Biologische Hochschulschriften (Goethe-Universität)
Refine
Year of publication
- 2018 (51) (remove)
Document Type
- Doctoral Thesis (51)
Has Fulltext
- yes (51) (remove)
Is part of the Bibliography
- no (51)
Keywords
- vascular endothelial cells (2)
- Aptamere (1)
- Arzneimittel (1)
- Arzneimittelanalogon (1)
- Autism Spectrum Disorder (1)
- Biologie (1)
- CNV 16p11.2 (1)
- Cell-free Protein Synthesis (1)
- FVIII (1)
- Ferroptosis (1)
Institute
- Biowissenschaften (25)
- Biochemie, Chemie und Pharmazie (23)
- Pharmazie (2)
- Informatik und Mathematik (1)
Role of npas4l and Hif pathway in endothelial cell specification and specialization in vertebrates
(2018)
Cardiovascular development requires two main steps, vasculogenesis and angiogenesis. During vasculogenesis, angioblasts, the precursors of endothelial cells (ECs), specify from the mesoderm and coalesce to form the axial vessels of the vertebrate embryo. Many questions regarding the transcriptional waves initiating and sustaining angioblast specification are still unanswered. The identity of cloche, a gene essential for EC differentiation in zebrafish, was only recently discovered by our group, and very little is known about its upstream regulators or its molecular mechanism of action. I described the molecular players involved in orchestrating npas4l expression, upstream of angioblast specification. By using genetic models and chemical treatments, I identified FGF-Erk axis and BMP signaling to be involved in npas4l regulation. I also showed that eomesa is a potent inducer of npas4l expression. In addition, in vitro experiments indicated that murine Eomes promotes EC specification, acting upstream of Etv2 and Tal1. Using a combination of gain-of-function and loss-of-function models for npas4l, I identified primary and secondary downstream effectors of npas4l. I showed that Npas4l binding sites are present in the promoter of genes involved in hematoendothelial specification, such as tal1, lmo2 and etv2. Importantly, I reported that npas4l is sufficient and necessary to promote the EC specification program. By performing a combined analysis of the developed datasets, I recovered putative genes with a potential role in EC specification. One of the most promising candidates was tspan18b. I generated a mutant allele for tspan18b and observed angiogenic defects in tspan18b-/- embryos, confirming a role for this gene in zebrafish cardiovascular development. I showed that Npas4l binds etv2 promoter in zebrafish. In mammalian embryonic stem cells, however, Etv2 promoter is bound by HIF-1α, a transcription factor homolog to Npas4l. Interestingly, Eomes knockdown in vitro lead to a significant reduction of Hif-1α expression. To test the function of Hif-1α in vivo, I took advantage of a murine loss-of-function model.
Hif-1α mouse mutant embryos exhibit a significant decrease in Etv2 expression, when compared with WT siblings. These data suggest a model where mammals lost npas4l during evolution and HIF-1α acquired a new function, replacing npas4l role in EC specification. I compared the phenotype of Hif-1α mouse mutant with zebrafish hif-1α loss-of- function models. Importantly, zebrafish hif-1α mutant did not show defects in vasculogenesis or EC specification, but in EC specialization, during HSC development. I showed that hypoxia is a potent inducer of HSC formation, and hif-1α as well as hif-2α act upstream of notch1, vegfaa and evi1 in hemogenic endothelial specification.
Conclusions
In this work, I explored the molecular mechanisms underlying EC specification in vertebrates, analyzing the role of bHLH-PAS transcription factors in this biological process. I identified the upstream regulators and the downstream effectors of npas4l, describing a novel role for tspan18b in zebrafish cardiovascular development. Npas4l is a transcription factor necessary and sufficient for angioblast differentiation in zebrafish, but the gene was lost in the mammalian lineage. hif-1α and hif-2α, paralogous genes of npas4l, are involved in the establishment of EC heterogeneity and specifically in the specification of hemogenic endothelium in zebrafish. Murine Hif-1α, however, is responsible for Etv2 regulation, indicating a role for hypoxia inducible factor in initiating the EC specification program in mouse, similarly to npas4l function in zebrafish.
The endoplasmic-reticulum-associated protein degradation pathway ensures quality control of newly synthesized soluble and membrane proteins of the secretory pathway. Proteins failing to fold into their native structure are processed in a multistep process and finally ubiquitinated and degraded by the proteasome in order to protect the cell from proteotoxic stress. My thesis covers structural as well as functional studies of various protein components that constitute the protein complexes that are responsible for this process.
One sub-project addressed the mechanism of glycan recognition by Yos9 as part of the ERAD substrate selection. NMR solution structures of the mannose-6-phosphate homology (MRH) domain of Yos9 both in a free and glycan bound conformation reveal a gripping movement of loop regions upon binding of correctly processed glycan structures.
The main projects focused on revealing the mechanism of efficient ubiquitin chain assembly by the ERAD ubiquitination machinery. This included the investigation of the role of the ERAD components Cue1 and Ubc7 in processive ubiquitin chain formation, how ubiquitin chain conformations change during elongation, how the conformation of a chain is impacted by interacting proteins and finally understand the activity regulation of the ERAD E2 enzyme Ubc7 by its cognate RING E3 ligases. Nuclear magnetic resonance (NMR) analysis and fluorescence-based ubiquitination assays show that the CUE domain of Cue1 contributes with its proximal binding preference as well as with its position dependent accelerating effect to efficient ubiquitin chain formation. This is required to efficiently drive degradation of substrates. Specific ubiquitin binding events dictate and coordinate the spatial arrangement of the E2 enzyme relative to the distal tip of a chain. This process can be further accelerated by RING E3 ligases that promote Ubc7 activity by more than ~20 fold via inducing allosteric changes around the catalytic cysteine. My results additionally suggest a model where Ubc7 dimerization results in proximity induced activation of the E2. This data ensures rapid diubiquitin formation that is followed by a CUE domain assisted chain elongation mechanism where Cue1 acts in an E4 like fashion.
