Biologische Hochschulschriften (Goethe-Universität; nur lokal zugänglich)
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ß1-integrins are essential for angiogenesis but the mechanisms regulating integrin function in endothelial cells (EC) and their contribution to angiogenesis remain elusive. BRAG2 is a guanine nucleotide exchange factor for the small Arf-GTPases Arf5 and Arf6. The role of BRAG2 in EC and angiogenesis and the underlying molecular mechanisms remains unclear. siRNA-mediated BRAG2-silencing reduced EC angiogenic sprouting and migration. BRAG2-siRNA-transfection differentially affected a5ß1- and aVß3-integrin function: specifically, BRAG2-silencing increased focal/fibrillar adhesions and EC adhesion on ß1-integrin-ligands (fibronectin and collagen), while reducing the adhesion on the aVß3-integrin-ligand, vitronectin. Consistent with these results, BRAG2-silencing enhanced surface expression of a5ß1-integrin, while reducing surface expression of aVß3-integrin. Mechanistically, BRAG2 mediated recycling of aVß3-integrins and endocytosis of ß1-integrins and specifically of the active/matrix bound a5ß1-integrin present in fibrillar/focal adhesions (FA), suggesting that BRAG2 contributes to the disassembly of FA via ß1-integrin-endocytosis. Arf5 and Arf6 are promoting downstream of BRAG2 angiogenic sprouting, ß1-integrin-endocytosis and the regulation of FA. In vivo silencing of the BRAG2-orthologues in zebrafish embryos using morpholinos perturbed vascular development. Furthermore, in vivo intravitral injection of plasmids containing BRAG2-shRNA reduced pathological ischemia-induced retinal and choroidal neovascularization. These data reveals that BRAG2 is essential for developmental and pathological angiogenesis by promoting EC sprouting through regulation of adhesion by mediating ß1-integrin internalization and associates for the first time the process of ß1-integrin endocytosis with angiogenesis.
The biogenesis and function of photosynthetically active chloroplasts relies on the import of thousands of nuclear encoded proteins via the coordinated actions of two multiprotein translocon machineries in the outer and inner envelope membrane. Trafficking of preproteins across the soluble compartment of InterMembrane Space (IMS) is currently envisioned to be facilitated by an IMS complex composed of outer envelope proteins Toc64 and Toc12, a soluble IMS component, Tic22 and an IMS-localized Hsp70. Among them, currently Tic22 is the only component that stands undisputed in terms of its existence. Having two closely related homologs in A. thaliana, their biochemical and functional characterization was still lacking. A critical analysis of Tic22 knockout mutants displayed growth phenotype reminiscent of ppi1, the mutant of Toc33. However, both the genes have similar expression patterns with no clear preference for photosynthetic or nonphotosynthetic tissues, which explained the absence of a detectable phenotype in single mutants. In addition, transgenic complementation study with either of the homolog affirmed the identical localization of both proteins in the IMS which characterizes the two homologs as functionally redundant. Based on the pale-yellow phenotype exhibited by the double mutant plants, an attempt to analyze the import capacity of a stromal substrate in the double mutant revealed threefold reduction when compared to wild-type acknowledging the essential role of Tic22 in the import mechanism. Initially, Tic22 was identified together with another protein, Tic20, which has been heavily discussed as a protein conducting channel in the inner membrane. Despite being characterized, in A. thaliana, two out of four homologs of Tic20 are differentially localized with one being additionally localized in mitochondria and the other, exclusively residing in the thylakoids.
According to in silico analysis, for all the Tic20 proteins, a four-helix transmembrane topology was predicted. Accordingly, its topology was mapped by employing the recently established selfassembling GFP-based in vivo experiments. Astonishingly, the expression of one of the inner envelope localized Tic20 homolog enforces inner membrane proliferation affecting the shape and organization of the membrane. Therefore this study focuses on analyzing the effects of high envelope protein concentrations on membrane structures, which together with the existing results, an imbalance in the lipid to protein ratio and a possible role of signaling pathway regulating membrane biogenesis is discussed.
Retroviral vectors are powerful tools in clinical gene therapy as they integrate permanently into the target cell genome and thus guarantee long-term expression of transgenes. Therefore, they belong to the most frequently used application platforms in clinical gene therapy involving a broad range of different target cells and tissues. However, stable genomic integration of retroviral vectors can be oncogenic, as reported in several animal models and in clinical trials. In particular, γ-retroviral vectors, which derive from naturally mutagenic γ-retroviruses, integrate semirandomly into the host genome with regard to the target sequence, but have a preference for regions of active transcription and regulatory elements of transcriptionally active genes. The integration can result in overexpression of adjacent genes or disruption of ‘target’ gene expression. Moreover, γ-retroviral integration can cause modified transcripts and proteins through alternative or aberrant splicing or through premature termination of transcription.
Initially, the event of insertional mutagenesis and subsequent induction of leukemia by the genotoxicity of a γ-retroviral vector was described in a mouse model after genetic modification of hematopoietic stem cells (HSCs). Vector-related activation and overexpression of the oncogene ecotropic viral integration site-1 (Evi1) fostered clonal outgrowth and leukemogenesis. Additional genotoxic events of γ-retroviral vectors were observed in clinical HSC gene therapy trials for X-linked severe combined immune deficiency (SCID-X1), chronic granulomatous disease (X-CGD), and Wiskott-Aldrich Syndrome (WAS). But, genotoxicity induced by γ-retroviral vectors has never been described in clinical gene therapy trials involving adoptive transfer of genetically modified mature T lymphocytes. This fact is surprising, since T cells are long-lived and have a high capacity of self-renewal.
