Regulation of signal transduction and signal diversity by receptor oligomerization

Mitogenic signaling from the egf receptor is attenuated by a phospholipase C-gamma/protein kinase C feedback mechanism

We recently demonstrated that epidermal growth factor receptor (EGFR)-mediated signaling of cell motility and mitogenesis diverge at the immediate post-receptor level. How these two mutually exclusive cell responses cross-communicate is not known. We investigated a possible role for a phospholipase C (PLC)-dependent feedback mechanism that attenuates EGF-induced mitogenesis. Inhibition of PLC gamma activation by U73122 (1 microM) augmented the EGF-induced [3H]thymidine incorporation by 23-55% in two transduced NR6 fibroblast lines expressing motility-responsive EGFR; increased cell division and mitosis was observed in parallel. The time dependence of this increase revealed that it was due to an increase in maximal incorporation and not a foreshortened cell cycle. Motility-responsive cell lines expressing a dominant-negative PLC gamma fragment (PLCz) also demonstrated augmented mitogenic responses by 25-68% when compared with control cells. PLCz- or U73122-augmented mitogenesis was not observed in three non-PLC gamma activating, nonmotility-responsive EGFR-expressing cell lines. Protein kinase C (PKC), which may be activated by PLC-generated second messengers, has been proposed as mediating feedback attenuation due to its capacity to phosphorylate EGFR and inhibit the receptor's tyrosine kinase activity. Inhibition of PKC by Calphostin C (0.05 microM) resulted in a 57% augmentation in the fold of EGF-induced thymidine incorporation. To further establish PKC's role in this feedback attenuation mechanism, an EGFR point mutation, in which the PKC target threonine654 was replaced by alanine, was expressed. Cells expressing these PKC-resistant EGFR constructs demonstrated EGF-induced motility comparable to cells expressing the threonine-containing EGFR. However, when these cells were treated with U73122 or Calphostin C, the mitogenic responses are not enhanced. These findings suggest a model in which PKC activation subsequent to triggering of motility-associated PLC gamma activity attenuates the EGFR mitogenic response.

Targeting the epidermal growth factor receptor for therapy of carcinomas

As a group, the carcinomas represent a substantial proportion of all human malignancies, but, with relatively few exceptions, current treatments are ineffective. Modification of existing chemotherapeutic agents has not led to significant improvements in the survival of carcinoma patients, and development of new therapeutic strategies is imperative. It is now becoming apparent that activation of the epidermal growth factor receptor (EGF-R) has much wider implications than a straightforward stimulation of cell division. The pleiotropic effects of EGF-R signalling may influence tumour behaviour and the response of carcinomas to treatment; these are important considerations for the development of new therapies that aim to exploit the expression or modulate the function of the EGF-R in these tumours.

Identification of the cysteine residues involved in the class I disulfide bonds of the human insulin receptor: properties of insulin receptor monomers

The cysteine residues involved in the class I disulfide bonds between the alpha subunits in the (alpha beta)2 dimer of the human insulin receptor have been identified by labeling with N-ethylmaleimide and by site-directed mutagenesis. Both cysteine 524 and cysteine 682 form interchain disulfide bonds; their conversion to serine residues results in the absence of receptor dimers and the presence of alpha beta monomers. The receptor monomers have a slightly lower affinity for insulin than the native receptor dimers. Insulin binding to the receptor monomers promotes their dimerization in the plasma membrane; at nanomolar concentrations of receptor, both unliganded and liganded receptors are monomers. Receptor monomers are stimulated by insulin to autophosphorylate and to phosphorylate exogenous subtrates with the same efficiency as the receptor dimers. The conclusion is that receptor dimerization is not required to activate the tyrosine kinase activity of the insulin receptor.

Ligand-independent dimerization of oncogenic v-erbB products involves covalent interactions

