The interferon gamma (IFN-gamma) receptor: a paradigm for the multichain cytokine receptor.

With the purification and cloning of the interferon gamma (IFN-gamma) receptor chains the mechanism of IFN-gamma action and the resultant signal transduction events were delineated in remarkable detail. The interferon gamma (IFN-gamma) receptor complex consists of two chains: IFN-gammaR1, the ligand-binding chain, and IFN-gammaR2, the accessory chain. Binding of IFN-gamma causes oligomerization of the two IFN-gamma receptor subunits, IFN-gammaR1 and IFN-gammaR2, which initiates the signal transduction events: activation of Jak1 and Jak2 receptor associated protein tyrosine kinases, phosphorylation of the IFN-gammaR1 intracellular domain on Tyr440 followed by phosphorylation and activation of Stat1alpha, the latent transcriptional factor. With all these steps established, the IFN-gamma receptor complex has provided the basic model for understanding the receptors for other members of the family of class II cytokine receptors.

The intracellular domain of the second chain of the interferon-gamma receptor is interchangeable between species.

In this report we show that the mouse interferon (IFN)-gamma R1 and IFN-gamma R2 subunits expressed in hamster cells are capable of rendering the cells sensitive to mouse IFN-gamma as measured by induction of class I MHC antigens and the activation of the transcription factor Stat1 alpha. However, these cells showed no antiviral protection in response to IFN-gamma when challenged with vesicular stomatitis virus (VSV) but limited protection when challenged with encephalomyocarditis virus (EMCV). Furthermore, the cytoplasmic domains of the IFN-gamma R2 subunits, like the cytoplasmic domains of the IFN-gamma R1 chains, can be interchanged between species with no loss of biologic activity, demonstrating that the species-specific interaction of the IFN-gamma R1 and IFN-gamma R2 chains involves only the extracellular domains of the two proteins.

Activation of neutrophil collagenase by cathepsin G.

Collagenase is secreted from neutrophils as a latent or proenzyme. In an effort to understand the mechanism of collagenase activation in inflammation, human peripheral neutrophils (PMNs) were isolated and incubated with the tumor promotor, phorbol myristate acetate (PMA), which induces the neutrophils to degranulate and secrete proteinases. Neutrophil media were then treated with various activators or inhibitors of collagenase and other proteinases, and the collagenase activity was measured. A serine proteinase secreted from neutrophils, cathepsin G, was found to activate latent collagenase, but it was also found to require activation itself. Both hypochlorous acid (HOCl) and oxidized glutathione (GSSG) were tested for their collagenase-activating ability and were found to be successful only in the presence of active cathepsin G. A specific cathepsin G inhibitor (0.5 mM Z-Gly-Leu-Phe-CH2Cl) prevented the activation of latent collagenase by HOCl. To confirm these results, purified neutrophil cathepsin G was incubated with a neutrophil proteinase mixture which contained latent collagenase. The collagenase was shown to be activated upon incubation with purified cathepsin G. These results indicate that cathepsin G is a key mediator in neutrophil collagenase activation.

Synthesis and NMR spectral study of some t(3)-aryl-r(2),c(4)-bisethoxycarbonyl-t(5)-hydroxy-c(5)-methylcyclohexanones.

Six t(3)-aryl-r(2),c(4)-bisethoxycarbonyl-t(5)-hydroxy-c(5)-methylcyclohexanones (6-11) were synthesized by condensing ArCHO (Ar = Ph, p-O(2)NC(6)H(4), p-CH(3)OC(6)H(4), p-ClC(6)H(4), m-O(2)NC(6)H(4) and m-C(6)H(5)O(6)H(4)) with ethyl acetoacetate in the presence of methylamine and their (1)H and (13)C NMR spectra were recorded. (1)H-(1)H COSY and NOESY spectra were recorded for 6 and 7 and also HSQC and HMBC spectra for 6 and 8. Elemental analysis was carried out for all compounds. The mass spectrum was recorded for 8. All analytical data are consistent with the proposed molecular formulae. Analysis of NMR spectral data suggests that these compounds largely adopt chair conformations with the hydroxyl group occupying an axial orientation and all the other substituents occupying equatorial orientations. Long-range coupling (2-3 Hz) between the OH proton and the axial methylene proton at C-6 is observed in 6, 7, 8 and 11.