In a previous study, the susceptibility towards oncogenic transformation of mature T cells and HSCs after genetic modification was compared. It could be demonstrated that T-cell receptor (TCR)-polyclonal mature T cells are far less prone to transformation after γ-retroviral transfer of (proto-)oncogenes in vivo than HSCs. Additional experiments revealed that TCR-oligoclonal (OT-I and P14) mature T cells are transformable in the same setting and give rise to mature T-cell lymphomas (MTCLs).
In the present thesis, the susceptibility of mature T cells towards insertional mutagenesis was investigated. Within the first part of the thesis, retroviral integration sites (RISs) from 33 murine MTCLs were retrieved and subsequently analyzed in terms of integration pattern, detection of common integration sites (CIS) and gene ontology (GO). As these bioinformatic results demonstrated that insertional mutagenesis most likely contributed to mature T-cell lymphomagenesis, the susceptibility of mature T cells was directly assessed in a mouse model. Therefore, murine TCR-oligoclonal OT-I T cells were transduced with an enhanced green fluorescent protein (EGFP) encoding γ-retroviral vector and gene-modified T cells were transplanted into RAG1-/- mice. After 16 months, including one round of serial transplantation, a case of MTCL emerged. Tumor cells were characterized by CD3, CD8, TCR and ICOS expression. Integration site analysis via ligation-mediated polymerase chain reaction (LM-PCR) revealed a proviral insertion in the Janus kinase 1 (Jak1) gene. Subsequent overexpression of Jak1 could be demonstrated on transcriptional and protein level. Furthermore, T-cell lymphoma cells were characterized by an activated Jak/STAT-pathway as signal transducer and activator of transcription 3 (STAT3) was highly phosphorylated. The overexpression of Jak1 was causally implicated in tumor growth promotion as specific pharmacological inhibition of Jak1 using Ruxolitinib significantly prolonged survival of mice transplanted with these Jak1-activated tumor cells. A concluding systematic metaanalysis of available gene expression data on human mature T-cell lymphomas/leukemias confirmed the relevance of Jak/STAT overexpression in sporadic human T-cell tumorigenesis.
This was the first reported case of an insertional mutagenesis event in mature T cells in vivo. Thus, the results obtained in this thesis underline the importance of long-term monitoring of genetically modified T cells in vivo and the evaluation of vector toxicology and safety in T-cell based gene therapies. In particular, the transduction of T cells with a recombinant TCR or CAR (chimeric antigen receptor) bears a risk enhancement, as normal T-cell homeostasis is perturbed besides the general risk of insertional mutagenesis.
Ribosome biogenesis is best understood in the yeast Saccharomyces cerevisiae. In human or mammalian ribosome biogenesis, it has been shown that basic principles are conserved to yeast, but additional features have been reported. Our understanding about the interplay between proteins and RNA in human ribosome biogenesis is far from complete.
The present study focused on the analysis of the human ribosome biogenesis co-factors PWP2, EMG1 and Exportin 5 (XPO5) to understand the degree of conservation of ribosome biogenesis. The proteins were characterized in respect to their localization and interaction partners. For the early 90S co-factor, PWP2, it was possible to pull down and identify the human UTP-B complex with MALDI mass spectrometry. Besides the orthologues of the members of this complex known in yeast (TBL3, WDR3, WDR36, UTP6, UTP18), the human UTP-B complex is not only conserved from yeast to humans, but contains also additional components, like the DEAD-box RNA helicase DDX21, which lacks a yeast orthologue. DDX21 was localized to the nucleus, assembled to the native UTP-B complex and co-precipitated also with other UTP-B complex members, presumably extending the functions of this complex in ribosome biogenesis.
This phenomenon was also observed for the 90S co-factor EMG1, an RNA methyltransferase, whose mutant form causes the Bowen-Conradi syndrome, if aspartic acid is mutated to glycine at position 86. This study revealed that the mutant, EMG1-D86G, clearly lost its nucleolar localization and co-precipitated to histones for unknown reasons.
A participation of the nuclear export receptor XPO5 in human ribosome biogenesis was shown in this study. Pulldown analysis, sucrose density gradients and UV crosslinking and analysis of cDNAs of XPO5 revealed the involvement of XPO5 in pre-60S subunit maturation. Moreover, besides the known pre-miRNAs and tRNAs as substrates for nuclear export, XPO5 crosslinked to snoRNAs. XPO5 was further demonstrated to interact with the miRNA Let-7a, which has an important regulatory function for MYC, a transcription factor required for ribosome biogenesis.
All results support a role of these proteins in human ribosome biogenesis and therefore it seems that the biogenesis of ribosomes in human cells requires additional components, like DDX21 and XPO5.
In the absence of apparent mutations, alteration of gene expression patterns represents the key mechanism by which normal cells evolve to cancer cells.
