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Single-molecule fluorescence microscopy in live \(Trypanosoma\) \(brucei\) and model membranes
(2018)
The eukaryotic parasite Trypanosoma brucei has evolved sophisticated strategies to escape
the host immune response and maintain a persistent infection inside a host. One central
feature of the parasite’s defense mechanism relies on the shielding function of their surface
protein coat. This coat is composed of a dense arrangement of one type of glycosylphosphatidylinositol
(GPI)-anchored variant surface glycoproteins (VSGs) which impair the
identification of epitopes of invariant surface proteins by the immune system. In addition
to the importance of understanding the function of the VSG coat and use it as a potential
target to efficiently fight the parasite, it is also crucial to study its biophysical properties as it is not yet understood sufficiently. This is due to the fact that microscopic investigations
on living trypanosomes are limited to a great extent by the intrinsic motility of the parasite.
In the present study, state-of-the-art single-molecule fluorescence microscopy (SMFM)
is introduced as a tool for biophysical investigations in the field of trypanosome research.
The work encompasses studies of VSG dynamics under the defined conditions of an
artificial supported lipid bilayer (SLB). First, the impact of the lateral protein density on
VSG diffusion was systematically studied in SLBs. Ensemble fluorescence after photobleaching
(FRAP) and complementary single-particle tracking experiments revealed that a
molecular crowding threshold (MCT) exists, above which a density dependent decrease
of the diffusion coefficient is measured. A relative quantification of reconstituted VSGs
illustrated that the VSG coat of living trypanosomes operates very close to its MCT and
is optimized for high density while maintaining fluidity. Second, the impact of VSG
N-glycosylation on VSG diffusion was quantitatively investigated. N-glycosylation was
shown to contribute to preserving protein mobility at high protein concentrations. Third,
a detailed analysis of VSG trajectories revealed that two distinct populations of freely
diffusing VSGs were present in a SLB, which is in agreement with the recent finding, that
VSGs are able to adopt two main structurally distinct conformations. The results from
SLBs were further complemented by single-particle tracking experiments of surface VSGs
on living trypanosomes. A high mobility and free diffusion were measured on the cell
surface, illustrating the overall dynamic nature of the VSG coat. It was concluded that
the VSG coat on living trypanosomes is a protective structure that combines density and
mobility, which is supported by the conformational flexibility of VSGs. These features are
elementary for the persistence of a stable infection in the host.
Different hydrogel embedding methods are presented, that facilitated SMFM in immobilized,
living trypanosomes. The hydrogels were found to be highly cytocompatible for one
hour after cross-linking. They exhibited low autofluorescence properties in the spectral
range of the investigations, making them suitable for super-resolution microscopy (SRM).
Exemplary SRM on living trypanosomes illustrated that the hydrogels efficiently immobilized
the cells on the nanometer lever. Furthermore, the plasma membrane organization was studied in living trypanosomes. A statistical analysis of a tracer molecule inside the
inner leaflet of the plasma membrane revealed that specific membrane domains exist, in
which the tracer appeared accumulated or diluted. It was suggested that this distribution
was caused by the interaction with proteins of the underlying cytoskeleton.
In conclusion, SMFM has been successfully introduced as a tool in the field of trypanosome
research. Measurements in model membranes facilitated systematic studies of VSG dynamics
on the single-molecule level. The implementation of hydrogel immobilization
allowed for the study of static structures and dynamic processes with high spatial and
temporal resolution in living, embedded trypanosomes for the first time.
The sequencing of several ant genomes within the last six years open new research avenues for understanding not only the genetic basis of social species but also the complex systems such as immune responses in general. Similar to other social insects, ants live in cooperative colonies, often in high densities and with genetically identical or closely related individuals. The contact behaviours and crowd living conditions allow the disease to spread rapidly through colonies. Nevertheless, ants can efficiently combat infections by using diverse and effective immune mechanisms. However, the components of the immune system of carpenter ant Camponotus floridanus and also the factors in bacteria that facilitate infection are not well understood.
To form a better view of the immune repository and study the C. floridanus immune responses against the bacteria, experimental data from Illumina sequencing and mass-spectrometry (MS) data of haemolymph in normal and infectious conditions were analysed and integrated with the several bioinformatics approaches. Briefly, the tasks were accomplished in three levels. First, the C. floridanus genome was re-annotated for the improvement of the existing annotation using the computational methods and transcriptomics data. Using the homology based methods, the extensive survey of literature, and mRNA expression profiles, the immune repository of C. floridanus were established. Second, large-scale protein-protein interactions (PPIs) and signalling network of C. floridanus were reconstructed and analysed and further the infection induced functional modules in the networks were detected by mapping of the expression data over the networks. In addition, the interactions of the immune components with the bacteria were identified by reconstructing inter-species PPIs networks and the interactions were validated by literature. Third, the stage-specific MS data of larvae and worker ants were analysed and the differences in the immune response were reported.