How ubiquitin binding events can modulate the conformations of a ubiquitin chain were investigated by pulsed electron-electron double resonance (PELDOR) spectroscopy combined with molecular modeling. This shows that K48-linked diubiquitin samples a broad conformational space which can be modulated in distinct ways. The CUE domain of Cue1 uses conformational selection of pre-populated open conformations to support ubiquitin chain elongation. In contrast, deubiquitinating enzymes shift the conformational distribution to weakly or even non-populated conformations to allow cleavage of the isopeptide bond that connects adjacent ubiquitins. Ubiquitin chain elongation increases the sampled conformational space and suggests that this high conformational flexibility might contribute to efficient proteasomal recognition.
Structured illumination microscopy (SIM) is part of the super-resolution methods developed at the beginning of this century. To produce a super-resolution image SIM requires three things: 1) illumination of the sample with a periodic pattern, 2) acquisition of multiple images per plane under different pattern’s phases and orientations and 3) the processing of these images has to be carried with a reconstruction algorithm. The result of the reconstruction is an image with a resolution gain that is proportional to the frequency of the pattern (po). The typical SIM set-up uses an epi-fluorescence configuration, thus the interference angle of the beams that create the pattern is restricted by the angular aperture of the objective. Under this restriction the maximum value of po is given by the cut-off frequency of the objective lens and sets at 2 the maximum resolution gain of SIM under linear illumination.
In the first part of this thesis we present the implementation and characterization of the 2D-SIM set-up designed by Dr. Bo-Jui Chang (B-J. Chang et al., PNAS 2017), this design exploits the concept introduced by light-sheet microscopy, i.e. separation of illumination and detection paths to obtain resolution gains larger than the usual two-fold (Chapter 3). The set-up is named coherent structured illumination light-sheet based fluorescence microscopy (csiLSFM) and it consists of a triangular array of three objectives, such that two are used for illumination and one for detection. With the independent illumination arms is possible to interfere two coherent light-sheets at angles beyond the angular aperture of the detection lens, attaining the maximum interference angle of 180° when the light-sheets counter-propagate. This condition delivers a pattern with a po 1.4 times larger than the cut-off frequency (ωo), hence our set-up provides generic resolution gains of 2.4.
The extraction of the high spatial frequencies that produce the resolution gain in the csiLSFM is a challenge due to a low pattern modulation. The low modulation inherently arises because the frequency associated to the pattern period lies beyond the cut-off frequency of the detection lens. To overcome this challenge we developed a filtering strategy that facilitates the withdrawal of information from a SIM data set, simultaneously the proposed filtering process optimizes the reconstruction algorithm by reducing the periodic artifacts that are recurrent in SIM images. In this same chapter we also performed an spectral analysis of the artifacts and determined that they originate from irregularities in the power spectrum that occur due to the partial or total lack of certain spatial frequencies (fig.4.2 and 4.3), our reconstruction reduces this information drops and diminishes the artifact occurrence. The relevance of our reconstruction pipeline is that it delivers a standardized process to enhance the SIM image in a current context in which the commonly used reconstruction algorithms employ empirical tuning to improve it (fig.4.13). Moreover, the pipeline is applicable to the csiLSFM data and also to images acquired with any other 2D-/3D-SIM set-up (fig.4.10 and 4.11).
The processing of various image data sets acquired with the csiLSFM exposed us to the question of how low the modulation of the illumination pattern can be before no super-resolution frequencies can be extracted. Answering this question is important to guarantee that the SIM data contains enough spatial frequencies to provide significant resolution gains. Thus in chapter 5 we developed a quantitative metric to indirectly determine the pattern modulation from the SIM data and find its critical value to use it as evaluation criterion. We called this metric the quality factor (Q-factor) and it represents the normalized strength (amplitude) of the extracted frequencies respect to the Gaussian noise contained in the images. Through simulations we estimated that Q=0.11 is a critical value and a SIM data set requires this as minimum value is to deliver a significant resolution gain. Q works then as an assessment tool for classifying SIM data as optimal or sub-optimal, i.e. Q≥0.11 or Q<0.11. We demonstrated such application with data acquired in various SIM commercial set-ups to prove its feasibility in the field (fig.5.6-5.11)
As mentioned at the beginning of this abstract SIM requires a specialized set-up and a processing algorithm to produce super-resolution images. This thesis contributes to these two areas in the following aspects: first, in its linear version a structured illumination microscope is highly associated to a 2-fold resolution gain. Here we demonstrated the possibility of extending this gain to 2.4 using our custom set-up the csiLSFM. Second, a reconstructed SIM image is prone to artifacts due to the mathematical process it undergoes, here we analyzed the artifact sources and identified them with drops of spatial information in the reconstructed spectrum, based on these conclusions we designed a processing pipeline to facilitate the extraction of spatial frequencies and directly reduce artifacts. A third and final outcome of this thesis is the development and practical implementation of a quantitative index to evaluate the quality of SIM data in terms of its relevant information content (Q-factor). Accordingly, the overall contributions of this work were done in the areas of SIM set-up, SIM reconstruction procedure and SIM data evaluation.
