The interferon-stimulated gene product HELZ2 destabilizes human LINE-1 RNA to inhibit LINE-1 retrotransposition and the associated type I interferon response / HELZ2はヒトLINE-1RNAの不安定化を介してLINE-1の転移とタイプIインターフェロン応答を抑制する

Luqman Bin Abdul Fatah, Ahmad

23 March 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24749号 / 生博第490号 / 新制||生||65(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 石川 冬木, 教授 高田 穣, 教授 朝長 啓造 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

retrotransposon

LINE-1

interferon-stimulated genes

innate immune response

HELZ2

460

RNase L Amplifies Interferon Signaling by Inducing Protein Kinase R-Mediated Antiviral Stress Granules

Manivannan, Praveen

January 2020

No description available.

Biology

Virology

PKR

RNase L

Rig-I

double-stranded RNA

interferon

stress granules

HOST-MICROBIOME INTERACTIONS AND REGULATION OF THE IMMUNE SYSTEM

Alvarez Contreras, Carlos Alberto

22 January 2021

No description available.

Immunology

Immunology

Microbiome

PSA

Polysaccharide A

T cells

Host-Microbiome

Bacteroides Fragilis

Interferon Responsive Genes

Current concepts of photosensitivity in cutaneous lupus erythematosus

Klein, Benjamin, Kunz, Manfred

28 November 2023

Cutaneous lupus erythematosus (CLE) represents a complex autoimmune disease with a broad phenotypic spectrum ranging from acute to chronic destructive cutaneous lesions. Patients with CLE exhibit high photosensitivity and ultraviolet (UV) irradiation can lead to systemic flares in systemic lupus erythematosus. However, the exact mechanisms how UV irradiation enhances cutaneous inflammation in lupus are not fully understood. Recently, new molecular mechanisms of UV-driven immune responses in CLE were identified, offering potential therapeutic approaches. Especially the induction of type I interferons, central cytokines in lupus pathogenesis which are released by various skin cells, have become the focus of current research. In this review, we describe current pathogenic concepts of photosensitivity in lupus erythematosus, including UV-driven activation of intracellular nucleic acid sensors, cellular cytokine production and immune cell activation. Furthermore, we discuss activated pathways contributing to enhanced apoptosis as well as intracellular translocation of autoantigens thereby promoting CLE upon UV light exposure.

info:eu-repo/classification/ddc/610

ddc:610

Site directed molecular design and performances of Interferon-α2a and Interleukin-4 bioconjugates with PEG alternative polymers / Seitenspezifisches molekulares Design und Eigenschaften von Interferon-α2a und Interleukin-4 Biokonjugaten mit PEG alternativen Polymeren