Concisely, all the three omics levels resulted to multiple findings, for instance, re-annotation and transcriptome profiling resulted in the overall improvement of structural and functional annotation and detection of alternative splicing events, network analysis revealed the differentially expressed topologically important proteins and the active functional modules, MS data analysis revealed the stage specific differences in C. floridanus immune responses against bacterial pathogens.
Taken together, starting from re-annotation of C. floridanus genome, this thesis provides a transcriptome and proteome level characterization of ant C. floridanus, particularly focusing on the immune system responses to pathogenic bacteria from a biological and a bioinformatics point of view. This work can serve as a model for the integration of omics data focusing on the immuno-transcriptome of insects.
African trypanosomes are the causative agents of fatal diseases in humans and livestock. Trypanosomes show a complex lifecycle and shuttle between the transmitting vector, the tsetse (Glossina spec.), and the mammalian host. As a result of this the parasite undergoes tremendous changes in morphology and metabolism to adapt to the different living environments.
The two best-studied lifecycle stages are the procyclic forms (PCF) that live in the tsetse fly and the proliferative bloodstream form (BSF) that resides in the mammalian blood. The most conspicuous weapon that trypanosomes use to evade the host immune attack is a dense layer of a single protein type, the variant surface glycoprotein (VSG), which shields the entire cell surface. Immune evasion required high rates of surface membrane turnover and surface coat recycling.
Trypanosomes show highly polarised cell architecture with all major eukaryotic organelles (endoplasmic reticulum, Golgi apparatus, endosomal apparatus, lysosome, mitochondrion and peroxisome-like glycosomes) generally present in single copy. Furthermore, trypanosomes possess a single flagellum, which is important not only for cellular motility but also for cell division.
How the duplication of all these cellular components is coordinated in order to progresss through the cell division cycle is poorly understood.
We used trypanosomes as a model organism due to the relative simplicity and the polarised nature of their cell architecture and determined the duplication of all their compartments. This was only possible due to a new synchronisation approach developed during this project.
In the first part of the thesis a precise temporal map of the cell division cycle of the BSF T. brucei cell division cycle was generated. By the use of well-described morphological markers (K/N status, new flagellum outgrowth and DNA synthesis) the position of individual cells was determined with high temporal resolution; this allowed us for the first time to synchronise a cell population in silico without affecting the naturally asynchronous growth.
In the second part of the thesis we used this tool to follow duplication events of the Major organelles during progression through the cell division cycle. We precisely determined the time points of organelle duplication and found that it is ordered in trypanosomes. Furthermore we found that BSF T. brucei cells do not grow continuously, cell size start to increase rapidly, during a short period of time, late in the cell division cycle. We speculate that the initiation of cell volume increase is temporally separated from the formation of all secretory organelles in order to ensure maintenance of the protective coat, which must remain intact at all times in order for BSF trypanosomes to be able to evade the host immune response.
Chronic Obstructive Pulmonary Disease (COPD) exacerbations are a considerable reason for increased morbidity and mortality in patients. Infections with influenza virus (H1N1), respiratory syncytial virus (RSV) or nontypeable Haemophilus influenzae (NTHi) are important triggers of exacerbations. To date, no treatments are available which can stop the progression of COPD. Novel approaches are urgently needed. Pre-clinical models of the disease are crucial for the development of novel therapeutic options.
In order to establish pre-clinical models which mimic aspects of human COPD exacerbations, mice were exposed to cigarette smoke (CS) and additionally infected with H1N1, RSV and/or NTHi. Clinically relevant treatments such as the corticosteroids Fluticasone propionate and Dexamethasone, the phosphodiesterase-4 (PDE-4) inhibitor Roflumilast and the long-acting muscarinic receptor antagonist Tiotropium were tested in the established models. Furthermore, a novel treatment approach using antibodies (Abs) directed against IL-1α, IL-1β or IL-1R1 was examined in the established CS/H1N1 model. Levels of IFN-γ, IL-1β, IL-2, IL-6, KC, TNF-α, RANTES, IL-17, MCP-1, MIP 1α and MIP-1β were measured in lung homogenate. Numbers of total cells, neutrophils and macrophages were assessed in bronchoalveolar lavage (BAL) fluid. Hematoxylin- and eosin- (H&E-) stained lung slices were analyzed to detect pathological changes. Quantitative polymerase-chain-reaction (qPCR) was used to investigate gene expression of ICAM-1 and MUC5 A/C. The viral/bacterial load was investigated in lung homogenate or BAL fluid. In addition to the in vivo studies, the effects of the above mentioned treatments were investigated in vitro in H1N1, RSV or NTHi-infected (primary) human bronchial epithelial cells using submerged or air-liquid-interface (ALI) cell culture systems.