Bei Autismus-Spektrum-Störungen (ASS) handelt es sich um genetisch komplexe Störungen mit hoher Erblichkeit. Als zugrundeliegender Pathomechanismus von ASS werden unter anderem Veränderungen der neuronalen Entwicklung diskutiert. Der Phänotyp von ASS ist definiert durch Einschränkungen in der sozialen Interaktion und Kommunikation sowie repetitives und stereotypes Verhalten. Genkopiepolymorphismen (englisch „copy number variations“/CNVs), also Deletionen oder Duplikationen einer chromosomalen Region, wurden wiederholt in Probanden mit ASS identifiziert. Hierbei ist in ASS die Region 16p11.2 mit am häufigsten von CNVs betroffen. Einige Gene aus diesem chromosomalen Abschnitt wurden bereits funktionell charakterisiert. Dennoch können die Befunde der bisherigen Einzelgenstudien nicht alle Aspekte erklären, die durch 16p11.2 CNVs hervorgerufen werden. Ziel dieser Studie war es daher, ein weiteres neuronal assoziiertes Kandidatengen dieser Region zu identifizieren und im Anschluss funktionell im Kontext der neuronalen Differenzierung zu charakterisieren.
Das SH-SY5Y Neuroblastom-Zellmodell wurde auf Transkriptom- und morphologischer Ebene auf seine Eignung als Modell für neuronale Differenzierung untersucht und bestätigt. Eine Analyse der Expressionen aller Gene der 16p11.2-Region zeigte, dass das Gen Quinolinat-Phosphoribosyltransferase (QPRT) eine vergleichsweise hohe Expression mit der stärksten und robustesten Regulierung über die Zeit aufwies. Eine de novo Deletion der 16p11.2-Region wurde in einem Patienten im Vergleich zu seinen Eltern validiert. In Patienten-spezifischen lymphoblastoiden Zelllinien derselben Familie konnten wir eine Gendosis-abhängige Expression von QPRT auf RNA-Ebene bestätigen. In SH-SY5Y-Zellen korrelierte die Expression von QPRT signifikant mit der Entwicklung von Neuriten während der Differenzierung. Um QPRT funktionell zu charakterisieren, benutzten wir drei verschiedene Methoden zur Reduktion der QPRT-Gendosis: (i) knock down (KD) durch siRNA, (ii) chemische Inhibition durch Phthalsäure und (iii) knock out (KO) über CRISPR/Cas9-Geneditierung. Eine Reduktion von QPRT durch siRNA führte zu einer schwachen Veränderung der neuronalen Morphologie differenzierter SH-SY5Y-Zellen. Die chemische Inhibition sowie der genetische KO von QPRT waren letal für differenzierende aber nicht für proliferierende Zellen. Eine Metabolitenanalyse zeigte keine Veränderungen des QPRT-assoziierten Tryptophanstoffwechsels. Gene, welche auf Transkriptomebene im Vergleich zwischen KO- und Kontrollzellen differenziell reguliert vorlagen, waren häufig an Prozessen der neuronalen Entwicklung sowie an der Bildung, Stabilität und Funktion synaptischer Strukturen beteiligt. Die Liste differenziell regulierter Gene enthielt außerdem überdurchschnittlich viele ASS-Risikogene und ko-regulierte Gengruppen waren assoziiert mit der Entwicklung des dorsolateralen präfrontalen Cortex, des Hippocampus sowie der Amygdala.
In dieser Studie zeigten wir einen kausalen Zusammenhang zwischen QPRT und der neuronalen Differenzierung in vitro sowie einen Einfluss von QPRT auf die Regulation von ASS-assoziierten Genen und Gen-Netzwerken. Funktionell standen diese Gene im Kontext mit synaptischen Vorgängen, welche durch Veränderungen zu einem Exzitations-Inhibitions-Ungleichgewicht und letztendlich zum Zelltod von Neuronen führen können. Unsere Ergebnisse heben in Summe die wichtige Rolle von QPRT in der Krankheitsentstehung von ASS, insbesondere in Trägern einer 16p11.2 Deletion, hervor.
Smut fungi (Ustilaginomycotina) were previously defined as plant parasites that produced blackish or brownish masses of teliospores in or on various organs of plants. Each teliospore germinates to form a single basidium with usually four basidiospores that subsequently grow as a saprobic, yeast-like, haploid stage. The Ustilaginomycotina are a highly diverse group with about 1,700 species in 115 different genera. All of the species were united in a single order, the Ustilaginales, in late 19th century. These teliospore producing fungi are now considered the classic smut fungi. Towards the end of the 20th century, new ideas were brought into this classification system. Most notable was the comparative work regarding the ultrastructure of septal pores and the anatomy of the interaction zones between host and parasite. This work changed the whole concept of smut fungi and their evolutionary relationships. These results were subsequently supported by molecular phylogenetic studies. Both lines of investigation led to the classification of the smut fungi into four different classes, Ustilaginomycetes, Exobasidiomycetes, Malasseziomycetes and Moniliellomycetes (see chapter 1.3).
A reliable taxonomy that reflects phylogenies needed in order to estimate the diversity and the relationships between the diverse groups of smut fungi. In the last 20 years, molecular investigations based mostly on rDNA loci, e.g. ITS (internal transcribed spacer) or LSU (large subunit), have revealed the evolutionary relationships between many taxa of smut fungi. However, there are few phylogenetic studies available for smut fungi (see chapter 1.5.1), and much work is needed to develop backbone phylogenetic trees and to resolve species complexes of many smut fungi.
