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Oncostatin M

April 11, 2024

Oncostatin M, also known as OSM, is a protein that in humans is encoded by the OSM gene.[5]

OSM
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
AliasesOSM, Osm, OncoM, oncostatin M
External IDsOMIM: 165095 MGI: 104749 HomoloGene: 10741 GeneCards: OSM
Orthologs
SpeciesHumanMouse
Entrez

5008

18413

Ensembl

ENSG00000099985

ENSMUSG00000058755

UniProt

P13725

P53347

RefSeq (mRNA)

NM_020530
NM_001319108

NM_001013365

RefSeq (protein)

NP_001306037
NP_065391

NP_001013383

Location (UCSC)Chr 22: 30.26 – 30.27 MbChr 11: 4.19 – 4.19 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

OSM is a pleiotropic cytokine that belongs to the interleukin 6 group of cytokines.[6] Of these cytokines it most closely resembles leukemia inhibitory factor (LIF) in both structure and function.[6] As yet poorly defined, it is proving important in liver development, haematopoeisis, inflammation and possibly CNS development. It is also associated with bone formation and destruction.[7]

OSM signals through cell surface receptors that contain the protein gp130. The type I receptor is composed of gp130 and LIFR, the type II receptor is composed of gp130 and OSMR.[8]

Discovery, isolation and cloning edit

The human form of OSM was originally isolated in 1986 from the growth media of PMA treated U-937 histiocytic lymphoma cells by its ability to inhibit the growth of cell lines established from melanomas and other solid tumours.[9] A robust protein, OSM is stable between pH2 and 11 and resistant to heating for one hour at 56 °C. A partial amino acid sequence allowed the isolation of human OSM cDNA and subsequently genomic clones.[10] The full cDNA clone of hOSM encodes a 252 amino acid precursor, the first 25 amino acids of which functions as a secretory signal peptide, which on removal yields the soluble 227 amino acid pro-OSM. Cleavage of the C-terminal most 31 residues at a trypsin like cleavage site yields the fully active 196 residue form. Two potential N-glycosylation sites are present in hOSM both of which are retained in the mature form.[11][12]

The 196 residue OSM is the predominant form isolated form a variety of cell lines and corresponds to a glycoprotein of 28 KDa, although the larger 227 residue pro-OSM can be isolated from over transfected cells. Pro-OSM, although an order of magnitude less efficacious in growth inhibition assays, displays similar binding affinity toward cells in radio ligand binding assays.[12] Thus, post translational processing may play a significant role in the in vivo function of OSM. Like many cytokines OSM is produced from cells by de novo synthesis followed by release through the classical secretion pathway. However, OSM can be released from preformed stores within polymorphonuclear leukocytes on degranulation.[13] It still remains unclear how OSM is targeted to these intracellular compartments.

Structure edit

 
Ribbon representation of oncostatin M showing the 4 alpha helix bundle.[14]

Primary sequence analysis of OSM allocates it to the gp130 group of cytokines. OSM most resembles LIF, bearing 22% sequence identity and 30% similarity. Incidentally the genes for OSM and LIF occur in tandem on human chromosome 22. Both LIF and OSM genes have very similar gene structures sharing similar promoter elements and intron-exon structure.[15] These data suggest that OSM and LIF arose relatively recently in evolutionary terms by gene duplication.[5] Of the five cysteine residues within the human OSM sequence four participate in disulfide bridges, one of these disulfide bonds namely between helices A and B is necessary for OSM activity. The free cysteine residue does not appear to mediate dimerisation of OSM.

The three-dimensional structure of human OSM has been solved to atomic resolution, confirming the predicted long chain four helix bundle topology.[14] Comparing this structure with the known structures of other known LC cytokines shows it to be most closely related to LIF (RMSD of 2.1 Å across 145 equivalent Cα). A distinctive kink in the A helix arises from departure of the classical alpha helical H-bonding pattern, a feature shared with all known structures of LIFR using cytokines. This "kink" results in a different special positioning of one extreme of the bundle to the other, significantly affecting the relative positioning of site III with sites I and II (see:Receptor recruitment sites)

Receptors edit

Receptors for OSM can be found on a variety of cells from a variety of tissues. In general cells derived from endothelial and tumour origins express high levels of OSM receptors, whereas cells of Haematopoietic origin tend to express lower numbers. Scatchard analysis of radio ligand binding data from 125I-OSM binding to a variety of OSM responsive cell lines produced curvilinear graphs which the authors interpreted as the presence of two receptor species, a high affinity form with an approximate dissociation constant Kd of 1-10 pM, and a low affinity form of 0.4-1 nM.[16] Subsequently it was shown that the presence of gp130 alone was sufficient to reproduce the low affinity form of the receptor, and co-transfection of COS-7 cells with LIFR and gp130 produced a high affinity receptor.[17] However further experiments demonstrated that not all actions of OSM could be replicated by LIF, that is certain cells that are irresponsive to LIF would respond to OSM.[18] This data hinted to the existence of an additional ligand specific receptor chain which led to the cloning of OSMR.[19] These two receptor complexes, namely gp130/LIFR and gp130/OSMR, were termed the type I and type II Oncostatin-M receptors. The ability of OSM to signal via two receptor complexes conveniently offers a molecular explanation to the shared and unique effects of OSM with respect to LIF. Thus common biological activities of LIF and OSM are mediated through the type I receptor and OSM specific activities are mediated through the type II receptor.

