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As one of the most widespread infectious diseases in the world, it is currently estimated that approximately 296 million people globally are chronically infected with Hepatitis B virus (HBV), the consequences of HBV infection cause more than 620,000 deaths each year. Although safe and effective HBV vaccines have reduced the incidence of new HBV infections in most countries, there are still around 1.5 million new infections each year. HBV remains a major health problem because there is no large-scale effective vaccination strategy in many countries with a high burden of disease, many people with chronic HBV infection are not receiving effective and timely treatment, and a complete cure for chronic infection is still far from being achieved.
Since its discovery, HBV has been identified as an enveloped DNA virus with a diameter of 42 nm. For efficient egress from host cells, HBV is thought to acquire the viral envelope by budding into multivesicular bodies (MVBs) and escape from infected cells via the exosome release pathway. It is clear that HBV hijacks the host vesicle system to complete self-assembly and propagation by interacting with factors that mediate exosome formation. Consequently, the overlap with exosome biogenesis, using MVBs as the release platform, raises the possibility for the release of exosomal HBV particles. Currently, virus containing exosomal vesicles have been described for several viruses. In light of this, this study explored whether intact HBV-virions wrapped in exosomes are released by HBV-producing cells.
First, this study established a robust method for efficient separation of exosomes from HBV virions by a combination of differential ultracentrifugation and iodixanol density gradient centrifugation. Fractionation of the density gradient revealed that two populations of infectious viral particles can be separated from the culture fluids of HBV-producing cells. The population present in the low-density peak co-migrates with the exosome markers. Whereas the population that appeared in the high-density fractions was the classical HBV virions, which are rcDNA-containing nucleocapsids encapsulated by the HBV envelope.
Subsequently, the characterization of this low-density population was performed, namely the highly purified exosome fraction was systematically investigated. Relying on the detergent sensitivity of the exosome membrane and the outer envelope of the HBV virus, disruption of the exosome structure by treatment with limited detergent revealed the presence of HBsAg in the exosomes. At the same time, mild and limited NP-40 treatment of highly purified exosomes and a further combination of density gradient centrifugation resulted in the stepwise release of intact HBV virions and naked capsids from the exosomes generated by HBV-producing cells. This implies the presence of intact HBV particles encapsulated by the host membrane.
The presence of exosome-encapsulated HBV particles was consequently also verified by suppressing the morphogenesis of MVBs or exosomes. Impairment of MVB- or exosome-generation with small molecule inhibitors has significantly inhibited the release of host membrane-encapsulated HBV particles as well. Likewise, silencing of exosome-related proteins caused a diminution of exosome output, which compromised the budding efficiency of wrapped HBV.
Moreover, electron microscopy images of ultra-thin sections combined with immunogold staining visualized the hidden virus in the exosomal structure. Additionally, the presence of LHBs on the surface of exosomes derived from HBV-expressing cells was also observed.
As expected, these exosomal membrane-wrapped HBV particles can spread productive infection in differentiated HepaRG cells. In HBV-susceptible cells, as LHBs on the membrane surface, this type of exosomal HBV appeared to be uptaken in an NTCP receptor-dependent manner.
Taken together these data indicate that a fraction of intact HBV virions can be released as exosomes. This reveals a so far not described release pathway for HBV. Exosomes hijacked by HBV act as a transporter impacting the dissemination of the virus.
Two main types of methods are used in gene therapy: integrating vectors and nuclease-based genome engineering. Nucleases are site-specific and are efficient for knock-outs, but inefficient at inserting long DNA sequences. Integrating vectors perform this task with high efficiency, but their insertion occurs at random genomic positions. This can result in transformation of target cells, which leads to severe adverse events in a gene therapy context. Thus, it is of great interest to develop novel genome engineering tools that combine the advantages of both technologies. The main focus of this thesis is on generating such a targetable integrating vector.
The integrating vector used in this project is the Sleeping Beauty (SB) transposon, a DNA transposon characterized by high activity across a wide range of cells. The SB transposase was combined with an RNA-guided Cas9 nuclease domain. This nuclease component was meant to direct transposase integration to specific targets defined by RNAs. The SB transposase was fused to cleavage-inactivated Cas9 (dCas9) to tether it to the target sites. In addition, adapter proteins consisting of dCas9 and domains non-covalently interacting with SB transposase or the SB transposon were generated. All constituent domains of these fusion proteins were tested in enzymatic assays and almost all enzymatic activities could be verified.
Combining the fusion protein dCas9-SB100X with a gRNA binding a sequence from the AluY repetitive element resulted in a weak, but statistically significant enrichment around sites bound by the gRNA. This enrichment was ca. 2-fold and occurred within a 300 bp window downstream of target sites, or within the AluY element.
Targeting with adapter proteins and targeting of other targets (L1 elements or single-copy targets) did not result in statistically significant effects. Single-copy targets tested included the HPRT gene and three specifically selected GSH targets that were known to be receptive to SB insertions. The combination with a more sequence-specific transposase mutant also failed to increase specificity to a level allowing targeting of single-copy loci. Genome-wide analysis of insertions however demonstrated, that dCas9-SB100X has a different insertion profile than SB100X, regardless of the gRNA used.