Gene expression is tightly regulated by posttranscriptional processes. Within this context, RNA-binding proteins (RBPs) represent fundamental factors, since they control mechanisms, such as mRNA-stabilization, -translation and -degradation. Human antigen R (HuR) was among the first RBPs that have been directly associated to carcinogenesis. HuR modulates the stability and translation of mRNAs which encode proteins facilitating various ‘hallmarks of cancer’, namely proliferation, evasion of growth suppression, angiogenesis, cell death resistance, invasion and metastasis. Furthermore, it is well established that tumor-promoting inflammation contributes to tumorigenesis. In this process, monocytes are attracted to the site of the tumor and educated towards a tumor-promoting macrophage phenotype. While HuR has been extensively studied in various tumor cell types, little is known about HuR in hepatocellular carcinoma (HCC). Thus, the aim of my work was to characterize the contribution of HuR to the development of cancer characteristics in HCC. I was particularly interested to investigate if HuR facilitates tumor-promoting inflammation, since a role for HuR has not been described in this context. To this end, I depleted HuR in HepG2 cells (HuR k/d) and used a co-culture model of HepG2 tumor spheroids and infiltrating monocytes to study the impact of HuR on the tumor microenvironment. I could show that depletion of HuR resulted in the reduction of cell numbers. Additionally, the expression of proliferation marker KI-67 and proto-oncogene c-Myc was reduced, supporting a proliferative role of HuR. Furthermore, exposure to cytotoxic staurosporine elevated apoptosis in HuR k/d cells compared to control cells. Concomitantly, the expression of the anti-apoptotic mediator B-cell lymphoma protein-2 (Bcl-2) was markedly reduced in the HuR k/d cells, pointing to an involvement of HuR in cell survival processes.
Accordingly, a pro-survival function of HuR was also observed in tumor spheroids, since HuR k/d spheroids exhibited a larger necrotic core region at earlier time points and showed elevated numbers of dead cells compared to control (Ctr.) spheroids. Interestingly, HuR k/d spheroids isplayed reduced numbers of infiltrated macrophages, suggesting that HuR contributes to a tumor-promoting, inflammatory microenvironment by recruiting monocytes/macrophages to the tumor site. Aiming at identifying HuR-regulated factors responsible for the recruitment of monocytes, I found reduced levels of the chemokine interleukin 8 (IL-8) in supernatants of HuR k/d spheroids, supporting a critical involvement of HuR in the chemoattraction of monocytes. Analyzing supernatants of co-cultures of macrophages and HuR k/d or Ctr. spheroids revealed additional differences in chemokine secretion patterns. Interestingly, protein levels of many chemokines were elevated in co-cultures of HuR k/d spheroids compared to control co-cultures. Albeit enhanced chemokine secretion was observed, less monocytes are recruited into HuR k/d spheroids, further underlining the necessity of HuR in cancer related monocyte/macrophage attraction and infiltration. Differences between chemokine profiles of mono- and co-cultured spheroids could be attributable to changes in spheroid-derived chemokines as a result of the crosstalk with the immune cells. Provided the chemokines originate from monocytes/macrophages, the different secretion patterns suggest that HuR contributes to the modulation of the functional phenotype of infiltrated macrophages, since the tumorenvironment is critically involved in the shaping of macrophage phenotypes. Regions of low-oxygen (hypoxia) represent another critical feature of tumors. Therefore, I next analyzed the impact of HuR on the hypoxic response. Loss of HuR attenuated hypoxia-inducible factor (HIF) 2α expression after exposure to hypoxia, while HIF-1α protein levels remained unaltered. Considering previous results of our group, showing that HIF-2α depletion (HIF-2α k/d) resulted in the enhanced expression of HIF-1α protein, I aimed to determine the involvement of HuR in the compensatory upregulation of HIF-1α protein in HIF-2α k/d cells. I could demonstrate that not only total HuR protein levels, but specifically cytoplasmic HuR was elevated in HIF-2α depleted cells pointing to enhanced HuR activity. Silencing HuR in HIF-2α deficient cells attenuated enhanced HIF-1α protein expression, thus confirming a direct role of HuR in the compensatory upregulation of HIF-1α. This as also reflected on HIF-1α target gene expression. I further investigated the mechanism underlying the compensatory HIF-1α expression in HIF-2α deficient cells. Analyzing HIF-1α mRNA expression, I excluded enhanced HIF1-α transcription and stability to account for elevated HIF-1α expression in HIF-2α k/d cells. HIF-1α promoter activity assays confirmed the mRNA data. Furthermore, HIF-1α protein half-life was not elevated in HIF-2α k/d cells compared to control cells, indicating that HIF-1α protein stability is not altered in HIF-2α k/d cells. Analysis of the association of HIF-1α with the translational machinery using polysomal fractionation finally revealed an increased istribution of HIF-1α mRNA in the heavier polysomal fractions in HIF-2α k/d cells compared to control cells. Since augmented ribosome occupancy is an indicator for more efficient translation, I propose enhanced HIF-1α translation as underlying principle of the compensatory increase in HIF-1α protein levels in HIF-2α k/d cells. In summary, my results demonstrate that HuR is critical for the development of cancer characteristics in HCC. Future work analyzing the impact of HuR on tumor-promoting inflammation, specifically macrophage attraction and activation could provide new trategies to inhibit macrophage-driven tumor progression. Furthermore, I provide evidence that HuR contributes to the hypoxic response by regulating the expression of HIF-1α and HIF-2α. Targeting single HIF-isoforms for tumor therapy should be carefully considered, because of their compensatory regulation when one α-subunit is depleted. Thus, therapeutic strategies targeting factors such as HuR that control both α-subunits and at the same time prevent compensation might be more promising.
