Untersuchung der Infizierbarkeit von Endothelzellen mit Masernviren und des Interferon-induzierten antiviral wirksamen Mechanismus / Investigation of the infection of endothelial cells with measles viruses and the antiviral mechanism induced by interferon

Obojes, Karola

January 2005

Das Masernvirus (MV) gehört zu den negativ-strängigen RNA-Viren der Familie der Paramyxoviridae und verursacht beim Menschen akute und subakute Enzephalitiden. Es wurde beschrieben, dass sich MV-RNA in den Endothelzellen von SSPE (subakute sklerosierende Panenzephalitis)-Gehirnen nachweisen lässt (Cosby & Brankin, 1995). In dieser Arbeit konnte ich eine CD46- und CD150-unabhängige Infektion von Endothelzellen durch Wildtyp-MV nachweisen. Ferner wurde beschrieben, dass das Typ II-Interferon (IFN-g) im Serum von Patienten mit akuten Masern und nach einer Masernimpfung erhöht ist (Okada et al., 2001; Ovsyannikova et al., 2003) und dieses Zytokin lässt sich auch in Gehirnläsionen von SSPE-Patienten detektieren (Nagano et al., 1994). Basierend auf diesen Erkenntnissen, konnte ich eine durch das Enzym Indolamin 2,3-Dioxygenase (IDO) vermittelte antivirale Aktivität von IFN-g gegen MV nachweisen. Endothelzellen (EZ) sind bei der akuten Masernerkrankung oder nachfolgenden Komplikationen, die auf einer persistierenden Infektion basieren, wichtige Zielzellen. CD46 und CD150 (signalling lymphocytic activation molecule, SLAM) wurden als zelluläre Rezeptoren für MV beschrieben (Dörig et al., 1993; Naniche et al., 1993; Tatsuo et al., 2000). Es konnte gezeigt werden, dass humane EZ aus dem Gehirn und aus der Nabelschnurvene (HBMECs und HUVECs) zwar CD46, aber auf RNA- und auf Proteinebene kein SLAM exprimieren. Diese Zellen konnten jedoch mit den Wildtyp-MV, die CD46 nicht als Rezeptor benutzen, infiziert werden. Diese Untersuchungen deuten auf die Präsenz eines zusätzlichen Rezeptors für die Aufnahme und Verbreitung von MV in humanen EZ hin. Der antivirale Effekt von Interferonen spielt bei der MV-Vermehrung eine entscheidende Rolle und variiert jedoch in Abhängigkeit von der Wirtszelle (Schnorr et al., 1993). Im Gegensatz zu den attenuierten MV-Impfstämmen können Wildtyp-MV den antiviralen Effekt von Typ I-IFN blockieren, indem sie die Induktion von IFNa/b hemmen und die Sensivität gegenüber dem antiviralen Effekt vermindern. Dabei spielen die V- und C-Proteine des MV eine Rolle (Naniche et al., 2000; Patterson et al., 2000; Shaffer et al., 2003), die mit zellulären STAT-Proteinen und IRF-9 interagieren (Palosaari et al., 2003; Takeuchi et al., 2003; Yokota et al., 2003). In dieser Arbeit konnte gezeigt werden, dass IFN-g die Replikation aller MV-Stämme vorwiegend in Endo- und Epithelzellen hemmen kann und, dass diese durch IFN-g induzierte, antivirale Aktivität mit der Induktion der Indolamin 2,3-Dioxygenase (IDO) korreliert. IDO ist ein Enzym, welches in Anwesenheit von Sauerstoff den Abbau von Tryptophan zu Kynurenin katalysiert (Hirata et al., 1975) und hauptsächlich antiparasitäre, antibakterielle und antivirale (Bodaghi et al., 1999; Adams et al., 2004) Effekte vermittelt. Im Zusammenhang mit Masern wurde beschrieben, dass die Tryptophan