Institut für Virologie und Immunbiologie
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Das Masernvirus (MV) kann in Erkrankten eine schwere, langanhaltende Immunsuppression verursachen, wodurch Infektionen mit opportunistischen Pathogenen begünstigt werden. Diese basiert auf einer Paralyse der hämatopoetischen Zellen, welche das Virus durch Kontakt eines viralen Glykoproteinkomplexes zu einem unbekannten RezeptorX auf der Zell- Oberfläche induzieren kann. Kerncharakterisitika hiervon sind unter anderem die Herabregulation der Akt-Kinase-Phosphorylierung, die Inhibition der zellulären Proliferation und die Aktivierung der neutralen Sphingomyelinase 2 (NSM2).
In einem kinetischen Phosphoproteom konnten zwei potentielle Interaktionsrezeptoren des MV identifiziert werden: CD43 und P2X3. Das hochglykosylierte Oberflächenmolekül CD43 ist auf hämatopoetischen Zellen ubiquitär exprimiert und reguliert in T-Zellen deren Überleben, Proliferation, Aktivierung, Migration und Adhäsion. P2X3 wird in hämatopoetischen Zellen nur in geringem Maße exprimiert. Seine funktionelle Bedeutung ist in diesem Kompartiment nicht bekannt. Beide Kandidaten wurden mittels CRISPR/Cas9 Verfahren einzeln oder kombiniert aus Jurkat-T-Zellen ablatiert, welche nachfolgend nach MV-Kontakt hinsichtlich der oben erwähnten MV-modulierten Parameter getestet wurden. Zusätzlich wurden iso- und allosterische P2X3-Inhibitoren an primären und Jurkat-T-Zellen verwendet, um dessen Rolle in Ca2+-Mobilisierung und Proliferation nach T-Zell-Rezeptor Co-Stimulation zu analysieren.
Die genetische Depletion beider Rezeptor-Kandidaten verringerte die Effekte des MV auf alle getesteten Parameter signifikant, was darauf hindeutet, dass beide Proteine entscheidend an der T-Zell-Suppression beteiligt sind. Während die isosterische Inhibition von P2X3 keinen Effekt hatte, wurde die Proliferation primärer T-Zellen durch dessen allosterische Inhibition vor Co-Stimulation fast verdoppelt und die Effizienz der Ca2+-Mobilisierung in Jurkat- und primären T-Zellen signifikant erhöht. In P2X3-depletierten Jurkat-Zellen hingegen war die Ca2+-Mobilisierung nach Stimulation signifikant geringer als in WT-Zellen.
In dieser Arbeit konnten zwei wichtige Mediatoren der MV induzierten T-Zell-Suppression identifiziert werden. Vor allem P2X3, dessen Expression, Regulation und funktionelle Bedeutung im hämatopoetischen Kompartiment noch nicht erforscht wurde, könnte ein vielversprechender Kandidat für eine antivirale Therapie darstellen, da ein klinisch getesteter P2X3-Inhibitor bereits verfügbar ist.
Gene expression in eukaryotic cells is regulated by the combinatorial action of numerous gene-regulatory factors, among which microRNAs (miRNAs) play a fundamental role at the post-transcriptional level. miRNAs are single-stranded, small non-coding RNA molecules that emerge in a cascade-like fashion via the generation of primary and precursor miRNAs. Mature miRNAs become functional when incorporated into the RNA induced silencing complex (RISC). miRNAs guide RISCs to target mRNAs in a sequence-specific fashion. To this end, base-pairs are usually formed between the miRNA seed region, spanning nucleotide positions 2 to 8 (from the 5' end) and the 3'UTR of the target mRNA. Once miRNA-mRNA interaction is established, RISC represses translation and occasionally induces direct or indirect target mRNA degradation. Interestingly, miRNAs are expressed not only in every multicellular organism but are also encoded by several viruses, predominately by herpesviruses. By controlling both, cellular as well as viral mRNA transcripts, virus-encoded miRNAs confer many beneficial effects on viral growth and persistence. Murine cytomegalovirus (MCMV) is a ß-herpesvirus and so far, 29 mature MCMV-encoded miRNAs have been identified during lytic infection. Computational analysis of previously conducted photoactivated ribonucleotide-enhanced individual nucleotide resolution crosslinking immunoprecipitation (PAR-iCLIP) experiments identified a read cluster within the 3' untranslated region (3'UTR) of the immediate early 3 (IE3) transcript in MCMV. Based on miRNA target predictions, two highly abundant MCMV miRNAs, namely miR-m01-2-3p and miR-M23-2-3p were found to potentially bind to two closely positioned target sites within the IE3 PAR-iCLIP peak. To confirm this hypothesis, we performed luciferase assays and showed that activity values of a luciferase fused with the 3'UTR of IE3 were downregulated in the presence of miR-m01- 2 and miR-M23-2. In a second step, we investigated the effect of pre-expression of miR-m01-2 and miR-M23-2 on the induction of virus replication. After optimizing the transfection procedure by comparing different reagents and conditions, plaque formation was monitored. We could demonstrate that the replication cycle of the wild-type but not of our MCMV mutant that harbored point mutations in both miRNA binding sites within the IE3-3'UTR, was significantly delayed in the presence of miR-m01-2 and miR-M23-2. This confirmed that miR-m01-2 and miR-M23-2 functionally target the major transcription factor IE3 which acts as an indispensable regulator of viral gene expression during MCMV lytic infection. Repression of the major immediate early genes by viral miRNAs is a conserved feature of cytomegaloviruses. The functional role of this type of regulation can now be studied in the MCMV mouse model.