As low efficiency of retargeting is likely a consequence of the high background activity of the SB100X transposase in the fusion constructs, a SB mutant with reduced DNA affinity, SB(C42), was generated. For this mutant, transposition activity was partly dependent on a dCas9 domain being supplied with a multi-copy target gRNA, specifically a 2-fold increase in the presence of a AluY-directed gRNA. Whether using this mutant results in improved targeting remains to be determined.
In a side project, an attempt was made to direct SB insertions to ribosomal DNA by fusing the transposase to a nucleolar protein. This fusion transposase partially localized to nucleoli and insertions catalyzed by this transposase were found to be enriched in nucleolus organizer regions (NORs) and nucleolus-associated domains (NADs).
The aim of a second side project was increasing the ratio between homology-directed repair (HDR) and non-homologous end-joining (NHEJ) at Cas9-mediated double-strand breaks (DSBs). To achieve this, Cas9 was fused to DNA-interacting domains and corresponding binding sequences were fused to the homology donors. While an increased HDR/NHEJ ration could be observed for the fusion proteins, it was not dependent on the presence on the binding sequences in the donor molecules.
In the recent years, myxobacteria have emerged as a novel source of natural compounds with structural diversity and biological activity for drug discovery. In this work, the two myxobacterial compounds archazolid and vioprolide were characterized for their potential pharmacological effects in vascular endothelial cells. Archazolid is a wellestablished v-ATPase inhibitor found in Archangium gephyra and Cystobacter spec. As the v-ATPase represents a promising target in cancer treatment, the effects of archazolid have been intensively studied in cancer cells, but rarely in endothelial cells. Vioprolide is an antifungal and cytotoxic metabolite obtained from Cystobacter violaceus. There are only few studies on vioprolide, most of them focusing on its biosynthesis. Preliminary studies revealed that it inhibited TNF-induced expression of ICAM-1, indicating possible anti-inflammatory properties. As the endothelium plays an important role in cancer and inflammation, it represents an attractive drug target. Therefore, the archazolid and vioprolide were investigated regarding their effects on endothelial cells.
V-ATPase inhibition by archazolid resulted in anti-tumor and anti-metastatic effects in vitro and in vivo. Archazolid was used to study the consequences of v-ATPase inhibition in endothelial cells that might contribute to the anti-metastatic activities observed in vivo. To analyze the impact of archazolid on the interaction endothelial and cancer cells, in vitro cell adhesion and transmigration assays were performed using primary HUVEC or immortalized HMEC-1 and different cancer cell types (MDA-MB-231, PC-3 and Jurkat cells). For these experiments, only the endothelial cells were treated with archazolid. VATPase inhibition by archazolid led to an increased adhesion of the metastatic breast cancer cell line MDA-MB-231 and prostate cancer cell line PC-3 onto endothelial cells whereas the adhesion of Jurkat cells was unaffected. Interestingly, archazolid treatment of HUVECs decreased the transendothelial migration of MDA-MB-231 cells. Endothelial ICAM-1, VCAM-1, E-selectin and N-cadherin are potential ligands of interacting cancer cells. Therefore, the mRNA and surface protein levels of these cell adhesion molecules were measured via qRT-PCR and flow cytometry, respectively. These adhesion molecules were not responsible for the archazolid-induced cancer cell adhesion, as archazolid treatment of HUVECs did not upregulate their mRNA or surface expression. Instead, cell adhesion assays using a monoclonal antibody against integrin subunit β1 showed that β1-integrins expressed on MDA-MB-231 and PC-3 cells mediated the archazolid-induced cancer cell adhesion. Cell adhesion assays onto plastic coated with ECM components which are the major ligands of β1-integrins, revealed that MDA-MB231 and PC-3 cells preferably interact with collagen. So next, we investigated the influence of archazolid on surface collagen levels in HUVECs by immunostaining, which demonstrated an increase of nearly 50 % upon archazolid treatment. We confirmed the hypothesis that the expression and activity of cathepsin B, a lysosomal enzyme that degrades extracellular matrix components including collagen, was inhibited by archazolid in endothelial cells. Finally, overexpression of cathepsin B reduced the cancer cell adhesion on archazolid-treated HUVECs, but also in control cells, indicating a negative correlation between cathepsin B expression and cancer cell adhesion.