Mutant v-erbB products of avian c-erbB1 have previously been used to correlate structural domains of the receptor encoded by this proto-oncogene with tissue-specific transformation potential. In these studies, deletion of the ligand-binding domain of the receptor has been shown to be required for transformation of erythroblasts, fibroblasts, and endothelial cells. It has, therefore, been postulated that deletion of this domain results in an allosteric change in the receptor analogous to the ligand-bound state of the epidermal growth factor receptor; i.e., it induces a receptor conformation that is constitutively active with respect to mitogenic signaling. While oncogenic v-erbB products have been shown to be expressed on the cell surface of both fibroblasts and erythroblasts, no comprehensive analysis of the oligomeric potential of these products has been conducted. Since the first event known to follow epidermal growth factor binding to its receptor is oligomerization, and receptor dimerization has been correlated with mitogenic signaling, we have carefully analyzed the ability of several v-erbB products to oligomerize in the three target cell types transformed by these oncogenes. In this report, we demonstrate the v-erbB products can efficiently homodimerize in all three target tissues, that this dimerization is ligand independent and occurs at the cell surface, and that there is no apparent correlation between v-erbB dimerization and transformation of avian fibroblasts. Furthermore, both oncogenic and nononcogenic v-erbB products can heterodimerize with the native c-erbB1 product in chicken embryo fibroblasts, suggesting that heterodimerization between v-erB and native c-erbB1 is not sufficient to result in c-erbB1-mediated sarcomagenesis.

Epidermal growth factor (EGF)

Despite the wealth of information concerning EGF and its related peptides, its precise role in the control of gastrointestinal functions is still not fully resolved. However, there is no doubt that it can have some very potent effects on the gastrointestinal tract. These may be related to the control of growth and development and to the regular control of cell renewal. Nevertheless, in the adult, EGF may only be active in response to luminal damage and repair, and furthermore this may also only occur if the luminal EGF is protected from proteolytic degradation. Notwithstanding this, 'EGF'-like responses may be evoked in the gut by intestinal TGF-alpha. The possible therapeutic use of EGF and members of its family in ulcer therapy will be discussed in later Chapters of this volume, other potential uses are in the control of necrotising enteritis and in the alleviation of the mucositis associated with cancer treatment.

pH-Dependent self-association of the Src homology 2 (SH2) domain of the Src homologous and collagen-like (SHC) protein

The Src homologous and collagen-like (SHC) protein plays an essential role in signal transduction pathways in that it participates in the chain of events that leads to the activation of the protein Ras. The crystal structure of the SH2 domain of SHC has been determined using the method of multiple isomorphous replacement at a resolution of 2.5 A. The SH2 domain of SHC is similar in fold to other SH2 domains. The peptide-binding surfaces resemble that of the SH2 domain of Src in that a deep pocket is formed where the third amino acid C-terminal to the phosphotyrosine can insert. A novel feature of this structure is the observation of a disulfide bond and an extensive dimer interface between two symmetry-related molecules. Solution studies under reducing conditions using analytical centrifugation and PAGE suggest that the SH2 domain of SHC dimerizes in a pH-dependent manner where low pH conditions (approximately 4.5) are conducive to dimer formation. Dimerization of SHC may have important biological implications in that it may promote the assembly of large heteromultimeric signaling complexes.

Stimulation of growth factor receptor signal transduction by activation of voltage-sensitive calcium channels

To understand the mechanisms by which electrical activity may generate long-term responses in the nervous system, we examined how activation of voltage-sensitive calcium channels (VSCCs) can stimulate the Ras/mitogen-activated protein kinase (MAPK) signaling pathway. Calcium influx through L-type VSCCs leads to tyrosine phosphorylation of the adaptor protein Shc and its association with the adaptor protein Grb2, which is bound to the guanine nucleotide exchange factor Sos1. In response to calcium influx, Shc, Grb2, and Sos1 inducibly associate with a 180-kDa tyrosine-phosphorylated protein, which was determined to be the epidermal growth factor receptor (EGFR). Calcium influx induces tyrosine phosphorylation of the EGFR to levels that can activate the MAPK signaling pathway. Thus, ion channel activation stimulates growth factor receptor signal transduction.

Clustered syk tyrosine kinase domains trigger phagocytosis

Phagocytosis is a phylogenetically primitive mechanism adapted by specialized cells of the immune system to ingest particulate pathogens. Recent evidence suggests that the program of specific cytoskeletal rearrangements that underlies phagocytosis may share elements with the antigen receptor signaling pathway in lymphocytes. Tyrosine phosphorylation, necessary for both lymphocyte effector function and phagocytosis, is thought to allow cytoskeletal elements to couple to the intracellular domains of antigen and Fc receptor subunits. We show here that the intracellular domains of the receptors are not inherently required for cytoskeletal coupling. Chimeric transmembrane proteins bearing syk but not src family tyrosine kinase domains are capable of autonomously triggering phagocytosis and redistribution of filamentous actin in COS cells. These responses cannot be initiated by a receptor chimera bearing a point mutation in the syk catalytic domain, and the kinase domain alone is sufficient for initiating cytoskeletal coupling.