Four pre-clinical models (CS/H1N1, CS/RSV, CS/NTHi, CS/H1N1/NTHi) were established depicting clinically relevant aspects of COPD exacerbations such as increased inflammatory cells and cytokines in the airways and impaired lung function.
In the CS/H1N1 model, Tiotropium improved lung function and was superior in reducing inflammation in comparison to Fluticasone or Roflumilast. Moreover, Fluticasone increased the loss of body-weight, levels of IL-6, KC and TNF-α and worsened lung function. In CS/RSV-exposed mice Tiotropium but not Fluticasone or Roflumilast treatment reduced neutrophil numbers and IL-6 and TNF α levels in the lung. The viral load of H1N1 and RSV was significantly elevated in CS/virus-exposed mice and NCI-H292 cells after Fluticasone and Dexamethasone treatment. The results from these studies demonstrate that Tiotropium has anti-inflammatory effects on CS/virus-induced inflammation and might help to explain the observed reduction of exacerbation rates in Tiotropium-treated COPD patients. Furthermore, the findings from this work indicate that treatment with Fluticasone or Dexamethasone might not be beneficial to reduce inflammation in the airways of COPD patients and supports clinical studies that link treatment with corticosteroids to an increased risk for pneumonia.
Testing of anti-IL-1α, anti-IL-1β or anti-IL-1R1 Abs in the CS/H1N1 model suggests that, in line with clinical data, antagonization of IL-1β is not sufficient to reduce pulmonary inflammation and indicates a predominant role of IL-1α in CS/virus-induced airway inflammation. In line with the in vivo findings, anti-IL-1α but not anti-IL-1β Abs reduced levels of TNF-α and IL-6 in H1N1-infected primary human bronchial epithelial ALI cell culture. Blocking the IL-1R1 provided significant inhibitory effects on inflammatory cells in vivo but was inferior compared to inhibiting both its soluble ligands IL-1α and IL-1β. Concomitant usage of Abs against IL-1α/IL-1β revealed strong effects and reduced total cells, neutrophils and macrophages. Additionally, levels of KC, IL-6, TNF-α, MCP-1, MIP-1α and MIP-1β were significantly reduced and ICAM-1 mRNA expression was attenuated. These results suggest that combined inhibition of IL-1α/IL-1β might be beneficial to reduce inflammation and exacerbations in COPD patients. Moreover, combined targeting of both IL-1α/IL-1β might be more efficient compared to inhibition of the IL-1R1.
As in the CS/virus models, corticosteroid treatment failed to reduce inflammatory cells in the CS/NTHi and CS/H1N1/NTHi models, increased the loss of body-weight and the bacterial load. Furthermore, Roflumilast administration had no significant effects on cell counts or cytokines. However, it improved compliance in the CS/NTHi model. Treatment with Azithromycin reduced the bacterial load in the CS/NTHi model and reduced numbers of total cells, neutrophils, macrophages and levels of KC and TNF-α in the CS/H1N1/NTHi model.
In conclusion, the established CS/H1N1, CS/RSV, CS/NTHi, CS/H1N1/NTHi models depict clinically relevant aspects of human COPD exacerbations in mice and provide the opportunity to investigate underlying disease mechanisms and to test novel therapies.
Die autosomal-dominant vererbte facioscapulohumerale Muskeldystrophie (FSHD) ist mit einer Prävalenz von etwa 1:20.000 die dritthäufigste Form der hereditären Myopathien. Erste Beschwerden werden meist in der zweiten Lebensdekade beobachtet. Betroffen sind vor allem die Muskulatur von Gesicht, Schultern, Oberarmen, die Fußhebermuskulatur und die Muskeln des Hüftgürtels.
FSHD wird durch einen Gendefekt ausgelöst, der den langen Arm des Chromosoms vier (4q35) betrifft, wobei es zur teilweisen Deletion des polymorphen Abschnitts D4Z4, der für das Protein DUX4 codiert, kommt. Dabei treten unter anderem Störungen in der DUX4-Expression, Veränderungen der myogenen Genexpression, eine Unterdrückung der Muskelzelldifferenzierung und eine Inhibition der Muskelbildung auf.
FSHD und eine andere Form der Muskeldystrophie, die Emery-Dreifuss-Muskeldystrophie (EDMD), zeigen trotz unterschiedlicher genetischer Ursachen phänotypisch Ähnlichkeiten in der Ausprägung der Erkrankungen. In früheren Studien zeigte die Kernhülle von EDMD-Myoblasten morphologische Auffälligkeiten. In anderen Untersuchungen waren morphologische Veränderungen der Mitochondrien von FSHD-Patienten festzustellen.
Daher wurden elektronenmikroskopische Untersuchungen der Kernhülle und der Mitochondrien von FSHD-Myoblasten durchgeführt und mit der entsprechenden Kontrolle verglichen.