This thesis reports the results of six different studies that aimed to develop new and improved tools for the phylogenetic analyses of smut fungi, and then apply these methods to selected groups of smut fungi. The first study (Kruse et al. 2017a, Chapter 3) developed a method to improve the amplification of ITS sequences of some smut fungi. Due to its high discrimination value, the ITS gene region is widely used as a barcoding locus for species delimitation of fungi. For this purpose, the general ITS primers ITS1 and ITS4 or more specific modifications, e.g. ITS1F for Ascomycota, ITS4B for Basidiomycota or M-ITS1 for smut fungi, were used. As these primer combinations often yielded unsatisfactory results, due to coamplification of other (contaminant) fungi or the host plant DNA, improvement of the amplification of the ITS region was needed. In order to design new smut specific primers for the ITS region, a representative set of several sequences of the flanking regions of the ITS region (LSU and SSU) of smut fungi, plants and other fungi were downloaded from GenBank. A set of primers was designed on this dataset. These primers were tested on a representative set of about 70 different smut genera under different PCR conditions. Finally, three different primers, one forward primer, smITS-F, and two reverse primers, smITS-R1 and -R2, were selected as the best ones. The following tests with different combinations of these primers, and also under inclusion of the M-ITS1 primer, showed only slight differences in the number of different genera that successfully amplified. But there were some differences regarding the genera that amplified. A broader test on 205 samples in 39 genera showed that the PCR efficiency of the newly designed primers was much better than the primer set ITS4/M-ITS1. With the primers designed in this study almost no non-target ITS was amplified, giving new opportunities especially for amplifying ancient DNA or DNA from older herbarium samples. However, many species groups remain unresolved by only one gene region.
The second study (Kruse et al. 2017c, Chapter 4) found new loci and suitable primers that better resolved multi-locus trees. To date, the most frequently used loci for making multi-locus trees are SSU (small subunit), LSU (large subunit) and ITS (internal transcribed spacer). While the LSU is not always sufficient to distinguish between closely related species, it is highly discriminative above the species level. In an effort to increase the phylogenetic resolution of smut phylogenies, some protein-coding genes were used, including rpb1, rpb2, and atp6 with varying success (see Chapter 2.1.2). As most of these loci are seldom used or sometimes only work on pure cultures because of their low specifity, new protein-coding loci were identified that produced reliable phylogenetic trees. Based on five available genomes, potential gene loci were filtered for possible primers. Initially, 40 different primer combinations for 14 gene loci were tested on a set of twelve different genera of smut fungi. The best candidates were selected and optimized during further tests. Finally, 22 different forward primers and 17 different reverse primers for nine different gene regions were developed, with each differentiating at least one genus of smut fungi (preferably for Ustilaginomycetes). The different primers showed varying discriminative power for different smut genera. They worked best for the Ustilaginaceae, based on the primer designed from Ustilaginomycetes genomes. These new primer sets and loci have the potential to resolve different species groups within the smut fungi and furthermore to produce reliable phylogenetic trees with high resolution. To prove their applicability, three species complexes were investigated in-depth, two from the Ustilaginomycetes and one from the Exobasidiomycetes.
...
The liver as the biggest endocrine gland of the human body plays a central role in many metabolic pathways such as detoxification, storage of carbohydrates and distribution of lipids. As the liver receives blood supply from the gut by the portal vein, liver cells are often challenged with high concentrations of nutrients and components of our commensal microbiota. Therefore, the immune system of the liver induces a tolerant state, meaning no or low inflammatory reactions to those constant stimuli. Yet, as various pathogens target the liver, the hepatic immune system also needs the capability to induce strong immune responses quickly. Chronical damage to the liver, which can be caused by alcohol, pathogens or toxins, might lead to liver cirrhosis, where the amount of functional liver tissue is decreased dramatically. This pathology can worsen and lead to acute-on-chronic liver failure, whose high mortality is due to high inflammation and multi-organ failure. Interleukin-7 is a cytokine known for its pro-survival functions especially in lymphopoiesis. However, it is also very important for maintenance of mature immune cells in the liver. As mouse experiments have demonstrated an induction of Interleukin-7 in the liver as a response to bacterial lipopolysaccharide, we aimed to characterize the role of Interleukin-7 in hepatic immunoregulation in both health and disease.
The experiments were mostly based on in vitro approaches. Induction of Interleukin-7 in liver cells was analyzed using ELISA, quantitative PCR, and Immunoblotting. Knockdown of signal transduction components was performed by siRNA transfection. Primary immune cells isolated from healthy donor buffy coat were studied for their ability to respond to Interleukin-7. Activation of downstream signal transduction was assessed by Immunoblotting. Functional consequences of Interleukin-7 signaling, such as alterations in cellular metabolism, cellular survival and endotoxin tolerance, were studied in monocyte-derived macrophages. Finally, serum concentrations of Interleukin-7 and frequencies of Interleukin-7 receptor positive immune cells were quantified in patients with compensated or decompensated liver cirrhosis or acute-on-chronic liver failure.
Interleukin-7 expression could be observed in human hepatic cell lines and primary hepatic sinusoidal endothelial cells when stimulated with IFNα or IFNγ, but not IFNλ. IRF-1 was identified as a key regulator of Interleukin-7 expression, as its transcription, translation and nuclear translocation were induced and enhanced upon IFNα or IFNγ, but not IFNλ treatment. We identified LPS-primed macrophages as innate immune target cells of Interleukin-7, which responded by an inhibitory phosphorylation of GSK3. This signal transduction led to enhanced production of pro-inflammatory cytokines and abolished endotoxin tolerance. In parallel, cellular fitness was reduced as demonstrated by reduced intracellular ATP concentration and intracellular WST-1 staining. Finally, we could identify components of the in vitro signal transduction also in liver cirrhosis patients. However, Interleukin-7 serum concentrations were significantly in liver cirrhosis patients compared to healthy controls. In addition, the frequencies of Interleukin-7 receptor positive immune cell populations differed in patients and controls.
We identify Interleukin-7 as a pro-inflammatory cytokine in hepatic immunoregulation. It is part of a cascade where its induction is regulated by type I and type II Interferons and mainly restricted by the presence of IRF1. We demonstrate the importance of Interleukin-7 also for innate immune cells, where the abolishment of endotoxin tolerance may provide an interesting strategy of liver cirrhosis patients. In addition, reduced viability of macrophages in response to Interleukin-7 is a striking contrast to the well-described survival functions in lymphocytes. The decrease of serum Interleukin-7 levels and alterations of Interleukin-7 receptor positive immune cell populations suggest an important role for Interleukin-7 also in the diseased liver. Due to the identified mechanisms of action, Interleukin-7 may be an interesting candidate for immunotherapeutic approaches of liver cirrhosis and acute-on-chronic liver failure.