The complete primary structure for the alpha 1-chain of mouse collagen IV. Differential evolution of collagen IV domains.

We report here the complete nucleotide and amino acid sequences for the alpha 1-chain of mouse collagen IV which is 1669 amino acids in length, including a putative 27-residue signal peptide. In comparison with the amino acid sequence for the alpha 2-chain (Saus, J., Quinones, S., MacKrell, A. J., Blumberg, B., Muthkumaran, G., Pihlajaniemi, J., and Kurkinen, M. (1989) J. Biol. Chem. 264, 6318-6324), the two chains of collagen IV are 43% identical. Most of the interruptions of the Gly-X-Y repeat are homologously placed but strikingly show no sequence similarity between the two chains. Availability of the amino acid sequences for human collagen IV allows a detailed comparison of the primary structure of collagen IV and reveals evolutionarily conserved domains of the protein. Between the two species, the alpha 1 (IV) chains are 90.6% and the alpha 2 (IV) chains are 83.5% identical in sequence. We discuss these data with respect to differential evolution between and within the collagen IV chain types.

Chimeric erythropoietin-interferon gamma receptors reveal differences in functional architecture of intracellular domains for signal transduction.

Binding of interferon gamma (IFN-gamma) causes oligomerization of the two interferon gamma receptor (IFN-gammaR) subunits, receptor chain 1 (IFN-gammaR1, the ligand-binding chain) and the second chain of the receptor (IFN-gammaR2), and causes activation of two Jak kinases (Jak1 and Jak2). In contrast, the erythropoietin receptor (EpoR) requires only one receptor chain and one Jak kinase (Jak2). Chimeras between the EpoR and the IFN-gammaR1 and IFN-gammaR2 chains demonstrate that the architecture of the EpoR and the IFN-gammaR complexes differ significantly. Although IFN-gammaR1 alone cannot initiate signal transduction, the chimera EpoR/gammaR1 (extracellular/intracellular) generates slight responses characteristic of IFN-gamma in response to Epo and the EpoR/gammaR1. EpoR/gammaR2 heterodimer is a fully functional receptor complex. The results demonstrate that the configuration of the extracellular domains influences the architecture of the intracellular domains.

Genomic organization and promoter analysis of the gene ifngr2 encoding the second chain of the mouse interferon-gamma receptor.

A clone containing the gene ifngr2 for the second chain (IFN-gamma R2) of the mouse interferon gamma receptor complex was isolated from a cosmid library made of 129/Sv mouse genomic DNA. Sequence analysis revealed that the second chain is encoded by 7 exons. The complete gene spans about 17 kb of the genomic DNA. In the 5'-flanking region several transcription initiation sites between 27 and 136 nucleotides upstream from the translation initiation codon were mapped. This region has a high GC content, but no TATA or CAAT box. Potential binding sites were found for transcription factors Sp1, AP-2, NF1, EGR and NF kappa B. Promoter activity was assayed with a series of constructs with firefly luciferase as a reporter gene, under the control of the promoter fragments of various lengths. This region showed promoter activity in transiently transfected Chinese hamster ovary cells.

The complete primary structure of mouse alpha 2(IV) collagen. Alignment with mouse alpha 1(IV) collagen.

We have determined the nucleotide and amino acid sequences of mouse alpha 2(IV) collagen which is 1707 amino acids long. The primary structure includes a putative 28-residue signal peptide and contains three distinct domains: 1) the 7 S domain (residues 29-171), which contains 5 cysteine and 8 lysine residues, is involved in the cross-linking and assembly of four collagen IV molecules; 2) the triple-helical domain (residues 172-1480), which has 24 sequence interruptions in the Gly-X-Y repeat up to 24 residues in length; and 3) the NC1 domain (residues 1481-1707), which is involved in the end-to-end assembly of collagen IV and is the most highly conserved domain of the protein. Alignment of the primary structure of the alpha 2(IV) chain with that of the alpha 1(IV) chain reported in the accompanying paper (Muthukumaran, G., Blumberg, B., and Kurkinen, M. (1989) J. Biol. Chem. 264, 6310-6317) suggests that a heterotrimeric collagen IV molecule contains 26 imperfections in the triple-helical domain. The proposed alignment is consistent with the physical data on the length and flexibility of collagen IV.