Hauptstein, Niklas

January 2023

Serum half-life elongation as well as the immobilization of small proteins like cytokines is still one of the key challenges for biologics. This accounts also for cytokines, which often have a molecular weight between 5 and 40 kDa and are therefore prone to elimination by renal filtration and sinusoidal lining cells. To solve this problem biologics are often conjugated to poly(ethylene glycol) (PEG), which is the gold standard for the so called PEGylation. PEG is a synthetic, non-biodegradable polymer for increasing the hydrodynamic radius of the conjugated protein to modulate their pharmacokinetic performance and prolong their therapeutic outcome. Though the benefits of PEGylation are significant, they also come with a prize, which is a loss in bioactivity due to steric hindrance and most often the usage of heterogeneous bioconjugation chemistries. While PEG is a safe excipient in most cases, an increasing number of PEG related side-effects, such as immunological responses like hypersensitivity and accelerated blood clearance upon repetitive exposure occur, which highlights the need for PEG alternative polymers, that can replace PEG in such cases. Another promising method to significantly prolong the residence time of biologics is to immobilize them at a desired location. To achieve this, the transglutaminase (TG) Factor XIIIa (FXIIIa), which is an important human enzyme during blood coagulation can be used. FXIIIa can recognize specific peptide sequences that contain a lysine as substrates and link them covalently to another peptide sequence, that contains a glutamine, forming an isopeptide bond. This mechanism can be used to link modified proteins, which have a N- or C-terminal incorporated signal peptide by mutation, to the extracellular matrix (ECM) of tissues. Additionally, both above-described methods can be combined. By artificially introducing a TG recognition sequence, it is possible to attach an azide group containing peptide site-specifically to the TG, recognition sequence. This allows the creation of a site-selective reactive site at the proteins N- or C-terminus, which can then be targeted by cyclooctyne functionalized polymers, just like amber codon functionalized proteins. This thesis has focused on the two cytokines human Interferon-α2a (IFN-α2a) and human, as well as murine Interleukin-4 (IL-4) as model proteins to investigate the above-described challenges. IFN-α2a has been chosen as a model protein because it is an approved drug since 1986 in systemic applications against some viral infections, as well as several types of cancer. Furthermore, IFN-α2 is also approved in three PEGylated forms, which have different molecular weights and use different conjugation techniques for polymer attachment. This turns it into an ideal candidate to compare new polymers against the gold standard PEG. Interleukin-4 (IL-4) has been chosen as the second model protein due to its similar size and biopotency. This allows to compare found trends from IFN-α2a with another bioconjugate platform and distinguish between IFN-α2a specific, or general trends. Furthermore, IL-4 is a promising candidate for clinical applications as it is a potent anti-inflammatory protein, which polarizes macrophages from the pro-inflammatory M1 state into the anti-inflammatory M2 state. / Die Verlängerung der Serum-Halbwertszeit sowie die Immobilisierung kleiner Proteine wie Zytokine ist nach wie vor eine der größten Herausforderungen für Biologika. Dies gilt auch für Zytokine, die häufig ein Molekulargewicht zwischen 5 und 40 kDa haben und daher leicht durch die Nierenfiltration und sinusoidale Endothelzellen eliminiert werden können. Um dieses Problem zu lösen, werden Biologika häufig an Poly(ethylenglykol) (PEG) konjugiert, das den Goldstandard für die so genannte PEGylierung darstellt. PEG ist ein synthetisches, biologisch nicht abbaubares Polymer, das den hydrodynamischen Radius des konjugierten Proteins vergrößert, um die pharmakokinetische Leistung zu modulieren und die therapeutische Wirkung zu verlängern. Obwohl die Vorteile der PEGylierung beträchtlich sind, haben sie auch ihren Preis, nämlich einen Verlust an Bioaktivität aufgrund sterischer Hindernisse und meist die Verwendung heterogener Biokonjugationstechniken. Obwohl PEG in den meisten Fällen ein sicherer Hilfsstoff ist, treten immer mehr PEG-bedingte Nebenwirkungen auf, wie z. B. immunologische Reaktionen wie Überempfindlichkeit und beschleunigter Abbau bei wiederholter Exposition, was den Bedarf an alternativen PEG-Polymeren unterstreicht, die PEG in solchen Fällen ersetzen können. Eine weitere vielversprechende Methode, um die Verweildauer von Biologika deutlich zu verlängern, besteht darin, sie an einem gewünschten Ort zu immobilisieren. Dazu kann die Transglutaminase (TG) Faktor XIIIa (FXIIIa) verwendet werden, die ein wichtiges menschliches Enzym bei der Blutgerinnung ist. FXIIIa kann bestimmte Peptidsequenzen, die ein Lysin enthalten, als Substrate erkennen und sie kovalent an eine andere Peptidsequenz, die ein Glutamin enthält, binden, wobei eine Isopeptidbindung entsteht. Dieser Mechanismus kann benutzt werden um modifizierte Proteine, welche durch Mutation ein N- oder C-terminal eingebautes Signalpeptid besitzen, mit der extrazellularen Gewebematrix (ECM) zu verknüpfen. Diese Arbeit konzentriert sich auf die beiden Zytokine humanes Interferon-α2a (IFN-α2a) und humanes sowie murines Interleukin-4 (IL-4) als Modellproteine, um die oben beschriebenen Herausforderungen zu untersuchen. IFN-α2a wurde als Modellprotein ausgewählt, weil es seit 1986 ein zugelassenes Medikament für die systemische Anwendung gegen einige Virusinfektionen und verschiedene Krebsarten ist. Darüber hinaus ist IFN-α2 auch in drei PEGylierten Formen zugelassen, die unterschiedliche Molekulargewichte haben und verschiedene Konjugationstechniken für die Polymeranbindung verwenden. Dies macht es zu einem idealen Kandidaten für den Vergleich neuer Polymere mit dem Goldstandard PEG. Interleukin-4 (IL-4) wurde als zweites Modellprotein gewählt, da es eine ähnliche Größe und Biopotenz aufweist. Dies ermöglicht es, die von IFN-α2a gefundenen Trends mit einer anderen Biokonjugat-Plattform zu vergleichen und zwischen IFN-α2a-spezifischen und allgemeinen Trends zu unterscheiden. Darüber hinaus ist IL-4 ein vielversprechender Kandidat für klinische Anwendungen, da es ein starkes entzündungshemmendes Protein ist, das Makrophagen vom entzündungsfördernden M1-Zustand in den entzündungshemmenden M2-Zustand polarisiert.