The murine homologue of OSM was not discovered until 1996,[20] whereas the murine OSMR homologue was not cloned until 1998.[21] Until recently, it was thought that mOSM only signals through the murine type II receptor, namely through mOSMR/mgp130 complexes, because of a low affinity for the type I receptor counterpart.[22] However, it is now known that, in bone at least, mOSM is able to signal through both mOSMR/mgp130 and mLIFR/mgp130.[7]

Receptor recruitment sites edit

Oncostatin M triggers the formation of receptor complexes by binding to receptors via two binding sites named site II and site III. The nomenclature of these sites is taken by direct analogy to Growth Hormone, probably the best studied of four helix bundle cytokines.

Site II consists of exposed residues within the A and C helices, and confers binding to gp130. The crucial residues of site III are located at the N-terminal extremity of the D-helix. This site is the most conserved amongst IL-6 like cytokines. OSM contains a conserved Phenylalanine and Lysine residues (F160 and K163). Cytokines that recruit LIFR via site 3 i.e. LIF, OSM, CNTF and CT-1 possess these conserved phenylalanine and lysine residues and is known as the FK motif.

Signal transduction through OSM receptors edit

Signalling by type I and type II OSM receptors have now been shown to be qualitatively distinct. These differences in signaling character, in addition to the tissue distribution profiles of OSMRb and LIFRb, offer another variable in the distinction between the common and specific cellular effects of OSM with respect to LIF. All IL-6 cytokines whether they homo- or heterodimerise gp130 seem to activate JAK1, JAK2 and to a lesser degree Tyk2.[8][23] JAK1, JAK2, and tyk2 are not interchangeable in the gp130 system, this has been demonstrated with the use of JAK1, Jak2 or Tyk2 deficient cell lines obtained from mutant mice. Cells from JAK1 deficient mice show reduced STAT activation and generation of biological responses in response to IL-6 and LIF.[24] In contrast, fibroblasts derived from JAK2 null mice can respond to IL-6, with demonstratable tyrosine phosphorylation of gp130, JAK1 and TYK2.[25] Thus it seems JAK1 is the critical JAK required for gp130 signalling. Activation of the same Jaks by all three receptor combinations (gp130/gp130, gp130/LIFR, gp130/OSMR) raises the question of how IL6, LIF and OSM can activate distinct intracellular signaling pathways. Selection of particular substrates, i.e. STAT isoform, depended not on which Jak is activated, but instead are determined by specific motifs, especially tyrosine-based motifs, within each receptor intracellular domain.

Aligning the intracellular domains of gp130, LIFR and hOSMR results in some interesting observations. Sequence identity is generally quite low across the group averaging at 4.6%. However, as with many Class I Haematopoeitin receptors, two short membrane proximal motifs, termed box 1 and box 2 are present. In addition these receptors also contain a serine rich region and a third more poorly conserved motif termed box 3. Box 1 is present in all signalling cytokine receptors. It is characteristically rich in proline residues and is essential for the association and activation of JAKs.[26] Box 2 is also important for association with JAKs. Gp130 contains box1 and box2 sequences within the membrane-proximal part of the cytoplasmic region, lying within the minimum 61 amino acids required for receptor activation.[27] Mutations within the box1 region reduce the ability of gp130 to associate with Jaks[28] and abolish ligand-induced activation of Jak1 and Jak2.[27][29] Box 2 also contributes to activation and binding of JAKs. Studies with various gp130 truncation mutants show a reduction of Jak2 binding and abrogation of certain biological effects upon deletion of box2.[27][30] However, Jaks are able to associate with gp130 devoid of box2 when overexpressed.[28]

LIFR and OSMR also contain the membrane-proximal box1/box2-like regions. The first 65 amino acid residues in the cytoplasmic domain of LIFR, in combination with full length gp130, can generate signalling on treatment with LIF.[31] Coprecipitation of Jak1, Jak2 and Tyk2 with receptors containing cytoplasmic parts of the LIFR[32] or OSMR.[8] All beta receptor subunits of the gp130 system also possess a box 3 region. This region corresponds to the C-terminal amino acids of the OSMR and LIFR receptors respectively. Box 3 is necessary for the action of OSMR; however Box3 is dispensable for the action of LIFR.[33] In the case of gp130 box 3 is dispensable for activity, however the presence of an intact box 3 sequence is required for certain aspects of gp130 signalling, i.e. stimulation of transcription through the STAT-3 response element. In addition to the poor sequence conservation amongst the intracellular domains of gp130 receptors, the number and position of conserved tyrosine residues are also poorly conserved. For example, LIFR and OSMR share three homologous tyrosines. In contrast none of the tyrosine residues present in the intracellular domain of gp130 share equivalents with LIFR or OSMR, even though the intracellular regions of LIFR and gp130 share more sequence identity than LIFR and OSMR.

Of the proteins recruited to type I cytokine receptors STAT proteins remain the best studied. Homodimerisation of gp130 has been shown to phosphorylate and activate both STAT1 and STAT3. gp130 preferentially activates STAT3 which it can do through four STAT3 activation consensus sequences YXXQ: (YRHQ), (YFKQ), Y905 (YLPQ), Y915 (YMPQ). The lower propensity for STAT1 activation may be a reflection of the lower number of STAT1 activation sequences, YZPQ (where X is any residue and Z is any uncharged residue), namely Y905 and Y915.[34] Cytokines that signal via homodimeric complexes of LIFR or OSMR (i.e. devoid of gp130) are currently unknown in nature. However, various investigators have attempted artificial homodimerisation of LIFR and OSMR intracellular domains, with conflicting results, by constructing receptor chimeras that fuse the extracellular domain of one cytokine receptor with the intracellular domain of LIFR or OSMR.