The influence of vioprolide on the interaction of endothelial cells with leukocytes was analyzed by in vitro cell adhesion assays using HUVECs and primary monocytes, THP-1 or Jurkat cells. Vioprolide inhibited the adhesion of these cells onto TNF-activated HUVECs. In addition, the endothelial-leukocyte interaction was observed in vivo by intravital microscopy in the mouse cremaster muscle. Vioprolide prevented the TNFinduced firm adhesion and transmigration of leukocytes, while leukocyte rolling was not affected. ICAM-1, VCAM-1 and E-selectin are cell adhesion molecules, which are upregulated by TNF and mediate leukocyte adhesion onto endothelial cells. Therefore, flow cytometric analysis was performed to measure their surface expression. Vioprolide significantly decreased TNF-induced expression of surface ICAM-1, VCAM-1 and E-selectin, which was in line with the in vitro results. In vivo, vioprolide may act in a different way on E-selectin expression, so that leukocyte rolling, which is governed by E-selectin, remained unaffected. qRT-PCR experiments revealed that the mRNA expression of ICAM-1 and VCAM-1 were also reduced by vioprolide, indicating a regulation on transcriptional level. In contrast, the mRNA expression of E-selectin was not decreased at the timepoint when surface protein expression was diminished. The induction of these cell adhesion molecules is mainly mediated by the transcription factor NFκB. A Dual-Luciferase® reporter assay was used to study the impact of vioprolide on the TNF-induced NFκB promotor activity. Vioprolide blocked the TNF-induced NFκB promotor activity while the TNF-induced IκBα degradation and nuclear translocation of the NFκB subunit p65 was not altered by vioprolide. Western blot analysis revealed that vioprolide had no effect on the activation of MAPK (p38, JNK) and AKT by TNF, which could interfere with the NFκB-dependent gene expression.
Taken together, archazolid and vioprolide are interesting myxobacterial compounds with different modes of actions. The study suggests that the v-ATPase inhibitor archazolid impairs the expression and activity of cathepsin B in endothelial cells, which leads to a higher amount of collagen on the endothelial surface. As a result, the adhesion of β1-integrin expressing metastatic cancer cells onto archazolid-treated endothelial cells increased while transendothelial migration was reduced. Further, archazolid represents a promising tool to elucidate the role of v-ATPase in endothelial cells. Vioprolide was able to prevent TNF-induced endothelial-leukocyte interaction in vitro and in vivo by interfering with NFκB-dependent gene expression. Further research is required to enlighten the underlying mechanism and the direct target of vioprolide.
In this research project we aimed to generate genetically modified megakaryocytes and platelets, by targeting protein expression to their secretory alpha-granules to delivery ectopic or therapeutic proteins, to be stored and kept there until an external stimulus triggers platelet activation and platelet secretion takes place. During platelet activation, the therapeutic proteins would then be released to the extracellular space, either as a soluble protein or exposed as a transmembrane protein on the cell surface of platelets. For long-term approaches, genetic modifications must be introduced at the hematopoietic stem cell level.
AIMS: As first approach, we aimed to characterize the lineage-specificity of expression of six different promoter fragments in lentiviral vectors: the murine platelet factor 4 (mPf4) 1222 bp (-1074 to +148), human glycoprotein Ib alpha (hGP1BA) 595 bp (-265 to +330), a short and a longer fragment of the human glycoprotein 6 (hGP6 / hGP6s) 351 bp (-322 to +29) / 726 bp (-697 to +29), as well the human glycoprotein 9 (GP9) promoter 794 bp (-782 to -12). These promoter fragments were included as internal cellular promoters in self-inactivating lentiviral vectors (SIN), using an enhanced green fluorescent protein (eGFP) as gene reporter. GFP detection was evaluated in vitro (in transduced non-megakaryocitc blood cell progenitors and in-vitro differentiated megakaryocytes) and in vivo (Bone marrow cells, blood cells and spleen cells). For targeting of proteins to the secretory alpha granules of megakaryocytes and platelets, we followed two strategies: A) The sorting signal of the cytokine RANTES was fused N-terminally to the destabilized GFP, d2eGFP (RANTES. d2eGFP), to deliver the protein into the granules as soluble cargo. B) The transmembrane granular targeting sequence of P-selectin (the transmembrane domain and cytoplasmic tail (referred as TDCT) was fused to d2eGFP or the B domain deleted codon optimized human coagulation Factor VIII cDNA (referred as BDcohFVIII_TDCT or FVIII_TDCT), to deliver the protein into the membrane of alpha granules. These two strategies were tested in-vitro, from transduced differentiated megakaryocytes in liquid cultures, and in-vivo, by analysis of genetically modified platelets by means of Laser Scanning Confocal Microscopy (LSM) in colocalization analysis (performed at the single cell level) and fluorescence intensity analysis.