Cytokine

Interferon <alpha-2a->

Konjugation

Polymere

Interleukin 4

Polyethylenglykole

ddc:572

Cellular Antagonization of the Type 1 Interferon Response for the Potentiation of Oncolytic Virotherapy

Wong, Boaz

25 January 2024

Oncolytic viruses (OVs) have made tremendous strides as a viable cancer therapeutic in recent years; however, variable infectivity rates have since limited clinical efficacy. Residual type 1 interferon (IFN-1) responses are integral to the tumour’s innate antiviral defense and confer resistance to OVs. To combat this, small molecules with viral sensitizing ability can be used in combination to transiently knockdown IFN-1 responses, allowing OVs to gain a foothold for increased infectivity and therapeutic efficacy. Accordingly, we hypothesize that some chemical or genetic manipulations of cellular processes can indirectly antagonize antiviral IFN-1 responses and modulate pro-inflammatory pathways to potentiate oncolytic virotherapy. In this thesis, we identify several avenues to modify cell signalling events to increase OV therapeutic efficacy through IFN-1 inhibition. Firstly, with respect to the demonstrated OV-enhancing effects of vanadium, a pan-phosphatase (PP) inhibitor, we elucidate that its IFN-1 suppressing activity involves activation of the epidermal growth factor receptor (EGFR) pathway via STAT1/2 and NF-κB. Pharmacological inhibition of EGFR abrogated vanadium’s viral sensitizing ability in vivo. Secondly, using high-throughput screening methodology, we identify protein phosphatases that inherently regulate the IFN-1 response as targets for oncolytic vesicular stomatitis virus (VSV∆51) potentiation. Indeed, cloning interfering RNA against one of these PP targets, acid phosphatase 2 (ACP2), into the VSV∆51 platform demonstrated superior infectivity and cancer cell cytotoxicity compared to the non-targeting VSV∆51 control. Thirdly, we characterize pevonedistat, a first in-class neddylation activating enzyme inhibitor, to potentiate OV therapeutic efficacy across several in vitro and in vivo contexts. We demonstrate pevonedistat’s ability to inhibit IFN-1 signalling and pro-inflammatory cytokine production using both neddylation independent and dependent mechanisms. Taken altogether, we dissect multiple signaling mechanisms by which the IFN-1 response can be modulated for the purposes of improving OV therapeutic efficacy. This knowledge can subsequently be directly translated into designing optimized OV strategies for clinical testing.

cancer

oncolytic virus

innate immunity

interferon response

viral sensitization

cell signalling

protein phosphatases

neddylation

The Impact of Rubella Virus Infection on a Secondary Inflammatory Response in Polarized Human Macrophages

Schilling, Erik, Grahnert, Anja, Pfeiffer, Lukas, Koehl, Ulrike, Claus, Claudia, Hauschildt, Sunna

24 March 2023

Macrophages (MF) are known to exhibit distinct responses to viral and bacterial infection, but how they react when exposed to the pathogens in succession is less well understood. Accordingly, we determined the effect of a rubella virus (RV)-induced infection followed by an LPS-induced challenge on cytokine production, signal transduction and metabolic pathways in human GM (M1-like)- and M (M2-like)-MF. We found that infection of both subsets with RV resulted in a low TNF-a and a high interferon (IFN, type I and type III) release whereby M-MF produced far more IFNs than GM-MF. Thus, TNF-a production in contrast to IFN production is not a dominant feature of RV infection in these cells. Upon addition of LPS to RV-infected MF compared to the addition of LPS to the uninfected cells the TNF-a response only slightly increased, whereas the IFN-response of both subtypes was greatly enhanced. The subset specific cytokine expression pattern remained unchanged under these assay conditions. The priming effect of RV was also observed when replacing RV by IFN-b one putative priming stimulus induced by RV. Small amounts of IFN-b were sufficient for phosphorylation of Stat1 and to induce IFN-production in response to LPS. Analysis of signal transduction pathways activated by successive exposure of MF to RV and LPS revealed an increased phosphorylation of NFkB (MMF), but different to uninfected MF a reduced phosphorylation of ERK1/2 (both subtypes). Furthermore, metabolic pathways were affected; the LPS-induced increase in glycolysis was dampened in both subtypes after RV infection. In conclusion, we show that RV infection and exogenously added IFN-b can prime MF to produce high amounts of IFNs in response to LPS and that changes in glycolysis and signal transduction are associated with the priming effect. These findings will help to understand to what extent MF defense to viral infection is modulated by a following exposure to a bacterial infection.

info:eu-repo/classification/ddc/610

ddc:610

Expression and Function of ART2.1 ecto-ADP-ribosyltransferase in Inflammatory Effector Cells

Hong, Shiyuan

13 October 2009

No description available.

Cellular Biology

Organotypic brain explants reveal an interleukin-12 / interferon-γ / T-cell dependent clearance of measles virus infection

Stubblefield Park, Samantha Renee

January 2011

No description available.

Virology

viral immunology

measles virus

T cell, interferon-&947

antiviral

CNS

Exploration of Pro- and Anti-inflammatory Effector Functions of Plasmacytoid Dendritic Cells in Systemic Lupus Erythematosus

Davison, Laura Marie

03 September 2015

No description available.

Immunology

systemic lupus erythematosus

plasmacytoid dendritic cells

auto-antibodies

interferon alpha

indoleamine 2,3-dioxygenase