Signalling by LIFR intracellular domain homodimerisation has been demonstrated in hepatoma and neuroblastoma cells,[31] embryonic stem cells[35][36] and COS-1 cells[37] by using chimeric receptors that homodimerise upon stimulation with their cognate cytokines (i.e. GCSF, neurotrophin-3, EGF). However a GCSFR/LIFR chimera was not capable of signaling in M1 or Baf cells.[36]

Anti- or pro-inflammatory? edit

The role of OSM as an inflammatory mediator was clear as early as 1986.[9] Its precise effect on the immune system, as with any cytokine, is far from clear. However, two schools of thought are emerging: The first proposes that OSM is pro-inflammatory; whilst the other holds the opposite view, claiming OSM is anti-inflammatory. It is important to note that before 1997[38] differences in human and murine OSM receptor usage were unknown. As a result, several investigators used human OSM in mouse assays and thus any conclusion drawn from the results of these experiments will be representative of LIF, i.e. signalling through gp130/LIFR complexes.

OSM is synthesized by stimulated T-cells and monocytes.[10] The effects of OSM on endothelial cells suggest a pro-inflammatory role for OSM. Endothelial cells possess a large number of OSM receptors.[39] Stimulation of a primary endothelial culture (HUVEC) with hOSM results in delayed but prolonged upregulation of P-selectin,[40] which facilitates leukocyte adhesion and rolling, necessary for their extravasation. OSM also promotes the production of IL-6 from these cells.[39]

As mentioned above the action of OSM as a quencher of the inflammatory response is by no means established yet. For example, conflicting results exist as to the action of OSM on various models of arthritis. For example, OSM reduces the degree of joint destruction in an antibody induced model of rheumatoid arthritis.[41]

OSM is a major growth factor for Kaposi's sarcoma "spindle cells", which are of endothelial origin.[42] These cells do not express LIFR but do express OSMR at high levels.[43] For example, OSM can modulate the expression of IL-6, an important regulator of the host defence system.[39] OSM can regulate the expression of acute phase proteins.[44] OSM regulates the expression of various protease and protease inhibitors, for example Gelatinase and a1-chymotrypsin inhibitor.

See also edit

References edit

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Further reading edit

  • Schieven GL, Kallestad JC, Brown TJ, Ledbetter JA, Linsley PS (September 1992). "Oncostatin M induces tyrosine phosphorylation in endothelial cells and activation of p62yes tyrosine kinase". J. Immunol. 149 (5): 1676–82. doi:10.4049/jimmunol.149.5.1676. PMID 1324279.
  • Hermanns HM, Radtke S, Schaper F, Heinrich PC, Behrmann I (December 2000). "Non-redundant signal transduction of interleukin-6-type cytokines. The adapter protein Shc is specifically recruited to the oncostatin M receptor". J. Biol. Chem. 275 (52): 40742–8. doi:10.1074/jbc.M005408200. PMID 11016927.

