Distinct yet overlapping sets of STAT transcription factors are activated by different cytokines. One example is the differential activation of acute phase response factor (APRF, also called Stat3) and Stat1 by interleukin 6 and interferon-␥. Interleukin 6 activates both factors while, at least in human cells, interferon-␥ recruits only Stat1. Stat1 activation by interferon-␥ is mediated through a cytosolic tyrosine motif, Y440, of the interferon-␥ receptor. In an accompanying paper (Gerhartz, C., Heesel, B., Sasse, J., Hemmann, U., Landgraf, C., Schneider-Mergener, J., Horn, F., Heinrich, P. C., and Graeve, L. (1996) J. Biol. Chem. 271, 12991-12998), we demonstrated that two tyrosine motifs within the cytoplasmic part of the interleukin 6 signal transducer gp130 specifically mediate APRF activation while two others can recruit both APRF and Stat1. By expressing a series of Stat1/APRF domain swap mutants in COS-7 cells, we now determined which domains of Stat1 and APRF are involved in the specific recognition of phosphotyrosine motifs. Our data demonstrate that the SH2 domain is the sole determinant of specific STAT factor recruitment. Furthermore, the SH2 domain of Stat1 is able to recognize two unrelated types of phosphotyrosine motifs, one represented by the interferon-␥ receptor Y440DKPH peptide, and the other by two gp130 YXPQ motifs. By molecular modeling, we propose three-dimensional model structures of the Stat1 and APRF SH2 domains which allow us to explain the different binding preferences of these factors and to predict amino acids crucial for specific peptide recognition.Most interleukins, colony-stimulating factors, and interferons bind to plasma membrane receptors which are members of the hematopoietic receptor superfamily (1). These cytokines regulate cellular functions and gene expression via various intracellular signaling cascades of which the so-called JAK-STAT 1 pathway has recently attracted considerable attention (2). This pathway has first been established for interferon (IFN) signaling. The transcription factors Stat1␣, Stat1, and Stat2, formerly known as p91, p84, and p113 components, respectively, of the IFN-stimulated gene factor-3 complex were shown to be activated by tyrosine phosphorylation in response to IFN␣ (3) and Stat1 also by IFN␥ (4, 5). Subsequent to their phosphorylation, STAT factors homo-or heterodimerize, translocate to the nucleus, and bind to regulatory DNA elements of target genes. STAT factors contain putative SH3 and SH2 domains in their carboxyl-terminal parts as well as potential leucine zipper-like ␣-helical structures toward their amino termini (6). The SH2 domains seem to be involved in both the activation process and the dimerization of the STATs (7). A centrally located portion of Stat1 has recently been demonstrated to represent its DNA-binding domain (8). Tyrosine phosphorylation of STATs is most likely catalyzed by members of the JAK family of protein-tyrosine kinases (9). To date, four members of that family, Jak1, Jak2, Jak3, and Tyk2, have been cloned,...
The cytokines IL-6, LIF, CNTF, OSM, IL-11, and CT-1 have been grouped into the family of IL-6-type cytokines, since they all require gp130 for signal transduction. Interestingly, gp130 binds directly to OSM, whereas complex formation with the other cytokines depends on additional receptor subunits. Only limited structural information on these cytokines and their receptors is available. X-ray structures have been solved for the cytokines LIF and CNTF, whose up-up-down-down four-helix bundle is common to all of these cytokines, and for the receptors of hGH and prolactin, which contain two domains with a fibronectin III-like fold. Since cocrystallization and x-ray analysis of the up to four different proteins forming the receptor complexes of the IL-6-type cytokines is unlikely to be achieved in the near future, model building based on the existing structural information is the only approach for the time being. Here we present model structures of the complexes of human and murine IL-6 with their receptors. Their validity can be deduced from the fact that published mutagenesis data and the different receptor specificity of human and murine IL-6 can be understood. It is now possible to predict the relative positions and contacts for all molecules in their respective complexes. Such information can be used for the rational design of cytokine and receptor antagonists, which may have a valuable therapeutic perspective.
