Struktur-Funktionsanalyse des Immediate-Early Proteins 2 (IE2) des humanen Zytomegalievirus

Asmar, Jasmin

17 January 2005

Das Immediate-Early Protein 2 (IE2) des humanen Zytomegalievirus ist ein essentieller Regulationsfaktor des lytischen Infektionszyklus. Es aktiviert verschiedene early Promotoren, autoreprimiert seine eigene Expression und besitzt darüber hinaus auch zellzyklusregulatorische Aktivitäten. Um einzelne Funktionen des IE2 Proteins gezielt analysieren zu können, ist eine genaue Kenntnis seiner regulatorischen Domänen unabdingbar. Im Rahmen dieser Arbeit wurde daher eine Struktur-Funktionsanalyse des IE2 Proteins durchgeführt mit dem Ziel, seine funktionellen Domänen genauer zu charakterisieren. Hierfür wurden verschiedene IE2-Mutanten hergestellt und ihre Aktivität im Hinblick auf Transaktivierung, Autorepression und DNA-Bindung sowie Zellzylusarrestinduktion bestimmt. Die Untersuchungen ergaben, dass innerhalb einer Core-Region im C-Terminus des Proteins (AS 450-544) die regulatorischen Domänen der untersuchten Funktionen überlappen und hier schon kleinere Mutationen zu einem Funktionsverlust führen. Im Gegensatz dazu ist der Bereich N-terminal des Core deutlich weniger sensitiv gegenüber Mutationen. Hier konnten Sequenzen identifiziert werden, die spezifisch für einzelne Funktionen wie die Transaktivierung oder die Zellzyklusarrestinduktion erforderlich sind. Darüber hinaus hat sich gezeigt, dass eine im bisherigen Verständnis essentielle putative Zinkfingerdomäne außerhalb des Core liegt und für die Funktionalität des Proteins, vor allem für seine DNA-Bindung, nicht benötigt wird. Somit ist der Bereich, in dem die regulatorischen Domänen der untersuchten Funktionen überlappen, deutlich kleiner, als bisher angenommen. Vor diesem Hintergrund lässt sich eine Strategie für die Erstellung von diskriminierenden Virusmutanten ableiten, bei der Einzelfunktionen von IE2 im Viruskontext eliminiert und somit im Sinne ihrer physiologischen Relevanz analysierbar werden. / The Immediate Early Protein 2 (IE2) of human cytomegalovirus is an essential regulatory factor of the viral replicative cycle. It fulfills several functions including transactivation, negative autoregulation and cell cycle regulation. In order to analyse the physiological significance of each of the IE2 functions a precise knowledge of the regulatory protein domains is needed. Therefore, a structure-function analysis of the IE2 protein was performed in this work. Different sets of IE2 mutants were tested in parallel with regard to transactivation, DNA-binding, autoregulation and cell cycle regulation. We found the IE2 protein to contain an unexpectedly clear-cut core domain (amino acids (aa) 450-544) that is defined by its absolute sensitivity to any kind of mutation. In contrast, the region adjacent to the core (aa 290-449) generally displays greater tolerance towards mutations. Although specific sequences correlate with distinct IE2 activities none of the mutations analysed completely abolished any particular function. The core is separated from the adjacent region by the putative zinc finger (428-452) which was found to be entirely dispensable for any function tested. Our work supports the view that the 100 amino acids of the core domain hold the key to most functions of IE2. A systematic, high-density mutational analysis of this region may identify informative mutants which discriminate between various IE2 functions. Such mutants could then be tested in a viral background.

Zellzyklus

humanes Zytomegalievirus

Immediate-Early Protein 2 (IE2)

DNA-Bindung

cell cycle

human cytomegalovirus

immediate-early-protein 2 (IE2)

dna-binding

570 Biowissenschaften, Biologie

32 Biologie

WF 4250

ddc:570

Innate response to human cytomegalovirus and the role of infections in the pathogenesis of atherosclerosis