Association of signaling proteins with a nonmitogenic heterodimeric complex composed of epidermal growth factor receptor and kinase-inactive p185c-neu

The functional consequences of heterodimer formation between the epidermal growth factor receptor (EGFr) and the p185c-neu receptor tyrosine kinase include increased mitogenic and transformation potencies. To determine the possible alteration of signal transduction pathways resulting from this heteromeric complex, the capacity of several signaling proteins to associate with the heterodimeric receptors has been assayed. The in vivo interaction with the EGFr/p185c-neu heterodimer of several signal transduction proteins, including phospholipase C-gamma 1 (PLC-gamma 1), the p85 subunit of phosphotidylinositol 3-kinase, the ras GTPase activating protein, SHC, NCK, p72RAF, and the tyrosine phosphatase SHPTP2, was measured by coimmunoprecipitation. The binding of these signaling proteins to a complex composed of EGFr and a kinase-inactive form of p185 (p185K757M) was not impaired, even though the mitogenic and transformation activity of this complex had been abrogated. In addition, the EGF-induced phosphorylation of GAP, p85, and PLC-gamma 1 did not correlate with the dominant-negative action of p185K757M on EGFr function. Thus, substrate association and phosphorylation do not correlate stringently with the mitogenic and transforming activity of this receptor complex, suggesting additional pathways or mechanisms vital to EGFr/p185c-neu heterodimeric signaling.

Epidermal growth factor behaves as a partial agonist in hepatocytes: effects on DNA synthesis in primary culture and competition with transforming growth factor alpha

The structurally related mitogens epidermal growth factor (EGF) and transforming growth factor (alpha (TGFalpha) are believed to exert all their effects via the same receptor. We have compared the effects of EGF and TGFalpha, and examined their interaction, on DNA synthesis in cultured rat hepatocytes. The potency of the two agents was similar, or slightly higher for EGF, but TGFalpha stimulated the DNA synthesis more efficiently, producing at high levels a rate of S phase entry that clearly exceeded (two to threefold) that obtained with maximally effective concentrations of EGF. While the hepatocytes became more sensitive both to TGFalpha and EGF when addition of the agents was postponed until late in the prereplicative period, TGFalpha exhibited higher efficacy than EGF both at early and late exposure. When EGF and TGFalpha were added together at 24 h, TGFalpha further enhanced the DNA synthesis in the presence of a saturating concentration (5 nM) of EGF, while EGF dose-dependently reduced the DNA synthesis in the presence of a high concentration (10 nM) of TGFalpha. The results show a lower efficacy of EGF than of TGFalpha, and, therefore, EGF displays the characteristics of a partial agonist in its EGF receptor-mediated growth stimulation in hepatocytes.

The specificity of the transforming growth factor beta receptor kinases determined by a spatially addressable peptide library

Type I and II receptors for the transforming growth factor beta (TGF-beta) are transmembrane serine/threonine kinases that are essential for TGF-beta signaling. However, little is known about their in vivo substrates or signal transduction pathways. To determine the substrate specificity of these kinases, we developed combinatorial peptide libraries synthesized on a hydrophilic matrix that is easily accessible to proteins in aqueous solutions. When we subjected these libraries to phosphorylation by the cAMP-dependent protein kinase, we obtained the optimal peptide sequence RRXS (I/L/V), in perfect agreement with the substrate sequence deduced from mutagenesis and crystal structure analyses. By using the same libraries, we showed that the optimal substrate peptide for both the type I and II TGF-beta receptors was KKKKKK(S/T)XXX. Since the two kinases are thought to play different roles in intracellular signal transduction, it was a surprise to find that they have almost identical substrate specificity. Our method is direct, sensitive, and simple and provides information about the kinase specificity for all the amino acid residues at each position.

PDGF-BB, IGF-I and mechanical load stimulate DNA synthesis in avian tendon fibroblasts in vitro

Resident cells in the surface epitenon and internal compartment of flexor tendons are subjected to cyclic mechanical load as muscle contracts to move limbs or digits. Tendons are largely tensile load bearing tissues and are highly matrix intensive with nondividing cells providing maintenance functions. However, when an injury occurs, tendon cells are stimulated to divide by activated endogenous growth factors and those from platelets and plasma. We hypothesize that tendon cells detect mechanical load signals but do not interpret such signals as mitogenic unless an active growth factor is present. We have used an in vitro mechanical load model, application of cyclic strain to cells cultured on flexible bottomed culture plates, to test the hypothesis that tendon cells require platelet-derived growth factor (PDGF-BB) and insulin-like growth factor-I (IGF-I) in addition to mechanical load to stimulate DNA synthesis. In addition, we demonstrate that in avian tendon cells, load and growth factors stimulate phosphorylation of tyrosine residues in multiple proteins, including pp60src, a protein kinase that phosphorylates receptor protein tyrosine kinases. A lack of mitogenic responsiveness to mechanical load alone by tendon cells may be a characteristic of a regulatory pathway that modulates cell division.

