UNIPROT:P05231 - FACTA Search

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Query: UNIPROT:P05231 (interleukin-6)
23,907 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Leukemia inhibitory factor (LIF) and interleukin-6 (IL-6) are multifunctional cytokines with many similar activities. LIF is structurally and functionally related to another cytokine, Oncostatin M (OSM), that binds to the high-affinity LIF receptor but not to the low-affinity LIF receptor. A complementary DNA was isolated that encodes the high-affinity converting subunit of the LIF receptor. The converter conferred high-affinity binding of both LIF and OSM when expressed with the low-affinity LIF receptor and is identical to the signal transducing subunit of the IL-6 receptor, gp130. The gp130 subunit alone confers low-affinity binding of OSM when expressed in COS-7 cells. This receptor system resembles the high-affinity receptors for granulocyte-macrophage colony-stimulating factor, IL-3, and IL-5, which share a common subunit.
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PMID:The IL-6 signal transducer, gp130: an oncostatin M receptor and affinity converter for the LIF receptor. 154 94

Leukemia inhibitory factor (LIF) and interleukin-6 (IL-6), two multifunctional cytokines lacking structural homology and binding to distinct receptors, share interesting functional similarities, which include induction of hematopoietic differentiation in normal and myeloid leukemia cells, induction of neuronal cell differentiation, and stimulation of acute-phase protein synthesis in hepatocytes. Structural information on the LIF receptor is not yet available, whereas recent cloning of the IL-6 receptor has shown it to be bipartite, with a signal-transducing subunit that lacks sequence homology to known protein kinases and produces second messengers of unknown nature. The molecular nature of the mechanisms which LIF and IL-6 use to induce cell differentiation is not known. To address this issue, we took advantage of a clone of M1 myeloblastic leukemia cells capable of being induced for terminal differentiation by both LIF and IL-6 directly activate the same set of immediate early response genes upon induction of M1 myeloid differentiation. At least two mechanisms of gene activation, one transcriptional and the other posttranscriptional, are shown to be involved. It is also shown that the LIF and IL-6 immediate early response, at suboptimal cytokine concentrations, is additive. Using a variety of protein kinase activators and inhibitors, we have shown that the intracellular signalling pathways for both LIF and IL-6 are distinct from those of known second messengers and involve protein phosphorylation, notably tyrosine phosphorylation of a 160-kDa protein, as an essential step(s) in the immediate early activation of MyD gene expression. These observations indicate that the functional similarities of LIF and IL-6 as inducers of cell differentiation prevail at the level of the complex differentiation immediate early response and implicate common mechanisms of signal transduction for LIF- and IL-6-induced differentiation.
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PMID:Leukemia inhibitory factor and interleukin-6 trigger the same immediate early response, including tyrosine phosphorylation, upon induction of myeloid leukemia differentiation. 190 51

Leukemia inhibitory factor (LIF) is a cytokine with a broad range of activities that in many cases parallel those of interleukin-6 (IL-6) although LIF and IL-6 appear to be structurally unrelated. A cDNA clone encoding the human LIF receptor was isolated by expression screening of a human placental cDNA library. The LIF receptor is related to the gp130 'signal-transducing' component of the IL-6 receptor and to the G-CSF receptor, with the transmembrane and cytoplasmic regions of the LIF receptor and gp130 being most closely related. This relationship suggests a common signal transduction pathway for the two receptors and may help to explain similar biological effects of the two ligands. Murine cDNAs encoding soluble LIF receptors were isolated by cross-hybridization and share 70% amino acid sequence identity to the human sequence.
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PMID:Leukemia inhibitory factor receptor is structurally related to the IL-6 signal transducer, gp130. 191 66

Ciliary neurotrophic factor (CNTF) is a cytokine sharing structural and functional similarities with interleukin-6 (IL-6) and other helical cytokines that utilize the common signalling chain gp130. While IL-6 induces gp130 dimerization, CNTF, after the initial interaction with the specific, non-signalling receptor subunit, CNTFR, induces the formation of gp130/LIF-receptor heterodimers. Through immunoprecipitation experiments with tagged soluble receptor molecules, we recently demonstrated that IL-6 drives the formation of a hexameric receptor complex with a defined topology and composed of two IL-6, two IL-6R alpha and two gp130 molecules. Here, we apply the same strategy to study the assembly in vitro of the CNTF receptor complex. We present evidence that both the cytokine and the specific binding chain undergo dimerization in the presence of gp130. Furthermore, although gp130 and LIFR are able to bind independently to the CNTF/CNTFR sub-complex, they never form homodimers but only heterodimers. We propose that CNTF assembles a hexameric receptor complex composed of two CNTF, two CNTFR, one gp130 and one LIFR molecule, and present a model of the reciprocal interaction of these molecules based on similarities with the IL-6 hexameric complex.
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PMID:In vitro binding of ciliary neurotrophic factor to its receptors: evidence for the formation of an IL-6-type hexameric complex. 750 Mar 50

