The role of insulin receptor autophosphorylation in signal transduction.

We have examined the role of autophosphorylation in insulin signal transmission by oligonucleotide directed mutagenesis of seven potential tyrosine autophosphorylation sites in the human insulin receptor. Chinese hamster ovary cells transfected with these receptors were analyzed for insulin stimulated 2-deoxyglucose uptake, thymidine incorporation, endogenous substrate phosphorylation, and in vitro kinase activity. We found that phosphorylation on tyrosine residues 953, 1316, and 1322 were not necessary for receptor-mediated signal transduction. Mutation of tyrosine 960 reduced but did not abolish the signaling capabilities of the receptor. Finally, the simultaneous mutation of tyrosine residues 1146, 1150, and 1151 (the numbering system is that of Ullrich et al. (Ullrich, A., Bell, J. R., Chen, E. Y., Herrera, R., Petruzzelli, L. M., Dull, T. J., Gray, A., Coussens, L., Liao, Y. C., Tsubokawa, M., Mason, A., Seeburg, P.H., Grunfeld, C., Rosen, O. M., and Ramachandran, J. (1985) Nature 313, 756-761) resulted in a biologically inactive receptor, suggesting that the insulin receptor can be inactivated by removal of key autophosphorylation sites.     

A mechanistic role for polypeptide hormone receptor lateral mobility in signal transduction

Summary Lateral diffusion of membrane-integral receptors within the plane of the membrane has been postulated to be mechanistically important for signal transduction. Direct measurement of polypeptide hormone receptor lateral mobility using fluorescence photobleaching recovery techniques indicates that tyrosine kinase receptors are largely immobile at physiological temperatures. This is presumably due to their signal transduction mechanism which requires intermolecular autophosphorylation through receptor dimerization and thus immobilization for activation. In contrast, G-protein coupled receptors must interact with other membrane components to effect signal transduction, and consistent with this, the phospholipase C-activating vasopressin V₁- and adenylate cyclase activating V₂-receptors are highly laterally mobile at 37°C. Modulation of the V₂-receptor mobile fraction (f) has demonstrated a direct correlation between f and receptor-agonist-dependent maximal cAMP productionin vivo at 37°C. This indicates that f is a key parameter in hormone signal transduction especially at physiological hormone concentrations, consistent with mobile receptors being required to effect V₂-agonist-dependent activation of G-proteins. Measurements using a V₂-specific antagonist show that antagonist-occupied receptors are highly mobile at 37°C, indicating that receptor immobilization is not the basis of antagonism. In contrast to agonist-occupied receptor however, antagonistoccupied receptors are not immobilized prior to endocytosis and down-regulation. Receptors may thus be freely mobile in the absence of agonistic ligand; stimulation by hormone agonist results in receptor association with other proteins, probably including cytoskeletal components, and immobilization. Receptor immobilization may be one of the important steps of desensitization subsequent to agonistic stimulation, through terminating receptor lateral movement which is instrumental in generating and amplifying the initial stimulatory signal within the plane of the membrane.Abbreviations FBR fluorescence photobleaching recovery - EGF epidermal growth factor - AC adenylate cyclase - D apparent lateral diffusion coefficient - f mobile fraction - G- GTP-binding protein - Gs stimulatory G-protein - TKR tyrosine kinase receptor - PDGF platelet-derived growth factor - IL interleukin     

A role for protein kinase C activity in interleukin-1 (IL-1) induction of IL-2 gene expression but not in IL-1 signal transduction.

