Ana M. Gamero

Type I interferon restricts type 2 immunopathology through the regulation of group 2 innate lymphoid cells

Viral respiratory tract infections are the main causative agents of the onset of infection-induced asthma and asthma exacerbations that remain mechanistically unexplained. Here we found that deficiency in signaling via type I interferon receptor led to deregulated activation of group 2 innate lymphoid cells (ILC2 cells) and infection-associated type 2 immunopathology. Type I interferons directly and negatively regulated mouse and human ILC2 cells in a manner dependent on the transcriptional activator ISGF3 that led to altered cytokine production, cell proliferation and increased cell death. In addition, interferon-γ (IFN-γ) and interleukin 27 (IL-27) altered ILC2 function dependent on the transcription factor STAT1. These results demonstrate that type I and type II interferons, together with IL-27, regulate ILC2 cells to restrict type 2 immunopathology.

Type-I interferon signaling through ISGF3 complex is required for sustained Rip3 activation and necroptosis in macrophages

Significance Although it has long been known that inflammatory immune responses are associated with death of cells through necrosis, the mechanisms controlling this process are not yet well understood. Recently a type of programmed inflammatory cell death, necroptosis, has been discovered. In this paper we reveal previously unidentified molecular mechanisms that operate to induce this form of cell death. Our results indicate that in order to undergo necroptosis, immune cells must produce and receive signals from the key immune regulator, interferon. Such interferon-dependent necroptosis of immune cells drives acute inflammatory pathology in a mouse model of sepsis. This work highlights the intimate connection between cell death and inflammation, and may lead to new understanding and treatment of inflammatory pathologies. Myeloid cells play a critical role in perpetuating inflammation during various chronic diseases. Recently the death of macrophages through programmed necrosis (necroptosis) has emerged as an important mechanism in inflammation and pathology. We evaluated the mechanisms that lead to the induction of necrotic cell death in macrophages. Our results indicate that type I IFN (IFN-I) signaling is a predominant mechanism of necroptosis, because macrophages deficient in IFN-α receptor type I (IFNAR1) are highly resistant to necroptosis after stimulation with LPS, polyinosinic-polycytidylic acid, TNF-α, or IFN-β in the presence of caspase inhibitors. IFN-I–induced necroptosis occurred through both mechanisms dependent on and independent of Toll/IL-1 receptor domain-containing adaptor inducing IFN-β (TRIF) and led to persistent phosphorylation of receptor-interacting protein 3 (Rip3) kinase, which resulted in potent necroptosis. Although various IFN-regulatory factors (IRFs) facilitated the induction of necroptosis in response to IFN−β, IRF-9–STAT1– or -STAT2–deficient macrophages were highly resistant to necroptosis. Our results indicate that IFN-β–induced necroptosis of macrophages proceeds through tonic IFN-stimulated gene factor 3 (ISGF3) signaling, which leads to persistent expression of STAT1, STAT2, and IRF9. Induction of IFNAR1/Rip3–dependent necroptosis also resulted in potent inflammatory pathology in vivo. These results reveal how IFN-I mediates acute inflammation through macrophage necroptosis.