Katabolite in SSPE-Patienten erhöht sind (Kurup & Kurup, 2002). Die Daten in dieser Arbeit zeigen, dass die durch IFN-g-induzierte antivirale Aktivität durch Zugabe von L-Tryptophan nahezu aufgehoben werden kann und daher IDO im Zuge der anti-MV Aktivität eine entscheidende Rolle spielt. / Measles virus (MV) belongs to the negative-stranded RNA-viruses of the family Paramyxoviridae and causes acute and subacute encephalitis in humans. It has been described that MV-RNA can be detected in endothelial cells of SSPE (subacute sclerosing panencephalitis)-brains (Cosby & Brankin, 1995). In this work I could show a CD46- and CD150-independent endothelial cell infection with wild-type measles viruses. Furthermore it has been described that after acute infections and vaccinations, the type II-interferon (IFN-g) concentrations are increased (Okada et al., 2001; Ovsyannikova et al., 2003) and this cytokine can also be detected in brain lesions of patients suffering from SSPE (Nagano et al., 1994). Based upon this findings I could detect an indoleamine 2,3-dioxygenase (IDO) mediated anti-MV activity of gamma interferon. Endothelial cells (ECs) are important target cells during acute measles and complications following the infection. CD46 and CD150 (signalling lymphocytic activation molecule, SLAM) have been described as cellular receptors for MV (Dörig et al., 1993; Naniche et al., 1993; Tatsuo et al., 2000). It has been shown that human ECs from brain and umbilical vein (HBMECs and HUVECs) were CD46-positive, but did not express SLAM neither at RNA- nor at protein level. However, these cells could be infected with the wild-type MV strains, which do not use CD46 as a receptor. These findings suggest the presence of an additional receptor for MV uptake and spread in human ECs. The antiviral effect of interferons plays an important role for the MV-replication. However, this effect depends from the host cell (Schnorr et al., 1993). Attenuated MV strains are more sensitive to type I-interferons than wild-type strains, because wild-type strains can block the induction of IFN-a/b. The V- and C-proteins of MV play a role in this process (Naniche et al., 2000; Patterson et al., 2000; Shaffer et al., 2003). They interact with STAT proteins and IRF-9 (Palosaari et al., 2003; Takeuchi et al., 2003; Yokota et al., 2003). In this work it could be shown, that IFN-g can inhibit the replication of all MV strains preferably in endo- and epithelial cells. Furthermore it could be demonstrated that the antiviral activity induced by IFN-g correlates with the induction of indoleamine 2,3-dioxygenase (IDO). IDO is an enzyme which in the presence of oxygen catalyses the degradation of tryptophan (Hirata et al., 1975) and is known to mediate antiparasitic as well as antibacterial and antiviral effects (Bodaghi et al., 1999; Adams et al., 2004). In the context with measles it has been described that the tryptophan catabolites were increased in SSPE-patients (Kurup & Kurup, 2002). The data in this work show that the IFN-g-induced antiviral activity can be overcome by the addition of L-tryptophan which indicates a decisive role of IDO in the anti-MV activity.