Hierfür wurden drei verschiedene Zelllinien-Paare in unterschiedlichen Passagen, das heißt unterschiedlicher Anzahl an Subkultivierungen, eingesetzt, wobei in den höheren Passagen vermehrt morphologische Atypien beobachtet werden konnten.
Die eingesetzten Zelllinien differenzieren sich durch verschiedene Parameter wie beispielsweise Alter und Geschlecht der Patienten. Dabei zeigten sich sowohl zwischen den Kontrollzellen als auch zwischen den FSHD-Myoblasten Unterschiede.
Im Rahmen der Probenvorbereitung für die Elektronenmikroskopie kamen zwei verschiedene Fixierungsmethoden zum Einsatz: die konventionelle chemische Fixierung, Entwässerung und Flacheinbettung von Kulturzellen und die Hochdruckgefrierung mit anschließender Gefriersubstitution. In Bezug auf die Qualität des Strukturerhalts, die beim Hochdruckgefrieren erreicht wird, wird dieser Art der Fixierung eine Überlegenheit gegenüber allen anderen Verfahren zugeschrieben. Diese allgemeine Aussage kann nicht vollständig auf die Untersuchungen an den Myoblasten übertragen werden.
Für die Untersuchung der Kernmembranen sind beide Methoden geeignet, wobei der Abstand zwischen innerer und äußerer Kernmembran nach der HPF-Fixierung schärfer abgebildet wurde. Bei der Darstellung der Mitochondrien zeigten die elektronenmikroskopischen Aufnahmen nach dem Hochdruckgefrieren bessere und schärfere Ergebnisse. Die Kernporen waren bei beiden Fixierungsmethoden gut erkennbar.
Beim Vergleich der gesunden und erkrankten Myoblasten wiesen die Kontrollzellen deutlich weniger Auffälligkeiten auf als die Myoblasten von FSHD-Patienten.
Innere und äußere Kernmembran verliefen bei den Kontrollzellen meist parallel und die Mitochondrien zeigten in den meisten Fällen eine typische wurmartige, längliche Form mit Cristae. Dies traf sowohl für die konventionelle Fixierung als auch für das Hochdruckgefrieren zu.
Die erkrankten Myoblasten wiesen im Vergleich zur Kontrolle bei beiden Fixierungsmethoden deutliche Auffälligkeiten in der Mitochondrien-Morphologie auf. Neben einer oft großen Variationsbreite hinsichtlich Form und Länge war auch das teilweise Fehlen der Cristae festzustellen.
Bei Betrachtung der Kernhülle fielen jedoch deutliche Unterschiede zwischen konventioneller und HPF-Fixierung auf. Die äußere Kernmembran der konventionell fixierten FSHD-Myoblasten verlief unregelmäßig und gewellt. Im Gegensatz dazu wies die Kernhülle der HPF-fixierten erkrankten Myoblasten einen erstaunlich parallelen Verlauf auf.
Da bei EDMD in vorangegangenen Untersuchungen auch fluoreszenzmikroskopisch Veränderungen der erkrankten Zellen auffällig waren, wurde neben den Methoden der Elektronenmikroskopie das Vorliegen und die Verteilung verschiedener Proteine in FSHD-Myoblasten mittels indirekter Immunfluoreszenz untersucht und mit den Kontrollzellen verglichen.
Zur Beurteilung der Kernhülle wurden Antikörper gegen Lamin A/C und Nukleoporine eingesetzt. Die Mitochondrien wurden mithilfe des Antikörpers ANT1/2, der an den Adenin-Nukleotid-Translokator der inneren Mitochondrienmembran bindet, untersucht.
Im Gegensatz zu den Untersuchungen an EDMD-Myoblasten waren die Lamine A und C sowie die Kernporen sowohl bei den Myoblasten der FSHD-Patienten als auch bei den Kontrollzellen nachweisbar und gleichmäßig verteilt.
Bei der indirekten Immunfluoreszenz mit ANT1/2 zeigten sich Unterschiede zwischen den untersuchten Myoblasten-Paaren.
Durch die vorliegenden Ergebnisse ist darauf zu schließen, dass die Myoblasten von FSHD-Patienten Veränderungen Mitochondrien aufweisen. Die Untersuchungen der Kernhülle liefern abhängig von der Fixierungsmethode unterschiedliche Ergebnisse.
The rotation of the earth leads to a cyclic change of night and day. Numerous strategies evolved to cope with diurnal change, as it is generally advantageous to be synchronous to the cyclic change in abiotic conditions. Diurnal rhythms are regulated by the circadian clock, a molecular feedback loop of RNA and protein levels with a period of circa 24 hours. Despite its importance for individuals as well as for species interactions, our knowledge of circadian clocks is mostly confined to few model organisms.
While the structuring of activity is generally adaptive, a rigid temporal organization also has its drawbacks. For example, the specialization to a diurnal pattern limits the breadth of the temporal niche. Organisms that are adapted to a diurnal life style are often poor predators or foragers during night time, constraining the time budget to only diurnal parts of the day/night cycle.