Acute myeloid leukemia (AML) is a clonal malignancy of hematopoietic stem cells (HSCs) characterized by expansion of myeloid blasts in the bone marrow. It has been shown that autophagy is a degradative process, which delivers cytoplasmic components to lysosomes to prevent malignant transformation by maintaining HSC integrity. Besides its function as a bulk degradation machinery to recycle cytoplasmic components during limited energy supply, autophagy also serves as an intracellular quality control mechanism. Selective autophagy requires autophagy receptors such as p62 to specifically bridge the targeted cargos into autophagosomes. p62 is known as a central signaling hub involved in pro-oncogenic signaling pathways and autophagic degradation pathways. However, little is known about the role of p62 as a selective autophagy receptor in AML. This study aims to elucidate the precise function of p62 as an autophagy receptor in leukemia development and maintenance.
In silico analysis revealed that high p62 expression was significantly associated with poor overall survival of adult patients with de novo AML, suggesting that p62 may promote leukemia maintenance. To address the functional role of p62 in leukemia, genome editing by CRISPR/Cas9 was used to knockout p62 in four human AML cell lines. Importantly, p62 loss reduced cell proliferation in all four cell lines. This observation could be transferred to a murine leukemia cell model in which leukemic transformation of lineage-depleted bone marrow (ldMBM) cells was induced by overexpression of the human transcriptional coactivator MN1. Knockdown of p62 by shRNA in MN1-driven leukemia cells impaired proliferation and decreased colony forming ability without altering apoptosis. This indicates that p62 is crucial for leukemia proliferation in vitro. To further characterize the role of p62 in leukemia development and maintenance a murine AML transplantation model was established. Therefore, ldMBM cells isolated from WT and p62-/- mice were transduced with MN1 and transplanted into lethally irradiated mice. As expected, all mice developed fatal myeloid proliferation. Notably, p62 loss in MN1-driven leukemia significantly prolonged survival in mice and caused a more immature phenotype. Consistent with the in vitro results, ex vivo analysis of p62-/- leukemic cells displayed decreased colony-forming ability, although p62 loss did not affect composition and function of HSCs. Moreover, re-transplantation of primary MN1-driven leukemia cells attenuated leukemia progression upon p62 loss. These findings support a decisive role of p62 in leukemia development and maintenance.
To gain molecular insight into the function of p62 during myeloid transformation an interactome analysis of murine MN1-driven leukemia cells was performed. This revealed first that p62 predominantly interacts with mitochondrial proteins and second that inhibition of autophagic degradation causes accumulation of p62-bound mitochondria. This leads to the first assumption that loss of p62 may provoke mitochondrial accumulation with increasing mitochondrial damage and second that p62 may mediate degradation of mitochondria by mitophagy. Indeed, in the absence of p62, accumulation of dysfunctional mitochondria was detected by morphological changes of the mitochondria, increased mitochondrial ROS and impaired mitochondrial respiration capacity. Furthermore, induction of PINK1/Parkin-independent mitophagy revealed that loss of p62 caused impaired degradation of mitochondrial proteins and reduced translocation of damaged mitochondria into autophagosomes. Taken together, p62 is required for effective degradation of dysfunctional mitochondria by mitophagy in AML.
Due to the fact that p62 is a multifunctional protein, rescue experiments with different mutants of p62 were performed to clarify if p62-mediated mitophagy contributes to leukemia proliferation. Notably, the autophagy-deficient mutant (disabled to bind autophagosomes) reduced cell growth and colony-forming ability to the same extent as knockdown of p62, as the clustering-deficient mutant (disabled to form aggregates) displayed an intermediate phenotype. Strikingly, only the autophagy-deficient mutant failed to rescue mitophagy.
In conclusion, this study demonstrates the prominent role of p62 as a selective autophagy receptor for mitochondrial quality control which contributes to leukemia development and maintenance. Therefore, targeting selective autophagy opens new venues in the treatment of AML.
Cells within a tissue form highly complex, cellular interactions. This architecture is lost in two-dimensional (2D) cell cultures. To close the gap between 2D cell cultures and in vivo tissues, three-dimensional (3D) cell cultures such as spheroids or embryoid bodies were developed. To fully take advantage of the third dimension, imaging techniques are essential. The emerging field of "image-based systems biology" exploits the information in images and builds a connection between experimental and theoretical investigation of biological processes. Such interdisciplinary approaches strongly depend on the development of protocols to establish 3D cell cultures, innovations in sample preparation, well-suited imaging techniques and quantitative segmentation methods.
Although 3D cell cultures and image-based systems biology provide a great potential, 2D methods are still not completely replaced by 3D methods. This is mainly due to methodical and technical hurdles. Therefore, this thesis provides a significant contribution to overcome these hurdles and to further develop 3D cell cultures. I established computational and experimental methods related to 3D aggregates and investigated fundamental, cellular processes such as adhesion, growth and differentiation.
The automatic segmentation method "PAS" and "LoS" were developed in the context of this thesis. They extract essential biological properties such as the projected area or features of cell nuclei from 2D or 3D images of 3D aggregates. Both algorithms show their accuracy robustly over image data from different samples and different microscopes. In addition, the superior performance of PAS and LoS was proven in a comparison with state-of-the-art methods.
