canonical signaling through the Ras-mitogen activated protein kinase (MAPK), phosphoinositide-3-kinase (PI3K)-Akt, and phospholipase C-gamma (PLC-γ) pathways. These RTK pathways can result in a variety of cellular processes, including differentiation, proliferation, survival, and migration (Fig. 1). The cellular context of signaling can dictate the biological outcome, and how each RTK initiates a given cellular process remains an area of active research.Open in a separate windowFigure 1.Receptor tyrosine kinases activate downstream pathways through recruitment of proteins containing pTyr-binding domains. Receptor tyrosine kinases are activated on growth factor binding to the extracellular domain of the receptor, leading to receptor dimerization and tyrosine phosphorylation (yellow circles labeled with a P) of their cytoplasmic tails, which act as docking sites for recruitment of PTB and SH2 domains. Various RTKs can mediate a diverse set of cellular processes (colored boxes) determined by the recruitment of specific SH2- and PTB-domain-containing proteins. The gray box displays how the adaptor Grb2 is recruited to an RTK through recognition of the pY-x-N (pY = pTyr, x = any natural amino acid) and activates cell growth and survival pathways such as MAPK and AKT, respectively, through complex formation via its SH3 domains.Tyrosine phosphorylation mediates RTK signaling through the recruitment and activation of proteins involved in downstream signaling pathways, mediated through pTyr binding of the SH2 and PTB domains of signaling effectors. SH2 and PTB domains are found in an otherwise diverse set of proteins containing a range of distinct catalytic and interaction domains, and provide a degree of specificity through their recognition of both a pTyr residue and surrounding amino acids. Here we will discuss the properties of proteins that contain SH2 and PTB domains and their roles in signaling downstream of RTKs, as well as the mechanisms by which they regulate the activity of these signaling effectors.     

Functional and structural stability of the epidermal growth factor receptor in detergent micelles and phospholipid nanodiscs

Cellular signaling mediated by the epidermal growth factor receptor (EGFR or ErbB) family of receptor tyrosine kinases plays an important role in regulating normal and oncogenic cellular physiology. While structures of isolated EGFR extracellular domains and intracellular protein tyrosine kinase domains have suggested mechanisms for growth factor-mediated receptor dimerization and allosteric kinase domain activation, understanding how the transmembrane and juxtamembrane domains contribute to transmembrane signaling requires structural studies on intact receptor molecules. In this report, recombinant EGFR constructs containing the extracellular, transmembrane, juxtamembrane, and kinase domains are overexpressed and purified from human embryonic kidney 293 cell cultures. The oligomerization state, overall structure, and functional stability of the purified EGF-bound receptor are characterized in detergent micelles and phospholipid bilayers. In the presence of EGF, catalytically active EGFR dimers can be isolated by gel filtration in dodecyl maltoside. Visualization of the dimeric species by negative stain electron microscopy and single particle averaging reveals an overall structure of the extracellular domain that is similar to previously published crystal structures and is consistent with the C-termini of domain IV being juxtaposed against one another as they enter the transmembrane domain. Although detergent-soluble preparations of EGFR are stable as dimers in the presence of EGF, they exhibit differential functional stability in Triton X-100 versus dodecyl maltoside. Furthermore, the kinase activity can be significantly stabilized by reconstituting purified EGF-bound EGFR dimers in phospholipid nanodiscs or vesicles, suggesting that the environment around the hydrophobic transmembrane and amphipathic juxtamembrane domains is important for stabilizing the tyrosine kinase activity in vitro.     

Role of c-kit/SCF in cause and treatment of gastrointestinal stromal tumors (GIST)

c-Kit encodes for the receptor tyrosine kinase (RTK) and belongs to type III receptor family. This includes platelet derived growth factor (PDGF) alpha and beta and macrophage colony stimulating factor (mCSF) apart from others. Their characteristic features are the presence of five immunologlobulin like domains in the extracellular region and 70-100 residues long kinase insert domain in the cytoplasmic region. The RTKs activate several signaling pathways within the cells leading to cell proliferation, differentiation, migration or metabolic changes. The Kit ligand-stem cell factor (SCF) induces a rapid and complete receptor dimerization resulting in activation by autophosphorylation of the catalytic tyrosine kinase and generation of signal transduction leading to regulation of cell growth. Various mutations in c-kit such as insertions and deletions (without affecting reading frame) and point mutations in the inhibitory juxtamembrane (JM) domain encoded by exon 11 have been reported in gastrointestinal stromal tumors (GISTs). Thus, c-kit signaling is believed to play a role in tumorigenesis. Efforts are being made to control and treat these tumors by blocking kit signaling using Imatinib with varying degrees of success. This review deals with the features of c-kit, its ligand and roles in gastrointestinal stromal tumors.     

