Synergism of type I and type II interferons in stimulating the activity of the same DNA enhancer

Antagonistic Action of IFN-β and IFN-γ on High Affinity Fcγ Receptor Expression in Healthy Controls and Multiple Sclerosis Patients

Monocyte-macrophage activation by IFN-γ is characterized by a pronounced increase of high affinity Fc receptors for IgG (FcγRI), capable of triggering respiratory burst, phagocytosis, Ab-dependent cytotoxicity, and release of proinflammatory cytokines. In view of the antagonism of IFN-β on IFN-γ action, of interest in the chronic inflammatory disorder multiple sclerosis, we examined the possible effect of IFN-β on IFN-γ induction of FcγRI gene expression. We found that IFN-β significantly down-regulated IFN-γ-induced FcγRI surface expression in peripheral blood monocytes from healthy donors, in a dose- and time-dependent manner. This down-regulation of FcγRI surface levels did not correspond to a decrease in FcγRI mRNA, suggesting a posttranscriptional effect of IFN-β. Down-regulation of FcγRI surface expression correlated with diminished cellular signaling through FcγRI, since the IFN-γ-induced increase in Fcγ receptor-triggered respiratory burst was nearly completely abrogated by simultaneous addition of IFN-β. Finally, the same antagonism between both IFNs on FcγRI surface expression was observed in peripheral blood monocytes derived from multiple sclerosis patients; inhibition by IFN-β was even increased (82 ± 11%), as compared with healthy controls (67 ± 4%). These results may partially help explain the beneficial effect of IFN-β in multiple sclerosis.

IFN-γ Priming Up-Regulates IFN-Stimulated Gene Factor 3 (ISGF3) Components, Augmenting Responsiveness of IFN-Resistant Melanoma Cells to Type I IFNs

IFN-stimulated gene factor 3 (ISGF3) mediates transcriptional activation of IFN-sensitive genes (ISGs). The component subunits of ISGF3, STAT1αβ, STAT2, and p48-ISGF3γ, are tyrosine phosphorylated before their assembly into a complex. Subsequently, the ISGF3 complex is translocated to the nucleus. We have recently established that the responsiveness of human melanoma cell lines to type I IFNs correlates directly with their intracellular levels of ISGF3 components, particularly STAT1. In the present study, we show that pretreating IFN-resistant melanoma cell lines with IFN-γ (IFN-γ priming) before stimulation with type I IFN also results in increased levels of ISGF3 components and enhanced DNA-binding activation of ISGF3. In addition, IFN-γ priming of IFN-resistant melanoma cell lines increased expression of type I IFN-induced ISG products, including ISG54, 2′-5′-oligoadenylate synthase, HLA class I, B7-1, and ICAM-1 Ags. Furthermore, IFN-γ priming enhanced the antiviral effect of IFN-β on the IFN-resistant melanoma cell line, MM96. These results support a role for IFN-γ priming in up-regulating ISGF3, thereby augmenting the responsiveness of IFN-resistant melanoma cell lines to type I IFN and providing a molecular basis and justification for using sequential IFN therapy, as proposed by others, to enhance the use of IFNs in the treatment of melanoma.

Jaks, Stats and the immune system

Changes in gene expression are necessary for an adaptive response of cells to immunological stimuli and thus for their proper function in the context of the immune system. Regulatory inputs usually originate from cell surface receptors and in many cases affect the transcription rates of specific genes by modulating the activity of transcription factors. The Jak-Stat signalling paradigm has received large attention by molecular immunologists because it applies to nuclear signalling by all cytokine receptors. In its simplest form it requires only two protein components downstream of the receptor: Janus family protein tyrosine kinases (Jaks) which are usually receptor-associated, and signal transducer and activator of transcription (Stat) family transcription factors which carry the receptor-generated signal to the nucleus and stimulate gene expression. Here we give a brief overview of both recent progress and open questions concerning the Jak and Stat molecules, their regulation, and the biological implications of their activity.