RESULTS: GFP expression in blood cells from transplanted mice was significantly higher in platelets, with a smaller background promoter activity in leukocytes and erythrocytes. The highest expression was observed from the mPf4-vector, followed by hGP1BA, hGP6 and hGP6s vectors, identifying the hGP6 vectors as the most restricted to the megakaryocyte and platelet lineage. Analysis in bone marrow cells showed that hGP6-vectors have the lowest activity in the hematopoietic stem and progenitor cells (HSPC) with less than 10% of GFP positive stem cells. Surprisingly, the mPf4 and hGP1BA vectors were both highly active in the HSPC, in a range of 20 to 70% of GFP-positive cells. Polyploidization in later stages of MK-maturation of in-vitro Mks differentiated from Mpl-/- lineage marker negative cells were recovered after gene transfer of the thrombopoietin receptor Mpl, under the control of MK-specific vectors in differentiated into MKs. These results were corroborated in in-vivo analysis, where Mpl-/- mice transplanted with lin-BM cells transduced with the mPf4.Mpl and hGP6.Mpl vectors, showed significantly elevated platelet counts compared to control mice transplanted with a GFP-encoding control vector (PGK-GFP). In the Fluorescent intensity and colocalization analysis of transduced megakaryocytes with the targeting vectors, we observed a significant difference in the GFP targeting compared with those MK transduced with the non-targeting vectors. The median of the WCC values observed from the RANTES.d2eGFP targeting vector was 0.8 (80 % of colocalization) with P-selectin stained granules, and 0.7 (70%) with von Willebrand Factor stained granules. In the case of the non-targeting vector SFFV.d2eGFP the median of the WCC observed were <0.3 (30%) both in P-selectin and von Willebrand Factor stained granules. We observed as well that the GFP signal of MK transduced with the P-selectin.d2eGFP fusion overlapped the signals emitted by P-selectin and von Willebrand factor stained granules, not just in LSM-digitalized images but in the fluorescens intensity analysis as well, indicating a clear signal of GFP colocalization. Likewise, an evident signal overlap between the targeted FVIII (FVIII_TDCT) with the P-selectin / von Willebrand marker was observed. Colocalization and fluorescens intensity analysis performed on activated platelets from transplanted mice with the targeting vectors, corroborated what was previously observed in in-vitro megakaryocytes. The genetic modification of megakaryocyte and platelets will allow in the furture, not just the development of new generation of cells with advanced functions, but it will help us to elucidate new mechanisms and pathways of important cellular processes, by modifying cell function and cell interactions.
Pretubulysin (PT), a biosynthetic precursor of the myxobacterial compound tubulysin D, was recently identified as a novel microtubule-targeting agent (MTA) causing microtubule destabilization. MTAs are the most frequently used chemotherapeutic drugs. They are well studied regarding their direct cytotoxic effects against various tumors as well as for their anti-angiogenic and vascular-disrupting action addressing endothelial cells of the tumor vasculature. However, the impact of MTAs on endothelial cells of the non-tumor vasculature has been largely neglected, although tumor cell interactions with the healthy endothelium play a crucial role in the process of cancer metastasis. Besides their use as potent anti-cancer drugs, some MTAs such as colchicine are traditionally used or recommended for the therapy of inflammatory diseases. Here, too, the role of endothelial cells has been largely neglected, although the endothelium is crucially involved in regulating the process of inflammation.
In the present study, the impact of PT on tumor-endothelial cell interactions was therefore analyzed in vitro to gain insights into the mechanism underlying its anti-metastatic effect that was recently confirmed in vivo. In the second part of this work, the influence of PT and other MTAs, namely the microtubule-destabilizing compounds vincristine (VIN) and colchicine (COL) and the microtubule-stabilizing drug paclitaxel (PAC), on leukocyte-endothelial cell interactions was investigated in vitro and in vivo (only PT). It is important to mention that in all in vitro experiments solely endothelial cells and not tumor cells or leukocytes were treated with the MTAs to strictly focus on the role of the endothelium in the action of these compounds.
The impact of PT on tumor-endothelial cell interactions was analyzed in vitro by cell adhesion and transendothelial migration assays as well as immunocytochemistry using the breast cancer cell line MDA-MB-231 and primary human umbilical vein endothelial cells (HUVECs). The treatment of HUVECs with PT increased the adhesion of MDA cells onto the endothelial monolayer, whereas their transendothelial migration was reduced by the compound. Thereafter, the influence of PT on the endothelial cell adhesion molecules (CAMs) E-selectin, N-cadherin, ICAM-1, VCAM-1 and galectin-3 and on the CXCL12/CXCR4 chemokine system was examined, since they might be involved in the PT-triggered tumor cell adhesion. Interestingly, although PT induced the upregulation of ICAM-1, VCAM-1, N-cadherin and CXCL12, cell adhesion assays using neutralizing antibodies or the CXCL12 inhibitor AMD3100 revealed that all these molecules were dispensable for the PT-evoked tumor cell adhesion. As PT induces the formation of interendothelial gaps and MDA cells might adhere onto components of the underlying extracellular matrix (ECM), the precise location of MDA cells attached to the PT-treated endothelial monolayer was investigated. Instead of a direct interaction between tumor and endothelial cells, this work showed that MDA cells preferred to adhere to the ECM component collagen that was exposed within PT-triggered endothelial gaps. Both the PT-evoked increase in tumor cell adhesion onto and the decrease in trans-endothelial migration were completely abolished when β1-integrins were blocked on MDA cells. Similar results were obtained when endothelial cells were treated with VIN and COL but not PAC, indicating that the observed effects of PT depend on its microtubule-destabilizing activity.