Masernvirus

Endothelzelle

Interferon

ddc:570

microRNA-221 und ihr Einfluss auf Zytokin-vermittelte Signalwege im Hochrisiko-Karzinom der Prostata / microRNA-221 and its influence on cytokine-mediated signaling pathways in high-risk prostate cancer

Krebs, Markus Karl Ludwig

January 2016

Der klinische Verlauf von Prostatakarzinom(PCa)-Erkrankungen ist extrem unterschiedlich und lässt sich mit den bisher üblichen Verfahren wie der feingeweblichen Beurteilung der Prostatastanzbiopsie bzw. des OP-Präparates und der PSA-Wert-Bestimmung nur unzureichend vorhersagen. Für eine bessere Versorgung von PCa-Patienten sind deshalb neuartige Marker notwendig, die das individuelle Progressions-Risiko bestimmen. Ein hoffnungsvoller Ansatz sind miRNA-Vertreter als Prognose-Parameter. Besonders interessant in dieser Hinsicht ist miR-221, die im PCa-Gewebe signifikant niedriger exprimiert wird. Jedoch existieren für diese in den meisten Neoplasien als Onkogen betrachtete miRNA kaum Erklärungsansätze für eine tumorsuppressive Funktion im PCa. Die vorliegende Arbeit konnte mit Hilfe von Microarray-basierten Expressionsanalysen und deren bioinformatischer Auswertung sowie zell- und molekularbiologischen Experimenten erstmals zeigen, dass miR-221 das protektive Interferon-Signal in PCa-Zellen stärkt und auf diese Weise deren Proliferation hemmt. Daneben konnten zwei prominente Inhibitoren dieses Signals, IRF2 und SOCS3, als neue Zielgene von miR-221 in vitro nachgewiesen und eine Korrelation von miR-221 mit diesen Zielgenen auch in PCa-Nativmaterial identifiziert werden. Somit konnte erstmals ein Mechanismus der – vorher lediglich aufgrund der Herabregulation in PCa-Nativmaterial postulierten – tumorsuppressiven Funktion von miR-221 im Rahmen der PCa-Entstehung und -Progression dargestellt werden. Eine Aktivierung des JAK / STAT-vermittelten Interferon-Signals durch miR-221 erscheint auch in einem breiteren infektiologischen Kontext interessant – sind doch zahlreiche Virenarten wie das HI-Virus, Hepatitis- und Herpesviren in der Lage, die zelluläre miR-221-Expression zu vermindern und auf diese Weise wohl das antivirale Interferon-Signal zu umgehen. Die Erhöhung der zellulären miR-221-Spiegel könnte nach diesem Prinzip auch Interferon-basierte Therapie-Strategien unterstützen bzw. erst ermöglichen. Für das PCa müssen weitere experimentelle sowie klinisch-translationale Untersuchungen zeigen, ob miR-221 als Bestandteil einer Biomarker-Signatur dazu beiträgt, Patienten mit einem letalen PCa frühzeitig zu identifizieren und der dringend notwendigen Primärtherapie bzw. einer adjuvanten Behandlung zuzuführen. Im Gegenzug könnte zahlreichen Patienten, deren (hohe) miR-221-Expression im Tumorgewebe einen günstigeren Verlauf prognostiziert, die übermäßige Therapie erspart werden. / The clinical course of prostate cancer (PCa) is extremely heterogeneous and cannot be predicted sufficiently with usual procedures such as histological examination of prostate biopsies and surgical specimen or determination of PSA values. For a better treatment of PCa patients, novel markers are necessary which predict individual progression risk. MicroRNAs are promising biomarker candidates and miR-221 – which is significantly downregulated in prostate cancer tissue – seems especially interesting. However, as this specific microRNA plays an oncogenic role in various malignancies, no potential tumor suppressive functions are known. By using Microarray-based gene expression analysis, bioinformatical algorithms, cell culture and molecular biology techniques, this thesis could show that miR-221 strengthens interferon signaling in PCa cells thereby serving as a tumor suppressor. Moreover, two prominent inhibitors of this signal, IRF2 and SOCS3, were introduced as new miR-221 target genes in vitro and a negative correlation of these targets and miR-221 was shown for PCa specimen. Altogether, this is the first miR-221-mediated mechanism fitting in with the previously postulated tumor suppressor role of miR-221 in PCa. An activation of JAK / STAT-mediated interferon signaling by miR-221 also seems interesting from an infectious diseases perspective. Several viruses like HIV and members of the Hepatitis and Herpes family are able to lower the cellular miR-221 expression, thereby possibly weakening the antiviral interferon signal. For PCa, further experimental as well as clinical-translational approaches have to determine whether miR-221 could be a part of a clinically relevant biomarker signature. This could help to identify and subsequently treat patients with a high-risk PCa, whereas many patients – with a prognostically favorable high miR-221 expression in tumor tissue – could be spared an overtreatment.