The human interferon alpha-receptor protein confers differential responses to human interferon-beta versus interferon-alpha subtypes in mouse and hamster cell transfectants

The human interferon alpha-receptor (IFNAR gene product or IFN alpha R protein) was expressed in hamster CHO cells and in mouse A9 cells. The response of the IFN alpha R cDNA transfectants to human IFNs was studied by measuring induction of (2'-5') A synthetase (2'-5' AS). In the murine cells, the IFN alpha R protein conferred response to the human IFN-alpha-8 (alpha-B) subtype, but not to huIFN-alpha-2 (alpha-A) or to huIFN-beta. In murine huIFN alpha R cDNA transfectants, containing a hygromycin B resistance gene placed under the control of the 2'-5' AS gene Interferon Response Sequence (IRS), survival and growth of the cells in the presence of hygromycin B was induced by huIFN-alpha-8 but not by huIFN-alpha-2, indicating that the effect of huIFN alpha R is transcriptional. In hamster CHO cells, the huIFN alpha R protein conferred a completely different pattern of response to human IFN subtypes. Thus, the CHO-IFN alpha R transfectants responded to huIFN-beta by 2'-5' AS induction as well as by activation of the ISGF3 and IRF-1 transcription factors. In contrast, the CHO-IFN alpha R cells showed no response to huIFN-alpha-8. The differential response conferred by the huIFN alpha R protein in the two types of rodent cells, indicates that IFN subtype recognition is influenced by another component contributed by the rodent host cell. The ability of human cells, and of human-mouse hybrid cells containing human chromosome 21, to respond to all IFN subtypes is likely to depend also on interactions of the IFN alpha R protein with additional receptor components.

Two cis-DNA elements involved in myeloid-cell-specific expression and gamma interferon (IFN-gamma) activation of the human high-affinity Fc gamma receptor gene: a novel IFN regulatory mechanism

The human high-affinity receptor for the constant region of immunoglobulin G (human Fc gamma R1) is encoded by two mRNAs induced selectively by gamma interferon (IFN-gamma) and expressed in cells of myeloid lineage. The cis-DNA element (GRR) previously found to confer IFN-gamma responsiveness to this gene acts as an inducible enhancer and is the target of an IFN-gamma-activated factor(s) (GIRE-BP) in cells of different origins. Although the GRR motif is not related to the DNA elements involved in the regulation of other IFN-stimulated genes, GIRE-BP binding depends on the IFN-gamma-dependent activation of the 91-kDa protein known to be one of the factors of a transcriptional complex activated by IFN-alpha. Deletions of the Fc gamma R1 promoter allowed us to identify a 25-bp element, downstream from the GRR motif, conferring cell-type-specific expression. This element, called MATE (myeloid activating transcription element), is the DNA target for constitutive factors forming two complexes, MATE-BP1 and MATE-BP2. In accordance with the functional analysis, MATE-BP binding activities were detected in extracts prepared from myeloid cell lines such as THP-1, HL-60, and U-937 but not in HeLa cell extracts. The MATE motif is present not only in the promoter of other Fc receptor genes but also in several promoters of genes whose expression is restricted to monocytic cells. Our results suggest that human Fc gamma R1 gene expression in myeloid cells is initiated by the interaction of IFN-gamma-activated factors with cell-type-specific factors through their binding to the GRR and MATE motifs.