Interleukin-1 (IL-1) is known to synergize with phorbol esters in the induction of interleukin-2 (IL-2) expression in T-lymphoid leukemia cells and proliferation of mouse thymocytes. We used a plasmid construct containing the bacterial gene for chloramphenicol acetyltransferase under the control of the human IL-2 promoter to study the nature of this synergism in the murine thymoma cell line EL4. Although IL-1 induction of the IL-2 promoter in these cells required costimulus with phorbol myristate acetate, the signal induced by IL-1 was qualitatively different. We provide evidence to support the hypothesis that the phorbol ester signal is mediated by protein kinase C, and we show that the IL-1 signal is not. That IL-1 and phorbol myristate acetate represent different stimuli was shown by their response to protein kinase C inhibitors, capacity to synergize with increased intracellular free calcium, and requirement for protein synthesis. In addition we show that pretreatment with IL-1 can prime EL4 cells to subsequent activation by concentrations of phorbol esters not normally sufficient to induce IL-2 expression. Pretreated cells remained primed for at least 40 h after removal of the IL-1. Neither phorbol myristate acetate nor a calcium ionophore was capable of preactivating EL4 cells.     

Inhibition of host cell signal transduction by Leishmania: observations relevant to the selective impairment of IL-12 responses.

Leishmania parasites are able to delay the onset of cell-mediated immunity by selectively impairing the ability of infected macrophages to produce interleukin (IL)-12. Leishmania infection arrests the JAK/STAT-mediated signal transduction involved in activation of the IL-12 p40 promoter; the phosphorylation defects may be initiated by ligation of the phagocyte receptors used by these organisms to gain entry into the host cell.     

Critical role of Kupffer cell-derived IL-10 for host defense in septic peritonitis

Intra-abdominal infection in patients following major visceral surgery is associated with high mortality. Using a macrophage depletion technique, we demonstrate that in murine septic peritonitis, Kupffer cells are a major source of systemic IL-10 levels. Kupffer cell-depleted mice were highly susceptible to the lethal effects of septic peritonitis and exhibited an increased bacterial load. Kupffer cell-depleted mice were protected by the administration of an IL-10-Fc fusion protein. Loss of Kupffer cell-derived IL-10 was associated with a weak increase in serum IL-12 levels, whereas TNF, IL-1alpha, and IL-18 levels were not significantly elevated, suggesting that the loss of Kupffer cell-derived IL-10 did not result in a toxic cytokine release syndrome. Instead, loss of Kupffer cell-derived IL-10 was associated with a reduced splenocyte production of IFN-gamma that is required for immune protection in murine septic peritonitis. Therefore, the results suggest that the protective function of IL-10 in septic peritonitis may not be restricted to the anti-inflammatory activities of IL-10.     

IL-12 receptor. II. Distribution and regulation of receptor expression.

IL-12 is a heterodimeric lymphokine that induces IFN-gamma production by resting PBMC, enhances the lytic activity of NK/lymphokine activated killer cells, and causes the proliferation of activated T cells and NK cells. In this report, we have investigated the expression of IL-12R on mitogen- and IL-2-activated PBMC or tonsillar lymphocytes as well as on a variety of cell lines. The results of radiolabeled IL-12-binding assays indicated that high affinity IL-12R are present on PBMC activated by various T cell mitogens or by IL-2. High affinity IL-12R were also found to be expressed constitutively on a transformed marmoset NK-like cell line HVS.SILVA 40. At the time of peak IL-12R expression, mitogen- or IL-2-activated cells displayed approximately 1000 to 9000 IL-12 binding sites/cell with an apparent Kd of 100 to 900 pM. Kinetic studies revealed that maximum expression of IL-12R occurred earlier on PHA-activated PBMC as compared with PBMC activated by IL-2, and that expression of IL-12R on these cells correlated with their ability to proliferate in response to IL-12. Although IL-2 could up-regulate IL-12R expression on resting PBMC, the ability of mitogen-activated PBMC to up-regulate IL-12R was found to be independent of IL-2. Analysis of IL-12R expression by flow cytometry revealed that receptors for IL-12 are present on activated T cells of both the CD4+ and CD8+ subsets and on activated CD56+ NK cells. In contrast, neither resting PBMC or tonsillar B cells nor tonsillar B cells activated by anti-IgM/Dx, anti-IgM/Dx + IL-2, or SAC + IL-2 displayed IL-12R detectable by flow cytometry or by the radiolabeled IL-12-binding assay. In summary, these results indicate that activation of T cells or NK cells results in up-regulation of IL-12R expression; on the other hand, B cell activation, at least under some circumstances, appears not to be associated with enhanced expression of IL-12R.     