Cell-cell adhesion is an essential process during the development of multicellular organisms. It is based on various cellular junctions and ensures a tight contact between neighboring cells, enabling interactive exchanges necessary for morphological and functional differentiation and maintaining the homeostasis of healthy tissue organization. Two important types of cell-cell adhesions are the adherens junction (AJ) and the desmosome which link the actin cytoskeleton and intermediate filaments to cadherin-based adhesion sites. The core of these structures is composed of single-span transmembrane proteins of the cadherin superfamily which include, among other members, the classical cadherins, e.g. E-cadherin, as well as the desmosomal cadherins, e.g. desmoglein-3. The cytoplasmic domains of the desmosomal and classical cadherins enable interactions with proteins of the catenin family. Classical cadherins preferentially associate with β-catenin and p120-catenin, whereas desmosomal cadherins bind to γ-catenin and plakophilins. Intriguingly, γ-catenin, also known as plakoglobin, is so far the only protein known to be present both in the AJ and the desmosome.
In this study, we showed that the two homologous, membrane raft-associated proteins flotillin-1 and flotillin-2 associate with core proteins of the AJ and the desmosome in vitro and in vivo. In confluent human, non-malignant epithelial MCF10A cells and human skin cryosections, flotillin-2 colocalized with E-cadherin, desmoglein-3 and γ-catenin at cell-cell contact sites, whereas flotillin-1 showed barely any overlap with these proteins. In addition, we detected a colocalization of both flotillins with the actin-binding protein α-actinin in membrane ruffles in subconfluent and at cell-cell contact sites in confluent MCF10A cells as well as in human skin cryosections. The interaction with α-actinin was later shown to be flotillin-1 dependent by performing indirect GST pulldown experiments with purified α-actinin-1-GST in MCF10A cell lysates.
Since flotillin-2 strongly colocalized with cell-cell junctions, this suggested that flotillins might be found in complex with cell adhesion proteins. Thus, we performed coimmunoprecipitation experiments in murine skin lysates and various cell lines of epithelial origin, such as human breast cancer MCF7 cells, human keratinocyte HaCaT cells and primary mouse keratinocytes. These experiments demonstrated that flotillins, especially flotillin-2, coprecipitated with E-cadherin, desmosomal cadherins and γ-catenin in relation to the respective cell type and the maturation status of these cell-cell adhesion structures. However, since γ-catenin is so far the only protein known to be present in the AJ and the desmosome, we further assumed that the complex formation of flotillins with cell adhesion structures is mediated by γ-catenin. For this, we performed indirect GST pulldown experiments in MCF10A cell lysates with bacterially expressed, purified flotillin-1-GST, flotillin-2-GST and γ-catenin-GST and were able to verify the complex formation of adhesion proteins and flotillins in vitro. To further test if the interaction of γ-catenin and flotillins is a direct one, we used purified flotillin-1-GST or flotillin-2-GST and γ-catenin-MBP fusion proteins. Both flotillins directly interacted with γ-catenin in this in vitro assay. In addition, mapping of the interaction domains in γ-catenin by using GST fusion proteins carrying different parts of γ-catenin suggested that flotillins bind to a discontinuous γ-catenin binding domain which consists of a Major determinant around ARM domains 6-12, most likely with a major contribution of the ARM domain 7, and possibly including the NT part of γ-catenin.
To study the effect of flotillin depletion on cell-cell adhesion, we generated stable MCF10A cell lines in which flotillins were knocked down by means of lentiviral shRNAs. Staining of E-cadherin and γ-catenin in these cells showed that the localization at the cell-cell borders was significantly altered after flotillin-2 depletion, which pointed to a role for flotillin-2 in the formation of cell-cell adhesion structures in epithelial cells. Furthermore, isolation of detergent resistant membranes (DRMs) from these cells demonstrated that upon depletion of flotillin-2, a significant amount of E-cadherin and γ-catenin shifted into raft fractions. On the contrary, no change was detected in flotillin-1 knockdown cells. These observations point to a functional role of flotillin-2 in the regulation of raft association of cell-cell adhesion proteins. To gain more insight into the in vivo relevance of our findings, we next studied the function of flotillins in the skin of Flot2-/- knockout mice. Analysis of lysates prepared from the skin of one year old female animals revealed an increased expression of E-cadherin, desmoglein-1 and γ-catenin but not β-catenin, implicating that specific adhesion proteins are upregulated in flotillin-2 knockout skin.
Since flotillins are tightly associated with membrane microdomains we next studied the interaction of flotillin-2 with membrane cholesterol. Using the photoreactive cholesterol analog azocholestanol, we were able to show that flotillin-2 and cholesterol directly interacted. In addition, previous studies speculated that flotillin-2 interacts with cholesterol via two putative cholesterol recognition/interaction amino acid consensus (CRAC) motifs. Analysis of the flotillin-2 sequence revealed that flotillin-2 actually contains four putative CRAC motifs. However, using various flotillin-2 CRAC mutant GFP fusion proteins, we were able to show that none of the putative CRAC motifs is functional, which suggested that flotillin-2 interacts with membrane cholesterol, e.g., via posttranslational modifications, such as myristoylation and palmitoylation which were previously shown to be essential for membrane association of flotillin proteins.