miRNS

Prostatakrebs

Interferon

ddc:611

Regulation of Hydrogen Peroxide in the Human Airway

Forteza, Radia

05 December 2008

In airway epithelia, lactoperoxidase (LPO) constitutes an important anti-microbial system to protect the host against infection and inflammation. LPO uses hydrogen peroxide and thiocyanate anion to form the biocidal compound, hypothiocyanite. The rate-limiting factor is hydrogen peroxide substrate availability. This study was conducted to identify the major source of hydrogen peroxide and to characterize its regulation in the human airway. Two homologues of the phagocytic NADPH oxidase, Duox1 and Duox2, were shown to be highly expressed and functional in human airway epithelial cells re-differentiated at the air liquid interface (ALI). Duox activity is regulated by intracellular calcium concentration via its two EF-hand motifs. A rise of intracellular calcium concentration exhibited kinetics that correlated with increase of Duox-generated hydrogen peroxide production, which was inhibited by DPI, a NADPH oxidase inhibitor. Additionally, the involvement of Duox activity in the LPO system was investigated. Bacterial products such as flagellin or inflammatory mediators were used to challenge ALI cultures. As a result, mRNAs from Duox2, LPO and DUOXA2, but not Duox1, were up-regulated in response to stimuli. This study provided new information about the regulation of the anti-microbial LPO system in innate immune host defense.

Characterizing Plasmacytoid Dendritic Cell Activation in the Context of HIV Stimulation

Lo, Calvin Chun Chung

10 January 2011

Plasmacytoid dendritic cells (pDCs) are important in innate and adaptive immune responses against viral infections, producing remarkable levels of type I interferon as well as other immunomodulatory cytokines. In vitro, pDCs can control replication of human immunodeficiency virus (HIV). Following natural challenge with simian immunodeficiency virus (SIV), PDCs infiltrate the vaginal mucosa. Despite this, pDCs are unable to prevent systemic dissemination of virus. To understand pDC activation immediately following HIV exposure, cytokine production and maturation of pDCs in response to HIV and a variety of other stimuli was compared. PDCs were found to respond suboptimally to HIV compared to other stimuli, with delayed interferon-alpha production, delayed maturation, and decreased production of inflammatory cytokines. Furthermore, HIV induced inhibitory signaling pathways in pDCs, suggesting subversion of the pDC response by HIV. Finally, different stimuli induced different early and late cytokine profiles, highlighting the complex and stimuli-dependant nature of the pDC response.

HIV

pDC

Interferon

Cytokine

0982

Characterizing Plasmacytoid Dendritic Cell Activation in the Context of HIV Stimulation

Lo, Calvin Chun Chung

10 January 2011

Plasmacytoid dendritic cells (pDCs) are important in innate and adaptive immune responses against viral infections, producing remarkable levels of type I interferon as well as other immunomodulatory cytokines. In vitro, pDCs can control replication of human immunodeficiency virus (HIV). Following natural challenge with simian immunodeficiency virus (SIV), PDCs infiltrate the vaginal mucosa. Despite this, pDCs are unable to prevent systemic dissemination of virus. To understand pDC activation immediately following HIV exposure, cytokine production and maturation of pDCs in response to HIV and a variety of other stimuli was compared. PDCs were found to respond suboptimally to HIV compared to other stimuli, with delayed interferon-alpha production, delayed maturation, and decreased production of inflammatory cytokines. Furthermore, HIV induced inhibitory signaling pathways in pDCs, suggesting subversion of the pDC response by HIV. Finally, different stimuli induced different early and late cytokine profiles, highlighting the complex and stimuli-dependant nature of the pDC response.