Structure-function relationships in the IL-17 receptor: implications for signal transduction and therapy

IL-17 is the defining cytokine of a newly-described "Th17" population that plays critical roles in mediating inflammation and autoimmunity. The IL-17/IL-17 receptor superfamily is the most recent class of cytokines and receptors to be described, and until recently very little was known about its function or molecular biology. However, in the last year important new insights into the composition and dynamics of the receptor complex and mechanisms of downstream signal transduction have been made, which will be reviewed here.     

IL-23 and IL-17A, but not IL-12 and IL-22, are required for optimal skin host defense against Candida albicans

IL-23 and Th17 cells play important roles in host defense against systemic infections with extracellular bacteria and fungi, although their roles in immunity against localized skin infections are less well defined. Here, the contributions of IL-23 and Th17 cytokines in host defense against cutaneous Candida albicans infection were evaluated. Mice deficient in IL-23 or IL-17A demonstrated delayed healing and decreased IL-17A production after skin infection with C. albicans compared with wild-type mice or mice deficient in IL-12 or IL-22. Histologic examination revealed epidermal hyperplasia overlying infected dermis four days postinoculation in wild-type mice. In IL-23-deficient mice, fungal burden was greater in skin, neither IL-17A nor IL-22 mRNAs were expressed postinfection, and these mice demonstrated only minimal epidermal hyperplasia. Exogenous recombinant IL-17A injected at the site of skin infection promoted more rapid healing of candidiasis in both wild-type mice and mice deficient in IL-23 and IL-12. Taken together, these results demonstrate that IL-23 and IL-17A, but not IL-12 and IL-22, are required for optimal host defense against cutaneous candidiasis. In addition, recombinant IL-17A may serve as a potential therapy to enhance healing in individuals with chronic cutaneous candidiasis.     