The N-terminal cytoplasmic tail of the aspartate receptor is not essential in signal transduction of bacterial chemotaxis

To determine the role in transmembrane signaling of the N-terminal peptide of the first transmembrane region of the aspartate receptor, it was subjected to extensive mutagenesis. Drastic changes did not alter the chemotactic ability of the receptor to aspartate significantly. Thus the cytoplasmic N terminus of the first transmembrane region does not play an essential role in transmembrane signaling, and the entire signal that is transmitted to the cytoplasmic domain must be sent through the second transmembrane region. This eliminates the models requiring an interaction of this N-terminal peptide with the remaining cytoplasmic portion of the receptor.

SHC and GRB-2 are constitutively by an epidermal growth factor receptor with a point mutation in the transmembrane domain

A single point mutation, Glu627--> Val, equivalent to the activating mutation in the Neu oncogene, was inserted in the transmembrane domain of the human epidermal growth factor (EGF) receptor. Unlike the wild type, Glu627-EGF receptor, transfected in NIH3T3 cells, gave rise to focal transformation and growth in agar even in the absence EGF. Constitutive activity of mutant EGF receptor amounted to 20% of that of wild type receptor stimulated by EGF. In addition, the mutant receptor was more sensitive to EGF, reaching maximum transforming activity at 5 ng/ml EGF. NIH3T3 cells expressing Glu627-EGF receptor showed a transformed phenotype and were not arrested in G0 upon serum deprivation. The mutant receptor was constitutively autophosphorylated, and several other cellular proteins were phosphorylated on tyrosine in absence of the ligand. Among these, the SHC adaptor protein was phosphorylated in absence of EGF, the other adaptor, GRB-2 was constitutively associated with the Glu627-EGF receptor in vivo and in vitro, and mitogen-activated protein kinase was constitutively phosphorylated. In contrast, other EGF receptor substrates, like phospholipase C gamma, were not phosphorylated in absence of EGF. The mutant receptor showed a higher sensitivity to cleavage by calpain both in absence and presence of EGF, appeared as a 170- and 150-kDa doublet in cell extracts, and a specific calpain inhibitor blocked the appearance of the 150-kDa form. Since the calpain cleavage site is located in the receptor cytoplasmic tail, this finding suggests that the Glu627 mutation induces a slightly different conformation in the EGF receptor intracellular domain. In conclusion, our data show that a point mutation in the EGF receptor transmembrane domain was able to constitutively activate the receptor and to induce transformation via constitutive activation of the Ras pathway.

A family of putative receptor-adenylate cyclases from Leishmania donovani

Leishmania parasites are exposed to pronounced changes in their environment during their life cycle as they migrate from the sandfly midgut to the insect proboscis and then into the phagolysosomes of the vertebrate macrophages. The developmental transformations that produce each life cycle stage of the parasite may be signaled in part by binding of environmental ligands to receptors which mediate transduction of extracellular signals. We have identified a family of five clustered genes in Leishmania donovani which may encode signal transduction receptors. The coding regions of two of these genes, designated rac-A and rac-B, have been sequenced and shown to code for proteins with an NH2-terminal hydrophilic domain, an intervening putative transmembrane segment, and a COOH-terminal domain that has high sequence identity to the catalytic domain from adenylate cyclases in other eukaryotes. We have expressed the receptor-adenylate cyclase protein (RAC)-A protein in Xenopus oocytes and demonstrated that it functions as an adenylate cyclase. Although RAC-B exhibits no catalytic activity when expressed in oocytes, co-expression of RAC-A and RAC-B negatively regulates the adenylate cyclase activity of RAC-A, suggesting that these two proteins interact in the membrane. Furthermore, a truncated version of RAC-A functions as a dominant negative mutant that inhibits the catalytic activity of the wild type receptor. The rac-A and rac-B genes encode developmentally regulated mRNAs which are expressed in the insect stage but not in the mammalian host stage of the parasite life cycle.