External links edit

April 11, 2024
oncostatin, also, known, protein, that, humans, encoded, gene, osmavailable, structurespdbortholog, search, pdbe, rcsblist, codes1evsidentifiersaliasesosm, oncom, oncostatin, mexternal, idsomim, 165095, 104749, homologene, 10741, genecards, osmgene, location, . Oncostatin M also known as OSM is a protein that in humans is encoded by the OSM gene 5 OSMAvailable structuresPDBOrtholog search PDBe RCSBList of PDB id codes1EVSIdentifiersAliasesOSM Osm OncoM oncostatin MExternal IDsOMIM 165095 MGI 104749 HomoloGene 10741 GeneCards OSMGene location Human Chr Chromosome 22 human 1 Band22q12 2Start30 262 829 bp 1 End30 266 851 bp 1 Gene location Mouse Chr Chromosome 11 mouse 2 Band11 A1 11 2 94 cMStart4 186 420 bp 2 End4 191 026 bp 2 RNA expression patternBgeeHumanMouse ortholog Top expressed inbone marrow cellsmonocytebloodappendixgallbladderupper lobe of left lungabdominal wallspleensynovial membraneleft uterine tubeTop expressed inmorulasubmandibular glandbloodthymusspleendermisplacentaskin of abdomenyolk sacesophagusMore reference expression dataBioGPSn aGene ontologyMolecular functioncytokine activity oncostatin M receptor binding growth factor activityCellular componentextracellular region extracellular spaceBiological processoncostatin M mediated signaling pathway positive regulation of peptidyl serine phosphorylation multicellular organism development immune response positive regulation of cell population proliferation positive regulation of acute inflammatory response regulation of growth cell population proliferation negative regulation of hormone secretion positive regulation of cell division positive regulation of MAPK cascade negative regulation of cell population proliferation positive regulation of transcription by RNA polymerase II positive regulation of tyrosine phosphorylation of STAT protein regulation of signaling receptor activity positive regulation of peptidyl tyrosine phosphorylation cytokine mediated signaling pathway positive regulation of phosphatidylinositol 3 kinase signaling positive regulation of inflammatory response positive regulation of protein kinase B signaling regulation of hematopoietic stem cell differentiationSources Amigo QuickGOOrthologsSpeciesHumanMouseEntrez500818413EnsemblENSG00000099985ENSMUSG00000058755UniProtP13725P53347RefSeq mRNA NM 020530NM 001319108NM 001013365RefSeq protein NP 001306037NP 065391NP 001013383Location UCSC Chr 22 30 26 30 27 MbChr 11 4 19 4 19 MbPubMed search 3 4 WikidataView Edit HumanView Edit MouseOSM is a pleiotropic cytokine that belongs to the interleukin 6 group of cytokines 6 Of these cytokines it most closely resembles leukemia inhibitory factor LIF in both structure and function 6 As yet poorly defined it is proving important in liver development haematopoeisis inflammation and possibly CNS development It is also associated with bone formation and destruction 7 OSM signals through cell surface receptors that contain the protein gp130 The type I receptor is composed of gp130 and LIFR the type II receptor is composed of gp130 and OSMR 8 Contents 1 Discovery isolation and cloning 2 Structure 3 Receptors 4 Receptor recruitment sites 5 Signal transduction through OSM receptors 6 Anti or pro inflammatory 7 See also 8 References 9 Further reading 10 External linksDiscovery isolation and cloning editThe human form of OSM was originally isolated in 1986 from the growth media of PMA treated U 937 histiocytic lymphoma cells by its ability to inhibit the growth of cell lines established from melanomas and other solid tumours 9 A robust protein OSM is stable between pH2 and 11 and resistant to heating for one hour at 56 C A partial amino acid sequence allowed the isolation of human OSM cDNA and subsequently genomic clones 10 The full cDNA clone of hOSM encodes a 252 amino acid precursor the first 25 amino acids of which functions as a secretory signal peptide which on removal yields the soluble 227 amino acid pro OSM Cleavage of the C terminal most 31 residues at a trypsin like cleavage site yields the fully active 196 residue form Two potential N glycosylation sites are present in hOSM both of which are retained in the mature form 11 12 The 196 residue OSM is the predominant form isolated form a variety of cell lines and corresponds to a glycoprotein of 28 KDa although the larger 227 residue pro OSM can be isolated from over transfected cells Pro OSM although an order of magnitude less efficacious in growth inhibition assays displays similar binding affinity toward cells in radio ligand binding assays 12 Thus post translational processing may play a significant role in the in vivo function of OSM Like many cytokines OSM is produced from cells by de novo synthesis followed by release through the classical secretion pathway However OSM can be released from preformed stores within polymorphonuclear leukocytes on degranulation 13 It still remains unclear how OSM is targeted to these intracellular compartments Structure edit nbsp Ribbon representation of oncostatin M showing the 4 alpha helix bundle 14 Primary sequence analysis of OSM allocates it to the gp130 group of cytokines OSM most resembles LIF bearing 22 sequence identity and 30 similarity Incidentally the genes for OSM and LIF occur in tandem on human chromosome 22 Both LIF and OSM genes have very similar gene structures sharing similar promoter elements and intron exon structure 15 These data suggest that OSM and LIF arose relatively recently in evolutionary terms by gene duplication 5 Of the five cysteine residues within the human OSM sequence four participate in disulfide bridges one of these disulfide bonds namely