Juvenile Neuronal Ceroid Lipofuscinosis (JNCL) is a rare inherited childhood neurodegenerative disease that is caused by a mutation in the gene CLN3. The function of the protein produced by the gene has remained elusive, and therefore the disease mechanism of JNCL is as of yet unknown. The disease is fatal, and no cure is currently available. We believe that simvastatin shows promise as a possible treatment. Simvastatin is well tolerated in children, and as currently no other viable, less invasive treatment for JNCL exists, at least pilot-scale clinical trials for this new off-label use of simvastatin are warranted.
The protein CLN3 has been indicated to have several different subcellular localizations and functions, but conclusive evidence about its role in cellular metabolism is lacking. It is also unclear why the mutation causes the distinct phenotype of the JNCL disease. In order to bring lucidity to the issue, we set out to identify metabolic pathways related to the phenotype of JNCL by using Multi-Epitope Ligand Cartography (MELC) and the related field of toponomics. Toponomic methods are required to process the massive amount of data generated by the MELC runs in order to extract information from them.
Our disease model of choice was the CLN3Δex7/8 knock-in mouse. To separate cause from effect, we compared embryonal wild type and mutant mouse brains to their adult counterparts. The first analyses revealed progressively abnormal Combinatorial Molecular Patterns (CMPs, an unit of toponomic data) related to cholera toxin/ganglioside 1 (Ctx/GM1), which is a membrane microdomain marker.
Cholesterol is an essential part of microdomains, so we utilized filipin staining to see if there were actual changes in cholesterol concentration and localization between healthy and diseased animals. After the disturbance in cholesterol metabolism was verified, we investigated the metabolic pathway that synthesizes cholesterol, the mevalonate pathway. Simvastatin is a drug that specifically down-regulates the mevalonate pathway. Fish oil affects lipid homeostasis and has some effects similar to those of simvastatin, and both of these drugs have previously been studied for their effects on neurodegenerative diseases. After treatment of mice with these drugs, highperformance liquid chromatography (HPLC) measurements on the brain homogenate showed a decrease in levels of farnesyl pyrophosphate (FPP) and geranyl-geranyl pyrophosphate (GGPP), products of the mevalonate pathway, confirming the effect of these drugs on the brains of the animals. Analyses of motor function of the mice further supported the notion that simvastatin had a positive effect on the condition of the diseased animals.
CMP analyses from the simvastatin treated mice showed a rescue of the Ctx/GM1 CMPs, suggesting at least a partial restoration of membrane microdomain homeostasis. Filipin staining revealed reversion of the apparent cholesterol depletion in the adult mutant mouse hippocampus by simvastatin. Interestingly, an additional effect of the treatment was found: simvastatin also affected glutamate receptor homeostasis, especially as regarding to N-methyl-D-aspartate (NMDA) and alphaamino-3-hydroxyl-5-methyl-4-isoxazole-propionate (AMPA) receptors. This finding suggested that excitotoxicity could be a part of the disease process, and pointed towards glutamate receptors as possible therapy targets. This is in line with previous studies that have shown that attenuation of AMPA receptors and L voltage-dependent channels improve the phenotype of a JNCL mouse and cell model, respectively.
Simvastatin mediates many of its effects via downregulation of the mevalonate pathway products, such as isoprenoids and cholesterol. However, simvastatin also has multiple pleiotropic effects that include suppression of excitotoxicity and granting neuroprotection. It is apparent that simvastatin treatment has a positive effect on JNCL mice, but if its effects are mediated via cholesterol (and membrane microdomains), isoprenoids (and isoprenylated proteins) or via a fully cholesterol independent mechanism remains to be solved.
In this study we have shown that with the MELC method and toponomics it is possible to approach rare diseases with confounded disease mechanisms with a hypothesis-free approach, to identify possible drug targets, and to monitor the effects of the drugs on treated individuals. This should open up a new avenue in the research of the many diseases that so far have avoided all attempts at discerning their nature.