Climate change causes shifts in phenology (seasonal timing) and northward range expansions, and changes in season or in latitude are associated with novel day length – temperature correlations. Thus, seasonal organisms will have some life history stages exposed to novel day lengths, and I hypothesized that the diurnal niche determines whether the day length changes are beneficial or harmful for the organism. I thus studied the effects of day length on life-history traits in a multi-trophic system consisting of the pea aphid Acyrthosiphon pisum and predatory larvae of Chrysoperla carnea (common green lacewing) and Episyrphus balteatus (marmalade hoverfly). In order to identify the mechanisms for phenological constraints I then focused on diurnal rhythms and the circadian clock of the pea aphid.
Aphids reacted to shorter days with a reduced fecundity and shorter reproductive period. Short days did however not impact population growth, because the fitness constraints only became apparent late in the individual’s life. In contrast, E. balteatus grew 13% faster in the shorter day treatment and preyed on significantly more aphids, whereas C. carnea grew 13% faster under longer days and the elevation of predation rates was marginally significant. These results show that day length affects vital life-history traits, but that the direction and effect size depends on species.
I hypothesized that the constraints or fitness benefits are caused by a constricted or expanded time budget, and hence depend on the temporal niche. E. balteatus is indeed night-active and C. carnea appears to be crepuscular, but very little data exists for A. pisum. Hence, I reared the pea aphid on an artificial diet and recorded survival, moulting and honeydew excretion. The activity patterns were clearly rhythmic and molting and honeydew excretion were elevated during day-time. Thus, the diurnal niche could explain the observed, but weak, day length constraints of aphids.
The diurnal niche of some organisms is remarkably flexible, and a flexible diurnal niche may explain why the day length constrains were relatively low in A. pisum. I thus studied its circadian clock, the mechanism that regulates diurnal rhythms. First, I improved an artificial diet for A. pisum, and added the food colorant Brilliant Blue FCF. This food colorant stained gut and honeydew in low concentration without causing mortalities, and thus made honeydew excretion visible under dim red light. I then used the blue diet to raise individual aphids in 16:08 LD and constant darkness (DD), and recorded honeydew excretion and molting under red light every three hours. In addition, we used a novel monitoring setup to track locomotor activity continuously in LD and DD. Both the locomotor rhythm and honeydew excretion of A. pisum appeared to be bimodal, peaking in early morning and in the afternoon in LD. Both metabolic and locomotor rhythm persisted also for some time under constant darkness, indicating that the rhythms are driven by a functional circadian clock. However, the metabolic rhythm damped within three to four days, whereas locomotor rhythmicity persisted with a complex distribution of several free-running periods. These results fit to a damped circadian clock that is driven by multiple oscillator populations, a model that has been proposed to link circadian clocks and photoperiodism, but never empirically tested.
Overall, my studies integrate constraints in phenological adaptation with a mechanistic explanation. I showed that a shorter day length can constrain some species of a trophic network while being beneficial for others, and linked the differences to the diurnal niche of the species. I further demonstrated that a flexible circadian clock may alleviate the constraints, potentially by increasing the plasticity of the diurnal niche.
The transcription factor MYC is deregulated in over 70% of all human tumors and, in its oncogenic form, plays a major role in the cancer metabolic reprogramming, promoting the uptake of nutrients in order to sustain the biosynthetic needs of cancer cells.
The research presented in this work aimed to understand if MYC itself is regulated by nutrient availability, focusing on the two major fuels of cancer cells: glucose and glutamine.
Initial observations showed that endogenous MYC protein levels strongly depend on the availability of glutamine, but not of glucose. Subsequent analysis highlighted that the mechanism which accounts for the glutamine-mediated regulation of MYC is dependent on the 3´-untranslated region (3´-UTR) of MYC. Enhanced glutamine utilization by tumors has been shown to be directly linked to MYC oncogenic activity and MYC-dependent apoptosis has been observed under glutamine starvation. Such effect has been described in experimental systems which are mainly based on the use of MYC transgenes that do not contain the 3´-UTR. It was observed in the present study that cells are able to survive under glutamine starvation, which leads to cell cycle arrest and not apoptosis, as previously reported. However, enforced expression of a MYC transgene, which lacks the 3´-UTR, strongly increases the percentage of apoptotic cells upon starvation. Evaluation of glutamine-derived metabolites allowed to identify adenosine nucleotides as the specific stimulus responsible for the glutamine-mediated regulation of MYC, in a 3´-UTR-dependent way. Finally, glutamine-dependent MYC-mediated effects on RNA Polymerase II (RNAPII) function were evaluated, since MYC is involved in different steps of global transcriptional regulation. A global loss of RNAPII recruitment at the transcriptional start site results upon glutamine withdrawal. Such effect is overcome by enforced MYC expression under the same condition.