The impact of PT, VIN, COL and PAC on leukocyte-endothelial cell interactions was analyzed in vivo (only PT) by intravital microscopy of the mouse cremaster muscle and in vitro by cell adhesion assays using the monocyte-like cell line THP-1 and TNFα-activated human dermal microvascular endothelial cells (HMEC-1). While PT did not affect the rolling of leukocytes on the endothelium, their firm adhesion onto and transmigration through the activated endothelium was reduced by PT in vivo. In accordance, the treatment of HMEC-1 with PT, VIN and COL decreased the TNFα-induced adhesion of THP-1 cells onto the endothelial monolayer, whereas PAC had no influence on this process. Thereafter, the influence of PT, VIN, COL and PAC on endothelial ICAM-1 and VCAM-1 was examined, since these molecules are substantially involved in the firm adhesion of leukocytes onto the endothelium. The cell surface protein expression of ICAM-1 and VCAM-1 was reduced by PT, VIN and COL in activated endothelial cells, whereas PAC did only slightly affect the TNFα-induced upregulation of VCAM-1. As the pro-inflammatory transcription factor NFκB plays a crucial role in the TNFα-induced expression of these CAMs, the impact of the MTAs on the NFκB promotor activity was investigated. While PT, VIN and COL decreased the activation of NFκB in activated endothelial cells, PAC did not affect this process. However, in contrast to the strong effects regarding the cell surface protein expression of ICAM-1 and VCAM-1, the effects of PT, VIN and COL on the NFκB activity was rather low. Thus, the used MTAs might also affect other relevant signaling pathways and/or the intracellular transport of CAMs might be influenced by the impact of the MTAs on the microtubule network.
Taken together, the current study provides – at least in part – an explanation for the anti-metastatic potential of PT and gives first insights into the use of PT and VIN as anti-inflammatory drugs. Moreover, this work highlights the endothelium as an attractive target for the development of new anti-cancer and anti-inflammatory drugs.
Schätzungen zufolge sind weltweit etwa 71 Millionen Menschen chronisch mit dem Hepatitis-C-Virus (HCV) infiziert. Im Jahre 2016 sind rund 400.000 Menschen an einer HCV-bedingten Lebererkrankung gestorben, insbesondere aufgrund der Entwicklung von Leberzirrhose und Lebertumoren. Trotz der großen Unterschiede in den Prävalenzschätzungen und der Qualität der epidemiologischen Daten zeigt die jüngste weltweite Bewertung, dass die virämische Ausbreitung der HCV-Infektion (Prävalenz der HCV-RNA) in den meisten Industrieländern, einschließlich der USA, weniger als 1,0% beträgt (www .cdc.gov / Hepatitis / HCV). In einigen osteuropäischen Ländern wie Lettland (2,2%) oder Russland (3,3%) und bestimmten Ländern in Afrika, Ägypten (6,3%) und Gabun (7,0%) oder im Nahen Osten Syriens (3,0%) ist die Prävalenz bemerkenswert höher. In den USA und den am weitesten entwickelten Ländern gilt die gemeinsame Nutzung von Werkzeugezur Herstellung von Arzneimitteln und zur Injektion von Medikamenten (Nadeln) als die häufigste derzeitige Übertragungsart. Die vorherrschende Übertragungsart in Ländern, in denen die Ausbreitung von HCV-Infektionen im Vergleich zu den Industrieländern höher ist, beruht jedoch auf schlechten Methoden zur Infektionskontrolle und unsicherer Handhabung von Injektionsnadeln.
Wenn die chronische Infektion unbehandelt bleibt, kann sich im fortschreitenden Verlauf eine Zirrhose oder ein hepatozelluläres Karzinom bilden (Alter H. J. und Seef L. B. 2000). Die Doppeltherapie, bei der es sich um eine Kombination aus pegyliertem Interferon-α (PEG IFNα) und Ribavirin (riba) handelt, war in einigen Ländern der Dritten Welt bis vor kurzem der goldene Standard für die Behandlung von Patienten mit chronischer Hepatitis C und hat eine anhaltende virologische Reaktion erzielt. Mit nur 50% der mit HCV-Genotyp 1 infizierten Patienten (der häufigere) im Vergleich zu 80% mit Genotyp 2 oder 3, obwohl sie kostspielig und langwierig sind (z. B. 24-48 Wochen) und zahlreiche harte Nebenwirkungen aufweisen, die schwer zu bekämpfen sind tolerieren (Erklärung der National Institutes of Health Consensus Development Conference: Management von Hepatitis C: 2002 - 10.-12. Juni 2002 2002). Die Identifizierung des JFH1 (japanische fulminante Hepatitis Typ 1) -Isolats wurde in einigen in vitro-Studien zu HCV als wichtiger Durchbruch bei der HCV-Behandlung angesehen. Die Verwendung dieses Isolats führte nachfolgend zu einem besseren Verständnis des HCV-Lebenszyklus und der 3D-Strukturen der viralen Proteine. Basierend auf dieser Erkenntnis konnten die ersten direkt wirkenden antiviralen Mittel (DAAs) entwickelt werden, die spezifisch virale Proteine beeinflussen. Die beiden Proteasehemmer (PI) Telaprevir und Boceprevir hemmen die virale NS3-4A-Protease und wurden 2011 als Kombinationstherapie mit PEG IFNα und Ribavirin zugelassen, was die anhaltende virologische Reaktion auf 67-75% erhöhte (Pawlotsky et al. 2015).