between helices A and B is necessary for OSM activity The free cysteine residue does not appear to mediate dimerisation of OSM The three dimensional structure of human OSM has been solved to atomic resolution confirming the predicted long chain four helix bundle topology 14 Comparing this structure with the known structures of other known LC cytokines shows it to be most closely related to LIF RMSD of 2 1 A across 145 equivalent Ca A distinctive kink in the A helix arises from departure of the classical alpha helical H bonding pattern a feature shared with all known structures of LIFR using cytokines This kink results in a different special positioning of one extreme of the bundle to the other significantly affecting the relative positioning of site III with sites I and II see Receptor recruitment sites Receptors editReceptors for OSM can be found on a variety of cells from a variety of tissues In general cells derived from endothelial and tumour origins express high levels of OSM receptors whereas cells of Haematopoietic origin tend to express lower numbers Scatchard analysis of radio ligand binding data from 125I OSM binding to a variety of OSM responsive cell lines produced curvilinear graphs which the authors interpreted as the presence of two receptor species a high affinity form with an approximate dissociation constant Kd of 1 10 pM and a low affinity form of 0 4 1 nM 16 Subsequently it was shown that the presence of gp130 alone was sufficient to reproduce the low affinity form of the receptor and co transfection of COS 7 cells with LIFR and gp130 produced a high affinity receptor 17 However further experiments demonstrated that not all actions of OSM could be replicated by LIF that is certain cells that are irresponsive to LIF would respond to OSM 18 This data hinted to the existence of an additional ligand specific receptor chain which led to the cloning of OSMR 19 These two receptor complexes namely gp130 LIFR and gp130 OSMR were termed the type I and type II Oncostatin M receptors The ability of OSM to signal via two receptor complexes conveniently offers a molecular explanation to the shared and unique effects of OSM with respect to LIF Thus common biological activities of LIF and OSM are mediated through the type I receptor and OSM specific activities are mediated through the type II receptor The murine homologue of OSM was not discovered until 1996 20 whereas the murine OSMR homologue was not cloned until 1998 21 Until recently it was thought that mOSM only signals through the murine type II receptor namely through mOSMR mgp130 complexes because of a low affinity for the type I receptor counterpart 22 However it is now known that in bone at least mOSM is able to signal through both mOSMR mgp130 and mLIFR mgp130 7 Receptor recruitment sites editOncostatin M triggers the formation of receptor complexes by binding to receptors via two binding sites named site II and site III The nomenclature of these sites is taken by direct analogy to Growth Hormone probably the best studied of four helix bundle cytokines Site II consists of exposed residues within the A and C helices and confers binding to gp130 The crucial residues of site III are located at the N terminal extremity of the D helix This site is the most conserved amongst IL 6 like cytokines OSM contains a conserved Phenylalanine and Lysine residues F160 and K163 Cytokines that recruit LIFR via site 3 i e LIF OSM CNTF and CT 1 possess these conserved phenylalanine and lysine residues and is known as the FK motif Signal transduction through OSM receptors editSignalling by type I and type II OSM receptors have now been shown to be qualitatively distinct These differences in signaling character in addition to the tissue distribution profiles of OSMRb and LIFRb offer another variable in the distinction between the common and specific cellular effects of OSM with respect to LIF All IL 6 cytokines whether they homo or heterodimerise gp130 seem to activate JAK1 JAK2 and to a lesser degree Tyk2 8 23 JAK1 JAK2 and tyk2 are not interchangeable in the gp130 system this has been demonstrated with the use of JAK1 Jak2 or Tyk2 deficient cell lines obtained from mutant mice Cells from JAK1 deficient mice show reduced STAT activation and generation of biological responses in response to IL 6 and LIF 24 In contrast fibroblasts derived from JAK2 null mice can respond to IL 6 with demonstratable tyrosine phosphorylation of gp130 JAK1 and TYK2 25 Thus it seems JAK1 is the critical JAK required for gp130 signalling Activation of the same Jaks by all three receptor combinations gp130 gp130 gp130 LIFR gp130 OSMR raises the question of how IL6 LIF and OSM can activate distinct intracellular signaling pathways Selection of particular substrates i e STAT isoform depended not on which Jak is activated but instead are determined by specific motifs especially tyrosine based motifs within each receptor intracellular domain Aligning the intracellular domains of gp130 LIFR and hOSMR results in some interesting observations Sequence identity is generally quite low across the group averaging at 4 6 However as with many Class I Haematopoeitin receptors two short membrane proximal motifs termed box 1 and box 2 are present In addition these receptors also contain a serine rich region and a third more poorly conserved motif termed box 3 Box 1 is present in all signalling cytokine receptors It is characteristically rich in proline residues and is essential for the association and activation of JAKs 26 Box 2 is also important for association with JAKs Gp130 contains box1 and box2 sequences within the membrane proximal part of the