Structure and activation of MuSK,a receptor tyrosine kinase central to neuromuscular junction formation

MuSK (muscle-specific kinase) is a receptor tyrosine kinase that plays a central signaling role in the formation of neuromuscular junctions (NMJs). MuSK is activated in a complex spatio-temporal manner to cluster acetylcholine receptors on the postsynaptic (muscle) side of the synapse and to induce differentiation of the nerve terminal on the presynaptic side. The ligand for MuSK is LRP4 (low-density lipoprotein receptor-related protein-4), a transmembrane protein in muscle, whose binding affinity for MuSK is potentiated by agrin, a neuronally derived heparan-sulfate proteoglycan. In addition, Dok7, a cytoplasmic adaptor protein, is also required for MuSK activation in vivo. This review focuses on the physical interplay between these proteins and MuSK for activation and downstream signaling, which culminates in NMJ formation. This article is part of a Special Issue entitled: Emerging recognition and activation mechanisms of receptor tyrosine kinases.     

The juxtamembrane region of MuSK has a critical role in agrin-mediated signaling

MuSK is a receptor tyrosine kinase expressed selectively in skeletal muscle and localized to neuromuscular synapses. Agrin activates MuSK and stimulates phosphorylation and clustering of acetylcholine receptors (AChRs) at synaptic sites. We expressed wild-type or mutant MuSK in MuSK(-/-) myotubes and identified tyrosine residues in the MuSK cytoplasmic domain that are necessary for agrin-stimulated phosphorylation and clustering of AChRs. The activation loop tyrosines and the single juxtamembrane tyrosine were found to be essential for agrin-stimulated phosphorylation and clustering of AChRs. Further, we show that the juxtamembrane tyrosine, contained within an NPXY motif, is phosphorylated in vivo by agrin stimulation. We constructed chimeras containing extracellular and transmembrane domains from MuSK and cytoplasmic sequences from TrkA and found that inclusion of 13 amino acids from the MuSK juxtamembrane region, including the NPXY motif, is sufficient to convert a phosphorylated but inactive MuSK-TrkA chimera into a phosphorylated active chimera. These data suggest that phosphorylation of the MuSK NPXY site leads to recruitment of a phosphotyrosine-binding domain-containing protein that functions to stimulate phosphorylation and clustering of AChRs.     

Insider influence on ErbB activity

The receptor tyrosine kinase ErbB is activated by ligand-induced dimerization, leading to transphosphorylation of the cytoplasmic kinase domains. Bill et al. (2010) now demonstrate that transphosphorylation can be modulated from within the cell by the cytoplasmic protein cytohesin, providing new insights into ErbB-dependent processes during normal development and cancer.     

Insulin and epidermal growth factor receptor family members share parallel activation mechanisms

Insulin receptor (IR) and the epidermal growth factor receptor (EGFR) were the first receptor tyrosine kinases (RTKs) to be studied in detail. Both are important clinical targets—in diabetes and cancer, respectively. They have unique extracellular domain compositions among RTKs, but share a common module with two ligand‐binding leucine‐rich‐repeat (LRR)‐like domains connected by a flexible cysteine‐rich (CR) domain (L1‐CR‐L2 in IR/domain, I‐II‐III in EGFR). This module is linked to the transmembrane region by three fibronectin type III domains in IR, and by a second CR in EGFR. Despite sharing this conserved ligand‐binding module, IR and EGFR family members are considered mechanistically distinct—in part because IR is a disulfide‐linked (αβ)₂ dimer regardless of ligand binding, whereas EGFR is a monomer that undergoes ligand‐induced dimerization. Recent cryo‐electron microscopy (cryo‐EM) structures suggest a way of unifying IR and EGFR activation mechanisms and origins of negative cooperativity. In EGFR, ligand engages both LRRs in the ligand‐binding module, “closing” this module to break intramolecular autoinhibitory interactions and expose new dimerization sites for receptor activation. How insulin binds the activated IR was less clear until now. Insulin was known to associate with one LRR (L1), but recent cryo‐EM structures suggest that it also engages the second LRR (albeit indirectly) to “close” the L1‐CR‐L2 module, paralleling EGFR. This transition simultaneously breaks autoinhibitory interactions and creates new receptor‐receptor contacts—remodeling the IR dimer (rather than inducing dimerization per se) to activate it. Here, we develop this view in detail, drawing mechanistic links between IR and EGFR.     

