Antiviral Immune Responses to Invertebrate Iridescent Virus 6 in Drosophila

West, Cara C.

02 January 2018

The innate immune system is a critical first line of defense against invading pathogens. Innate immunity directly detects pathogens, sets up an appropriate adaptive response, and can directly kill pathogens. Drosophila may lack an adaptive immune response, but have a robust innate immune system with a variety of defense effector mechanisms. While the responses to bacteria, fungi, and RNA viruses have been well characterized, not much is known about the response to DNA viruses. My studies have set out to characterize the Drosophila immune response to a DNA virus, utilizing the large dsDNA virus, Invertebrate Iridescent Virus 6 (IIV-6). IIV-6 infection causes shortened lifespan, and in later stages of infection, flies present with abdominal swelling and iridescent blue color. Our objectives were to identify pathways flies use to protect themselves from IIV-6 infection, determine how this protection is mediated, and to identify any immune inhibitors that IIV-6 uses to suppress innate immune signaling. I have found that IIV-6 strongly up-regulates a class of stress proteins with unknown function, termed Turandots, after infection in vivo or in vitro. This induction is dependent upon viral replication, requires JAK-STAT activation, and activation of p38b MAPK. In addition, the unpaireds, which function as JAK-STAT ligands, are upregulated after IIV-6 infection in a p38b-dependent manner. Together, this data suggests that p38b activation leads to production of unpaired cytokines and activation of JAK-STAT signaling to induce Turandots. I have also found that IIV-6 infected cells secrete protective factors. This response is induced within 12 hours of IIV-6 infection, exosome-mediated, and provides robust protection to naive cells challenged with an mCherry-expressing strain of IIV-6. Additionally, IIV-6 inhibits two major immune responses in Drosophila, the IMD and Toll pathways. Stimulation of IIV-6 infected Drosophila S2* cells with either IMD or Toll stimulators results in very poor antimicrobial peptide responses. Yet, IMD and Relish are still cleaved upon stimulation in IIV-6 infected cells, indicating that the block is downstream. In support of this finding, IIV-6 infected flies respond very poorly to infection with the enterobacteria Erwinia carotovora carotovora compared to mock-injected flies.