Two cis-DNA elements involved in myeloid-cell-specific expression and gamma interferon (IFN-gamma) activation of the human high-affinity Fc gamma receptor gene: a novel IFN regulatory mechanism

The human high-affinity receptor for the constant region of immunoglobulin G (human Fc gamma R1) is encoded by two mRNAs induced selectively by gamma interferon (IFN-gamma) and expressed in cells of myeloid lineage. The cis-DNA element (GRR) previously found to confer IFN-gamma responsiveness to this gene acts as an inducible enhancer and is the target of an IFN-gamma-activated factor(s) (GIRE-BP) in cells of different origins. Although the GRR motif is not related to the DNA elements involved in the regulation of other IFN-stimulated genes, GIRE-BP binding depends on the IFN-gamma-dependent activation of the 91-kDa protein known to be one of the factors of a transcriptional complex activated by IFN-alpha. Deletions of the Fc gamma R1 promoter allowed us to identify a 25-bp element, downstream from the GRR motif, conferring cell-type-specific expression. This element, called MATE (myeloid activating transcription element), is the DNA target for constitutive factors forming two complexes, MATE-BP1 and MATE-BP2. In accordance with the functional analysis, MATE-BP binding activities were detected in extracts prepared from myeloid cell lines such as THP-1, HL-60, and U-937 but not in HeLa cell extracts. The MATE motif is present not only in the promoter of other Fc receptor genes but also in several promoters of genes whose expression is restricted to monocytic cells. Our results suggest that human Fc gamma R1 gene expression in myeloid cells is initiated by the interaction of IFN-gamma-activated factors with cell-type-specific factors through their binding to the GRR and MATE motifs.

Multiple cytokine interactions regulate Ly-6E antigen expression: cooperative Ly-6E induction by IFNs, TNF, and IL-1 in a T cell lymphoma and in its induction-deficient variants

The cell surface Ly-6E antigen, known to play a role in T cell activation, is up-regulated by IFNs. In the present study, we investigated the possible interactions between IFNs and other cytokines in this regulation. As a model system, we used the YAC T cell lymphoma, in which Ly-6E is normally absent but can be highly induced both at the mRNA and surface protein levels by IFN-gamma or IFN-alpha/beta. The combination of the two IFNs was found to result in markedly synergistic Ly-6E induction in this cell line. Moreover, mutants of YAC cells were isolated that did not respond to the Ly-6E-inducing action of IFN-gamma or IFN-alpha/beta alone but did respond to their combination. Such a synergistic interaction is consistent with the notion that the two IFN types utilize different intracellular mechanisms to induce Ly-6E expression. Ly-6E induction mediated by IFN-gamma or IFN-alpha/beta was also enhanced by cotreatment with TNF-alpha or IL-1 alpha, which by themselves had no detectable Ly-6E-inducing effect. These two cytokines similarly synergized with IFNs to trigger a response in several Ly-6E-induction-deficient mutants. However, their action could be dissociated in one mutant (B54) where the response to IFN-alpha/beta was enhanced by TNF-alpha, but not by IL-1 alpha. Altogether, these data indicate that Ly-6E antigen expression is regulated by the interaction of several inflammatory cytokines, which may provide a mechanism for the local modulation of T cell activation. The YAC cell mutants described here should facilitate further analysis of the molecular bases of Ly-6E regulation.

Interleukin-6 induces the (2'-5') oligoadenylate synthetase gene in M1 cells through an effect on the interferon-responsive enhancer

Interleukin-6 (IL-6) activates (2'-5') A synthetase (2'-5' AS) gene expression in differentiating myeloleukemic M1 cells. Antibodies to type I interferon (IFN) inhibit 2'-5' AS induction but not differentiation. Analysis of the mechanism of 2'-5' AS induction shows that it does not result from increased IFN formation, but from a synergism between IL-6 and endogenously secreted IFN. IL-6 can activate expression of a CAT construct fused to the interferon response sequence (IRS) of the 2'-5' AS gene. In extracts of IL-6-treated M1 cells, changes in protein binding to IRS DNA can be demonstrated. One of the effects of IL-6 on M1 cells is, therefore, to induce DNA binding factors, some of which act on the same enhancer sequence as IFNs, resulting in a synergistic gene activation. M1 variants resistant to differentiation by IL-6 have lost the ability to induce the 2'-5' AS gene.