MDSCs are suppressive immune cells with a high relevance in various pathologies including cancer, autoimmunity, and chronic infections. Surface marker expression of MDSCs resembles monocytes and neutrophils which have immunostimulatory functions instead of suppressing T cells. Therefore, finding specific surface markers for MDSCs is important for MDSC research and therapeutic MDSC manipulation. In this study, we analyzed if the integrin VLA-1 has the potential as a novel MDSC marker. VLA-1 was expressed by M-MDSCs but not by G-MDSCs as well as by Teff cells. VLA-1 deficiency did not impact iNOS expression, the distribution of M-MDSC and G-MDSC subsets, and the suppressive capacity of MDSCs towards naïve and Teff cells in vitro. In mice, VLA-1 had no effect on the homing capability of MDSCs to the spleen, which is a major reservoir for MDSCs. Since the splenic red pulp contains collagen IV and VLA-1 binds collagen IV with a high affinity, we found MDSCs and Teff cells in this area as expected. We showed that T cell suppression in the spleen, indicated by reduced T cell recovery and proliferation as well as increased apoptosis and cell death, partially depended on VLA-1 expression by the MDSCs. In a mouse model of multiple sclerosis, MDSC injection prior to disease onset led to a decrease of the disease score, and this effect was significantly reduced when MDSCs were VLA-1 deficient. The expression of Sema7A by Teff cells, a ligand for VLA-1 which is implicated in negative T cell regulation, resulted in a slightly stronger Teff cell suppression by MDSCs compared to Sema7A deficient T cells. Live cell imaging and intravital 2-photon microscopy showed that the interaction time of MDSCs and Teff cells was shorter when MDSCs lacked VLA 1 expression, however VLA-1 expression had no impact on MDSC mobility. Therefore, the VLA-1-dependent interaction of MDSC and Teff cells on collagen IV in the splenic red pulp is implicated MDSC-mediated Teff cell suppression.
Diarrheal diseases are a major cause of death in developing countries. Vaccinating against the causative pathogens could reduce mortality and morbidity in these countries. Unfortunately, only for some of the most common enteral pathogens are vaccines available. Some of these available vaccines have limitations in terms of effectiveness and duration of protection. There is therefore an urgent need to develop new vaccine strategies that can generate protection against enteral pathogens.
The presence of all-trans retinoic acid (ATRA) during lymphocyte maturation is known to imprint a phenotype on lymphocytes that enables them to home to the intestines. Additionally, ATRA is known to play a role in B cell class switch to IgA, which is the dominant immunoglobulin in the intestines.
The aim of this study was therefore to investigate whether the addition of all-trans retinoic acid (ATRA) or a retinoic acid receptor agonist (AM80) to a parenteral vaccination could provide protection at the intestinal mucosa against enteric pathogens.
C57BL/6 mice received s.c. priming and boosting immunizations with Ovalbumin followed by several s.c. injections with either ATRA, AM80 or the respective solvent as control substance. Feces, serum, saliva and vaginal lavage samples were collected and analyzed by ELISA for detection and relative quantification of antigen-specific antibodies. B cell populations in the draining lymph nodes were investigated after immunization using flow-cytometry. Antigen-specific antibodies producing cells were visualized in the small intestine of vaccinated animals using two-photon microscopy.
