Functional analysis of the ligand binding site of EGF-receptor utilizing chimeric chicken/human receptor molecules.

The epidermal growth factor (EGF)-receptor is composed of an extracellular ligand-binding region connected by a single transmembrane region to the cytoplasmic kinase domain. In spite of its importance for understanding signal transduction, the ligand-binding domain of the EGF-receptor is not yet defined. We describe the identification of a major ligand-binding domain of the EGF-receptor by utilizing chimeras between the human EGF-receptor and the chicken EGF-receptor. This approach is based on the fact that murine EGF binds to the chicken EGF-receptor with 100-fold lower affinity as compared to the human EGF-receptor. Hence, the substitution of various domains of the chicken EGF-receptor by domains of the human EGF-receptor may restore the higher binding affinity towards EGF, characteristic of the human receptor. We show that chimeric chicken/human EGF-receptor, which contains domain III of the extracellular region of the human receptor, behaves like the human EGF-receptor with respect to EGF binding affinity and biological responsiveness. However, a chimeric chicken/human EGF-receptor containing domains I and II of the human receptor behaves like the chicken rather than the human EGF-receptor. Moreover, two different monoclonal antibodies which compete for the binding of EGF to EGF-receptor recognize specifically domain III of the human EGF-receptor. It is concluded that domain III which is flanked by the two cysteine-rich domains is a major ligand-binding domain of the EGF-receptor.     

Crystal structure of the complex of human epidermal growth factor and receptor extracellular domains

Epidermal growth factor (EGF) regulates cell proliferation and differentiation by binding to the EGF receptor (EGFR) extracellular region, comprising domains I-IV, with the resultant dimerization of the receptor tyrosine kinase. In this study, the crystal structure of a 2:2 complex of human EGF and the EGFR extracellular region has been determined at 3.3 A resolution. EGFR domains I-III are arranged in a C shape, and EGF is docked between domains I and III. The 1:1 EGF*EGFR complex dimerizes through a direct receptor*receptor interaction, in which a protruding beta-hairpin arm of each domain II holds the body of the other. The unique "receptor-mediated dimerization" was verified by EGFR mutagenesis.     

Enhancement of tyrosine kinase activity of the Drosophila epidermal growth factor receptor homolog by alterations of the transmembrane domain

The Drosophila epidermal growth factor receptor homolog (DER) displays sequence similarity to both the epidermal growth factor (EGF) receptor and the neu vertebrate proteins. We have examined the possibility of deregulating the tyrosine kinase activity of DER by introducing structural changes which mimic the oncogenic alterations in the vertebrate counterparts. Substitution of valine by glutamic acid in the transmembrane domain, in a position analogous to the oncogenic mutation in the rat neu gene, elevated the in vivo kinase activity of DER in Drosophila Schneider cells sevenfold. A chimera containing the oncogenic neu extracellular and transmembrane domains and the DER kinase region, also showed a threefold elevated activity relative to a similar chimera with normal neu sequences. Double truncation of DER in the extracellular and cytoplasmic domains, mimicking the deletions in the v-erbB oncogene, did not however result in stimulation of in vivo kinase activity. The chimeric constructs were also expressed in monkey COS cells, and similar results were obtained. The ability to enhance the DER kinase activity by a specific structural modification of the transmembrane domain demonstrates the universality of this activation mechanism and strengthens the notion that this domain is intimately involved in signal transduction. These results also support the inclusion of DER within the tyrosine-kinase receptor family.     

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.     

Perinuclear location and recycling of epidermal growth factor receptor kinase: immunofluorescent visualization using antibodies directed to kinase and extracellular domains

This paper describes studies on the migratory behavior of epidermal growth factor (EGF) receptor kinase using antibodies that are specific for either the kinase domain or the extracellular domain of the receptor. Antiserum was raised to a 42,000-D subfragment of EGF receptor, which was shown earlier to carry the kinase catalytic site but not the EGF-binding site. Another antiserum was raised to the pure intact 170,000-D EGF receptor. The specificities of these antibodies were established by immunoprecipitation and immunoblotting experiments. The domain specificity was examined by indirect immunofluorescent staining of fixed cells. The anti-42-kD peptide antibody could bind specifically to EGF receptors of both human and murine origin and was found to be directed to the cytoplasmic part of the molecule. It did not bind to EGF receptor-negative cells, which contained other types of tyrosine kinases. The antibodies raised against the intact receptor recognized only EGF receptor-specific epitopes and were directed to the extracellular part of the molecule. The anti-receptor antibodies described above were used to visualize the cyclic locomotory behavior of EGF receptor kinase under various conditions of EGF stimulation and withdrawal. The receptor was examined in fixed and permeabilized cells by indirect immunofluorescent staining. The results demonstrate the following: (a) the receptor kinase domain migrates to the perinuclear region upon challenge with EGF; (b) both extracellular and cytoplasmic domains of the receptor are involved in migration as a unit; (c) withdrawal of EGF results in rapid recycling of the perinuclear receptors to the plasma membrane; (d) this return to the cell surface is inhibited by methylamine, chloroquine, and monensin; and (e) neither the internal migration nor the recycling process is blocked by inhibitors of protein biosynthesis.     