cytoplasmic region lying within the minimum 61 amino acids required for receptor activation 27 Mutations within the box1 region reduce the ability of gp130 to associate with Jaks 28 and abolish ligand induced activation of Jak1 and Jak2 27 29 Box 2 also contributes to activation and binding of JAKs Studies with various gp130 truncation mutants show a reduction of Jak2 binding and abrogation of certain biological effects upon deletion of box2 27 30 However Jaks are able to associate with gp130 devoid of box2 when overexpressed 28 LIFR and OSMR also contain the membrane proximal box1 box2 like regions The first 65 amino acid residues in the cytoplasmic domain of LIFR in combination with full length gp130 can generate signalling on treatment with LIF 31 Coprecipitation of Jak1 Jak2 and Tyk2 with receptors containing cytoplasmic parts of the LIFR 32 or OSMR 8 All beta receptor subunits of the gp130 system also possess a box 3 region This region corresponds to the C terminal amino acids of the OSMR and LIFR receptors respectively Box 3 is necessary for the action of OSMR however Box3 is dispensable for the action of LIFR 33 In the case of gp130 box 3 is dispensable for activity however the presence of an intact box 3 sequence is required for certain aspects of gp130 signalling i e stimulation of transcription through the STAT 3 response element In addition to the poor sequence conservation amongst the intracellular domains of gp130 receptors the number and position of conserved tyrosine residues are also poorly conserved For example LIFR and OSMR share three homologous tyrosines In contrast none of the tyrosine residues present in the intracellular domain of gp130 share equivalents with LIFR or OSMR even though the intracellular regions of LIFR and gp130 share more sequence identity than LIFR and OSMR Of the proteins recruited to type I cytokine receptors STAT proteins remain the best studied Homodimerisation of gp130 has been shown to phosphorylate and activate both STAT1 and STAT3 gp130 preferentially activates STAT3 which it can do through four STAT3 activation consensus sequences YXXQ YRHQ YFKQ Y905 YLPQ Y915 YMPQ The lower propensity for STAT1 activation may be a reflection of the lower number of STAT1 activation sequences YZPQ where X is any residue and Z is any uncharged residue namely Y905 and Y915 34 Cytokines that signal via homodimeric complexes of LIFR or OSMR i e devoid of gp130 are currently unknown in nature However various investigators have attempted artificial homodimerisation of LIFR and OSMR intracellular domains with conflicting results by constructing receptor chimeras that fuse the extracellular domain of one cytokine receptor with the intracellular domain of LIFR or OSMR Signalling by LIFR intracellular domain homodimerisation has been demonstrated in hepatoma and neuroblastoma cells 31 embryonic stem cells 35 36 and COS 1 cells 37 by using chimeric receptors that homodimerise upon stimulation with their cognate cytokines i e GCSF neurotrophin 3 EGF However a GCSFR LIFR chimera was not capable of signaling in M1 or Baf cells 36 Anti or pro inflammatory editThe role of OSM as an inflammatory mediator was clear as early as 1986 9 Its precise effect on the immune system as with any cytokine is far from clear However two schools of thought are emerging The first proposes that OSM is pro inflammatory whilst the other holds the opposite view claiming OSM is anti inflammatory It is important to note that before 1997 38 differences in human and murine OSM receptor usage were unknown As a result several investigators used human OSM in mouse assays and thus any conclusion drawn from the results of these experiments will be representative of LIF i e signalling through gp130 LIFR complexes OSM is synthesized by stimulated T cells and monocytes 10 The effects of OSM on endothelial cells suggest a pro inflammatory role for OSM Endothelial cells possess a large number of OSM receptors 39 Stimulation of a primary endothelial culture HUVEC with hOSM results in delayed but prolonged upregulation of P selectin 40 which facilitates leukocyte adhesion and rolling necessary for their extravasation OSM also promotes the production of IL 6 from these cells 39 As mentioned above the action of OSM as a quencher of the inflammatory response is by no means established yet For example conflicting results exist as to the action of OSM on various models of arthritis For example OSM reduces the degree of joint destruction in an antibody induced model of rheumatoid arthritis 41 OSM is a major growth factor for Kaposi s sarcoma spindle cells which are of endothelial origin 42 These cells do not express LIFR but do express OSMR at high levels 43 For example OSM can modulate the expression of IL 6 an important regulator of the host defence system 39 OSM can regulate the expression of acute phase proteins 44 OSM regulates the expression of various protease and protease inhibitors for example Gelatinase and a1 chymotrypsin inhibitor See also editOncostatin M receptorReferences edit a b c GRCh38 Ensembl release 89 ENSG00000099985 Ensembl May 2017 a b c GRCm38 Ensembl release 89 ENSMUSG00000058755 Ensembl May 2017 Human PubMed Reference National Center for Biotechnology Information U S National Library of Medicine Mouse PubMed Reference National Center for Biotechnology Information U S National Library of Medicine a b Rose TM Bruce AG October 1991 Oncostatin M is a member of a cytokine family that includes leukemia inhibitory factor granulocyte colony stimulating factor and interleukin 6 Proc Natl Acad Sci U S A 88 19 8641 5 Bibcode 1991PNAS 88 8641R doi 10 1073 pnas 88 19 8641 PMC 52565 