This study shows that the 3´UTR of MYC acts as metabolic sensor and that MYC globally regulates the RNAPII function according to the availability of glutamine. The observations presented in this work underline the importance of considering stress-induced mechanisms impinging on the 3´UTR of MYC.
N-MYC is a member of the human MYC proto-oncogene family, which comprises three transcription factors (C-, N- and L-MYC) that function in multiple biological processes. Deregulated expression of MYC proteins is linked to tumour initiation, maintenance and progression. For example, a large fraction of neuroblastoma displays high N-MYC levels due to an amplification of the N-MYC encoding gene. MYCN-amplified neuroblastoma depend on high N-MYC protein levels, which are maintained by Aurora-A kinase. Aurora-A interaction with N-MYC interferes with degradation of N-MYC via the E3 ubiquitin ligase SCFFBXW7. However, the underlying mechanism of Aurora-A-mediated stabilisation of N-MYC remains to be elucidated.
To identify novel N-MYC interacting proteins, which could be involved in N-MYC stabilisation by Aurora-A, a proteomic analysis of purified N-MYC protein complexes was conducted. Since two alanine mutations in MBI of N-MYC, T58A and S62A (N-MYC mut), disable Aurora-A-mediated stabilisation of N-MYC, N-MYC protein complexes from cells expressing either N-MYC wt or mut were analysed. Proteomic analysis revealed that N-MYC interacts with two deubiquitinating enzymes, USP7 and USP11, which catalyse the removal of ubiquitin chains from target proteins, preventing recognition by the proteasome and subsequent degradation. Although N-MYC interaction with USP7 and USP11 was confirmed in subsequent immunoprecipitation experiments, neither USP7, nor USP11 was shown to be involved in the regulation of N-MYC stability. Besides USP7/11, proteomic analyses identified numerous additional N-MYC interacting proteins that were not described to interact with MYC transcription factors previously. Interestingly, many of the identified N-MYC interaction partners displayed a preference for the interaction with N-MYC wt, suggesting a MBI-dependent interaction. Among these were several proteins, which are involved in three-dimensional organisation of chromatin domains and transcriptional elongation by POL II. Not only the interaction of N-MYC with proteins functioning in elongation, such as the DSIF component SPT5 and the PAF1C components CDC73 and CTR9, was validated in immunoprecipitation experiments, but also with the POL III transcription factor TFIIIC and topoisomerases TOP2A/B. ChIP-sequencing analysis of N-MYC and TFIIIC subunit 5 (TFIIIC5) revealed a large number of joint binding sites in POL II promoters and intergenic regions, which are characterised by the presence of a specific motif that is highly similar to the CTCF motif. Additionally, N-MYC was shown to interact with the ring-shaped cohesin complex that is known to bind to CTCF motifs and to assist the insulator protein CTCF. Importantly, individual ChIP experiments demonstrated that N-MYC, TFIIIC5 and cohesin subunit RAD21 occupy joint binding sites comprising a CTCF motif.
Collectively, the results indicate that N-MYC functions in two biological processes that have not been linked to MYC biology previously. Furthermore, the identification of joint binding sites of N-MYC, TFIIIC and cohesin and the confirmation of their interaction with each other suggests a novel function of MYC transcription factors in three-dimensional organisation of chromatin.
Staphylococcus aureus asymptomatically colonises one third of the healthy human population, finding its niche in the nose and on skin. Apart from being a commensal, it is also an important opportunistic human pathogen capable of destructing tissue, invading host cells and killing them from within. This eventually contributes to severe hospital- and community-acquired infections. Methicillin-resistant Staphylococcus aureus (MRSA), resistant to commonly used antibiotics are protected when residing within the host cell.
This doctoral thesis is focused on the investigation of staphylococcal factors governing intracellular virulence and subsequent host cell death. To initiate an unbiased approach to conduct this study, complex S. aureus mutant pools were generated using transposon insertional mutagenesis. Genome-wide infection screens were performed using these S. aureus transposon mutant pools in vitro and in vivo, followed by analysis using Transposon insertion site deep sequencing (Tn-seq) technology.
Amongst several other factors, this study identified a novel regulatory system in S. aureus that controls pathogen-induced host cytotoxicity and intra-host survival. The primary components of this system are an AraC-family transcription regulator called Repressor of surface proteins (Rsp) and a virulence associated non-coding RNA, SSR42. Mutants within rsp exhibit enhanced intra-host survival in human epithelial cells and delayed host cytotoxicity. Global gene-expression profiling by RNA-seq demonstrated that Rsp controls the expression of SSR42, several cytotoxins and other bacterial factors directed against the host immune system. Rsp enhances S. aureus toxin response when triggered by hydrogen peroxide, an antimicrobial substance employed by neutrophils to destroy pathogens. Absence of rsp reduces S. aureus-induced neutrophil damage and early lethality during mouse pneumonia, but still permits blood stream infection. Intriguingly, S. aureus lacking rsp exhibited enhanced survival in human macrophages, which hints towards a Trojan horse-like phenomenon and could facilitate dissemination within the host.