Activation of preformed EGF receptor dimers by ligand-induced rotation of the transmembrane domain

The epidermal growth factor receptor plays crucial roles throughout the development of multicellular organisms, and inappropriate activation of the receptor is associated with neoplastic transformation of many cell types. The receptor is thought to be activated by ligand-induced homodimerisation. Here, however, we show by chemical cross-linking and sucrose density-gradient centrifugation that in the absence of bound ligand the receptor has an ability to form a dimer and exists as a preformed dimer on the cell surface. We also analysed the receptor dimerisation by inserting cysteine residues at strategic positions about the putative alpha-helix axis of the extracellular juxtamembrane region. The mutant receptors spontaneously formed disulphide bridges and transformed NIH3T3 cells in the absence of ligand, depending upon the positions of the cysteine residue inserted. Kinetic analyses of the disulphide bonding indicate that EGF binding induces flexible rotation or twist of the juxtamembrane region of the receptor in the plane parallel with the lipid bilayer. The binding of an ATP competitor to the intracellular domain also induced similar flexible rotation of the juxtamembrane region. All the disulphide-bonded dimers had flexible ligand-binding domains with the same biphasic affinities for EGF as the wild-type. These results demonstrate that ligand binding to the flexible extracellular domains of the receptor dimer induce rotation or twist of the juxtamembrane regions, hence the transmembrane domains, and dissociate the dimeric, inactive form of the intracellular domains. The flexible rotation of the intracellular domains may be necessary for the intrinsic catalytic kinase to become accessible to the multiple tyrosine residues present in the regulatory domain and various substrates, and may be a common property of many cell-surface receptors, such as the insulin receptor.     

The chicken IL-1 receptor: differential evolution of the cytoplasmic and extracellular domains.

The evolutionary conservation of a sequence or part of it can help to identify the essential functional and structural domains within a protein. We have cloned and characterised a cDNA coding for the type-I interleukin-1 receptor (IL-1R) of chick (ch) embryo fibroblasts. The comparison of the amino acid (aa) sequences of the avian with that of murine (m) and human (h) IL-1Rs shows a 60% homology. The intracellular domain is the most conserved region of the chIL-1R, showing 76-79% homology to the murine and human sequences, respectively. The striking conservation of the cytoplasmic region of the receptor is confirmed by its homology with the Toll receptor protein of Drosophila melanogaster. The alignment between the chicken and D. melanogaster proteins shows the presence of four aa blocks with more than 80% homology. The possible functional significance of this homology is discussed. The extracellular binding region of the receptor has a clearly recognisable immunoglobulin-like structure although the sequence divergence is higher than in the cytoplasmic domain.     

Molecular cloning and characterization of the human and porcine transforming growth factor-beta type III receptors.

Full-length cDNAs for the transforming growth factor-beta (TGF-beta) type III receptors were isolated from porcine uterus and human placenta cDNA libraries. The human TGF-beta type III receptor coding region encodes a protein of 849 amino acids with a single transmembrane domain and a short stretch of the intracellular domain. Potential glycosaminoglycan attachment sites were found in the extracellular domain. The overall amino acid sequence identities with those of the porcine and rat TGF-beta type III receptors were 83% and 81%, respectively. A high degree of sequence conservation was observed in the transmembrane and intracellular domains, which also have sequence similarity with human endoglin. In addition, two portions with 29 and 52 amino acids in the extracellular domain were found to be substantially similar with human endoglin.     