The PAS approach served as an essential basis for investigating cellular processes such as adhesion and growth which are tightly regulated to contribute to tissue integrity. These processes are involved in the formation of spheroids. The temporally resolved data of spheroid formation of three mammary epithelial cell lines revealed differences in their formation dynamics as well as in the onset of spheroid formation phases (aggregation, compaction and growth). Despite these differences, adhesion- and growth-associated proteins such as E-cadherin, actin, microtubules, and the focal adhesion kinase show similar importance in a particular phase. Notably, certain proteins (e.g. E-Cadherin) contribute differently to spheroid formation of cells from different cell types in terms of cell adhesion and growth. Overall, analyses of the individual phases of spheroid formation revealed the temporal coordination of fundamental tissue-specific processes. The results contribute to a better understanding of the maintenance and disruption of tissue integrity.
An important but yet unknown process is how cells accomplish to arrange themselves against the gravitational force to form a spheroid. Live imaging with light sheet-based microscopy provides the best solution for a temporally and in particular spatially resolved investigation of spheroid formation. Although the imaging possibilities increase with this particular microscopy technique, available sample preparation methods are rare. Therefore, I have significantly optimized "agarose beaker" as preparation method for 3D long-term imaging of spheroid formation. The data show that upward movement of the cells takes place early. This movement is initiated in the centre of the initially flat cell layer. Subsequently, the cells move from the periphery of the cell layer toward the centre. Cells rearrange within the spheroid which is followed by growth. It is very likely that 3D aggregates form by adopting an energetically favoured, spherical shape by increasing cell-cell or cell-matrix contacts.
Besides the knowledge gained from the examination of the self-assembly process in different contexts, fully formed cellular aggregates can serve as basis to investigate differentiation processes. Differentiation guide cell fate specification during early embryonic development (i.e. preimplantation) and is not fully understood yet. Due to the lack of an in vitro system for preimplantation, I have developed "blastoids". These are 3D multicellular aggregates of mouse embryonic stem cells which represent important phases of preimplantation and beyond. In qualitative and quantitative analyses, a strong similarity was proven between blastoids and the inner cell mass of in vivo mouse embryos. Further results strongly suggest that both, the cell number and the trophectoderm play a subordinate role for cell fate decision during preimplantation. Furthermore, 3D neighbourhood analyses have shown that both, blastoids and mouse embryos, do not show a random "salt-and-pepper" pattern during differentiation. Instead, they show a yet unknown local clustering of cells with identical fates, suggesting local cell interactions that influence cell fate decision. Furthermore, the data indicate that the maturation of the epiblast in the later stages of preimplantation is initiated by an interaction between cells of the epiblast and the primitive endoderm.
Using image-based systems biology, I have investigated fundamental cellular processes such as adhesion, growth and differentiation in the context of tissue integrity and early embryonic development using 3D cellular aggregates. This highly interdisciplinary work is a major contribution to 3D cell biology and demonstrates how cells bind and interact within a complex system. The main methods developed in this thesis as well as the biological findings can be used not only in further biological but also in medical and pharmacological studies. They have the potential to advance our understanding of complex biological systems and to provide new opportunities for practical applications.
In den letzten Jahren findet die Wirkung von Polyphenolen auf den Alterungsprozess oder zur Behandlung von Krankheiten immer mehr Beachtung. Das Ziel dieser Arbeit war die Aufklärung der Wirkmechanismen der Polyphenole Gossypol, Curcumin und Quercetin, um Hinweise für neue oder verbesserte Therapieansätze zu erhalten. Die dazu durchgeführten Untersuchungen lieferten folgende Ergebnisse:
1. Der Ascomycet "P. anserina" eignet sich als Modellorganismus zur Untersuchung der Wirkmechanismen verschiedener Polyphenole, da die bereits aus der Literatur bekannten Effekte auf das Überleben höherer Organismen auch in "P. anserina" beobachtet wurden.
2. Die Mitochondrienfunktion spielt auf unterschiedliche Art eine Rolle in der Kompensation von Dysfunktionen oder Stressbedingungen in der Zelle und wirkt somit positiv auf die Regulation der Lebensspanne von "P. anserina". In der "PaSod3"-Deletionsmutante wurde eine Verschiebung der mitochondrialen Atmung von einer Komplex I-abhängigen hin zu einer vermehrt Komplex II-abhängigen Atmung festgestellt. Die damit verbundene Abnahme des mitochondrialen Membranpotentials dient neben der bereits bekannten hohen Superoxid-Menge als Signal zur Mitophagie-Induktion. Auch die Anpassung der Mitochondrienfunktion durch die erhöhte Bildung von mtRSCs, wie im Falle von Gossypol oder Quercetin, kann zur Kompensation von Dysfunktionen beitragen bzw. sie abschwächen.
3. Es gibt keinen grundlegenden gemeinsamen Wirkmechanimus der drei untersuchten Polyphenole. Zwar spielt Wasserstoffperoxid bei verschiedenen Stoffen eine Rolle, aber nicht bei allen. Zusätzlich wurde gezeigt, dass Wasserstoffperoxid abhängig von der vorherrschenden Konzentration wirkt und daher auch keine Allgemeingültigkeit des Effektes vorherzusagen ist. In niedrigen Konzentrationen sorgt Wasserstoffperoxid z. B. für eine Induktion der Autophagie und damit einhergehende eine Lebensverlängerung. Im Gegensatz dazu wirken hohe Wasserstoffperoxid-Konzentrationen lebensverkürzend und lösen verschiedene Formen von Zelltod aus.
4. Die Curcumin-vermittelte Langlebigkeit wurde das erste Mal in Verbindung mit einer funktionellen Autophagie gebracht. Im Detail führt die Behandlung mit Curcumin durch eine PaSOD1-abhängige leichte Erhöhung der Wasserstoffperoxid-Menge zu einer Induktion von nicht-selektiver Autophagie. Die induzierte Autophagie ist Ursache der Lebensverlängerung durch Curcumin.