Mechanoreception at the cellular level: the detection, interpretation, and diversity of responses to mechanical signals

Cells from diverse tissues detect mechanical load signals by similar mechanisms but respond differently. The diversity of responses reflects the genotype of the cell and the mechanical demands of the resident tissue. We hypothesize that cells maintain a basal equilibrium stress state that is a function of the number and quality of focal adhesions, the polymerization state of the cytoskeleton, and the amount of extrinsic, applied mechanical deformation. A load stimulus detected by a mechano-electrochemical sensory system, including mechanically sensitive ion channels, integrin-cytoskeleton machinery, and (or) a load-conformation sensitive receptor or nonreceptor tyrosine kinase, may activate G proteins, induce second messengers, and activate an RPTK or JAK/STAT kinase cascade to elicit a response. We propose the terms autobaric to describe a self-loading process, whereby a cell increases its stress state by contracting and applying a mechanical load to itself, and parabaric, whereby a cell applies a load to an adjacent cell by direct contact or through the matrix. We predict that the setpoint for maintaining this basal stress state is affected by continuity of incoming mechanical signals as deformations that activate signalling pathways. A displacement of the cytoskeletal machinery may result in a conformational change in a kinase that results in autophosphorylation and cascade initiation. pp60Src is such a kinase and is part of a mechanosensory protein complex linking integrins with the cytoskeleton. Cyclic mechanical load induces rapid Src phosphorylation. Regulation of the extent of kinase activation in the pathway(s) may be controlled by modulators such as G proteins, kinase phosphorylation and activation, and kinase inhibitors or phosphatases. Intervention at the point of ras-raf interaction may be particularly important as a restriction point.

Binding stoichiometry of the cytotoxic T lymphocyte-associated molecule-4 (CTLA-4). A disulfide-linked homodimer binds two CD86 molecules

CD28 and CTLA-4 are homologous T cell receptors of the immunoglobulin (Ig) superfamily, which bind B7 molecules (CD80 and CD86) on antigen-presenting cells and transmit important costimulatory signals during T cell activation. Here we have investigated the subunit structure of CTLA-4 and the stoichiometry of its binding to B7 molecules. We demonstrate CTLA-4 is a homodimer interconnected by one disulfide bond in the extracellular domain at cysteine residue 120. Each monomeric polypeptide chain of CTLA-4 contains a high affinity binding site for B7 molecules; soluble CTLA-4 and CD86 form complexes containing equimolar amounts of monomeric CTLA-4 and CD86 (i.e. a 2:2 molecular complex). Thus, CTLA-4 and probably CD28 have a receptor structure consisting of preexisting covalent homodimers with two binding sites. Dimerization of CTLA-4 and CD28 is not required for B7 binding, nor is it sufficient to trigger signaling.

Multisubunit receptors in the immune system and their association with the cytoskeleton: in search of functional significance

Various multisubunit receptors of the immune system share similarities in structure and induce closely related signal transduction pathways upon ligand binding. Examples include the T cell antigen receptor (TCR), the B cell antigen receptor (BCR), and the high-affinity receptor for immunoglobulin E (Fc epsilon RI). Although these receptors are devoid of intrinsic kinase activity, they can associate with a similar array of intracellular kinases, phosphatases and other signaling molecules. Furthermore, these receptor complexes all form an association with the cytoskeletal matrix. In this review, we compare the structural and functional characteristics of the TCR, BCR and Fc epsilon RI. We examine the role of the cytoskeleton in regulating receptor-mediated signal transduction, as analyzed in other well-characterized receptors, including the epidermal growth factor receptor and integrin receptors. On the basis of this evidence, we review the current data depicting a cytoskeletal association for multisubunit immune system receptors and explore the potential bearing of this interaction on signaling function.

Src family protein tyrosine kinases and cellular signal transduction pathways

Members of the Src family of protein tyrosine kinases are thought to be involved in signal transduction pathways that control growth and cellular architecture. In recent years it has been shown that they interact with receptor tyrosine kinases (such as the platelet-derived growth factor receptor) and with receptors that themselves lack intrinsic tyrosine kinase activity (such as the interleukin-2 receptor). In some cases they are required for mitogenic signalling by these receptors. They are also activated in response to stress and during mitosis.

The first structure of a receptor tyrosine kinase domain: a further step in understanding the molecular basis of insulin action

Both the observed cis-inhibition and the proposed trans-activation of the insulin receptor tyrosine kinase help explain insulin signalling through its receptor.