Romo Saladrigas, Neus

21 December 2011

We comparatively analyzed the natural killer (NK) cell response against HCMV-infected pro-inflammatory (M1) and anti-inflammatory (M2) M[Fi] derived from autologous monocytes. M1 M[Fi] were more resistant to infection, secreting TNF-[alfa], IL-6, IL-12 and type I IFN. By contrast, in HCMV-infected M2 M[Fi] the production of proinflammatory cytokines, type I IFN and IL-10 was limited, and IL-12 undetectable. NK cell degranulation was triggered by interaction with HCMV-infected M1 and M2 M[Fi] and was partially inhibited by specific anti-NKp46, anti-DNAM-1 and anti-2B4 mAbs, thus supporting a dominant role of these activating receptors. By contrast, only HCMV-infected M1 M[Fi] efficiently promoted NK cell-mediated IFN-[gamma] secretion, an effect partially related to IL-12 production. These observations reveal differences in the NK cell response triggered by distinct HCMV-infected monocyte-derived cell types, which may be relevant in the pathogenesis of this viral infection. HCMV infection has been proposed to contribute to the development of atherosclerosis, a chronic inflammatory process in which M[Fi] play a key role. The contribution of HCMV to vascular disease may depend on features of the immune response not reflected by the detection of specific antibodies. Persistent HCMV infection in healthy blood donors has been associated with changes in the distribution of NK cell receptors (NKR). The putative relationship among HCMV infection, NKR distribution, subclinical atherosclerosis and coronary heart disease was assessed. An association of overt and subclinical atherosclerotic disease with LILRB1+ NK and T cells was observed, likely reflecting a relationship between the immune challenge by infections and cardiovascular disease risk, without attributing a dominant role for HCMV. / Hem analitzat la resposta de la cèl•lula NK als macròfags proinflamatoris (M1) i antiinflamatoris (M2) derivats de monòcits autòlegs infectats pel citomegalovirus humà (HCMV). Els macròfags M1 son més reistents a la infecció i secreten TNF-[alfa], IL-6, IL-12 i IFN de tipus I. Per altra banda, en els macròfags M2 infectats per HCMV la producció de citoquines proinflamatories, IFN de tipus I i IL-10 es limitada i la IL-12 indetectable. La cèl•lula NK degranula al interaccionar amb els macròfags M1 i M2 infectats. Aquesta degranulació s’inhibeix parcialment al bloquejar amb anticossos específics anti-NKp46, anti-DNAM-1 i anti-2B4, això indica que aquests receptors tenen un rol important en el procés. En canvi, només els macròfags M1 infectats amb HCMV promouen de manera eficient la producció d’IFN-[gamma] per part de la cèl•lula NK, degut parcialment a la producció de IL-12. Aquestes observacions posen de manifest diferències en la resposta de la cèl•lula NK a diferents tipus de macròfags infectats per HCMV que pot ser relevant en la patogènesis d’aquesta infecció viral. S’ha proposat que la infecció per HCMV contribueix al desenvolupament de l’aterosclerosis, un procés inflamatori crònic en el que els macròfags tenen un paper clau. La contribució del HCMV a la malaltia cardiovascular pot dependre de la resposta immune. La infecció per HCMV en donants de sang sans s’ha associat a canvis en la distribució dels receptors de les cèl•lules NK. S’ha evaluat la possible relació entre la infecció per HCMV, la distribució dels receptors de les cèl•lules NK i l’infart agut de miocardi. S’ha observat una associació de l’infart agut de miocardi i l’aterosclerosi subclínica tant amb les cèl•lules NK LILRB1+ com amb les cèl•lules T LILRB1+. Això possiblement reflexa la relació entre la pressió que les infeccions exerceixen en el sistema immunitari i el risc cardiovascular sense atribuir un paper principal al HCMV.

Atherosclerosis

NK cell

Macrophage

Human cytomegalovirus

Infection

T lymphocyte

NK cell receptor

LILRB1 receptor

Aterosclerosi

Cèl•lula NK

Macròfag

Citomegalovirus humà

Infecció

Limfòcit T

Receptor de cèl•lula NK

575

Nový chimérický antigenní receptor (CAR) pro terapii infekce lidským cytomegalovirem (HCMV) / New chimeric antigen receptor (CAR) for therapy of human cytomegalovirus (HCMV) infection