The role of receptor interactions in regulating ethylene signal transduction

The phytohormone ethylene is perceived in Arabidopsis by a five-member receptor family. Earlier work has demonstrated that the basic functional unit for an ethylene receptor is a disulfide-linked homodimer. We recently reported in The Journal of Biological Chemistry that the ethylene-receptor ETR1 physically associates with other ethylene receptors through higher order interactions, suggesting the existence of receptor clusters. Here we consider the implications of such clusters upon the mechanism of ethylene signal transduction. In particular, we consider how such clustering provides a cooperative mechanism, akin to what has been found for the prokaryotic chemoreceptors, by which plant sensitivity to ethylene may be increased. In addition, we consider how the dominant ethylene insensitivity conferred by some receptor mutations, such as etr1-1, may also be propagated by interactions among members of the ethylene receptor family.Key words: ethylene, receptor, ETR1, cooperativity, ArabidopsisThe plant hormone ethylene regulates growth and development, and is perceived by a five-member family of receptors (ETR1, ERS1, ETR2, ERS2 and EIN4) in Arabidopsis.¹ Genetic analysis indicates that ethylene receptors are functionally redundant and negatively regulate ethylene responses through interactions with the Raf-like kinase CTR1.^2–5 The functional unit of an ethylene receptor in a disulfide-linked homodimer, with each homodimer capable of binding one ethylene molecule.^6,7 However, several observations suggest that propagation of the ethylene signal through the receptors is likely to involve more than just ethylene-induced changes within individual receptor homodimers. First, Arabidopsis is amazingly sensitive to ethylene and can respond to ethylene concentrations as low as 0.2 nl/L,⁸ 300-fold lower than the K_d of the receptors for ethylene, which suggests that some mechanism exists for amplifying the input signal.^7,9 Second, ethylene-insensitive mutations in the binding sites of the receptors exhibit greater dominance than would be predicted solely from a lesion within one member of the receptor family.¹⁰In our paper published in The Journal of Biological Chemistry,¹¹ we demonstrate that the Arabidopsis ethylene receptor ETR1 physically associates with other ethylene receptors through higher order interactions. Such physical interactions suggest that the receptors exist in plants as clusters, and that models for cooperative signaling previously applied to the histidine-kinaselinked chemoreceptors of bacteria may also be applicable to the evolutionarily related ethylene receptors of plants. In bacteria, the highly packed chemoreceptors are found in clusters at one or both poles of the cell.^12,13 Structural studies indicate that chemoreceptors can associate to form a ‘trimer of dimers’^14,15 and also support the possibility that domain swapping may occur to produce a large interconnected array of receptors. 16 Our studies indicate that ethylene receptors can interact through their cytosolic GAF domains, identifying one possible interface through which conformational changes could be propagated in an ethylene receptor cluster.A higher-order cooperative mechanism among the ethylene receptors may explain the high sensitivity of plants to ethylene. In this model, the ethylene receptors amplify ethylene signaling by lateral signal output. Binding of ethylene to one receptor induces the conformation change of the receptor from a tense state (T) to a relaxed state (R). This conformational change is then propagated to other empty receptors in the cluster due to their physical associations with the receptor in the R state. As a result empty receptors also adopt the relaxed state (R′), resulting in amplification of the initial signal. It should be noted here that mutational evidence supports the unbound state of the receptors (T state) as being the lower energy conformation of the receptors.¹⁷ Thus, according to this model, part of the energy from ligand binding would be used to transmit conformational changes to the neighboring receptors.An alternative model that may also explain the high sensitivity of ethylene responsiveness in plants, and one that is not necessarily incompatible with the previous model, is a conjugation model.¹⁸ Here it is hypothesized that, due to the physical proximity of the ethylene receptors, that ethylene released from one receptor then binds to another receptor rather than diffusing away. Through this conjugation mechanism, one ethylene molecule could amplify its signal by converting the conformations of multiple ethylene receptors from the ethylene-unbound state (T) to the ethylene-bound state (R). This model is based on several assumptions. One assumption is that a single ethylene molecule can bind ethylene receptors in the same cluster multiple times due to the dynamic binding of ethylene and ethylene receptor. A second assumption is that, after ethylene is released from one ethylene receptor, the recovery time for that receptor to resume the T state is longer than the time required for the released ethylene to bind to and convert another receptor from the T to the R state.Models for cooperativity need to also explain the dominant ethylene insensitivity of various mutant receptors such as etr1-1, in which a missense mutation results in a receptor incapable of binding ethylene. Several studies indicate that the etr1-1 mutant receptor acts cooperatively to affect the signal output from other wild-type receptors (i.e., the presence of the etr1-1 receptor in its T state increases the likelihood of other receptors adopting the T state).^10,11 This observation can be most readily explained if the dominant ethylene-insensitive mutations result in a receptor that requires more energy to undergo the T to R transition than do the wild-type receptors. For example, the etr1-1 mutation may increase the stability of the T form (a T′ state). There is evidence to support this possibility. The etr1-1 missense mutation results in a receptor unable to chelate a copper cofactor necessary for ethylene binding,¹⁹ but the effects of this mutation on signaling are different from wild-type receptors that lack their copper cofactor. The etr1-1 mutant receptor appears locked in its T state, whereas wild-type receptors lacking the copper cofactor appear to be in the R state.²⁰ Thus etr1-1 is truly a gain-of-function mutation that alters the conformation of the receptor in ways not necessarily predicted from just the loss of the copper cofactor.In conclusion, we have attempted here to provide models that can resolve an apparent contradiction in the cooperative signaling behavior exhibited by ethylene receptors. The high sensitivity of plants to ethylene suggest cooperative changes in which an R state can be propagated within a receptor cluster, but the dominance of the ethylene ethylene-insensitive mutant etr1-1 suggests that the T state can also be propagated within a receptor cluster. It should be born in mind, however, that ethylene signaling is mediated by multiple signaling components. The ethylene receptors regulate ethylene responses through interaction with and modulation of CTR1 kinase activity. Thus, the total kinase activity of CTR1 represents the signal output from the receptors. This situation is very similar to that of the bacterial chemoreceptors, which regulate the activity of an associated histidine kinase, and, as with the chemoreceptors, the stoichiometry of CTR1 interactions with the ethylene receptors and the means by which its kinase activity is regulated are important for the elucidation of the mechanism of ethylene signal transduction.     