Hence, Rsp emerged as a global regulator of bacterial virulence, which has an impact on disease progression with prolonged intra-cellular survival, delayed-lethality but allows disseminated manifestation of disease. Moreover, this study exemplifies the use of genome-wide approaches as useful resources for identifying bacterial factors and deduction of its pathogenesis.
Genetic foundation of unrivaled survival strategies - Of water bears and carnivorous plants -
(2018)
All living organisms leverage mechanisms and response systems to optimize reproduction, defense, survival, and competitiveness within their natural habitat. Evolutionary theories such as the universal adaptive strategy theory (UAST) developed by John Philip Grime (1979) attempt to describe how these systems are limited by the trade-off between growth, maintenance and regeneration; known as the universal three-way trade-off. Grime introduced three adaptive strategies that enable organisms to coop with either high or low intensities of stress (e.g., nutrient deficiency) and environmental disturbance (e.g., seasons). The competitor is able to outcompete other organisms by efficiently tapping available resources in environments of low intensity stress and disturbance (e.g., rapid growers). A ruderal specism is able to rapidly complete the life cycle especially during high intensity disturbance and low intensity stress (e.g., annual colonizers). The stress tolerator is able to respond to high intensity stress with physiological variability but is limited to low intensity disturbance environments. Carnivorous plants like D. muscipula and tardigrades like M. tardigradum are two extreme examples for such stress tolerators. D. muscipula traps insects in its native habitat (green swamps in North and South Carolina) with specialized leaves and thereby is able to tolerate nutrient deficient soils. M. tardigradum on the other side, is able to escape desiccation of its terrestrial habitat like mosses and lichens which are usually covered by a water film but regularly fall completely dry. The stress tolerance of the two species is the central study object of this thesis. In both cases, high througput sequencing data and methods were used to test for transcriptomic (D. muscipula) or genomic adaptations (M. tardigradum) which underly the stress tolerance. A new hardware resource including computing cluster and high availability storage system was implemented in the first months of the thesis work to effectively analyze the vast amounts of data generated for both projects. Side-by-side, the data management resource TBro [14] was established together with students to intuitively approach complex biological questions and enhance collaboration between researchers of several different disciplines. Thereafter, the unique trapping abilities of D. muscipula were studied using a whole transcriptome approach. Prey-dependent changes of the transcriptional landscape as well as individual tissue-specific aspects of the whole plant were studied. The analysis revealed that non-stimulated traps of D. muscipula exhibit the expected hallmarks of any typical leaf but operates evolutionary conserved stress-related pathways including defense-associated responses when digesting prey. An integrative approach, combining proteome and transcriptome data further enabled the detailed description of the digestive cocktail and the potential nutrient uptake machinery of the plant. The published work [25] as well as a accompanying video material (https://www.eurekalert.org/pub_releases/ 2016-05/cshl-fgr042816.php; Video credit: Sönke Scherzer) gained global press coverage and successfully underlined the advantages of D. muscipula as experimental system to understand the carnivorous syndrome. The analysis of the peculiar stress tolerance of M. tardigradum during cryptobiosis was carried out using a genomic approach. First, the genome size of M. tardigradum was estimated, the genome sequenced, assembled and annotated. The first draft of M. tardigradum and the workflow used to established its genome draft helped scrutinizing the first ever released tardigrade genome (Hypsibius dujardini) and demonstrated how (bacterial) contamination can influence whole genome analysis efforts [27]. Finally, the
M. tardigradum genome was compared to two other tardigrades and all species present in the current release of the Ensembl Metazoa database. The analysis revealed that tardigrade genomes are not that different from those of other Ecdysozoa. The availability of the three genomes allowed the delineation of their phylogenetic position within the Ecdysozoa and placed them as sister taxa to the nematodes. Thereby, the comparative analysis helped to identify evolutionary trends within this metazoan lineage. Surprisingly, the analysis did not reveal general mechanisms (shared by all available tardigrade genomes) behind the arguably most peculiar feature of tardigrades; their enormous stress tolerance. The lack of molecular evidence for individual tardigrade species (e.g., gene expression data for M. tardigradum) and the non-existence of a universal experimental framework which enables hypothesis testing withing the whole phylum Tardigrada, made it nearly impossible to link footprints of genomic adaptations to the unusual physiological capabilities. Nevertheless, the (comparative) genomic framework established during this project will help to understand how evolution tinkered, rewired and modified existing molecular systems to shape the remarkable phenotypic features of tardigrades.