Molecular characterization of the murine interferon gamma receptor cDNA.

Interferon gamma receptors (IFN-gamma R) exhibit remarkable species specificity. In order to understand the basis for this phenomenon, we have isolated a recombinant cDNA clone corresponding to the mouse (Mu) IFN-gamma R. Microinjection of the mRNA synthesized in vitro corresponding to the cloned cDNA into Xenopus laevis oocytes resulted in the synthesis of a protein that specifically binds Mu-IFN-gamma. Analysis of murine genomic and RNA blots with the cDNA probe indicates the presence of a single gene and a single mRNA species of about 2300 bases. Sequence analysis of the cDNA encoding the Mu-IFN-gamma R and comparison with the corresponding human IFN-gamma R sequence shows about 68% conservation of the extracellular domains and 51% conservation of the cytoplasmic domains at the nucleotide level. The results indicate that, as expected, the sequence of the receptor confers species specificity for the binding of IFN-gamma to the cell surface receptor. Moreover, it was previously shown that a human factor is required in addition to the receptor for the human IFN-gamma to function in hamster or mouse cells (Jung, V., Rashidbaigi, A., Jones, C., Tischfield, J.A., Shows, T.B., and Pestka, S. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 4151-4155). These results suggest an explanation for the second species-specific event required for function of the human receptor in mouse or hamster cells in that the intracellular domains are significantly different and thus cannot interact with the corresponding heterologous factor.

Other kinases can substitute for Jak2 in signal transduction by interferon-gamma.

Each cytokine which utilizes the Jak-Stat signal transduction pathway activates a distinct combination of members of the Jak and Stat families. Thus, either the Jaks, the Stats, or both could contribute to the specificity of ligand action. With the use of chimeric receptors involving the interferon gamma receptor (IFN-gammaR) complex as a model system, we demonstrate that Jak2 activation is not an absolute requirement for IFN-gamma signaling. Other members of the Jak family can functionally substitute for Jak2. IFN-gamma can signal through the activation of Jak family members other than Jak2 as measured by Statlalpha homodimerization and major histocompatibility complex class I antigen expression. This indicates that Jaks are interchangeable and indiscriminative in the Jak-Stat signal transduction pathway. The necessity for the activation of one particular kinase during signaling can be overcome by recruiting another kinase to the receptor complex. The results may suggest that the Jaks do not contribute to the specificity of signal transduction in the Jak-Stat pathway to the same degree as Stats.

Interaction between the components of the interferon gamma receptor complex.

Interferon gamma (IFN-gamma) signals through a multimeric receptor complex consisting of two different chains: the IFN-gamma receptor binding subunit (IFN-gamma R, IFN-gamma R1), and a transmembrane accessory factor (AF-1, IFN-gamma R2) necessary for signal transduction. Using cell lines expressing different cloned components of the IFN-gamma receptor complex, we examined the function of the receptor components in signal transduction upon IFN-gamma treatment. A specific IFN-gamma R2:IFN-gamma cross-linked complex was observed in cells expressing both IFN-gamma R1 and IFN-gamma R2 indicating that IFN-gamma R2 (AF-1) interacts with IFN-gamma and is closely associated with IFN-gamma R1. We show that the intracellular domain of IFN-gamma R2 is necessary for signaling. Cells coexpressing IFN-gamma R1 and truncated IFN-gamma R2, lacking the COOH-terminal 51 amino acids (residues 286-337), or cells expressing IFN-gamma R1 alone were unresponsive to IFN-gamma treatment as measured by MHC class I antigen induction. Jak1, Jak2, and Stat1 alpha were activated, and IFN-gamma R1 was phosphorylated only in cells expressing both IFN-gamma R1 and IFN-gamma R2. Jak2 kinase was shown to associate with the intracellular domain of the IFN-gamma R2.