Animals that were vaccinated and were exposed to AM80, and to a lesser extent ATRA exposed mice, had higher serum, fecal, saliva and vaginal lavage antigen-specific IgA titers when compared to animals that were vaccinated but did not receive ATRA/AM80. Antigen-specific IgG titers were not altered in any of the investigated tissues. In the draining lymph nodes, IgA+ and IgG+ B cells were increased after vaccination and AM80 exposure at several time points within 14 days after vaccination. Antigen-specific IgA+ cells were found in the small intestine of immunized and AM80-exposed but not control substance-exposed mice.
These results suggest that the addition of ATRA or AM80 to parenteral vaccine formulations increases the abundance of antigen-specific antibodies at mucosal surfaces, and therefore have the potential to generate protective antibody titers at those mucosal surfaces.
Measles is an ancient disease with historical records as early as the 9th century.
Extensive study as well as advances in scientific knowledge of virology have led to
identification of the viral pathogen and subsequent development of an effective vaccine
leading to global efforts towards measles elimination. In 2018, around 140,000 deaths were
reported due to measles with incomplete vaccine coverage being one of the leading causes
of resurgence. Measles is highly contagious and often regarded as a childhood illness.
However, measles is associated with a number of complications and persistent infections
like subacute sclerosing panencephalitis (SSPE), which have brought into focus the need
for specific anti-viral therapies.
The aim of this study was to target host and viral factors to optimize anti-measles virus
therapy. Our approach was to test a panel of compounds known to inhibit host cell
functions or viral factors for their antiviral effect on measles replication. Primary human
lymphocytes, persistently infected NT2 cells and post-mitotic neurons were used as in vitro
model systems of acute, persistent and neuronal infection respectively to test the inhibitors.
Using the inhibitors Ceranib-2 and SKI-II to target the sphingolipid metabolism enzymes
acid ceramidase and sphingosine kinase in infected human primary lymphocytes, we
observed a decreased protein translational capacity mediated by mTORC1, EIF4E and
ribosomal protein S6 phosphorylation that probably contributes to the antiviral effect. In
the persistently infected neural NT2 cells and post-mitotic neurons derived from LUHMES
cells, we observed effective infection inhibition and viral clearance upon treatment with a
small non-nucleoside inhibitor (ERDRP-0519) specifically targeting the Morbillivirus
large polymerase. Other inhibitors such as Ribavirin and Favipiravir were less effective. To
conclude, 1) we identified a mTOR associated protein translation axis associated with the
sphingolipid metabolism, which affects measles virus replication and 2) In vitro
persistently infected neuronal and post-mitotic neuron models were successfully used as a
rapid method to test antivirals against measles virus.
In Ratten und Mäusen aktiviert der superagonistische anti-CD28 monoklonale Antikörper (CD28SA) vorzugsweise regulatorische T-Zellen. In niedriger Dosierung führt CD28SA zu einer fast ausschließlichen Aktivierung von regulatorischen T-Zellen (Tregs). Diese Beobachtung konnte inzwischen auch für menschliche Zellen in Zellkultur bestätigt werden.
In gesunden und freiwilligen Testpersonen deutet die Zytokin-Antwort nach Applikationen von niedrigen CD28SA-Dosen darauf hin, dass sich diese Beobachtung auch in-vivo bewahrheitet. Eine Gabe von CD28SA in niedriger Dosierung, die zu einer exklusiven Aktivierung von regulatorischen T-Zellen führt, könnte somit in der Behandlung von Autoimmunkrankheiten oder von entzündlichen Erkrankungen eingesetzt werden.
Eine mechanistische Erklärung für dieses Phänomen blieb lange Zeit unklar. Die CD28SA-vermittelte T-Zell-Aktivierung ist abhängig von der Verstärkung von basalen tonischen Signalen, die T-Zellen über ihren T-Zell-Rezeptor erhalten. Diese Tatsache führte zu der Hypothese, dass die schwachen, tonischen Signale, die konventionelle CD4+ T-Zellen in Abwesenheit ihrer spezifischen Antigene über den T-Zell-Rezeptor erhalten, ein stärkeres CD28 Signal für ihre Aktivierung benötigen als die selbstreaktiven regulatorischen T-Zellen, die ein stärkeres Selbstpeptid-TCR Signal erhalten.
In dieser Arbeit konnte gezeigt werden, dass die Blockade von MHC-Klasse-II-Molekülen in Mäusen, in-vitro und in-vivo, den Vorteil der regulatorischen T-Zellen gegenüber den konventionellen T-Zellen bezüglich der Antwort auf niedrige CD28SA Dosierungen, aufhebt.