Eine Infektion mit dem Hepatitis B Virus (HBV) kann bei 5-10 % der infizierten Erwachsenen und 70-90 % der infizierten Kinder chronisch verlaufen. Trotz einer verfügbaren Impfung gegen die Erkrankung sind heute nach Angaben der WHO weltweit etwa 350 Mio. Menschen chronisch HBV-infiziert [Lupberger and Hildt, 2007, Hollinger and Liang, 2001]. In 5-10 % der Fälle führt eine chronische Infektion zu einer Leberfibrose und Zirrhose, welche letztlich zur Ausbildung eines hepatozellulären Karzinoms (HCC) führen kann. HCCs sind die dritthäufigste karzinomassoziierte Todesursache weltweit [Blum, 2005]. Um Therapien gegen eine HBV-Infektion und das damit erhöhte Risiko einer HCC-Entstehung entwickeln zu können, müssen die einzelnen Schritte des HBV-Replikationszyklus verstanden sein. Wesentliche Schritte der frühen Infektionsphase, insbesondere der Rezeptor bzw. Rezeptorkomplex, welcher den Zelleintritt des Virus vermittelt sowie der Transport des Virusgenoms in den Zellkern, sind bisher noch unklar. Auch der Exportprozess und die Freisetzung der Viruspartikel ist bisher noch nicht im Detail verstanden. Es ist jedoch bekannt, dass die Viruspartikel unter Nutzung der zellulären ESCRT (endosomal sorting complex required for transport)-Maschinerie aus der Zelle freigesetzt werden [Lambert et al., 2007]. Auf der Suche nach Faktoren, die in diese Vorgänge involviert sind, konnte in dieser Arbeit das vesikeltransportassoziierte Protein α-Taxilin identifiziert werden. Der Einfluss von HBV auf die α-Taxilin-Bildung und seine mögliche Beteiligung am viralen Export wurden dabei näher charakterisiert. In HBV-positiven Zellen konnte in vivo und in vitro eine signifikante Steigerung der α-Taxilin-Expression nachgewiesen werden. Diese wird hierbei durch die HBV-Proteine HBx und LHBs über den Raf/Mek/Erk-Signalweg induziert [Glatzel, 2011]. Mithilfe von knockdown-Experimenten konnte beobachtet werden, dass α-Taxilin für den Export der Viruspartikel, nicht aber für den Export subviraler Partikel (SVPs) essentiell ist. Der Export der Virionen findet hierbei über das ESCRT-System statt. Den HBV-Strukturproteinen fehlen jedoch die für die Interaktion mit dem ESCRT-System essentiellen late-Domänen. Die Proteinstruktur von α-Taxilin dagegen weist diese late-Domänen auf. In dieser Arbeit konnte diese interaktionsvermittelnde Funktion von α-Taxilin zwischen dem Virus und dem ESCRT-System charakterisiert werden. Über eine Interaktion von α-Taxilin mit dem viralen LHBs-Protein auf der einen Seite und der tsg101-Komponente des ESCRT-I-Komplexes auf der anderen Seite agiert α-Taxilin als eine Art Linker zwischen dem ESCRT-System und HBV.
Darüber hinaus wurde Annexin A5 als zellulärer Interaktionspartner für α-Taxilin identifiziert [Röttger, 2011]. Es dirigiert α-Taxilin in einer Art shuttle-Funktion auf die Zellmembran suszeptibler Zellen und bindet es an deren Zelloberfläche. Diese Exposition von α-Taxilin nimmt während der Dedifferenzierung in Korrelation mit dem Suszeptibilitätsverlust primärer Hepatozyten ab. Eine Maskierung von α-Taxilin durch eine vorherige Inkubation der Zellen mit α-Taxilin-spezifischen Antikörpern konnte die Bindung und die Aufnahme der Viren inhibieren. Überexpressionsstudien bestätigten die essentielle Rezeptorfunktion von α-Taxilin. Die verstärkte Produktion von α-Taxilin führte zur Suszeptibilität der Zellen. Auch die Speziesspezifität der Bindung zwischen humanem α-Taxilin und HBV konnte in einem Co-Immunpräzipitationsexperiment mit den rezeptorbindenden Domänen von HBV, WHV und DHBV identifiziert werden.
In der vorliegenden Arbeit konnte somit zum ersten Mal eine Rezeptorfunktion von α-Taxilin bei der Aufnahme von HBV in die Wirtszelle nachgewiesen werden. Darüber hinaus schreiben die in dieser Arbeit gemachten Beobachtungen α-Taxilin eine essentielle Funktion für die Vermittlung des ESCRT-abhängigen Exports der Virionen aus der Zelle zu. Die hierbei gewonnen Erkenntnisse sind von hoher Relevanz für die weitere Erforschung der HBV-assoziierten Pathogenese und die Etablierung eines in vivo Infektions-Modells.
Der programmierte Zelltod (Apoptose) ist ein wichtiger Mechanismus zur Eliminierung von beschädigtem Gewebe und entarteten Zellen. Die Deregulierung der Apoptose führt zu zahlreichen Erkrankungen wie neuro-degenerativen Störungen und Krebs. Insbesondere in Tumoren wird der programmierte Zelltod mit Hilfe von hochregulierten, anti-apoptotischen Proteinen umgangen und es entstehen Resistenzen gegen Chemotherapien. Um innovative therapeutische Ansätze zu finden, wurden in diesem Projekt mit Hilfe eines Hefe-Survival-Screens neue, potentiell anti-apoptotische Proteine im Pankreaskarzinom identifiziert. Von den insgesamt 38 identifizierten Genprodukten wurden zwei für eine weiterführende Analyse ausgewählt.
Eins der näher untersuchten Proteine ist die Pyruvoyl-tetrahydrobiopterin-Synthase (PTS), ein wichtiges Enzym für die Biosynthese von Tetrahydrobiopterin (BH4). BH4 ist ein Kofaktor, der von mehreren Enzymen der Zelle für ihre Funktionen benötigt wird. In Zellkultur-Experimenten konnte gezeigt werden, dass eine Überexpression von PTS die Zellen vor Apoptose schützen kann, während eine Herunterregulation durch genetischen knockdown die Zellen gegenüber Apoptose-Stimuli sensibilisiert und ihr Wachstum beeinträchtigt. In Xenograft-Experimenten mit NOD/SCID-Mäusen konnte zudem gezeigt werden, dass Tumore mit einem PTS-Knockdown signifikant langsamer wachsen als die der Kontrollgruppe. Zusammengenommen deuten diese Ergebnisse auf eine Rolle von PTS bei der Apoptose-Regulation und beim Tumorwachstum hin, was das Protein zu einem attraktiven Target für die Krebstherapie macht.