Ciliary neurotrophic factor (CNTF), leukemia inhibitory factor (LIF), oncostatin M (OSM), and interleukin-6 (IL6) compose a family of distantly related cytokines that initiate signaling by inducing either homodimerization of the "beta" signal transducing receptor component gp130 (in the case of IL6) or heterodimerization between gp130 and the gp130-related LIFR beta (in the case of CNTF, LIF, and OSM); dimerization of beta receptor components in turn activates members of the Jak/Tyk family of receptor-associated tyrosine kinases. Here we report that CNTF, LIF, OSM, and IL6 induce most of the same protein tyrosine phosphorylations, regardless of the cell type assayed or whether they initiate signaling by inducing homo- or heterodimerization of beta components. Although several of the protein tyrosine phosphorylations induced by the CNTF/LIF/OSM/IL6 family of factors may correspond to novel tyrosine kinase targets, we have been able to demonstrate the involvement of known signaling molecules, such as phospholipase C gamma, phosphoinositol 3-kinase, phosphotyrosine phosphatase (PTP1D), pp120, SHC, GRB2, STAT91, Raf-1, and the mitogen-activated protein kinases ERK1 and ERK2, revealing substantial convergence not only between the pathways activated by this cytokine family and other cytokines, but with pathways previously known to be activated only by factors that utilize receptor tyrosine kinases. Our data suggest the beta receptor components can form complexes with some of the signaling proteins identified and may play some role in their recruitment.
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PMID:Ciliary neurotrophic factor/leukemia inhibitory factor/interleukin 6/oncostatin M family of cytokines induces tyrosine phosphorylation of a common set of proteins overlapping those induced by other cytokines and growth factors. 751 71

By rational mutagenesis, receptor-specific functional analysis, and visualization of complex formation in solution, we identified individual amino acid side chains involved specifically in the interaction of ciliary neurotrophic factor (CNTF) with CNTFR alpha and not with the beta-components, gp130 and LIFR. In the crystal structure, the side chains of these residues, which are located in helix A, the AB loop, helix B, and helix D, are surface accessible and are clustered in space, thus constituting an epitope for CNTFR alpha. By the same analysis, a partial epitope for gp130 was also identified on the surface of helix A that faces away from the alpha-epitope. Superposition of the CNTF and growth hormone structures showed that the location of these epitopes on CNTF is analogous to the location of the first and second receptor epitopes on the surface of growth hormone. Further comparison with proposed binding sites for alpha- and beta-receptors on interleukin-6 and leukemia inhibitory factor indicated that this epitope topology is conserved among helical cytokines. In each case, epitope I is utilized by the specificity-conferring component, whereas epitopes II and III are used by accessory components. Thus, in addition to a common fold, helical cytokines share a conserved order of receptor epitopes that is function related.
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PMID:Localization of functional receptor epitopes on the structure of ciliary neurotrophic factor indicates a conserved, function-related epitope topography among helical cytokines. 753 96

Oncostatin M (OM), which shares functional similarity and structural homology to leukemia inhibitory factor (LIF) and interleukin-6 (IL-6), functions as a potent growth factor for AIDS-associated Kaposi's sarcoma-derived cells (AIDS-KS cells). OM was also suggested to bind to the LIF receptor (LIF/OM receptor), which consists of a signal transducing subunit for LIF and IL-6 (gp130) and a LIF receptor alpha-subunit. Recent studies indicate that IL-6 has growth-stimulating activity for AIDS-KS cells. However, we find that AIDS-KS cell growth is exclusively induced by OM and not by LIF or IL-6. We also observed the lack of binding properties of AIDS-KS cells for LIF and IL-6. Scatchard plots revealed the existence of two affinity classes of OM receptor sites on AIDS-KS cells, with Kd values of 6-12 pM (high affinity) and 521-815 pM (low affinity). In competition binding studies, we find that the OM-specific receptor, but not the LIF/OM receptor, contributes to the OM-specific growth stimulation of AIDS-KS cells. We also noted that anti-gp130 antibodies can completely abolish OM-induced growth stimulation of AIDS-KS cells as well as OM binding to AIDS-KS cells. PCR amplification clearly revealed high levels of gp130 expression in AIDS-KS cells, while the transcript of LIF receptor alpha-subunit or IL-6 receptor alpha-subunit was not observed. Therefore, we conclude that (a) AIDS-KS cells express the OM-specific receptor with high and low affinity, but not the LIF/OM receptor; (b) gp130 on AIDS-KS cells plays a key role in OM binding and signaling on the OM-specific receptor; and (c) the lack of biological response of AIDS-KS cells to IL-6 and LIF can be explained by the absence of the IL-6 and LIF/OM receptors. All this evidence shows the correlation of OM-specific biological activity with expression of the OM-specific receptor and the involvement of gp130 on this receptor, as based on findings in in vitro growth assays and binding experiments for AIDS-KS cells.
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PMID:AIDS-associated Kaposi's sarcoma (KS) cells express oncostatin M (OM)-specific receptor but not leukemia inhibitory factor/OM receptor or interleukin-6 receptor. Complete block of OM-induced KS cell growth and OM binding by anti-gp130 antibodies. 765 7