Trotz zahlreicher Fortschritte im Verständnis der Funktionsweise des kostimulatorischen Rezeptors CD28 in Mensch, Maus, Ratte und Makake ist nach wie vor wenig hierüber in Bezug auf das Tiermodell Schwein bekannt. Die vorliegende Arbeit untersucht die Funktion und Expression von CD28 in Schweine-T-Zellen sowie die Regulierbarkeit der T-Zellaktivierung durch anti-pCD28 mAb. Die Ergebnisse zeigen, dass hierbei vor allem CD4+ und CD8+ T-Zellen differenziert betrachtet werden müssen. Grundsätzlich unterscheiden sich die beiden T-Zellpopulationen in der CD28 mRNA Expression, im Expressionsverhältnis zwischen CD28 mRNA und Protein, sowie im proliferativen Ansprechen auf anti-pCD28mAb. So reagierten CD4+ im Vergleich zu CD8+ T-Zellen auf die kostimulatorische Inkubation mit anti-pCD28 mAb des Klons 3D11 sensibler. In direkt stimulatorischen Ansätzen zeigte sich, dass CD4+ und CD8+ T-Zellen durch unterschiedliche anti-pCD28 mAb differentiell angesprochen werden können. Eine superagonistische Funktion konnte für CD4+ T-Zell aktivierende anti-pCD28 mAb in den bisherigen Versuchen noch nicht beobachtet werden. Letzteres ist hierbei vor allem für den Transfer von vielversprechenden Therapiestrategien vom Kleintier- zum Großtiermodell auf dem Weg zur Entwicklung neuer Therapieoptionen für Autoimmunerkrankungen, Erkrankungen mit starker proinflammatorischer Aktivität und dem Myokardinfarkt von Bedeutung.
Transcription describes the process of converting the information contained in DNA into RNA. Although, tremendous progress has been made in recent decades to uncover this complex mechanism, it is still not fully understood. Given the advances and reduction in cost of high-throughput sequencing experiments, more and more data have been generated to help elucidating this complex process. Importantly, these sequencing experiments produce massive amounts of data that are incomprehensible in their raw form for humans. Further, sequencing techniques are not always 100% accurate and are subject to a certain degree of variability and, in special cases, they might introduce technical artifacts. Thus, computational and statistical methods are indispensable to uncover the information buried in these datasets.
In this thesis, I worked with multiple high throughput datasets from herpes simplex virus 1 (HSV-1) and human cytomegalovirus (HCMV) infections. During the last decade, it has became clear that a gene might not have a single, but multiple sites at which transcription initiates. These multiple transcription start sites (TiSS) demonstrated to have regulatory effects on the gene itself depending on which TiSS is used. Specialized experimental approaches were developed to help identify TiSS (TiSS-profiling). In order to facilitate the identification of all potential TiSS that are used for cell type- and condition-specific transcription, I developed the tool iTiSS. By using a new general enrichment-based approach to predict TiSS, iTiSS proved to be applicable in integrated studies and made it less prone to false positives compared to other TiSS-calling tools. Another improvement in recent years was made in metabolic labeling experiments such as SLAM-seq. Here, they removed the time consuming and laborious step of physically separating new from old RNA in the samples. This was achieved by inducing specific nucleotide conversions in newly synthesized RNA that are later visible in the data. Consequently, the separation of new and old RNA is now done computationally and, hence, tools are needed that accurately quantify these fold-changes. My second tool that I developed, called GRAND-SLAM proved to be capable to accomplish this task and outperform competing programs. As both of my tools, iTiSS and GRAND-SLAM are not specifically tailored to my own goals, but could also facilitate the research of other groups in this field, I made them publicly available on GitHub.
I applied my tools to datasets generated in our lab as well as to publicly available data sets from HSV-1 and HCMV, respectively. For HSV-1, I was able to predict and validate TiSS with nucleotide precision using iTiSS. This has lead to the most comprehensive annotation for HSV-1 to date, which now serves as the fundamental basis of any future transcriptomic research on HSV-1. By combining both my tools, I was further able to uncover parts of the highly complex gene kinetics in HCMV and to resolve the limitations caused by the densely packed genome of HCMV.
With the ever-increasing advances in sequencing techniques and their decrease in cost, the amounts of data produced will continue to rise massively in the future. Additionally, more and more specialized omics approaches are appearing, calling for new tools to leverage their full information potential. Consequently, it has become apparent that specialized computational tools such as iTiSS and GRAND-SLAM are needed and will become an essential and indispensable part of the analysis.