Die Optimierung der gegenwärtigen Arzneimittelregime, die Einschränkung des Problems der Mutationsresistenz, die Gestaltung einer individualisierten Therapie, der Zugang zu diesen therapeutischen antiviralen Arzneimitteln und ihr hoher Preis bleiben weiterhin eine Herausforderung (Pawlotsky 2016; Pawlotsky et al. 2015; Sarrazin 2016). Die Entwicklung eines Impfstoffs wird jedoch als größte Herausforderung für die weltweite Kontrolle von HCV angesehen (Bukh 2016). Aus diesem Grund ist es wichtig, weiterhin mehr über den HCV-Lebenszyklus und die Faktoren zu erfahren, die sich auf die Replikation und den gesamten Lebenszyklus auswirken können, um effiziente, qualitativ hochwertige und vor allem leicht zugängliche Behandlungen für alle Menschen weltweit zu entwickeln.
Der Lipidstoffwechsel und insbesondere das Cholesteringleichgewicht werden durch die HCV-Infektion beeinflusst. Die Korrelation zwischen Lipidstoffwechsel und HCV wurde klinisch seit langem beobachtet. In den Leberbiopsien von mit HCV infizierten Patienten wurde ein Anstieg der in den Lipidtröpfchen im Cytosol akkumulierten neutralen Lipide festgestellt (Dienes et al. 1982). Das Hepatitis-C-Virus wurde auch von Hypobetalipoproteinämie, Hypocholesterinämie und Lebersteatose begleitet (Schaefer und Chung 2013). Die Leber ist der primäre Ort für die Synthese, Speicherung und Oxidation von Lipiden und anderen Makromolekülen. Daher ist der Fettstoffwechsel in der Leber für die Aufrechterhaltung der systemischen Nährstoffhomöostase von wesentlicher Bedeutung. Eine Dysregulation des Leberlipidstoffwechsels ist ein Kennzeichen mehrerer Krankheiten wie Diabetes, alkoholische und nichtalkoholische Fettlebererkrankungen sowie parasitäre und virale Infektionen, einschließlich einer HCV-Infektion. (Erklärung der National Institutes of Health Consensus Development Conference: Management von Hepatitis C: 2002 - 10.-12. Juni 2002 2002; Fon Tacer und Rozman 2011; Chen et al. 2013; Reddy und Rao 2006; Visser et al. 2013; Wu und Parhofer 2014)
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The overall survival for patients with acute lymphoblastic leukemia (ALL) often is the function of age, in particular in 2019 analysis revealed that 5-year overall survival for patients older than 20 years remains below 35% (American Cancer Society, Cancer Facts &Figures 2019). Importantly, one of the major issues in ALL therapy is the ability of tumor cells to escape the treatment via the establishment of an immunosuppressive environment. The tumor microenvironment has gained tremendous importance in the past decade. This is largely based on the reasoning that, in order to devise better therapeutic strategies for patients, we need to gain better understanding into how malignant cells transform their microenvironment to promote growth, escape immune control and gain therapeutic resistance.
TAM receptors (TAMRs) are engaged in innate immune cells as a feed-back mechanism to terminate the immune response and promote the return to homeostasis (Rothlin et al. 2007). In the context of cancers, aberrant TAMR signaling was mainly explored concerning its pro-oncogenic function (Paolino and Penninger 2016). There are only limited data available suggesting the modulation of cancer immune response via TAMR signaling in highly immunogenic solid tumor models (Paolino et al. 2014; Ubil et al. 2018). So far, however, little is known about their potential indirect immune-modulatory function in hematological malignancies. Taking into account the pronounced importance of TAMR signaling in immune cells combined with the leukemic immune tolerance, the current study focused on the function of TAMR and their ligands in anti-leukemic immunity.
This work uncovers the mechanism of dampening anti-leukemic immune response via TAMR signaling on macrophages using the syngeneic BCR-ABL1 B-ALL mouse model. Using genetic depletion of GAS6 in the host environment or ablation of AXL and/or MERTK receptors in macrophages the bone marrow microenvironment could be rewired in order to achieve an efficient anti-leukemic immune response. In particular, the GAS6/AXL blockade triggers an effective NKand T- cell-dependent anti-leukemic response that results in prolonged survival. This finding specifically tackles the obstacle of inefficient bridging between innate and adaptive immune response typical for hematological malignancies in contrast to solid tumors (E. K. Curran, Godfrey, and Kline 2017).
Besides establishing the vital function of TAMR signaling in anti-leukemic immunity using murine models, the analysis of human blood plasma revealed that age-related immune dysregulation was manifested by significant GAS6 decrease and PROS1 upregulation among elderly donors (>60 y.o.) compared to controls (<25 y.o.). These data are indicative that TAMR signaling likely favors the age-dependent immune system decline, which in turn is associated with a poor survival rate of elderly patients diagnosed with leukemia.
In conclusion, using a preclinical ALL model here it was identified in vivo, that Axl significantly increases upon B-ALL challenge in Mph and NK cells. Therefore, AXL targeting, using the orally bioavailable selective inhibitor Bemcentinib, could serve as a powerful approach to revert early immunosuppression created by leukemia.
Taken together these data propose the AXL receptor as a novel immune checkpoint and attractive candidate for the development of a new therapeutic approach via unleashing the patient’s own immune system to combat leukemic cells.