PMID 1717982 a b Tanaka M Miyajima A 2003 Oncostatin M a multifunctional cytokine Rev Physiol Biochem Pharmacol Reviews of Physiology Biochemistry and Pharmacology 149 39 52 doi 10 1007 s10254 003 0013 1 ISBN 978 3 540 20213 4 PMID 12811586 a b Walker EC McGregor NE Poulton IJ Solano M Pompolo S Fernandes TJ Constable MJ Nicholson GC Zhang JG Nicola NA Gillespie MT Martin TJ Sims NA 2010 Oncostatin M promotes bone formation independently of resorption when signaling through leukemia inhibitory factor receptor in mice J Clin Invest 120 2 582 92 doi 10 1172 JCI40568 PMC 2810087 PMID 20051625 How to build bone Separate bone formation from bone destruction ScienceDaily Press release January 5 2010 a b c Auguste P Guillet C Fourcin M Olivier C Veziers J Pouplard Barthelaix A Gascan H June 1997 Signaling of type II oncostatin M receptor J Biol Chem 272 25 15760 4 doi 10 1074 jbc 272 25 15760 PMID 9188471 a b Zarling JM Shoyab M Marquardt H Hanson MB Lioubin MN Todaro GJ December 1986 Oncostatin M a growth regulator produced by differentiated histiocytic lymphoma cells Proc Natl Acad Sci U S A 83 24 9739 43 Bibcode 1986PNAS 83 9739Z doi 10 1073 pnas 83 24 9739 PMC 387216 PMID 3540948 a b Malik N Kallestad JC Gunderson NL Austin SD Neubauer MG Ochs V Marquardt H Zarling JM Shoyab M Wei CM July 1989 Molecular cloning sequence analysis and functional expression of a novel growth regulator oncostatin M Mol Cell Biol 9 7 2847 53 doi 10 1128 mcb 9 7 2847 2853 1989 PMC 362750 PMID 2779549 Linsley PS Kallestad J Ochs V Neubauer M May 1990 Cleavage of a hydrophilic C terminal domain increases growth inhibitory activity of oncostatin M Mol Cell Biol 10 5 1882 90 doi 10 1128 mcb 10 5 1882 1890 1990 PMC 360533 PMID 2325640 a b Malik N Graves D Shoyab M Purchio AF 1992 Amplification and expression of heterologous oncostatin M in Chinese hamster ovary cells DNA Cell Biol 11 6 453 9 doi 10 1089 dna 1992 11 453 PMID 1524679 Grenier A Dehoux M Boutten A Arce Vicioso M Durand G Gougerot Pocidalo MA Chollet Martin S February 1999 Oncostatin M production and regulation by human polymorphonuclear neutrophils Blood 93 4 1413 21 doi 10 1182 blood V93 4 1413 PMID 9949186 a b PDB 1EVS Deller MC Hudson KR Ikemizu S Bravo J Jones EY Heath JK August 2000 Crystal structure and functional dissection of the cytostatic cytokine oncostatin M Structure 8 8 863 74 doi 10 1016 S0969 2126 00 00176 3 PMID 10997905 Rose TM Lagrou MJ Fransson I Werelius B Delattre O Thomas G de Jong PJ Todaro GJ Dumanski JP July 1993 The genes for oncostatin M OSM and leukemia inhibitory factor LIF are tightly linked on human chromosome 22 Genomics 17 1 136 40 doi 10 1006 geno 1993 1294 PMID 8406444 Linsley PS Bolton Hanson M Horn D Malik N Kallestad JC Ochs V Zarling JM Shoyab M March 1989 Identification and characterization of cellular receptors for the growth regulator oncostatin M J Biol Chem 264 8 4282 9 doi 10 1016 S0021 9258 18 83737 1 PMID 2538434 Gearing DP Comeau MR Friend DJ Gimpel SD Thut CJ McGourty J Brasher KK King JA Gillis S Mosley B March 1992 The IL 6 signal transducer gp130 an oncostatin M receptor and affinity converter for the LIF receptor Science 255 5050 1434 7 Bibcode 1992Sci 255 1434G doi 10 1126 science 1542794 PMID 1542794 Thoma B Bird TA Friend DJ Gearing DP Dower SK February 1994 Oncostatin M and leukemia inhibitory factor trigger overlapping and different signals through partially shared receptor complexes J Biol Chem 269 8 6215 22 doi 10 1016 S0021 9258 17 37590 7 PMID 8119965 Mosley B De Imus C Friend D Boiani N Thoma B Park LS Cosman D December 1996 Dual oncostatin M OSM receptors Cloning and characterization of an alternative signaling subunit conferring OSM specific receptor activation J Biol Chem 271 51 32635 43 doi 10 1074 jbc 271 51 32635 PMID 8999038 Yoshimura A Ichihara M Kinjyo I Moriyama M Copeland NG Gilbert DJ Jenkins NA Hara T Miyajima A March 1996 Mouse oncostatin M an immediate early gene induced by multiple cytokines through the JAK STAT5 pathway EMBO J 15 5 1055 63 doi 10 1002 j 1460 2075 1996 tb00443 x PMC 450003 PMID 8605875 Lindberg RA Juan TS Welcher AA Sun Y Cupples R Guthrie B Fletcher FA June 1998 Cloning and Characterization of a Specific Receptor for Mouse Oncostatin M Mol Cell Biol 18 6 3357 67 doi 10 1128 MCB 18 6 3357 PMC 108917 PMID 9584176 Ichihara M Hara T Kim H Murate T Miyajima A July 1997 Oncostatin M and leukemia inhibitory factor do not use the same functional receptor in mice Blood 90 1 165 73 doi 10 1182 blood V90 1 165 165 165 173 inactive 2024 04 07 PMID 9207450 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of April 2024 link Stahl N Boulton TG Farruggella T Ip NY Davis S Witthuhn BA Quelle FW Silvennoinen O Barbieri G Pellegrini S January 1994 Association and activation of Jak Tyk kinases by CNTF LIF OSM IL 6 beta receptor components Science 263 5143 92 5 Bibcode 1994Sci 263 92S doi 10 1126 science 8272873 PMID 8272873 Briscoe J Rogers NC Witthuhn BA Watling D Harpur AG Wilks AF Stark GR Ihle JN Kerr IM February 1996 Kinase negative mutants of JAK1 can sustain interferon gamma inducible gene expression but not an antiviral state EMBO J 15 4 799 809 doi 10 1002 j 1460 2075 1996 tb00415 x PMC 450278 PMID 8631301 Parganas E Wang D Stravopodis D Topham DJ Marine JC Teglund S Vanin EF Bodner S Colamonici OR van Deursen JM Grosveld G Ihle JN May 1998 Jak2 is essential for signaling through a variety of cytokine receptors Cell 93 3 385 95 doi 10 1016 S0092 8674 00 81167 8 PMID 9590173 Taga T Kishimoto T 1997 Gp130 and the interleukin 6 family of cytokines Annu Rev Immunol 15 797 819 doi 10 1146 annurev immunol 15 1 797 PMID 9143707 a b c Murakami