Self-phosphorylation of epidermal growth factor receptor: evidence for a model of intermolecular allosteric activation

The membrane receptor for epidermal growth factor (EGF) is a 170,000-dalton glycoprotein composed of an extracellular EGF-binding domain and a cytoplasmic kinase domain connected by a stretch of 23 amino acids traversing the plasma membrane. The binding of EGF to the extracellular domain activates the cytoplasmic kinase function even in highly purified preparations of EGF receptor, suggesting that the activation occurs exclusively within the EGF receptor moiety. Conceivably, kinase activation may require the transfer of a conformational change through the single transmembrane region from the ligand binding domain to the cytoplasmic kinase region. Alternatively, ligand-induced receptor-receptor interactions may activate the kinase and thus bypass this requirement. Both mechanisms were contrasted by employing independent experimental approaches. The following lines of evidence support an intermolecular mechanism for the activation of the detergent-solubilized receptor: the EGF-induced receptor self-phosphorylation has a parabolic dependence on the concentration of EGF receptor, cross-linking of EGF receptors by antibodies or lectins stimulates receptor self-phosphorylation, immobilization of EGF receptor on various solid matrices prevents EGF from activating the kinase function, and cross-linking of EGF receptors increases their affinity toward EGF. On the basis of these results, an allosteric aggregation model is formulated for the activation of the cytoplasmic kinase function of the receptor by EGF. This model may be relevant to the mechanism by which the mitogenic signal of EGF is transferred across the membrane.     

Epidermal growth factor (EGF) induces oligomerization of soluble, extracellular, ligand-binding domain of EGF receptor. A low resolution projection structure of the ligand-binding domain.

Ligand-induced oligomerization is a universal phenomenon among growth factor receptors. Although the mechanism involved is yet to be defined, much evidence indicates that receptor oligomerization plays a crucial role in receptor activation and signal transduction. Here we show that epidermal growth factor (EGF) is able to stimulate the oligomerization of a recombinant, soluble, extracellular ligand-binding domain of EGF receptor. Covalent cross-linking experiments, analysis by sodium dodecyl sulfate-gel electrophoresis, size exclusion chromatography, and electron microscopy demonstrate that receptor dimers, trimers and larger multimers are formed in response to EGF. This establishes that receptor oligomerization is an intrinsic property of the extracellular ligand-binding domain of EGF receptor. Ligand-induced conformational change in the extracellular domain will stimulate receptor-receptor interactions. This may bring about the allosteric change involved in signal transduction from the extracellular domain across the plasma membrane, resulting in the activation of the cytoplasmic kinase domain. Electron microscopic images of individual extracellular ligand-binding domains appear as clusters of four similarly-sized stain-excluding areas arranged around a central, relatively less stain-excluded area. This suggests that the extracellular ligand-binding domain is structurally composed of four separate domains.     

Activation of receptor protein-tyrosine kinases from the cytoplasmic compartment

It is widely accepted that receptor protein-tyrosine kinases (RTKs) are activated upon dimerization by binding to their extracellular ligands. However, EGF receptor (EGFR) dimerization per se does not require ligand binding. Instead, its cytoplasmic kinase domains have to form characteristic head-to-tail asymmetric dimers to become active, where one 'activator' domain activates the other 'receiver' domain. The non-catalytic, cytoplasmic regions of RTKs, namely the juxtamembrane and carboxy terminal portions, also regulate kinase activity. For instance, the juxtamembrane region of the RTK MuSK inhibits the kinase domain probably together with a cellular factor(s). These findings suggest that RTKs could be activated by cytoplasmic proteins. Indeed, Dok-7 and cytohesin have recently been identified as such activators of MuSK and EGFR, respectively. Given that failure of Dok-7 signaling causes myasthenia, and inhibition of cytohesin signaling reduces the proliferation of EGFR-dependent cancer cells, cytoplasmic activators of RTKs may provide new therapeutic targets.     

Regulation of EGF receptor expression and function

From the results of these studies of the activities of the various EGF receptor mutants we were able to disassociate the ability of EGF to increase intracellular calcium from its ability to induce genes and to cause morphological transformation and growth. These results lead us to the following concept. The kinase domain has a C-terminal border at about residue 957. The remainder of the C-terminus is regulatory. The 164 amino acids from residue 1022 to 1186 constitute an inhibitory region for the kinase. It contributes to ligand-induced internalization because this is reduced in a mutant receptor truncated to residue 1052. Proximally within the C-terminus kinase inhibitory domain is a domain that is required for endocytosis and for raising intracellular calcium that we call the calcium internalization (CAIN) domain. In summary, we have found that the kinase activity of the EGF receptor is required for its function even when all of the self-phosphorylation sites have been removed. The EGF receptor has several distinct cytoplasmic domains that are important for its activity to regulate gene expression, DNA synthesis, and the intracellular calcium level. Biological signaling occurs from the cell surface via essential protein tyrosine kinase activity with ligand-induced internalization serving to abbrogate the biological signal.     