Als zweites wurde ein Protein analysiert, das eine Untereinheit des respiratorischen Komplex I bildet: NDUFB5 (NADH-Dehydrogenase 1 beta Subcomplex, 5). Das besondere an diesem Protein sind die verschiedenen Isoformen, die durch alternatives Splicing zustandekommen. Eine Isoform, der die Exone 2 und 3 fehlen, wurde im Hefe-Survival-Screen identifiziert. Bei Überexpression in Zelllinien konnte sie im Gegensatz zum Volllänge-Protein die Apoptoserate reduzieren. Und auch Ergebnisse aus Versuchen mit Isoformen-spezifischem knockdown deuten an, dass hauptsächlich die verkürzte Isoform sNDUFB5 für die Regulation von Apoptose und Proliferation verantwortlich ist. Diese Beobachtungen konnten mit denselben Zellen im Xenograft-Tiermodell jedoch nicht bestätigt werden. Die Ursachen dafür blieben unklar. Zusätzlich wurden immunhistochemische Analysen von Pankreaskarzinomen und normalem Pankreasgewebe durchgeführt. Sie ergaben, dass die kurze Isoform sNDUFB5 im Tumor stark überexpremiert ist, während die Expression des Volllänge-Proteins in normalem und Tumorgewebe ähnlich hoch ausfällt. Dieser Befund macht NDUFB5 zu einem interessanten therapeutischen Target.
Die näher untersuchten Kandidaten-Gene zeigen beide Potential als neue Angriffspunkte für eine molekulare Krebstherapie. Andere in dem Hefe-Survival-Screen identifizierte Proteine wurden bereits als anti-apoptotisch und/oder in Krebszellen überexprimiert beschrieben. Diese Ergebnisse demonstrieren, dass ein funktionelles, Hefe-basiertes Screeningsystem geeignet ist, neue bisher unbekannte Proteine mit anti-apoptotischer Funktion zu identifizieren. Auch zeigen die Befunde, dass bereits bekannte Proteine weitere bisher unbekannte Funktionen wie z.B. die Inhibition von Apoptose aufweisen können. Basierend auf solchen mehrfachen Proteinfunktionen lassen sich weitere therapeutische Möglichkeiten ableiten.
Plants absorb sunlight via photosynthetic pigments and convert light energy intochemical energy in the process of photosynthesis. These pigments are mainly bound to antenna protein complexes that funnel the excitation energy to the photosynthetic reaction centres. The peripheral antenna of plant photosystem II (PSII) consists of the major light-harvesting complex of PSII (LHC-II) and the minor LHCs CP29, CP26 and CP24. Light intensity can change frequently and plants need to adapt to high-light conditions in order to avoid photodamage. When more photons are absorbed than can be utilised by the photosynthetic machinery, excessive excitation energy is dissipated as heat by short-term adaptation processes collectively known as non-photochemical quenching (NPQ). A decrease in PSII antenna chlorophyll (Chl) fluorescence yield and a reduction in the average Chl fluorescence lifetime are associated with NPQ. The main component of NPQ is the so-called energy-dependent quenching (qE), and it is triggered by the rapid drop in thylakoid lumenal pH resulting from the plant’s photosynthetic activity. This process is thought to take place at the PSII antenna complexes, which therefore not only capture and transfer light energy but are also involved in balancing the energy flow. The decrease in lumenal pH acivates the enzyme violaxanthin de-epoxidase (VDE), which converts the xanthophyll violaxanthin (Vio) into zeaxanthin (Zea) in the xanthophyll cycle. In addition, the PSII subunit PsbS was discovered to be essential for qE by screening qE-deficient Arabidopsis thaliana mutants. This membrane protein is considered a member of the LHC superfamily, which also includes LHC-II and the minor LHCs. Previous studies on PsbS isolated either from native source or refolded in vitro have produced inconsistent results on its pigment binding capacity. Interestingly, a pH-dependent change in the quaternary structure of PsbS under high light conditions has been reported. This observed dimer-tomonomer transition very likely follows the protonation of lumenal glutamates upon the drop in pH and is accompanied by a change in PSII supercomplex localisation. PsbS dimers are preferentially found in association with the PSII core, whereas PsbS monomers co-localise with LHC-II.Despite the identification of !pH, Zea and PsbS as key players in qE, both the nature of the quencher(s) as well as the underlying molecular mechanism leading to excess energy dissipation still remain unknown. Several models have been put forward to explain the reversible switch in the antenna from an energy-transmitting to a quenched state. Proposals include a simple pigment exchange of Vio for Zea, and aggregation or an internal conformational change of LHC-II. Charge transfer (CT)quenching in the minor LHCs or quenching by carotenoid dark state (Car S1)-Chl interactions have also been suggested. However, none of these qE models has so far been capable of accommodating all the physiological observations and available experimental data. Most importantly, the function of PsbS remains an enigma. A recent qE model suggested that monomerisation of PsbS enables the protein to transiently bind a carotenoid and form a quenching unit with a Chl of a PSII LHC. In view of the various proposed qE mechanisms, this thesis aimed at understanding the interplay of the different qE components and the contribution of the PSII subunits LHC-II, the minor LHCs and PsbS to qE. The initial approach was to investigate the properties of the PSII subunits in the most simple in vitro model system, namely in detergent solution. For this purpose, LHC-II was isolated either from native source or refolded from recombinantly produced protein. Investigation of the minor LHCs and PsbS required heterologous expression and refolding. In addition, experiments were performed on aggregated LHC-II. Aggregates of LHC-II have been used as a popular model system for qE because they exhibit highly quenched Chl fluorescence. At the final stage of this doctoral work, a more sophisticated model system to approximate the thylakoid membrane was developed by reconstitution of the PSII subunits