CD spectra of bovine pancreatic ribonuclease A (RNase A) and its subtilisin-modified from (RNase S) have been calculated, based upon high-resolution structures from x-ray diffraction. All known transitions in the peptide and side-chain groups, especially the aromatic and disulfide groups, have been included. Calculations have been performed with both the matrix method and with first-order perturbation theory. A newly developed method for treating the electrostatic interactions among transition charge densities and between static charge distributions and transition charge densities is used. The effects of local electrostatic fields upon the group transition energies are included for all transitions. Rotational strengths generated by the matrix method were combined with Gaussian band shapes to generate theoretical CD spectra. The calculated spectra reproduce the signs and approximate magnitudes of the near-uv CD bands of both RNase A and S. Agreement is most satisfactory for the negative 275 nm band, dominated by tyrosine contributions. In agreement with two previous studies by other workers, coupling between Tyr 73 and Tyr 115 is the single most important factor in this band. The positive band observed near 240 nm is dominated by disulfide contributions, according to our results. The far-uv CD spectrum is poorly reproduced by the calculations. The observed 208 nm band, characteristic of alpha-helices, is absent from the calculated spectrum, probably because the helices in RNase are short. A strong positive couplet centered near 190 nm is predicted but not observed. Possible reasons for these incorrect predictions of the current theoretical model in the far-uv are discussed.
The pleiotropic cytokine interleukin-6 (IL-6) interacts with the specific ligand binding subunit (IL-6R alpha) of the IL-6 receptor, and this complex associates with the signal-transducing subunit gp130 (IL-6R beta). Human IL-6 acts on human and murine cells, whereas murine IL-6 is only active on murine cells. The construction of a set of chimeric human/murine IL-6 proteins has recently allowed us to define a region (residues 43-55) within the human IL-6 protein, which is important for the interaction with gp130. Subdividing this region shows that mainly residues 50-55 of the human IL-6 are necessary for this interaction. Recently, another human IL-6 double mutant (Q159E and T162P) showed reduced affinity to gp130 but residual activity on the human myeloma cell line XG-1. Into this IL-6 mutant we introduced the murine residues 43-49 or 50-55 together with two point mutations, F170L and S176A, which had been reported to increase the affinity of IL-6 to the IL-6R alpha. The resulting IL-6 molecule, which contained the murine residues 50-55, was inactive on human myeloma cells and in addition completely inhibited wild type IL-6 activity on these cells. Such an antagonist may be used as a specific inhibitor of IL-6 activity in vivo.
The cytokines IL-6, LIF, CNTF, OSM, IL-11, and CT-1 have been grouped into the family of IL-6-type cytokines, since they all require gp130 for signal transduction. Interestingly, gp130 binds directly to OSM, whereas complex formation with the other cytokines depends on additional receptor subunits. Only limited structural information on these cytokines and their receptors is available. X-ray structures have been solved for the cytokines LIF and CNTF, whose up-up-down-down four-helix bundle is common to all of these cytokines, and for the receptors of hGH and prolactin, which contain two domains with a fibronectin III-like fold. Since cocrystallization and x-ray analysis of the up to four different proteins forming the receptor complexes of the IL-6-type cytokines is unlikely to be achieved in the near future, model building based on the existing structural information is the only approach for the time being. Here we present model structures of the complexes of human and murine IL-6 with their receptors. Their validity can be deduced from the fact that published mutagenesis data and the different receptor specificity of human and murine IL-6 can be understood. It is now possible to predict the relative positions and contacts for all molecules in their respective complexes. Such information can be used for the rational design of cytokine and receptor antagonists, which may have a valuable therapeutic perspective.