The mobile receptor hypothesis revisited: a mechanistic role for hormone receptor lateral mobility in signal transduction.

Recent application of the technique of fluorescence photobleaching recovery to direct measurement of the lateral mobility of plasma membrane-localized hormone receptors has shed new light on the role of receptor lateral mobility in signal transduction. Receptors for insulin and EGF have been known for some time to be largely immobile at physiological temperatures. This presumably relates to their signal transduction mechanism, which appears to require intermolecular autophosphorylation (receptor aggregation) for activation. In contrast, G-protein coupled receptors must interact with other membrane components to bring about signal transduction, and it is interesting in this regard that the adenylate cyclase (AC) activating vasopressin V2-receptor is highly laterally mobile at 37 degrees C. It has recently been possible to reversibly modulate the V2-receptor mobile fraction (f) to largely varying extents, and to demonstrate thereby a direct effect on the maximal rate of in vivo cAMP production at 37 degrees C in response to vasopressin. A direct correlation between f and maximal cAMP production indicates that f may be a key parameter in hormone signal transduction in vivo, especially at sub-KD (physiological) hormone concentrations, with mobile receptors being required to effect G-protein activation.     

The role of calcium in hypoxia-induced signal transduction and gene expression

Mammalian cells require a constant supply of oxygen in order to maintain adequate energy production, which is essential for maintaining normal function and for ensuring cell survival. Sustained hypoxia can result in cell death. Sophisticated mechanisms have therefore evolved which allow cells to respond and adapt to hypoxia. Specialized oxygen-sensing cells have the ability to detect changes in oxygen tension and transduce this signal into organ system functions that enhance the delivery of oxygen to tissue in a wide variety of different organisms. An increase in intracellular calcium levels is a primary response of many cell types to hypoxia/ischemia. The response to hypoxia is complex and involves the regulation of multiple signaling pathways and coordinated expression of perhaps hundreds of genes. This review discusses the role of calcium in hypoxia-induced regulation of signal transduction pathways and gene expression. An understanding of the molecular events initiated by changes in intracellular calcium will lead to the development of therapeutic approaches toward the treatment of hypoxic/ischemic diseases and tumors.     

Potential role for triglycerides in signal transduction

We previously reported that endothelin-1 or platelet-derived growth factor promoted in aortic smooth muscle cells a rapid hydrolysis of 1-O-alkyl-2-acyl-sn-glycero-3-phosphoethanolamine (alkyl-PE) which was immediately converted into 1-O-alkyl-2,3-diacyl-sn-glycerol (alkyl-TG) within 5 s or 60 s respectively [C. Comminges et al. (1996) Biochem. Biophys. Res. Commun. 220, 1008-1013 and C. Comminges et al. (1997) Biochim. Biophys. Acta 1355, 69-80]. In this study, we show that this alkyl-PE hydrolysis is triggered by a transient activation of a specific phospholipase C (PLC) regulated by pertussis toxin-sensitive heterotrimeric G-proteins. Moreover, this PLC can be triggered through a Ca2+ influx depending on L-type Ca2+ channel activation, as suggested by the use of a specific 'activator' S(-)-BayK 8644 and of selective inhibitors such as nimodipine. Interestingly, low concentrations (10(-8)-10(-7)M) of alkyl-TG block the opening of L-type Ca2+ channels, whereas identical concentrations of DG do not alter L-type Ca2+ channels. This study thus unravels a hitherto unrecognized signaling pathway generating alkyl-TG as a novel lipid second messenger, potentially acting as a negative feedback regulator of L-type Ca2+ channels.     