5. Gossypol wirkt in Abhängigkeit der mitochondrialen Permeabilitäts-Transitionspore bzw. von ihrem Regulator Cyclophilin D. Hierbei verstärkt die deutlich erhöhte Wasserstoffperoxid-Menge wahrscheinlich die Induktion von programmiertem Zelltod. Gleichzeitig wird eine cytoprotektive Form von Autophagie und ein scheinbar ATG-unabhängiger Abbau von Mitochondrien induziert.
6. Quercetin wirkt in "P. anserina" abhängig vom Methylierungs-Status. Untersuchungen mit Mutanten der "O"-Methyltransferase PaMTH1 ergaben die Notwendigkeit der Anwesenheit von PaMTH1 für den lebensverlängernden Effekt von Quercetin. Analysen mit dem methylierten Derivat Isorhamnetin verdeutlichten diese Abhängigkeit und zeigten zudem, dass Quercetin sowohl in der methylierten als auch unmethylierten Form Effekte hervorruft. Jedoch sind nur die Effekte des unmethylierten Quercetin unabhängig von der Lebensverlängerung und eher schädlich für die Zelle.
Die forensische Entomologie nutzt nekrophage Insekten, hauptsächlich Dipteren und ihre juvenilen Stadien, zur Schätzung der minimalen Leichenliegezeit. Dem liegt zugrunde, dass nekrophage Dipteren binnen Minuten nach dem Todeseintritt potentiell in der Lage sind, einen Leichnam zu detektieren und zu besiedeln. Das anschließende Wachstum und die Entwicklung der juvenilen Stadien erfolgt als Funktion von der Art und der Umgebungstemperatur.
Mit Hilfe von Laborstudien konnten bislang für einige forensisch relevante Fliegenarten Entwicklungsdaten erhoben werden, die eine Altersbestimmung der sich an einem Leichnam entwickelnden Larven und Puppen erlauben und so eine Schätzung der minimalen Leichenliegezeit ermöglichen. Als Nährsubstrat für Laborstudien werden tierische Gewebe verwendet. Eine Übertragbarkeit der Daten auf humanes Gewebe wurde aber bislang nicht verifiziert. In der vorliegenden Arbeit wurde das larvale Wachstum und die juvenile Entwicklungsgeschwindigkeit der forensisch relevanten Schmeißfliege Calliphora vicina (Diptera: Calliphoridae) auf humanem Muskelgewebe untersucht und mit dem Wachstum auf Schweineleber, magerem Schweinemuskelfleisch und Schweinehackfleisch verglichen. Die auf humanem Gewebe heranwachsenden Individuen waren mit bis zu 3,5 mm signifikant länger als die Individuen, die sich auf Leber und dem mageren Schweinemuskelfleisch entwickelten. Bei der Verwendung von Hackfleisch vom Schwein zeigte sich kein Unterschied. Darauf basierend wird die Empfehlung ausgesprochen, für zukünftige Entwicklungsstudien Schweinehackfleisch als Ersatz für humanes Gewebe zu verwenden.
Zahlreiche Anleitungen zur Asservierung forensisch-entomologischer Spuren empfehlen das Sammeln getrennt nach Körperregionen eines Leichnams. Dies soll eine mögliche gewebespezifische Entwicklungsrate berücksichtigen. Das für die vorliegende Arbeit durchgeführte systematische Absammeln von Fliegenlarven von 51 Leichnamen getrennt nach Körperregionen zeigte keine artspezifischen Präferenzen für bestimmte Gewebe oder Körperregionen. Das Artenspektrum entsprach größtenteils dem aufgrund von Studien an Schweinekadavern zu erwartendem Artenspektrum für Deutschland und Mitteleuropa. Insgesamt konnten 15 Schmeißfliegenarten nachgewiesen werden, von denen in der Regel mehrere gleichzeitig an einem Leichnam zu finden waren. Dies zeigt, dass ein Faktor wie interspezifische Konkurrenz in Zukunft mehr Beachtung in der Forschung erhalten sollte.
Bislang wurde in der forensischen Entomologie die minimale Leichenliegezeit durch die Untersuchung juveniler Stadien von Fliegen eingegrenzt. Eine eventuell mögliche Ausweitung dieses Zeitfensters könnte durch eine Altersbestimmung der adulten Fliegen oder der leeren Puparien gelingen. Der Nachweis, dass die dafür untersuchten Fliegen bzw. Puparien tatsächlich von dem fraglichen Leichnam stammen, war bislang nicht möglich. Die forensische relevante Schmeißfliege Lucilia sericata wurde in der vorliegenden Arbeit auf humanem Gewebe und Gewebe von elf weiteren Tierarten großgezogen. Durch die Analyse stabiler Kohlen- und Stickstoffisotope konnte ein von diesen elf Tierarten abgrenzbares humanes Isotopenprofil sowohl für die adulten Fliegen von L. sericata, als auch für ihre leeren Puparien detektiert werden. Dieses Profil spiegelte die Nahrungszusammensetzung der Wirte wider.
Die vorliegende Arbeit erhebt Daten zur Entwicklung einer forensisch relevanten Schmeißfliegenart auf humanem Gewebe, belegt das bislang lediglich am tierischen Modell erhobene Schmeißfliegeninventar als für menschliche Leichen relevant und hinterfragt die gewebespezifische Asservierungsempfehlung als ein akademisches Artefakt. Auf dieser Basis konnten Empfehlungen für die Weiterzucht fallrelevanter entomologischer Spuren ausgesprochen werden, die gerichtsverwertbar sind und die Verwendung von tierischem Gewebe oder Tierkadaver in der forensisch-entomologischen Forschung legitimieren. Die Analyse stabiler Isotope legt darüber hinaus einen neuen, innovativen Grundstein für die routinemäßige Spurenzuordnung älterer Entwicklungsstadien und ist damit Vorreiter auf dem Gebiet der forensischen Entomologie.