Ciliary neurotrophic factor (CNTF) promotes survival in vitro and in vivo of several neuronal cell types including sensory and motor neurons. The primary structure of CNTF suggests it to be a cytosolic protein with strong similarity to the alpha-helical cytokine family which is characterized by a bundle of four anti-parallel helices. CNTF exerts its activity via complexation with CNTF receptor (CNTF-R). This complex consists of a CNTF-binding protein (CNTF-R) and two proteins important for signal transduction [gp130 and leukaemia inhibitory factor receptor (LIF-R)]. We have shortened the cDNA coding for CNTF at both the 5' and the 3' end and expressed the truncated proteins in bacteria. Biological activities of the protein preparations were determined by their ability to induce proliferation of BAF/3 cells that were stably transfected with CNTF-R, gp130 and LIF-R cDNAs. CNTF proteins with 14 amino acid residues removed from the N-terminus were biologically active whereas the removal of 23 amino acids resulted in an inactive protein. In addition, 18 amino acid residues could be removed from the C-terminus of the CNTF protein without apparent loss of bioactivity, but further truncation at the C-terminus yielded biologically inactive proteins. The introduction of two point mutations into the CNTF protein at a site that presumably interacts with one of the two signal-transducing proteins resulted in a CNTF mutant with no measurable bioactivity. In addition, a model of the three-dimensional structure of human CNTF was constructed using the recently established structural co-ordinates of the related cytokine, granulocyte colony-stimulating factor. CD spectra of CNTF together with our mutational analysis and our three-dimensional model fully support the view that CNTF belongs to the family of alpha-helical cytokines. It is expected that our results will facilitate the rational design of CNTF mutants with agonistic or antagonistic properties.
A model of the tertiary structure of human IL-6, derived from the crystal-structure of granulocyte-colony stimulating factor, reveals a 5th helical region in the loop between the first and second alpha-helix. To investigate the importance of this region for biological activity of IL-6, residues Glu-52, Ser-53, Ser-54, Lys-55, Glu-56, Leu-58, and Glu-60 were individually replaced by alanine. IL-6.Leu-58Ala displayed a 5-fold reduced biological activity on the IL-6 responsive human cell lines XG-1 and A375. This reduction in bioactivity was shown to be due to a decreased capacity of the mutant protein to trigger IL-6 receptor-alpha-chain-dependent binding to the IL-6 signal transducer, gp130.
The peptide group between residues B24 and B25 of insulin was replaced by an ester bond. This modification only in the backbone was meant to eliminate a structurally important H-bond between the amide proton of B25 and the carbonyl oxygen of A19. and consequently to enhance detachment of the C-terminal B-chain from the body of the molecule, exposing the underlying A-chain. According to a model derived from the effects of side-chain substitutions, main-chain shortening, and crosslinking, this conformational change is prerequisite for receptor binding.Contrary to the expectation that increased flexibility would increase receptor binding and activity, depsi-insulin ([B24-B25 CO-O]insulin) has turned out to be only 3-4% potent. In search of an explanation for this observation, the solution structure of depsi-insulin was determined by two-dimensional 'H-NMR spectroscopy. It was found that the loss of the B25-AI9 H-bond does not entail detachment of the C-terminal B-chain. On the contrary, it is overcompensated by a gain in hydrophobic interaction achieved by insertion of the Phe B25 side chain into the molecule's core. This is possible because of increased rotational freedom in the backbone owing to the ester bond. Distortion of the B20-B23 turn and an altered direction of the distal B-chain are consequences that also affect self-association. The exceptional position of the B25 side chain is thus the key feature of the depsi-insulin structure. Being buried in the interior, it is not available for guiding the interaction with the receptor, a crucial role attributed to it by the model. This seems to be the main reason why the structure of depsi-insulin represents an inactive conformation.Keywords: conformation; insulin; NMR-spectroscopy; structure Among the numerous insulin mutants and derivatives investigated in structurelfunction studies during the last 25 years, the mini proinsulins crosslinked between the amino groups of Gly AI and Lys B29 by bifunctional reagents have been particularly revealing
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