Kroutilová, Marie

January 2018

Human cytomegalovirus (HCMV, Herpesviridae) can cause severe complications in the infected individuals undergoing hematopoietic stem cell transplantation. Nowadays, these patients are treated using antivirotics or HCMV-specific T cells derived from the seropositive graft donor. This study explored the possibility of redirecting HCMV-non-specific T cells from a seronegative donor towards HCMV-infected cells via chimeric antigen receptor (CAR), i.e. artificially designed T cell receptor. Viral glycoprotein B (gB) has been selected as a target for this receptor. Published sequence of a single chain variable fragment of a human antibody was used for the design of the CAR against gB (gBCAR). After the verification of production and surface localization in cell lines, gBCAR was being introduced into human T cells via lentiviral vectors. Human fetal lung fibroblasts (LEP) infected with HCMV were used as target cells after the expression of gB at their surface was demonstrated. gBCAR functionality was evaluated by the incubation of modified T cells with infected cells and subsequent analysis of media for IFNγ concentration, which was significantly higher in the setting of gBCAR T cells incubated with HCMV-LEP than in the control incubations. The results obtained show the specificity of gBCAR against...

Investigating the role of human cytomegalovirus protein LUNA in regulating viral gene expression during latency

Lau, Jonathan

January 2018

Human cytomegalovirus (HCMV) is a widespread human herpesvirus pathogen and prototypical member of the β-herpesvirus subfamily. Like all herpesviruses, the virus establishes a lifelong latent infection following host exposure, which has the potential to reactivate periodically and contribute to recurrent disease processes. In individuals with weak or compromised immune systems, such reactivation can lead to profound pathology. Understanding how latent infections are maintained is important for uncovering how HCMV causes disease. The study of viral genes that are expressed during latent infection grants insight into how latency is regulated and how it could be therapeutically targeted. To that end, this project has sought to evaluate the functional significance of one such viral gene termed LUNA in the context of latency. In models of experimental latent infection based on primary myeloid cells, levels of viral gene transcription were found to be significantly reduced following infection with LUNA deletion mutant viruses, consistent with corresponding observable changes in post-translational histone modifications over the viral promoters of latency-associated genes. Additionally, using luciferase reporter systems, latency-associated viral gene promoters became activated in response to the expression of wild-type LUNA. Together, these findings argue for a role of LUNA in regulating viral gene expression during latent HCMV infection. One possible mechanism by which LUNA may fulfil its role is by targeting cellular ND10 structures, known intrinsic inhibitors of herpesvirus gene expression, for disruption. In support of this, latently infected cells were found to be devoid of ND10, a phenotype that was recapitulated by the direct expression of wild-type LUNA. Furthermore, mutation studies confirmed the identification of a novel deSUMOylase activity encoded by LUNA that was responsible for mediating ND10 disruption. Use of a catalytically inactive LUNA mutant in transcriptional analyses of latent infection also generated similar results as with the LUNA deletion viruses. Overall, these data support the hypothesis that LUNA serves as an important regulator of viral gene expression during latency, which is likely linked to its ability to target ND10 structures for disruption, thus raising the possibility that inhibition of deSUMOylation may serve as a novel therapeutic strategy to target latent HCMV infection.