The physiologic program of macrophage differentiation normally proceeds in a coordinated manner in response to several different growth factors. Although the utilization of common receptor subunits may explain in part overlapping biologic functions, mechanisms by which unique actions are mediated remain obscure. We examined growth factor-induced macrophage differentiation in M1 leukemia cells that simultaneously display receptors for interleukin-6 (IL-6), leukemia inhibitory factor (LIF) and Oncostatin-M (OSM). Differentiation induced by all three factors was associated with decreased expression of transcription factors myb and SCL, increased expression of macrophage markers, and suppression of proliferation. Cell lines were established in which SCL expression was enforced. In the absence of growth factors, cells were indistinguishable from parental cells. However, LIF (or OSM)-induced macrophage differentiation was perturbed; there was failure to undergo morphologic differentiation, disturbed expression of lysozyme and Mac1 alpha, and failure to suppress proliferation. Surprisingly the perturbation of macrophage differentiation did not apply to induced expression of macrophage colony-stimulating factor (M-CSF) or granulocyte colony stimulating factor (G-CSF) receptors. This dissociation of elements normally coordinated in a macrophage differentiation program applied at a clonal level. There was no disturbance of IL-6-induced macrophage differentiation. These data directly implicate SCL in components of the macrophage differentiation program (suggesting that LIF receptor/gp130 heterodimers utilize an SCL-inhibitable pathway while gp130 homodimers do not) and demonstrate differential-regulation of components of the mature macrophage phenotype.
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PMID:Differential regulation of macrophage differentiation in response to leukemia inhibitory factor/oncostatin-M/interleukin-6: the effect of enforced expression of the SCL transcription factor. 781 94

Leukaemia inhibitory factor (LIF) plays an important role in embryo development and implantation. We detected peak LIF activity in porcine uterine luminal fluids (ULF) at day 12 of gestation and during day 7 and 13 of the oestrous cycle. A radio-receptor competition assay showed the presence of a molecule in ULF specifically binding to human LIF receptor (LIF-R). LIF activity was partially neutralized by anti-human LIF antibody. Interleukin-6 (IL-6) activity was detected in ULF throughout the oestrous cycle and pre-implantation period. An anti-murine alpha chain (gp80) of IL-6 receptor (IL-6R) specifically neutralized this activity. LIF and IL-6 mRNA were only detected in day 11 endometrium. The presence of LIF or IL-6 in the uterine cavity has not been previously reported. Our results extend LIF production by endometrium during the oestrous cycle and pre-implantation period to another mammalian species other than mouse.
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PMID:Presence of leukaemia inhibitory factor and interleukin 6 in porcine uterine secretions prior to conceptus attachment. 782 86

Recent efforts to understand the mechanism of action of CNTF have led to the identification of a three-component receptor complex for CNTF. The distributions of these receptor components explain the known target cell specificity of CNTF, and have also helped identify new and unexpected targets of CNTF action. In addition to including a CNTF-specific component, known as CNTFR alpha, the CNTF receptor complex utilizes two receptor components, gp130 and LIFR beta, that are shared with members of a family of broadly acting cytokines, including leukemia inhibitory factor (LIF) and interleukin-6 (IL6). The finding that the CNTF receptor complex shares components with this family of cytokines has led to the realization that CNTF should also be considered a cytokine--but one that differs from its relatives in that its actions are largely limited to cells of the nervous system due to the restricted expression of one of its receptor components, CNTFR alpha. CNTFR alpha does not play a direct role in signaling, but instead forms a complex with CNTF that promotes its binding to the signal transducing "beta" receptor components, gp130 and LIFR beta. Thus CNTF utilizes identical signal transducing receptor components in neurons that its relatives use on nonneuronal cells to elicit strikingly dissimilar responses, indicating that different cells interpret the same cell surface signal in dramatically different ways. The three CNTF receptor components are initially unassociated on the cell surface, and are brought together in step-wise fashion upon CNTF binding. CNTF first binds to CNTFR alpha, then recruits gp130, and finally complexes with LIFR beta. It is this last step in complex formation, involving heterodimerization between "beta" components, that activates intracellular signaling. Signal initiation is due to activation of members of a family of cytoplasmic tyrosine kinase, known as the Jak/Tyk kinases, which are preassociated with the beta components in an inactive state and then become activated upon beta component dimerization; the Jak/Tyk kinases, in turn, activate a variety of intracellular signaling molecules, such as members of the STAT family of DNA binding transcriptional activators. A detailed understanding of the mechanism of activation of the CNTF receptor complex has led to the realization that all members of the CNTF family of cytokines activate signaling in much the same way, by inducing either homo- or heterodimerization of beta receptor components and thus activation of the preassociated Jak/Tyk kinases; this mode of receptor activation may prove to be more generally applicable to all cytokine receptors.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The tripartite CNTF receptor complex: activation and signaling involves components shared with other cytokines. 785 97

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