Ribonukleinsäure (ribonucleic acid, RNA) wirkt bei der Proteinbiosynthese nicht nur als Informationsüberträger, sondern kann auch beispielsweise durch sogenannten Riboschalter (auch Riboswitches) regulatorische Funktionen übernehmen. Riboschalter sind komplett aus RNA aufgebaut und man kann sie sich als molekulare Schalter vorstellen, die die Genexpression kontrollieren. Konzeptionell besteht ein Riboswitch aus zwei Untereinheiten, dem Aptamer und der Expressionsplattform. Das Aptamer bindet, üblicherweise sehr spezifisch, kleine organische Moleküle, aber auch Ionen. Diese Ligandenbindung induziert Änderungen in der Struktur des Riboswitches, welche wiederum die Expressionsplattform beeinflussen. Je nach Riboswitch ermöglicht oder verhindert dies schließlich die Genexpression. Die vorliegende Doktorarbeit beschäftigt sich mit der Entwicklung und Etablierung von Methoden der optischen Spektroskopie zur Aufklärung von RNA-Dynamiken und -Strukturen im Allgemeinen und der Erforschung von Aptamerbindungsmechanismen im Besonderen.
Eine der dazu verwendetet Methoden ist die FTIR-Spektroskopie. Hierfür wurden zunächst kritische Parameter wie verschiedenste Messeinstellungen oder die Probenpräparation ausgiebig an RNA-Modellsträngen getestet. Dabei war es möglich, eine kleine Spektrenbibliothek als internen Standard aufzubauen. Gleichzeitig konnte gezeigt werden, dass kleinere RNA-Oligonukleotide (< ca. 20 Nukleobasen) gut mittels FTIR-Methoden untersucht werden können. Anschließend wurde eine statische Bindungsstudie am adenosin- sowie am guanosinbindenden Aptamer vorgenommen.
Die zweite hier vorgestellte Methode zur Untersuchung von RNA-Molekülen ist die Fluoreszenzspektroskopie. Im Gegensatz zur FTIR-Spektroskopie ist dazu allerdings eine Modifizierung der RNA durch ein Fluoreszenzlabel nötig. Deshalb beschäftigt sich der Hauptteil dieser Doktorarbeit mit der Charakterisierung und der Anwendung des quasi bifunktionellen RNA-Markers (auch RNA-Labels) Çmf. So wurden zunächst die photophysikalischen und photochemischen Eigenschaften des Markers untersucht. Dabei konnte gezeigt werden, dass Çmf sich als lokale Sonde eignet, da es empfindlich auf Änderungen der Mikroumgebung in Lösung reagiert. Durch direkten Vergleich der optischen Eigenschaften von Çmf mit den entsprechenden Eigenschaften des Spinlabels Çm war es möglich, den starken Fluoreszenzlöschungseffekt (sog. quenching) des Çm aufzuklären. So kann davon ausgegangen werden, dass die Fluoreszenz des Çm durch eine sehr schnelle interne Konversion (IC) in einen dunklen Dublettzustand (D1) gelöscht wird.
Im nächsten Schritt wurde Çmf in RNA-Modellstränge eingebaut, um den Einfluss der RNA auf die Photochemie des Markers zu untersuchen. Dabei konnte gezeigt werden, dass sich dessen Fluoreszenzsignal abhängig von den direkten Nachbarbasen sowie abhängig vom Hybridisierungszustand signifikant ändert. Gleichzeitig konnte keine deutliche Veränderung der Stabilität der Modellstränge festgestellt werden. So konnte also nachgewiesen werden, dass sich Çmf sehr gut als lokale Sonde in RNA eignet. Im Speziellen wurde aus den Ergebnissen geschlossen, dass der Fluorophor für Ligandenbindungsstudien herangezogen werden kann.
Deshalb wurde Çmf schließlich an mehreren verschiedenen Stellen in das neomycinbindende Aptamer (N1) eingebaut, um dessen Bindungskinetik zu untersuchen. Mittels Stopped-Flow-Messungen war es möglich, die Bindungsdynamik des Aptamers zu beobachten. Anhand dieser transienten Daten konnte ein Zweischrittbindungsmodell abgeleitet werden. Dabei bindet Neomycin zunächst unspezifisch an das weitgehend vorgeformte Aptamer. Anschließend kommt es durch die Ausbildung von Wasserstoffbrücken zu einer spezifischen Bindung des Liganden am Aptamer.
Im dritten Teil dieser Arbeit geht es ebenfalls um die Entwicklung und Etablierung eines spektroskopischen Werkzeuges. Dabei stehen allerdings Rhodopsine im Mittelpunkt der Aufmerksamkeit. Hierbei handelt es sich um Membrantransportproteine, die nach optischer Anregung einen sehr schnellen Photozyklus mit mehreren Intermediaten durchlaufen. Es ist möglich, diese Intermediate dank transienter Absorptionsmessungen mit sehr guter zeitlicher und spektraler Auflösung zu beobachten. Allerdings besteht der Bedarf, diese Intermediate statisch zu präparieren, um sie näher charakterisieren und mit anderen Methoden, wie z.B. der Festkörper-NMR, vergleichen zu können.
Ein spektroskopisches Werkzeug zum Präparieren von frühen Photointermediaten ist kryogenes Einfangen (sog. Cryotrapping) dieser Intermediate. Im Rahmen dieser Arbeit wurden das Cryotrapping und die anschließende statische UV/vis-Absorptionsspektroskopie der fixierten (getrappten) Zustände optimiert und an einer Reihe von Rhodopsinen (ChR2, GPR) demonstriert.