HIV

pDC

Interferon

Cytokine

0982

Identification of novel implantation-related genes in the ovine uterus

Song, Gwon Hwa

17 September 2007

The peri-implantation period in mammals is critical with respect to survival of the conceptus and establishment of pregnancy. During this period of pregnancy, reciprocal communication between ovary, conceptus, and endometrium is required for successful implantation and placentation. Therefore, studies were conducted to indentify and characterize novel endometrial genes important for implantation and conceptus development in the ovine uterus. The first and second studies defined the uterine expression of seven members of the cathepsin (CTS) family of lysosomal proteases, and a secreted inhibitor of CTSL called cystatin C (CST3) during the peri-implantation period. In addition, regulation of CTS and CST3 by progesterone (P4) and interferon tau (IFNT) was evaluated. CTSL was the most abundant CTS in the ovine ovine uterus and was also coordinately expressed with CST3 in the endometrial epithelia and conceptus trophectoderm. CTSL and CST3 were found to be novel P4-induced and IFNT-stimulated genes in the luminal epithelial cells of the ovine endometrium. The third study identified radical S-adenosyl methionine domain containing 2 (RSAD2) and interferon-induced with helicase C domain 1 (IFIH1) in the ovine uterus. Results of this study indicated that IFNT induces RSAD2 and IFIH1 in a P4-independent manner in the stroma, immune cells, and glands of the ovine endometrium. These two genes are proposed to have biological roles in the establishment of uterine receptivity to the conceptus during implantation. The fourth study characterized endometrial expression of stanniocalcins (STC) during pregnancy. STC1 appeared in the endometrial glands on Day 18 of pregnancy, increased from Days 18 to 80, and remained abundant through Day 120 of gestation. In addition, this study demonstrated that STC1 is induced by P4 and increased by placental hormones, such as placental lactogen (CSH1) and growth hormone (GH), in the ovine endometrial glands. Collectively, these studies identified genes that are expected to be critical to unraveling the mechanism(s) of reciprocal fetal-maternal interactions required for successful implantation and pregnancy. A more complete understanding of these genes will be important for developing therapeutic strategies to prevent, treat and/or diagnose infertility in domestic animals and humans, because they are biomarkers of P4 and/or IFN effects.

uterus

implantation

progesterone

interferon tau

The effects of a synthetic inducer of interferon (polyriboinosinic acid-polyribocytidylic acid) on a synergistic combination of influenza virus and Diplococcus pneumoniae in mice

Miller, Robert Donald, 1945-

January 1972

No description available.

Interferon.

Influenza -- Research.

Immunology -- Research.

Investigating the Role of Cytokines in Immunity to Marek's Disease

Haq, Kamran

14 May 2012

Marek’s disease (MD) is a lymphoproliferative disease of chickens caused by an oncogenic herpesvirus, Marek’s disease virus (MDV). Despite the availability of MD vaccines, little is known about the underlying immunological mechanisms that mediate vaccine-induced immunity. The objective of this research was to elucidate these mechanisms. To characterize host responses in the lungs, chickens were vaccinated with herpesvirus of turkeys (HVT) and infected with MDV-RB1B. Vaccinated MDV-infected chickens had a higher accumulation of viral genome in the lungs, associated with T cell infiltration in lung tissue and an up-regulation of interferon (IFN) - and interleukin (IL) -10. This finding led us to conclude that IFN-γ has a role in immunity; hence, we further investigated the role of this cytokine. The hypothesis tested was that the protective efficacy of HVT against MDV-RB1B would be enhanced when combined with recombinant chicken IFN-γ (rChIFN-). Chicken IFN-γ coding sequence was cloned into an expression plasmid, and the bioactivity of rChIFN- was confirmed. Administration of this plasmid led to a significant reduction in tumour occurrence in HVT vaccinated MDV-infected chickens, suggesting enhanced vaccine-induced immunity. To shed more light on the relevance of IFN-γ to immunity against MD, studies were designed to down-regulate the expression of IFN-γ in chicken tissues. Three small interfering (si)RNAs specific for chicken IFN- were selected which significantly inhibited expression of IFN-γ by up to 80% in cultured cells. These three siRNAs and a non-target control were cloned and expressed as short hairpin RNA (shRNA) using an avian adeno-associated virus (rAAAV) vector system. An MDV challenge trial was conducted once shRNA expression by the rAAAV was confirmed in vitro. It was reasoned that down-regulation of IFN- would lead to abrogation of immunity conferred by HVT. There was an increase in the number of chickens with tumours that received HVT and rAAAV + IFN-γ shRNA compared to the control group, though not statistically significant. However, no difference in MDV genome load in feathers was detected between vaccinated MDV-infected birds with or without rAAAV. In summary, we have demonstrated here that cytokines are induced in the course of vaccination against Marek’s disease and that IFN-γ plays a role in vaccine-induced immunity against MD.