Drosophila

innate immunity

Drosophila antiviral responses

antiviral responses

virus

IIV-6

Drosophila immune responses

p38

JAK-STAT

IMD

Immunity

Immunology of Infectious Disease

Virology

Innate Immune Responses to Respiratory Syncytial Virus: Age-associated Changes

Wong, Terianne Maiko

01 January 2013

Respiratory syncytial virus (RSV) infection causes ~64 million cases of respiratory disease and 200,000 deaths annually worldwide, yet there is no broadly effective prophylactic or treatment regimen. RSV can produce acute respiratory illness in patients of all ages but strikes the age extremes, infants and the elderly, with highest frequency presumably due to innate immune deficiencies. A higher morbidity and mortality has been reported for the elderly above 65 years of age, which has been attributed to immune senescence. Efforts to generate an effective vaccine have thus far been unsuccessful. The innate immune system provides the first line of defense against viral pathogens with a repertoire of anatomical barriers, phagocytic immune cells, pattern recognition receptors (PRRs) and antiviral cytokines like interferons (IFNs). The precise mechanism of subversion of innate immunity in young and aged is poorly understood. A better understanding of innate immune pathways is expected to aid in the development of appropriate vaccines or prophylactics for these high-risk groups. Previously, the RSV nonstructural protein 1 (NS1) was shown to antagonize IFN responses by disrupting components of the innate immune system, although the mechanism is not well defined. We hypothesized that NS1 targets constituents of the PRR pathways to evade innate immunity and thus ensure viral survival. Using microscopy and co-immunoprecipitation assays, we found that NS1 localizes to the mitochondria and binds to the mitochondrially associated adaptor protein MAVS, thus preventing MAVS interaction with the RNA helicase, RIG-I. Expression of NS1 was also correlated with upstream IFN-response regulator, LGP2, and its expression was inducible in the absence of a viral infection. Tetracycline-inducible expression of recombinant NS1 in a cell model also promoted viral replication and emphasizes the key contribution of NS1 to RSV survival. Through this study, we demonstrated a mechanism for RSV NS1 in the disruption of early innate responses through mitochondrial localization and alteration of the RLH signaling. Whereas the above studies showed the importance RSV-induced innate immune pathways, whether the expression and signaling of innate immune pathways were adversely affected upon RSV infection in the high-risk groups remains unknown. Since elderly individuals are at an increased risk for severe bronchiolitis and RSV-induced pneumonia, often resulting in hospitalization and medical intervention and adaptive immune cell functionality and responsiveness reportedly decline with age, we hypothesized a similar age-related deterioration of the innate antiviral system. In this investigation, we used an aged mouse model to correlate age-associated changes in innate immune gene expression with RSV pathology. Of 84 antiviral genes examined, five genes including RIG-I, IFNAR1, TLR8, IL-1Β, and osteopontin (OPN) were associated with both age and infection. In response to RSV infection, aged mice had delayed induction of antiviral genes and diminished ability to secrete IL-6 in response to TLR7/8 agonist in primary alveolar macrophages. Lungs from aged, RSV-infected mice had increased cellular infiltration and prolonged infection as compared to young mice. In summary, age-related decline in expression and functionality of antiviral defenses were correlated with enhance RSV-induced lung disease in aged mice. In the absence of infection, aged mice chronically overproduced IL-1Β and OPN relative to young mice. Upon infection, aged mice had impaired ability to secrete higher levels of IL-1Β and mucus. In contrast, OPN secretion remained high and prolonged in aged mice throughout infection. The age-related decline in host antiviral gene induction and delayed cytokine production correlated with enhanced disease pathology. Using a transgenic strain of mice deficient in OPN (OPN-KO), we observed greater resistance to RSV and enhanced secretion of mucus, but unaltered cellular infiltration into the lungs. Therefore, OPN overproduction and defective mucus production likely contribute to pathology in aged mice. These findings demonstrate that RSV targets the innate virus recognition and antiviral cytokine activation pathways but also that the antiviral defense system is significantly affected by age. Consequently, efforts to generate vaccines or develop therapies that stimulate IFN induction may prove unsuccessful in the elderly given that RSV virulence factors and age weaken these responses. This study contributes to our understanding of how aging relates to the RSV subversion of the host antiviral response and should help with the development of better antiviral therapies suited to the growing elderly population.

Aging

Antiviral responses

Innate Immunity

Respiratory Infections

Respiratory Syncytial Virus

virus

Biology

Immunology and Infectious Disease

Virology

The enzymology and substrate selectivity of the ISG15 conjugation system

Durfee, Larissa Anne

03 February 2011

ISG15 is an interferon-induced and anti-viral ubiquitin-like protein (Ubl). Ube1L, UbcH8, and Herc5 have been identified as the E1-E2-E3 enzymes for ISG15 conjugation, and, like ISG15, their expression is induced by type I interferons. Although Herc5 is the major E3 for ISG15, over 300 proteins have been identified as ISG15 target proteins in interferon-stimulated cells. In this work, I address two aspects of the human ISG15 conjugation system: 1) the specificity of the Ube1L-UbcH8 interaction and 2), the basis of substrate recognition by Herc5. Regarding the selection of UbcH8 by Ube1L, my experiments show that although UbcH8 had been reported to function as an E2 for both Ub and ISG15, UbcH8 is preferentially activated by Ube1L compared to Ube1 (E1[superscript Ub]). The basis of this preference is a result of specific interactions between the ubiquitin-fold domain (UFD) of Ube1L and the amino-terminal [alpha]1 helix and [beta]1 [beta]2 region within UbcH8. Examination of the interferon-induced and transfected expression levels of UbcH8, combined with the kinetic constants, suggest that UbcH8 is unlikely to function as a Ub E2 in most cell lines. In examining the selection of target proteins by Herc5, I show that the range of substrates extends far beyond the proteins identified in proteomics studies and includes many exogenously expressed foreign proteins. Furthermore, I show that ISG15 conjugation is restricted to newly synthesized pools of proteins and Herc5 is associated with polyribosomes. I propose a model for ISGylation in which Herc5 broadly modifies newly synthesized proteins in a co-translational manner and suggest that, in the context of an interferon-stimulated cell, newly translated viral proteins may be primary targets of ISG15. Consistent with this, I show that ISGylation of human papillomavirus (HPV) L1 capsid protein has a dominant-inhibitory effect on the infectivity of HPV16 pseudoviruses. These discoveries have greatly increased our understanding of the mechanism of ISG15 pathway and provide a framework for establishing an in vitro ISG15 conjugation system and further examination of the anti-viral function of ISG15. / text

ISG15

Herc5

Ubiquitin-like proteins

Interferon

Antiviral responses

Ubiquitin

Anti-viral proteins