LHC-II and PsbS into liposomes. This system not only allowed for investigation of these membrane proteins in their native environment, but also for mimicking the xanthophyll cycle by distribution of Zea within the membrane as well as !pH by outside buffer exchange. The role of Zea in qE was first investigated with detergent solubilised antenna proteins. The requirement of this xanthophyll for qE is well-known, but the specific contribution to the molecular quenching mechansim is unclear. Previous work had shown that replacement of Vio for Zea in LHC-II was not sufficient to induce Chl fluorescence quenching in Zea-LHC-II, as suggested by the so-called molecular gearshift mechanism. However, by means of selective two-photon excitation spectroscopy, an increase in electronic interactions between Car S1 and Chls was observed for LHC-II upon lowering the pH of the detergent buffer. Electronic Car S1-Chl coupling became even stronger when Zea-LHC-II was probed. The extent of Car S1-Chl coupling correlated directly with the extent of Chl fluorescence quenching, in a similar way as observed previously in live plants under high-light conditions. However, very similar results were obtained with LHC-II aggregates. This implied that the increase in electronic interactions and fluorescence quenching was independent of Zea and low pH. Further experiments on aggregates of LHC-II Chl mutants indicated that the targeted pigments were also not essential for the observed effects. It is proposed that the same molecular mechanism causes an increase in electronic Car S1-Chl interactions and Chl fluorescence quenching in Zea-LHC-II at low pH as well as in aggregated LHC-II. Most likely, surface exposed pigments form random quenching centres in both cases. On the other hand, it was possible that Zea could act as a direct quencher of excess excitation energy in the minor LHCs. However, enrichment of refolded CP29, CP26 and CP24 with Zea did not lead to a change in the Chl excited state lifetime. Formation of a carotenoid radical cation, previously implied in CT quenching, was also not observed, although artificial generation of such a radical cation was principally possible as shown for CP29. During the course of this work, a study reporting the formation of Zea radical cations in minor LHCs was published. Therefore, Zea-enriched minor LHCs were again investigated on the experimental apparatus used in the reported study. Indeed, the presence of at least one carotenoid radical cation for each minor complex was detected. It is suggested that either the preparation method of incubating the refolded minor LHCs with Zea in contrast to refolding the complexes with only Zea and lutein causes the observed differences or that the observed spectral radical cation signatures are due to experimental artifacts. While the experiments with LHC-II and the minor LHCs gave useful insights into the putative qE mechanism, the quencher site and the mode of action of Zea could still not be unambiguously identified. Most importantly, these studies could not explain the function of the qE keyplayer PsbS. Therefore, the focus of the work was shifted to PsbS protein production, purification and characterisation. In view of inconsistent reports on the pigment binding capacity of this PSII subunit, refolding trials with and without photosynthetic pigments were conducted. The formation of a specific pigmentprotein complex typical for other LHCs was not observed and neither was the earlier reported “activation” of Zea for qE by binding to this protein. Nevertheless, PsbS refolded without pigments displayed secondary structure content in agreement with previous studies, indicating pigment-independent folding. Reconstitution of pigmentfree, refolded PsbS into liposomes confirmed that the protein is stable in the absence of pigments. Zea distributed in PsbS-containing liposomes also showed no spectral alteration that would indicate its “activation”. With the ability to reconstitute PsbS, it was then possible to proceed to modelling qE in a proteoliposome system. For this purpose, PsbS was co-reconstituted with LHC-II, which has been reported to interact with PsbS. One-photon excitation (OPE) and two-photon excitation (TPE) spectroscopy measurements were performed on LHC-II- and LHC-II/PsbS-containing liposomes. This enabled both quantification of Chl fluorescence quenching as well as determination of the extent of electronic Car S1-Chl interactions. The effect of Zea was investigated by incorporating it in the proteoliposome membrane. It was shown that Zea alone was not able to induce significant Chl fluorescence quenching when only LHC-II was present. However, when LHC-II and PsbS were co-reconstituted, pronounced Chl fluorescence quenching and an increase in electronic Car S1-Chl interactions were observed and both effects were enhanced when Zea was present. Western blot analysis indicated the presence of a LHC-II/PsbS-heterodimer in these proteoliposomes. In addition to the OPE and TPE measurements, the average Chl fluorescence lifetime was determined in detergent-free buffer at neutral pH and directly after buffer exchange to low pH. No significant changes in the average lifetime were observed for LHC-II proteoliposomes when either Zea was present or after exchange for low pH buffer. This indicated that Zea alone cannot act as a direct quencher, which concurs with the OPE measurements. Moreover, the complex was also properly reconstituted as no aggregation or significant Chl fluorescence quenching were observed. The average lifetime was not significantly affected in LHC-II/PsbS-proteoliposomes, independent of Zea or pH. However, a shortlived component in the presence of a long-lived component was not resolvable with the time resolution of the fluorescence lifetime apparatus.
Implications for qE model systems and the in vivo quenching mechanism are discussed based on the experiments in detergent solution, on LHC-II aggregates and with the proteoliposome model system.