A role for the mouse 12/15-lipoxygenase pathway in promoting epithelial wound healing and host defense

The surface of the eye actively suppresses inflammation while maintaining a remarkable capacity for epithelial wound repair. Our understanding of mechanisms that balance inflammatory/reparative responses to provide effective host defense while preserving tissue function is limited, in particular, in the cornea. Lipoxin A(4) (LXA(4)) and docosahexaenoic acid-derived neuroprotectin D1 (NPD1) are lipid autacoids formed by 12/15-lipoxygenase (LOX) pathways that exhibit anti-inflammatory and neuroprotective properties. Here, we demonstrate that mouse corneas generate endogenous LXA(4) and NPD1. 12/15-LOX (Alox15) and LXA(4) receptor mRNA expression as well as LXA(4) formation were abrogated by epithelial removal and restored during wound healing. Amplification of these pathways by topical treatment with LXA(4) or NPD1 (1 microg) increased the rate of re-epithelialization (65-90%, n = 6-10, p < 0.03) and attenuated the sequelae of thermal injury. In contrast, the proinflammatory eicosanoids, LTB(4) and 12R-hydroxyeicosatrienoic acid, had no impact on corneal re-epithelialization. Epithelial removal induced a temporally defined influx of neutrophils into the stroma as well as formation of the proinflammatory chemokine KC. Topical treatment with LXA(4) and NPD1 significantly increased PMNs in the cornea while abrogating KC formation by 60%. More importantly, Alox15-deficient mice exhibited a defect in both corneal re-epithelialization and neutrophil recruitment that correlated with a 43% reduction in endogenous LXA(4) formation. Collectively, these results identify a novel action for the mouse 12/15-LOX (Alox15) and its products, LXA(4) and NPD1, in wound healing that is distinct from their well established anti-inflammatory properties.     

Identification of a novel receptor/signal transduction pathway for IL-15/T in mast cells.

Interleukin-15/T(IL-15) is a growth factor that utilizes IL-2 receptor (IL-2R) components in addition to its private binding protein IL-15R(alpha) in T-cells. Here, we report that IL-15 induces mast cell proliferation in the absence of IL-2R alpha and beta. Using transfectants of these cells with a cytoplasmic-truncated mutant of gamma(c), we demonstrated that IL-15 signaling in mast cells does not involve gamma(c). Cross-linking of mast cells with [(125)I]IL-15 revealed a 60-65 kDa IL-15 binding protein that is distinct from known components of T-cell IL-15 receptors. Mast cell IL-15 receptors recruit JAK-2 and STAT-5, instead of JAK1/3 and STAT3/5 that are activated in T-cells. Thus IL-15 is a mast cell growth factor that utilizes a novel receptor and distinct signaling pathway.     

IL-4 receptor signal transduction in human monocytes is associated with protein kinase C translocation.

IL-4 regulates B cell differentiation and monocyte functions. Protein kinases, such as kinase C (PKC), transduce receptor signals. The involvement of PKC in IL-4R signaling was investigated in human monocytes. Treatment with IL-4 (10 ng/ml) for 10 min resulted in a significant redistribution of the PKC activity from cytosol to nuclear fraction. Total PKC activity localized in the nuclear fraction of IL-4-treated and control monocytes was, respectively, 68 and 19%. In contrast, similar PKC activity was found in membrane fraction of IL-4-treated and control cells. The kinetics of IL-4-mediated redistribution of PKC activity to the nuclear fraction were rapid. Within 30 s of IL-4 exposure, 29% of the total PKC activity localized in the nuclear fraction as compared to 15% in control monocytes and increased to 69% at 10 min. The PKC activity in the nuclear fraction appears to be a sequestered form. Extraction with Triton X-100 and additional sonication were required for functional assay of PKC activity. Additional support for PKC involvement in IL-4R signaling is provided by the dose-dependent effect of IL-4 on PKC activity and the abrogation of this effect after heat denature and immunoabsorption of IL-4. Furthermore, electron microscope examination and subcellular marker enzyme assays excluded significant contamination of the nuclear fraction by plasma membranes or subcellular organelles and IL-4 altering membrane disruption. The data presented indicate that IL-4R signaling in human monocytes involves PKC translocation to a nuclear fraction.