M Narazaki M Hibi M Yawata H Yasukawa K Hamaguchi M Taga T Kishimoto T December 1991 Critical cytoplasmic region of the interleukin 6 signal transducer gp130 is conserved in the cytokine receptor family Proc Natl Acad Sci U S A 88 24 11349 53 Bibcode 1991PNAS 8811349M doi 10 1073 pnas 88 24 11349 PMC 53132 PMID 1662392 a b Tanner JW Chen W Young RL Longmore GD Shaw AS March 1995 The conserved box 1 motif of cytokine receptors is required for association with JAK kinases J Biol Chem 270 12 6523 30 doi 10 1074 jbc 270 12 6523 PMID 7896787 Narazaki M Witthuhn BA Yoshida K Silvennoinen O Yasukawa K Ihle JN Kishimoto T Taga T March 1994 Activation of JAK2 kinase mediated by the interleukin 6 signal transducer gp130 Proc Natl Acad Sci U S A 91 6 2285 9 Bibcode 1994PNAS 91 2285N doi 10 1073 pnas 91 6 2285 PMC 43355 PMID 8134389 Lai CF Ripperger J Morella KK Wang Y Gearing DP Fey GH Baumann H June 1995 Separate signaling mechanisms are involved in the control of STAT protein activation and gene regulation via the interleukin 6 response element by the box 3 motif of gp130 J Biol Chem 270 25 14847 50 doi 10 1074 jbc 270 25 14847 PMID 7797460 a b Baumann H Symes AJ Comeau MR Morella KK Wang Y Friend D Ziegler SF Fink JS Gearing DP January 1994 Multiple regions within the cytoplasmic domains of the leukemia inhibitory factor receptor and gp130 cooperate in signal transduction in hepatic and neuronal cells Mol Cell Biol 14 1 138 46 doi 10 1128 mcb 14 1 138 146 1994 PMC 358364 PMID 8264582 Heinrich PC Behrmann I Muller Newen G Schaper F Graeve L September 1998 Interleukin 6 type cytokine signalling through the gp130 Jak STAT pathway Biochem J 334 Pt 2 297 314 doi 10 1042 bj3340297 PMC 1219691 PMID 9716487 Kuropatwinski KK De Imus C Gearing D Baumann H Mosley B June 1997 Influence of subunit combinations on signaling by receptors for oncostatin M leukemia inhibitory factor and interleukin 6 J Biol Chem 272 24 15135 44 doi 10 1074 jbc 272 24 15135 PMID 9182534 Gerhartz C Heesel B Sasse J Hemmann U Landgraf C Schneider Mergener J Horn F Heinrich PC Graeve L May 1996 Differential activation of acute phase response factor STAT3 and STAT1 via the cytoplasmic domain of the interleukin 6 signal transducer gp130 I Definition of a novel phosphotyrosine motif mediating STAT1 activation J Biol Chem 271 22 12991 8 doi 10 1074 jbc 271 22 12991 PMID 8662591 Ernst M Novak U Nicholson SE Layton JE Dunn AR April 1999 The carboxyl terminal domains of gp130 related cytokine receptors are necessary for suppressing embryonic stem cell differentiation Involvement of STAT3 J Biol Chem 274 14 9729 37 doi 10 1074 jbc 274 14 9729 PMID 10092661 a b Starr R Novak U Willson TA Inglese M Murphy V Alexander WS Metcalf D Nicola NA Hilton DJ Ernst M August 1997 Distinct roles for leukemia inhibitory factor receptor alpha chain and gp130 in cell type specific signal transduction J Biol Chem 272 32 19982 6 doi 10 1074 jbc 272 32 19982 PMID 9242667 Stahl N Farruggella TJ Boulton TG Zhong Z Darnell JE Yancopoulos GD March 1995 Choice of STATs and other substrates specified by modular tyrosine based motifs in cytokine receptors Science 267 5202 1349 53 Bibcode 1995Sci 267 1349S doi 10 1126 science 7871433 PMID 7871433 S2CID 2899899 Hermanns HM Radtke S Haan C Schmitz Van de Leur H Tavernier J Heinrich PC Behrmann I December 1999 Contributions of leukemia inhibitory factor receptor and oncostatin M receptor to signal transduction in heterodimeric complexes with glycoprotein 130 J Immunol 163 12 6651 8 doi 10 4049 jimmunol 163 12 6651 PMID 10586060 a b c Brown TJ Rowe JM Liu JW Shoyab M October 1991 Regulation of IL 6 expression by oncostatin M J Immunol 147 7 2175 80 doi 10 4049 jimmunol 147 7 2175 PMID 1918953 Yao L Pan J Setiadi H Patel KD McEver RP July 1996 Interleukin 4 or oncostatin M induces a prolonged increase in P selectin mRNA and protein in human endothelial cells J Exp Med 184 1 81 92 doi 10 1084 jem 184 1 81 PMC 2192668 PMID 8691152 Wallace PM MacMaster JF Rouleau KA Brown TJ Loy JK Donaldson KL Wahl AF May 1999 Regulation of inflammatory responses by oncostatin M J Immunol 162 9 5547 55 doi 10 4049 jimmunol 162 9 5547 PMID 10228036 Nair BC DeVico AL Nakamura S Copeland TD Chen Y Patel A O Neil T Oroszlan S Gallo RC Sarngadharan MG March 1992 Identification of a major growth factor for AIDS Kaposi s sarcoma cells as oncostatin M Science 255 5050 1430 2 doi 10 1126 science 1542792 PMID 1542792 Murakami Mori K Taga T Kishimoto T Nakamura S September 1995 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 J Clin Invest 96 3 1319 27 doi 10 1172 JCI118167 PMC 185754 PMID 7657807 Heinrich PC Horn F Graeve L Dittrich E Kerr I Muller Newen G Grotzinger J Wollmer A 1998 Interleukin 6 and related cytokines effect on the acute phase reaction Z Ernahrungswiss 37 Suppl 1 43 9 PMID 9558728 Further reading editSchieven GL Kallestad JC Brown TJ Ledbetter JA Linsley PS September 1992 Oncostatin M induces tyrosine phosphorylation in endothelial cells and activation of p62yes tyrosine kinase J Immunol 149 5 1676 82 doi 10 4049 jimmunol 149 5 1676 PMID 1324279 Hermanns HM Radtke S Schaper F Heinrich PC Behrmann I December 2000 Non redundant signal transduction of interleukin 6 type cytokines The adapter protein Shc is specifically recruited to the oncostatin M receptor J Biol Chem 275 52 40742 8 doi 10 1074 jbc M005408200 PMID 11016927 External links editOncostatin M at the U S National Library of Medicine Medical Subject Headings MeSH Retrieved from https en wikipedia org w index php title Oncostatin M amp oldid 1217701027, wikipedia, wiki, book, books, library,

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