Cecal Ligation Puncture Procedure

Human sepsis is characterized by a set of systemic reactions in response to intensive and massive infection that failed to be locally contained by the host. Currently, sepsis ranks among the top ten causes of mortality in the USA intensive care units. During sepsis there are two established haemodynamic phases that may overlap. The initial phase (hyperdynamic) is defined as a massive production of proinflammatory cytokines and reactive oxygen species by macrophages and neutrophils that affects vascular permeability (leading to hypotension), cardiac function and induces metabolic changes culminating in tissue necrosis and organ failure. Consequently, the most common cause of mortality is acute kidney injury. The second phase (hypodynamic) is an anti-inflammatory process involving altered monocyte antigen presentation, decreased lymphocyte proliferation and function and increased apoptosis. This state known as immunosuppression or immune depression sharply increases the risk of nocosomial infections and ultimately, death. The mechanisms of these pathophysiological processes are not well characterized. Because both phases of sepsis may cause irreversible and irreparable damage, it is essential to determine the immunological and physiological status of the patient. This is the main reason why many therapeutic drugs have failed. The same drug given at different stages of sepsis may be therapeutic or otherwise harmful or have no effect. To understand sepsis at various levels it is crucial to have a suitable and comprehensive animal model that reproduces the clinical course of the disease. It is important to characterize the pathophysiological mechanisms occurring during sepsis and control the model conditions for testing potential therapeutic agents. To study the etiology of human sepsis researchers have developed different animal models. The most widely used clinical model is cecal ligation and puncture (CLP). The CLP model consists of the perforation of the cecum allowing the release of fecal material into the peritoneal cavity to generate an exacerbated immune response induced by polymicrobial infection. This model fulfills the human condition that is clinically relevant. As in humans, mice that undergo CLP with fluid resuscitation show the first (early) hyperdynamic phase that in time progresses to the second (late) hypodynamic phase. In addition, the cytokine profile is similar to that seen in human sepsis where there is increased lymphocyte apoptosis (reviewed in). Due to the multiple and overlapping mechanisms involved in sepsis, researchers need a suitable sepsis model of controlled severity in order to obtain consistent and reproducible results.

An essential role for IFN-β in the induction of IFN-stimulated gene expression by LPS in macrophages.

TLR agonists such as LPS and poly(I:C) induce expression of type I IFNs, such as IFN‐α and ‐β, by macrophages. To examine the role of IFN‐β in the induction of ISGs by LPS, we compared the ability of LPS to induce ISGF3 activity and ISG expression in bone marrow–derived macrophages from WT and Ifnb1−/− mice. We found that LPS treatment activated ISGF3 and induced expression of ISGs such as Oas1, Mx1, Ddx58 (RIG‐I), and Ifih1 (MDA5) in WT macrophages, but not in macrophages derived from Ifnb1−/− mice or Ifnar1−/− mice. The inability of LPS to induce activation of ISGF3 and ISG expression in Ifnb1−/− macrophages correlated with the failure of LPS to induce activation of STAT1 and ‐2 in these cells. Consistent with these findings, LPS treatment also failed to induce ISG expression in bone marrow–derived macrophages from Stat2 KO mice. Although activation of ISGF3 and induction of ISG expression by LPS was abrogated in Ifnb1−/− and Ifnar1−/− macrophages, activation of NF‐κB and induction of NF‐κB‐responsive genes, such as Tnf (TNF‐α) and Il1b (IL‐1β), were not affected by deletion of either the IFN‐β or IFN‐αR1 genes. These findings demonstrate that induction of ISGF3 activity and ISG expression by LPS is critically dependent on intermediate production of IFN‐β and autocrine signaling through type I IFN receptors.

Stat2 loss leads to cytokine-independent, cell-mediated lethality in LPS-induced sepsis

Deregulated Toll-like receptor (TLR)-triggered inflammatory responses that depend on NF-κB are detrimental to the host via excessive production of proinflammatory cytokines, including TNF-α. Stat2 is a critical component of type I IFN signaling, but it is not thought to participate in TLR signaling. Our study shows that LPS-induced lethality in Stat2−/− mice is accelerated as a result of increased cellular transmigration. Blocking intercellular adhesion molecule-1 prevents cellular egress and confers survival of Stat2−/− mice. The main determinant of cellular egress in Stat2−/− mice is the genotype of the host and not the circulating leukocyte. Surprisingly, lethality and cellular egress observed on Stat2−/− mice are not associated with excessive increases in classical sepsis cytokines or chemokines. Indeed, in the absence of Stat2, cytokine production in response to multiple TLR agonists is reduced. We find that Stat2 loss leads to reduced expression of NF-κB target genes by affecting nuclear translocation of NF-κB. Thus, our data reveal the existence of a different mechanism of LPS-induced lethality that is independent of NF-κB triggered cytokine storm but dependent on cellular egress.