Bei ca. 95% der chronisch myeloischen Leukämie (CML) und 20-30% der akuten lymphatischen Leukämie (ALL) des Erwachsenen liegt eine reziproke Chromosomentranslokation t(9;22)(q34;q11) vor, in deren Rahmen das BCR (Breakpoint Cluster Region) Gen auf Chromosom 22 mit dem ABL (Abelson-Leukämie-Virus) Gen auf Chromosom 9 fusioniert. Auf Chromosom 22 gibt es zwei verschiedene Bruchpunkte, die somit zur Bildung von unterschiedlichen Fusionsgenen führen. Bei der CML findet man den sogenannten „großen“ Bruchpunkt (M-bcr), während bei der Ph+ ALL der sogenannte „kleine“ Bruchpunkt (m-bcr) vorkommt. Das hybride Fusionsgen auf Chromosom 22q+ (Philadelphia-Chromosom) kodiert für das jeweilige BCR/ABL Protein, während das Fusionsgen auf Chromosom 9q+ für das reziproke ABL/BCR Protein kodiert. Das ABL-Protein ist eine Nicht-Rezeptor Tyrosinkinase, die eine wichtige Rolle in der Signaltransduktion und der Regulation des Zellwachstums spielt. Im BCR/ABL Fusionsprotein wird die Kinase-Aktivität von ABL, die im Normalfall streng reguliert ist, durch die Fusion mit BCR konstitutiv aktiv. Dadurch kommt es zur Deregulierung intrazellulärer Signalwege, welche die maligne Transformation hämatopoetischer Zellen verursacht. Eine zielgerichtete Inhibierung von BCR/ABL mittels ABL-Kinase-Inhibitoren induziert Apoptose in BCR/ABL transformierten Zellen, was eine komplette Remission im größten Teil Ph+ Leukämie Patienten zur Folge hat.
The human Long Interspersed Nuclear Element-1 (LINE-1, L1) is a member of the group of autonomous non-LTR retrotransposons found in almost every eukaryotic genome. L1 elements generate copies of themselves by reverse transcription of an RNA intermediate and integrate into the host genome by a process called Target Primed Reverse Transcription (TPRT). They are responsible for the generation of approximately 35% of the human genome, cover about 17% of the genome and represent the only group of active autonomous transposable elements in humans. L1 activity bears several risks for the integrity of the human genome, since the L1-encoded protein machinery generates DNA double-strand breaks (DSBs) and is capable of conducting numerous genome-destabilizing effects, e.g. causing deletions at insertion sites, disrupting or rearranging coding sequences and deregulating transcription of functional host genes. On the other side, L1 elements have had and still exert a great impact on human genome structure and evolution by increasing the genome size and rearranging and modulating gene expression. Furthermore, due to its endogenous and generally non-pathogenic nature, L1 is a promising candidate as vector for gene delivery in somatic gene therapy. The structure of the flanking regions between de novo L1 integrants and the genomic sequence suggests an involvement of cellular DSB repair pathways in L1 mobilization. To elucidate the role of DSB repair proteins in L1 retrotransposition, I disabled DSB repair factors ATM, ATR, DNA-PK, p53 and Ku70 by knock down (KD) using short hairpin RNA (shRNA) expression constructs. To inhibit the function of DSB repair factors PARP and Rad51, I used dominant negative (DN) PARP and Rad51 mutants. Applying a well established L1-retrotransposition reporter assay in HeLa cells, de novo retrotransposition events were launched in order to test L1 for its retrotransposition activity in the context of altered DSB repair conditions. I could show that L1 retrotransposition frequency after ATM KD had increased by 3-fold, while ATR and p53 KD reduced L1 retrotransposition by approximately one third. Unfortunately, the cytotoxic effects of the DNA-PK and Ku70 shRNA expression constructs were too strong to determine potential effects of DNA-PK and Ku70 KD on L1 retrotransposition. Inhibition of PARP function by expression of the DN mutant and overexpression of wild type PARP were found to increase L1 retrotransposition by 1.8 and 1.5, respectively, while Rad51 DN had no detectable effect. Interestingly, overexpression of wild type Rad51 seemed to roughly double L1 retrotransposition frequencies. Since in my experiments KD or expression of DN mutants was time-delayed to the onset of L1 retrotransposition after transfection into the cells, I developed a temporally controllable, tetracyclin transactivator (tTA)-dependent L1 retrotransposition reporter assay which will be of great value for future L1 retrotransposition studies that rely on temporally controllable retrotransposition. Due to a previously published hypothesis of L1 playing a role in brain development by contributing to somatic mosaicism in neuronal precursor cells, I generated a transgenic mouse (LORFUS) using the tTA-dependent L1 construct to further test this hypothesis. LORFUS harbors a bidirectional cassette driving simultaneous expression of a GFP-tagged L1 retrotransposition reporter and beta-galactosidase. It was bred to another transgenic mouse line expressing tTA in the forebrain. The double transgenic offspring was used to characterize L1 expression and retrotransposition patterns in the brain at postnatal day 15 (P15). General transgene expression indicated by beta-galactosidase activity was found in hippocampus, cortex and striatum, while retrotransposition events revealed by GFP expression were found in hippocampus, cortex, striatum, olfactory bulb and brainstem. These results suggested L1 retrotransposition in the granule layer of the dentate gyrus earlier than P15 and migration of cells carrying these events along the rostral migratory stream into the olfactory bulb. To facilitate the use of L1 as gene delivery tool in gene therapy or genetic engineering, I furthermore intended to manipulate the L1 target site recognition to allow the site-specific integration into defined genomic locations. To this end, I performed crystal structure-guided mutational analysis exchanging single amino acid residues within the endonuclease (EN) domain of L1 to identify residues influencing target site recognition. However, individual point mutations did not change the nicking pattern of L1-EN, but resulted in a reduction of endonucleolytic activity reflected by a reduced retrotransposition frequency. This suggests that additional factors other than the DNA nicking specificity of L1-EN contribute to the targeted integration of non-LTR retrotransposons in the host genomes.