Activation of Neu (ErbB-2) Mediated by Disulfide Bond-Induced Dimerization Reveals a Receptor Tyrosine Kinase Dimer Interface

Receptor dimerization is a crucial intermediate step in activation of signaling by receptor tyrosine kinases (RTKs). However, dimerization of the RTK Neu (also designated ErbB-2, HER-2, and p185^neu), while necessary, is not sufficient for signaling. Earlier work in our laboratory had shown that introduction of an ectopic cysteine into the Neu juxtamembrane domain induces Neu dimerization but not signaling. Since Neu signaling does require dimerization, we hypothesized that there are additional constraints that govern signaling ability. With the importance of the interreceptor cross-phosphorylation reaction, a likely constraint was the relative geometry of receptors within the dimer. We have tested this possibility by constructing a consecutive series of cysteine substitutions in the Neu juxtamembrane domain in order to force dimerization along a series of interreceptor faces. Within the group that dimerized constitutively, a subset had transforming activity. The substitutions in this subset all mapped to the same face of a predicted alpha helix, the most likely conformation for the intramembrane domain. Furthermore, this face of interaction aligns with the projected Neu* V664E substitution and with a predicted amphipathic interface in the Neu juxtamembrane domain. We propose that these results identify an RTK dimer interface and that dimerization of this RTK induces an extended contact between juxtamembrane and intramembrane alpha helices.     

Structural analysis of receptor tyrosine kinases

Receptor tyrosine kinases (RTKs) are single-pass transmembrane receptors that possess intrinsic cytoplasmic enzymatic activity, catalyzing the transfer of the γ-phosphate of ATP to tyrosine residues in protein substrates. RTKs are essential components of signal transduction pathways that affect cell proliferation, differentiation, migration and metabolism. Included in this large protein family are the insulin receptor and the receptors for growth factors such as epidermal growth factor, fibroblast growth factor and vascular endothelial growth factor. Receptor activation occurs through ligand binding, which facilitates receptor dimerization and autophosphorylation of specific tyrosine residues in the cytoplasmic portion. The phosphotyrosine residues either enhance receptor catalytic activity or provide docking sites for downstream signaling proteins. Over the past several years, structural studies employing X-ray crystallography have advanced our understanding of the molecular mechanisms by which RTKs recognize their ligands and are activated by dimerization and tyrosine autophosphorylation. This review will highlight the key results that have emerged from these structural studies.     

Structure of the membrane reconstituted transmembrane-juxtamembrane peptide EGFR(622-660) and its interaction with Ca2+/calmodulin

The transmembrane (TM) and juxtamembrane (JM) regions of the epidermal growth factor receptor (EGFR) couple ligand binding in the extracellular domain to activation of the kinase domain. Solid-state NMR and polarized FTIR measurements of peptides corresponding to the TM plus JM regions of EGFR (residues 622-660) reconstituted in model phospholipid membranes are presented to address the role of the short cytoplasmic JM sequence (residues 645-660) in regulating EGFR activity. We show that the TM domain is helical with a transition to non-helical structure at the TM-JM boundary. Fluorescence measurements indicate that the JM region of EGFR(622-660) binds to the membrane surface and that binding can be reversed by the addition of the complex of Ca2+ and calmodulin. Together these data support models suggesting the cytoplasmic JM region of EGFR plays an active role in regulating receptor activity.     

Strong oligomerization behavior of PDGFβ ?receptor transmembrane domain and its regulation by the juxtamembrane regions

The platelet-derived growth factor β-receptor (PDGFβR) represents an important subclass of receptor tyrosine kinase (RTK) thought to be activated by ligand-induced dimerization. Interestingly, the receptor is also activated by the bovine papillomavirus E5 oncoprotein, an interaction involving the transmembrane domains of both proteins and resulting in constitutive downstream signalling. This unique mode of activation along with emerging data for other RTKs raises important questions about the role of the PDGFβR transmembrane domain in signalling. To address this, we have investigated the murine PDGFβR transmembrane and juxtamembrane domains. We show for the first time the strong oligomerization behavior of PDGFβR transmembrane domain, forming dimers and trimers in natural membranes and detergents; and that these self-interactions are mediated by a leucine-zipper-like motif. The juxtamembrane regions are found to regulate these helix-helix interactions and select specifically for dimer formation. These data provide evidence that PDGFβR is able to form ligand-independent dimers, supporting similar observations in a number of other RTK's. A point mutant in the PDGFβR juxtamembrane domain previously shown to cause receptor activation was studied and yielded no change in oligomerization or folding, suggesting (in-line with observations of the c-Kit receptor) that it may moderate interactions with other regions of PDGFβR.