Lack of acid sphingomyelinase (ASM) activity, either through genetic deficiency or through pharmacological inhibition, is linked with increased activity and frequency of Foxp3+ regulatory T cells (Treg) among cluster of differentiation (CD) 4+ T cells in mice in vivo and in vitro1. Thus, pharmacological blockade of ASM activity, which catalyzes the cleavage of sphingomyelin to ceramide and phosphocholine, might be used as a new therapeutic mechanism to correct numeric and/ or functional Treg de-ficiencies in diseases like multiple sclerosis or major depression.
In the present study, the effect of pharmacological inhibition of ASM in humans, in vitro and in vivo, was analyzed. In the in vitro experiments, peripheral blood mono-nuclear cells (PBMC) of healthy human blood donors were treated with two widely prescribed antidepressants with high (sertraline, Ser) or low (citalopram, Cit) capaci-ty to inhibit ASM activity. Similar to the findings in mice an increase in the frequency of Treg among human CD4+ T cells upon inhibition of ASM activity was observed. For the analysis in vivo, a prospective study of the composition of the CD4+ T cell com-partment of patients treated for major depression was done. The data show that pharmacological inhibition of ASM activity was superior to antidepressants with little or no ASM-inhibitory activity in increasing CD45RA- CD25high effector Treg (efTreg) frequencies among CD4+ T cells to normal levels. Independently of ASM inhibition, correlating the data with the clinical response, i.e. improvement of the Hamilton rat-ing scale for depression (HAMD) by at least 50 per cent (%) after four weeks of treatment, it was found that an increase in efTreg frequencies among CD4+ cells dur-ing the first week of treatment identified patients with a clinical response.
Regarding the underlying mechanism, it could be found that the positive effect of ASM inhibition on Treg required CD28 co-stimulation suggesting that enhanced CD28 co-stimulation was the driver of the observed increase in the frequency of Treg among human CD4+ T cells. Inhibition of ASM activity was further associated with changes in the expression and shuttling of CTLA-4, a key inhibitory molecule ex-pressed by Treg, between cellular compartments but the suppressive activity of CTLA-4 through its transendocytosis activity was unaffected by the inhibition of ASM activity.
In summary, the frequency of (effector) Treg among CD4+ T cells in mice and in hu-mans is increased after inhibition of ASM activity suggesting that ASM blockade might beneficially modulate autoimmune diseases and depression-promoting in-flammation.
CD4+Foxp3+ Tregs can be induced in vitro by TGF-b stimulation. Here, CNS1 deficient CD4+ T cells were found to show compromised Foxp3 upregulation in vitro compared to CNS1 WT CD4+ T cells. Moreover, we could demonstrate that antigen-specific CD4+Foxp3+ Tregs can be induced in vivo by tolerogenic antigen stimulation. Parenteral application of agonist BDC2.5 mimetope induced Foxp3 expression in CD4+ BDC2.5 tg cells. We could show that induction of Foxp3 expression by tolerogenic peptide stimulation is impaired in CNS1 deficient CD4+ BDC2.5 tg cells compared to CNS1 WT CD4+ BDC2.5 tg controls. These results indeed indicate that in vivo induced Tregs share mechanistic characteristics with naturally occurring pTregs.
Additional in vivo experiments with blocking monoclonal anti-TGF-b demonstrated that high dosage TGF-b blockade abrogated peptide-induced Foxp3 expression in CNS1 WT BDC2.5 tg CD4+ cells, akin to what is seen for impaired Foxp3 upregulation in peptide-stimulated CNS1 KO BDC2.5 tg CD4+ cells without anti-TGF-b-treatment.
Adoptive transfer of CD4+CD25- T cells in T cell deficient recipients dramatically increased CD4+Foxp3+ Treg frequencies in both CNS1 WT CD4+ and CNS1 KO CD4+ donor cells. Despite an initially lower increase in Foxp3 expression in CNS1 KO donor cells compared to CNS1 WT donor cells early after transfer, in this setting impaired Treg induction in CNS1 deficient cells was not preserved over time. Consequently, diabetes onset and progression were indistinguishable between mice that received CNS1 WT or CNS1 KO donor cells. Additional Foxp3 induction by peptide stimulation of immunodeficient recipients after transfer of CNS1 WT BDC2.5. tg or CNS1 KO BDC2.5 tg donor cells was not detectable.