Regulation des Zellzyklus durch das Maus- und Ratten-Zytomegalievirus

Neuwirth, Anke

29 November 2005

Das humane Zytomegalievirus, ist ein ubiquitäres Pathogen, welches akute und persistierende Infektionen verursacht. Bei immunsupprimierten Patienten kann das Virus zu schweren Erkrankungen, wie Hepatitis, Pneumonie und bei kongenitaler Infektion außerdem zu Schädigungen des ZNS führen. HCMV blockiert die Zellproliferation durch einen Arrest am G1/S-Übergang des Zellzyklus, andererseits wird aber gleichzeitig die Expression S-Phase spezifischer Gene aktiviert. Teilweise lässt sich dies durch eine Virus vermittelte spezifische Inhibition der zellulären DNA-Repliaktion sowie durch eine massive Deregulation Zyklin-assozzierter Kinasen erklären. Zellkulturexperimente deuten darauf hin, dass die Zellzyklusalterationen wichtige Voraussetzungen für eine erfolgreiche Virusreplikation darstellen. Es ist hingegen nicht bekannt, welche Relevanz sie für die Virusvermehrung in vivo und das pathologische Erscheinungsbild im erkrankten Organismus besitzen. Diese Frage kann nur in einem Tiermodell sinnvoll angegangen werden. Aufgrund der Wirtsspezifität der Zytomegalieviren, ist man dabei auf die Verwendung der jeweiligen artspezifischen CMV angewiesen. Murines CMV (MCMV) und Ratten-CMV (RCMV) sind dabei die bislang bestuntersuchtesten Systeme. Das Anliegen dieser Arbeit war es zu prüfen, inwieweit die für HCMV beschriebenen Zellzyklusregulationen in MCMV und RCMV auf Zellkulturbasis konserviert sind. Es konnte gezeigt werden, dass sowohl RCMV als auch MCMV einen antiproliferativen Effekt auf infizierte Zellen besitzen und ebenso wie HCMV zu einem Zellzyklusarrest führen. Nager-Zytomegalieviren können Zellen auch in der G2-Phase arretieren und in dieser Zellzyklusphase auch effizient replizieren können. Die Infektion mit Nager-CMV führt außerdem auf breiter Basis zur Veränderung Zyklin-assoziierter Kinaseaktivitäten. Allen Zytomegalieviren ist die Hemmung der zellulären DNA-Synthese am G1/S-Übergang durch die Inhibition des replication licensing, dem Beginn der DNA-Synthese gemein. Durch diese vergleichende Studie wird einerseits deutlich, dass wesentliche funktionelle Schritte der Zellzyklusregulation zwischen den Zytomegalieviren konserviert sind, aber andererseits die zu Grunde liegenden molekularen Mechanismen zum Teil deutlich variieren. / Human Cytomegalovirus (HCMV) is an ubiquitous, species-specific beta-herpesvirus that, like other herpesviruses, can establish lifelong latency following primary infection. HCMV infection becomes virulent only in immunocompromised patients such as premature infants, transplant recipients and AIDS patients where the virus causes severe disease like hepatitis, pneumonitis and retinitis. Congenital infection produces birth defects, most commonly hearing loss. To develop rational-based strategies for prevention and treatment of HCMV infection, it is crucial to understand the interactions between the virus and its host cell that support the establishment and progression of the virus replicative cycle. In general, herpesviruses are known to replicate most efficiently in the absence of cellular DNA synthesis. What is more, they have evolved mechanisms to avoid the cell´s DNA replication phase by blocking cell cycle progression outside S phase. HCMV has been shown to specifically inhibit the onset of cellular DNA synthesis resulting in cells arrested with a G1 DNA content. Towards a better understanding of CMV-mediated cell cycle alterations in vivo, we tested murine and rat CMV (MCMV/RCMV), being common animal models for CMV infection, for their influence on the host cell cycle. It was found that both MCMV and RCMV exhibit a strong anti-proliferative capacity on immortalised and primary embryonic fibroblasts after lytic infection. This results from specific cell cycle blocks in G1 and G2 as demonstrated by flow cytometry analysis. The G1 arrest is at least in part caused by a specific inhibition of cellular DNA synthesis and involves both the formation and activation of the cells’ DNA replication machinery. Interestingly, and in contrast to HCMV, the replicative cycle of rodent CMVs started from G2 as efficiently as from G1. Whilst the cell cycle arrest is accompanied by a broad induction of cyclin-cdk2 and cyclin-cdk1 activity, cyclin D1-cdk4/6 activity is selectively suppressed in MCMV and RCMV infected cells. Thus, given that both rodent and human CMVs are anti-proliferative and arrest cell cycle progression we found a surprising divergence of some of the underlying mechanisms. Therefore, any question put forward to a rodent CMV model involving cell cycle regulation has to be well defined in order to extrapolate meaningful information for the human system.

Zellzyklus

Herpesvirus

Zytomegalievirus

CMV

Zellproliferation

Deregulation Zyklin-assozzierter Kinasen

G1-Phase-Arres

G2-Phase-Arrest

Murines Zytomegalievirus

MCMV

Ratten-Zytomegalievirus

RCMV

Inhibition des replication licensing

Hemmung der zellulären DNA-Synthese

cell cycle

HCMV

Human Cytomegalovirus

murine CMV

MCMV

rat CMV

RCMV

avoid the cell´s DNA replication

G1 arrest

G2 arrest

inhibition of cellular DNA synthesis

cyclin-dependent-kinase

610 Medizin

33 Medizin

XD 7404

XD 7421

YD 7404

YD 7421

ddc:610