Development and application of a vaccinia virus based system to study viral proteins modulating interferon expression and interferon induced antiviral activities

Arsenio, Janilyn

07 1900

The interferon (IFN) system is integral to antiviral innate immunity in vertebrate hosts. Inside a cell, viral pathogen associated molecular patterns (PAMPs) trigger the IFN response, comprised of IFN induction and an IFN-induced antiviral state. However, viruses have evolved strategies to counteract the IFN system. The E3 protein of vaccinia virus (VV), encoded by the E3L gene, impedes cytokine expression and suppresses the activation and function of antiviral proteins. Deletion of the E3L gene (VVΔE3L) produces an IFN sensitive mutant virus that is replication defective in most human cell lines. Due to the limited human cell lines available to support VVΔE3L replication, the capacity of E3 inhibition of human IFN-induced antiviral activities is not well defined. In this study, VVΔE3L was generated and characterized to facilitate the study of other viral IFN antagonists at modulating human IFN-induced antiviral responses. A human liver carcinoma cell line, Huh7, was found to support VVΔE3L replication. A comprehensive analysis of VVΔE3L IFN sensitivity revealed E3 inhibits all human type I and type II IFN-induced antiviral activities by modulation of the protein kinase R (PKR) pathway. Influenza non-structural protein 1 (NS1) is well-known to mediate the suppression of IFN induction and IFN action in influenza virus infections. However, the IFN antagonizing potential of influenza NS1 may be virus subtype and/or isolate specific. VVΔE3L was next applied as an expression vector to study influenza NS1 function in modulating IFN-induced antiviral activities and IFN induction in human cells. Recombinant viruses were generated to express influenza NS1 (from avian H5N1 and pandemic viruses 1918 pH1N1, 1968 pH3N2, and 2009 pH1N1) in replacement of E3. It was found that influenza NS1 inhibits human IFN-induced antiviral activity in a subtype and isolate specific manner. Moreover, influenza NS1 differentially regulates human IFN expression in a virus isolate-dependent manner. Altogether, this work highlights the potential of VVΔE3L as an excellent virus model system to study viral proteins modulating IFN expression and IFN-induced antiviral activities in human cells.

interferon

vaccinia

E3

influenza

NS1

Development and application of a vaccinia virus based system to study viral proteins modulating interferon expression and interferon induced antiviral activities

Arsenio, Janilyn

07 1900

The interferon (IFN) system is integral to antiviral innate immunity in vertebrate hosts. Inside a cell, viral pathogen associated molecular patterns (PAMPs) trigger the IFN response, comprised of IFN induction and an IFN-induced antiviral state. However, viruses have evolved strategies to counteract the IFN system. The E3 protein of vaccinia virus (VV), encoded by the E3L gene, impedes cytokine expression and suppresses the activation and function of antiviral proteins. Deletion of the E3L gene (VVΔE3L) produces an IFN sensitive mutant virus that is replication defective in most human cell lines. Due to the limited human cell lines available to support VVΔE3L replication, the capacity of E3 inhibition of human IFN-induced antiviral activities is not well defined. In this study, VVΔE3L was generated and characterized to facilitate the study of other viral IFN antagonists at modulating human IFN-induced antiviral responses. A human liver carcinoma cell line, Huh7, was found to support VVΔE3L replication. A comprehensive analysis of VVΔE3L IFN sensitivity revealed E3 inhibits all human type I and type II IFN-induced antiviral activities by modulation of the protein kinase R (PKR) pathway. Influenza non-structural protein 1 (NS1) is well-known to mediate the suppression of IFN induction and IFN action in influenza virus infections. However, the IFN antagonizing potential of influenza NS1 may be virus subtype and/or isolate specific. VVΔE3L was next applied as an expression vector to study influenza NS1 function in modulating IFN-induced antiviral activities and IFN induction in human cells. Recombinant viruses were generated to express influenza NS1 (from avian H5N1 and pandemic viruses 1918 pH1N1, 1968 pH3N2, and 2009 pH1N1) in replacement of E3. It was found that influenza NS1 inhibits human IFN-induced antiviral activity in a subtype and isolate specific manner. Moreover, influenza NS1 differentially regulates human IFN expression in a virus isolate-dependent manner. Altogether, this work highlights the potential of VVΔE3L as an excellent virus model system to study viral proteins modulating IFN expression and IFN-induced antiviral activities in human cells.

interferon

vaccinia

E3

influenza

NS1