The vascular endothelium is a monolayer of endothelial cells that builds the inner lining of the blood vessels and constitutes a regulatory organ within the physiological system to sustain homeostasis. Endothelial cells participate in physiological processes including inflammation and angiogenesis. Dysregulation of these processes, however, can evoke or maintain pathological disorders, including cardiovascular and chronic inflammatory diseases or cancer. Although pathological inflammation and angiogenesis represent treatable conditions, current pharmacotherapeutic approaches are frequently not satisfying since their long-term application can evoke therapy resistance and thus reduced clinical efficacy. Consequently, there is an ongoing demand for the discovery of new therapeutic targets and drug leads. Considering that endothelial cells play a critical role in both angiogenesis and inflammation, the vascular endothelium represents a promising target for the treatment of diseases.
Vioprolide A is a secondary metabolite isolated from the myxobacterium Cystobacter violaceus Cb. vi35. Recently, vioprolide A was identified to interact with NOP14, a nucleolar protein involved in ribosome biogenesis. Ribosome biogenesis is an indispensable cellular event that ensures adequate homeostasis. Abnormal alterations in the ribosome biogenesis, referred to as ribosomopathies, however, can lead to an overall increase in the risk of developing cancer. Accordingly, several studies have outlined the involvement of NOP14 in cancer progression and metastasis, and vioprolide A has been demonstrated to exert anti-cancer effects in vitro. However, the impact of vioprolide A and NOP14 on the endothelium has been neglected so far, although endothelial cells are crucially involved in inflammation and angiogenesis under both physiological and pathological conditions.
In the present study, the effect of vioprolide A on inflammatory and angiogenic actions was analysed. In vivo, the laser-induced choroidal neovascularization (CNV) assay outlined a strong inhibitory effect of vioprolide A on both inflammation and angiogenesis. Furthermore, intravital microscopy of the cremaster muscle in mice revealed that vioprolide A strongly impaired the TNF-induced leukocyte-endothelial cell interaction in vivo.
In further experiments, the specific effect of vioprolide A on activation processes of primary human umbilical vein endothelial cells (HUVECs) was examined. According to the in vivo results, vioprolide A decreased the leukocyte-endothelial cell interaction in vitro through downregulating the cell surface expression and total protein expression of ICAM-1, VCAM-1 and E-selectin. Vioprolide A evoked its anti-inflammatory actions via a dual mechanism: On the one hand, the expression of pro-inflammatory proteins, including TNFR1 and cell adhesion molecules, was lowered through a general downregulation of de novo protein synthesis. The inhibition of de novo protein synthesis is most likely linked to the interaction with and inhibition of NOP14 by vioprolide A in HUVECs. On the other hand, the natural product prevented the nuclear translocation and promotor activity of the pro-inflammatory transcription factor NF-ĸB. Interestingly, most anti-inflammatory compounds that interfere with the NF-ĸB signaling pathway prevent NF-ĸB nuclear translocation through recovering or stabilizing the inhibitory IĸB proteins. Vioprolide A, however, decreased rather than stabilized the IĸB proteins and prevented NF-ĸB nuclear translocation through interfering with its importin-dependent nuclear import. By performing siRNA-mediated knockdown experiments, we evaluated the role of NOP14 in inflammatory processes in HUVECs and could establish a causal link between the anti-inflammatory actions of vioprolide A and the deletion of NOP14.
Besides exerting anti-inflammatory actions, we found that vioprolide A potently decreased the angiogenic key features proliferation, migration and sprouting of endothelial cells. Mechanistically, the natural product interfered with pro-angiogenic signaling pathways. Vioprolide A reduced the protein level of growth factor receptors, including VEGFR2, which is the most prominent receptor responsible for angiogenic signaling in endothelial cells. This effect was based on the general inhibition of de novo protein synthesis by the natural product. Downregulation of growth factor receptors impaired the activation of downstream signaling intermediates, including the MAPKs ERK, JNK and p38. To our surprise, however, activation of Akt, another downstream effector of VEGFR2, was increased rather than decreased. Furthermore, vioprolide A lowered the nuclear translocation of the transcriptional coactivator TAZ, which is regulated by the evolutionary conserved Hippo signaling pathway. Interestingly, however, and in contrast to NF-ĸB, TAZ nuclear translocation in mammalian cells seems to be independent of importins. In this context, we found that vioprolide A reduced both the protein level and nuclear localization of MAML1, which is needed to retain TAZ in the nucleus after its successful translocation.
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