Identification of STAT2 Serine 287 as a Novel Regulatory Phosphorylation Site in Type I Interferon-induced Cellular Responses

Background: STAT2 is a key transcription factor that mediates the protective role of type I interferons in host defense. Results: Type I interferons induce the phosphorylation of STAT2 at serine 287. Conclusion: Serine 287-STAT2 is a regulatory site involved in modulating the transcriptional and cellular responses to type I interferons. Significance: Deregulated STAT2 signaling may contribute to heightened type I interferon responses and susceptibility to many diseases. STAT2 is a positive modulator of the transcriptional response to type I interferons (IFNs). STAT2 acquires transcriptional function by becoming tyrosine phosphorylated and imported to the nucleus following type I IFN receptor activation. Although most STAT proteins become dually phosphorylated on specific tyrosine and serine residues to acquire full transcriptional activity, no serine phosphorylation site in STAT2 has been reported. To find novel phosphorylation sites, mass spectrometry of immunoprecipitated STAT2 was used to identify several phosphorylated residues. Of these, substitution of serine 287 with alanine (S287A) generated a gain-of-function mutant that enhanced the biological effects of IFN-α. S287A-STAT2 increased cell growth inhibition, prolonged protection against vesicular stomatitis virus infection and enhanced transcriptional responses following exposure of cells to IFN-α. In contrast, a phosphomimetic STAT2 mutant (S287D) produced a loss-of-function protein that weakly activated IFN-induced ISGs. Our mechanistic studies suggest that S287A-STAT2 likely mediates its gain-of-function effects by prolonging STAT2/STAT1 dimer activation and retaining it in transcriptionally active complexes with chromatin. Altogether, we have uncovered that in response to type I IFN, STAT2 is serine phosphorylated in the coiled-coil domain that when phosphorylated can negatively regulate the biological activities of type I IFNs.

The Protective Role of Type I Interferons in the Gastrointestinal Tract

The immune system of the gastrointestinal (GI) tract manages the significant task of recognizing and eliminating pathogens while maintaining tolerance of commensal bacteria. Dysregulation of this delicate balance can be detrimental, resulting in severe inflammation, intestinal injury, and cancer. Therefore, mechanisms to relay important signals regulating cell growth and immune reactivity must be in place to support GI homeostasis. Type I interferons (IFN-I) are a family of pleiotropic cytokines, which exert a wide range of biological effects including promotion of both pro- and anti-inflammatory activities. Using animal models of colitis, investigations into the regulation of intestinal epithelium inflammation highlight the role of IFN-I signaling during fine modulation of the immune system. The intestinal epithelium of the gut guides the immune system to differentiate between commensal and pathogenic microbiota, which relies on intimate links with the IFN-I signal-transduction pathway. The current paradigm depicts an IFN-I-induced antiproliferative state in the intestinal epithelium enabling cell differentiation, cell maturation, and proper intestinal barrier function, strongly supporting its role in maintaining baseline immune activity and clearance of damaged epithelia or pathogens. In this review, we will highlight the importance of IFN-I in intestinal homeostasis by discussing its function in inflammation, immunity, and cancer.

STAT2 Is Required for TLR-Induced Murine Dendritic Cell Activation and Cross-Presentation

TLR-stimulated cross-presentation by conventional dendritic cells (cDCs) is important in host defense and antitumor immunity. We recently reported that cDCs lacking the type I IFN signaling molecule STAT2 are impaired in cross-presenting tumor Ags to CD8+ T cells. To investigate how STAT2 affects cross-presentation, we determined its requirements for dendritic cell activation. In this study, we report that STAT2 is essential for the activation of murine female cDCs upon TLR3, -4, -7, and -9 stimulation. In response to various TLR ligands, Stat2−/− cDCs displayed reduced expression of costimulatory molecules and type I IFN-stimulated genes. The cDC responses to exogenous IFN-α that we evaluated required STAT2 activation, indicating that the canonical STAT1–STAT2 heterodimers are the primary signaling transducers of type I IFNs in cDCs. Interestingly, LPS-induced production of IL-12 was STAT2 and type I IFN receptor (IFNAR) dependent, whereas LPS-induced production of TNF-α and IL-6 was STAT2 and IFNAR independent, suggesting a specific role of the IFNAR–STAT2 axis in the stimulation of proinflammatory cytokines by LPS in cDCs. In contrast, R848- and CpG-induced cytokine production was less influenced by the IFNAR–STAT2 axis. Short kinetics and IFNAR blockade studies showed that STAT2 main function is to transduce signals triggered by autocrine type I IFNs. Importantly, Stat2−/− cDCs were deficient in cross-presenting to CD8+ T cells in vitro upon IFN-α, CpG, and LPS stimulation, and also in cross-priming and licensing cytotoxic T cell killers in vivo. We conclude that STAT2 plays a critical role in TLR-induced dendritic cell activation and cross-presentation, and thus is vital in host defense.