Interactions of Drosophila Cbl with epidermal growth factor receptors and role of Cbl in R7 photoreceptor cell development.

The human proto-oncogene product c-Cbl and a similar protein in Caenorhabditis elegans (Sli-1) contain a proline-rich COOH-terminal region that binds Src homology 3 (SH3) domains of proteins such as the adapter Grb2. Cb1-Grb2 complexes can be recruited to tyrosine-phosphorylated epidermal growth factor (EGF) receptors through the SH2 domain of Grb2. Here we identify by molecular cloning a Drosophila cDNA encoding a protein (Drosophila Cbl [D-Cbl]) that shows high sequence similarity to the N-terminal region of human c-Cbl but lacks proline-rich sequences and fails to bind Grb2. Nonetheless, in COS-1 cells, expression of hemagglutinin epitope-tagged D-Cbl results in its coimmunoprecipitation with EGF receptors in response to EGF. EGF also caused tyrosine phosphorylation of D-Cbl in such cells, but no association of phosphatidylinositol 3-kinase was detected in assays using anti-p85 antibody. A point mutation in D-Cbl (G305E) that suppresses the negative regulation of LET-23 by the Cbl homolog Sli-1 in C. elegans prevented tyrosine phosphorylation of D-Cbl as well as binding to the liganded EGF receptor in COS-1 cells. Colocalization of EGF receptors with both endogenous c-Cbl or expressed D-Cbl in endosomes of EGF-treated COS-1 cells is also demonstrated by immunofluorescence microscopy. In lysates of adult transgenic Drosophila melanogaster, GST-DCbl binds to the tyrosine-phosphorylated 150-kDa torso-DER chimeric receptor. Expression of D-Cbl directed by the sevenless enhancer in intact Drosophila compromises severely the development of the R7 photoreceptor neuron. These data suggest that despite the lack of Grb2 binding sites, D-Cbl functions as a negative regulator of receptor tyrosine kinase signaling in the Drosophila eye by a mechanism that involves its association with EGF receptors or other tyrosine kinases.     

Characterization of a comparative model of the extracellular domain of the epidermal growth factor receptor

The Epidermal Growth Factor (EGF) receptor is a tyrosine kinase that mediates the biological effects of ligands such as EGF and transforming growth factor alpha. An understanding of the molecular basis of its action has been hindered by a lack of structural and mutational data on the receptor. We have constructed comparative models of the four extracellular domains of the EGF receptor that are based on the structure of the first three domains of the insulin-like growth factor-1 (IGF-1) receptor. The first and third domains of the EGF receptor, L1 and L2, are right-handed beta helices. The second and fourth domains of the EGF receptor, S1 and S2, consist of the modules held together by disulfide bonds, which, except for the first module of the S1 domain, form rod-like structures. The arrangement of the L1 and S1 domains of the model are similar to that of the first two domains of the IGF-1 receptor, whereas that of the L2 and S2 domains appear to be significantly different. Using the EGF receptor model and limited information from the literature, we have proposed a number of regions that may be involved in the functioning of the receptor. In particular, the faces containing the large beta sheets in the L1 and L2 domains have been suggested to be involved with ligand binding of EGF to its receptor.     

The mannose 6-phosphate receptor cytoplasmic domain is not sufficient to alter the cellular distribution of a chimeric EGF receptor.

Unlike most receptors, 300 kd mannose 6-phosphate receptors (MPRs) are localized primarily in the trans-Golgi network (TGN) and endosomes, and they cycle constitutively between these compartments. Yet, when present at the cell surface, MPRs are internalized together with other cell surface receptors in clathrin-coated vesicles. We constructed a chimeric receptor, comprised of human EGF receptor extracellular and transmembrane domains joined to the bovine MPR cytoplasmic domain, to test whether the MPR cytoplasmic domain contained sufficient information to direct a cell surface receptor into both of these transport pathways. The expressed protein was stable, bound EGF with high affinity, and was efficiently endocytosed and recycled back to the cell surface, in the presence or absence of EGF. If the cytoplasmic domain alone is responsible for sorting native MPRs, chimeric receptors might have been expected to be located primarily in the TGN and in endosomes at steady state. Surprisingly, under conditions in which essentially all endogenous MPRs were intracellular, greater than 85% of the chimeric receptors were located at the cell surface. These experiments demonstrate that the MPR cytoplasmic domain is not sufficient to alter the distribution of the EGF receptor, and suggest a role for extracellular and transmembrane domains in MPR routing.