TLR ligands up‐regulate Trex1 expression in murine conventional dendritic cells through type I Interferon and NF‐κB‐dependent signaling pathways

Mutations in the Trex1 are associated with a spectrum of type I IFN‐dependent autoimmune diseases. Trex1 plays an essential role in preventing accumulation of excessive cytoplasmic DNA, avoiding cell‐intrinsic innate DNA sensor activation and suppressing activation of type I IFN‐stimulated and ‐independent antiviral genes. Trex1 also helps HIV to escape cytoplasmic detection by DNA sensors. However, regulation of Trex1 in innate immune cells remains elusive. We report that murine cDCs have high constitutive expression of Trex1 in vitro and in vivo in the spleen. In resting bone marrow‐derived cDCs, type I IFNs up‐regulate Trex1 expression via the IFNAR‐mediated signaling pathway (STAT1‐ and STAT2‐dependent). DC activation induced by TLR3, ‐4, ‐7, and ‐9 ligands also augments Trex1 expression through autocrine IFN‐β production and triggering of the IFN signaling pathway, whereas TLR4 ligand LPS also stimulates an early expression of Trex1 through IFN‐independent NF‐κB‐dependent signaling pathway. Furthermore, retroviral infection also induces Trex1 up‐regulation in cDCs, as we found that a gene therapy HIV‐1‐based lentiviral vector induces significant Trex1 expression, suggesting that Trex1 may affect local and systemic administration of gene‐therapy vehicles. Our data indicate that Trex1 is induced in cDCs during activation upon IFN and TLR stimulation through the canonical IFN signaling pathway and suggest that Trex1 may play a role in DC activation during infection and autoimmunity. Finally, these results suggest that HIV‐like viruses may up‐regulate Trex1 to increase their ability to escape immunosurveillance.

Interferon-γ signaling in melanocytes and melanoma cells regulates expression of CTLA-4

CTLA4 is a cell surface receptor on T cells that functions as an immune checkpoint molecule to enforce tolerance to cognate antigens. Anti-CTLA4 immunotherapy is highly effective at reactivating T-cell responses against melanoma, which is postulated to be due to targeting CTLA4 on T cells. Here, we report that CTLA4 is also highly expressed by most human melanoma cell lines, as well as in normal human melanocytes. Interferon-γ (IFNG) signaling activated the expression of the human CTLA4 gene in a melanocyte and melanoma cell-specific manner. Mechanistically, IFNG activated CTLA4 expression through JAK1/2-dependent phosphorylation of STAT1, which bound a specific gamma-activated sequence site on the CTLA4 promoter, thereby licensing CBP/p300-mediated histone acetylation and local chromatin opening. In melanoma cell lines, elevated baseline expression relied upon constitutive activation of the MAPK pathway. Notably, RNA-seq analyses of melanoma specimens obtained from patients who had received anti-CTLA4 immunotherapy (ipilimumab) showed upregulation of an IFNG-response gene expression signature, including CTLA4 itself, which correlated significantly with durable response. Taken together, our results raise the possibility that CTLA4 targeting on melanoma cells may contribute to the clinical immunobiology of anti-CTLA4 responses.Significance: These findings show that human melanoma cells express high levels of the immune checkpoint molecule CTLA4, with important possible implications for understanding how anti-CTLA4 immunotherapy mediates its therapeutic effects. Cancer Res; 78(2); 436-50. ©2017 AACR.