Plant-associated fungi can affect the plants‘ interaction with herbivores and
other microorganisms. For example, many common forage grasses are infected
with Epichloë endophytes. The endophytes systemically colonize the aerial
parts of the plants. They produce bioprotective alkaloids that can negatively
affect insects and livestock feeding on the grasses, and interact with other
fungal species which living from the plants‘ nutrients. Environmental conditions
strongly influence Epichloë endophytes. Endophyte-mediated effects
on herbivores are more pronounced under increased temperatures and the
endophytes may benefit from land use in managed grasslands. Under the
framework of the large-scale German project “Biodiversity Exploratories”, I
investigated whether infection rates and alkaloid concentrations of Epichloë
festucae var. lolii in Lolium perenne (Chapter I) and Epichloë endophytes (E.
uncinata, E. siegelii) in Festuca pratensis (Chapter II) depend on land use and
season. Further I analysed, whether foliar fungal assemblages of L. perenne
are affected by the presence of Epichloë endophytes (Chapter IV).
Neuropeptides and peptide hormones carrying neural or physiological information are intercellular signalling substances. They control most if not all biological processes in vertebrates and invertebrates by acting on specific receptors on the target cell. In mammals, many different neuropeptides and peptide hormones are involved in the regulation of feeding and sleep. In \textit{Drosophila}, allatostatin A (AstA) and myoinhibitory peptides (MIPs) are brain-gut peptides. The AstA receptors are homologues of the mammalian galanin receptors and the amino acid sequences of MIPs are similar to a part of galanin, which has an orexigenic effect and is implicated in the control of sleep behaviour in mammals. I am interested in dissecting pleiotropic functions of AstA and MIPs in the regulation of food intake and sleep in \textit{Drosophila}. \par
In the first part of the dissertation the roles of brain-gut peptide allatostatin A are analysed. Due to the genetic and molecular tools available, the fruit fly \textit{Drosophila melanogaster} is chosen to investigate functions of AstA. The aims in this part are to identify pleiotropic functions of AstA and assign specific effects to the activity of certain subsets of AstA expressing cells in \textit{Drosophila} adults. A new and restricted \textit{AstA\textsuperscript{34}-Gal4} line was generated. The confocal imaging result showed that AstA neurons are located in the posterior lateral protocerebrum (PLP), the gnathal ganglia (GNG), the medullae, and thoracic-abdominal ganglion (TAG). AstA producing DLAa neurons in the TAG innervate hindgut and the poterior part of midgut. In addition, AstA are detected in the enteroendocrine cells (EECs).\par
Thermogenetic activation and neurogenetic silencing tools with the aid of the \textit{UAS/Gal4} system were employed to manipulate the activity of all or individual subsets of AstA cells and investigate the effects on food intake, locomotor activity and sleep. Our experimental results showed that thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs reduced food intake, which can be traced to AstA signalling by using \textit{AstA} mutants. In the locomotor activity, thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs resulted in strongly inhibited locomotor activity and promoted sleep without sexual difference, which was most apparent during the morning and evening activity peaks. The experimental and control flies were not impaired in climbing ability. In contrast, conditional silencing of the PLP neurons and/or AstA expressing EECs reduced sleep specifically in the siesta. The arousal experiment was employed to test for the sleep intensity. Thermogenetically activated flies walked significantly slower and a shorter distance than controls for all arousal stimulus intensities. Furthermore, PDF receptor was detected in the PLP neurons and the PLP neurons reacted with an intracellular increase of cAMP upon PDF, only when PDF receptor was present. Constitutive activation of AstA cells by tethered PDF increased sleep and thermogenetic activation of the PDF producing sLNvs promoted sleep specifically in the morning and evening. \par
The study shows that the PLP neurons and/or EECs vis AstA signalling subserve an anorexigenic and sleep-regulating function in \textit{Drosophila}. The PLP neurons arborise in the posterior superior protocerebrum, where the sleep relevant dopaminergic neurons are located, and EECs extend themselves to reach the gut lumen. Thus, the PLP neurons are well positioned to regulate sleep and EECs potentially modulate feeding and possibly locomotor activity and sleep during sending the nutritional information from the gut to the brain. The results of imaging, activation of the PDF signalling pathway by tethered PDF and thermoactivation of PDF expressing sLNvs suggest that the PLP neurons are modulated by PDF from sLNv clock neurons and AstA in PLP neurons is the downstream target of the central clock to modulate locomotor activity and sleep. AstA receptors are homologues of galanin receptors and both of them are involved in the regulation of feeding and sleep, which appears to be conserved in evolutionary aspect.\par
In the second part of the dissertation, I analysed the role of myoinhibitory peptides. MIPs are brain-gut peptides in insects and polychaeta. Also in \textit{Drosophila}, MIPs are expressed in the CNS and EECs in the gut. Previous studies have demonstrated the functions of MIPs in the regulation of food intake, gut motility and ecdysis in moths and crickets. Yet, the functions of MIPs in the fruit fly are little known. To dissect effects of MIPs regarding feeding, locomotor activity and sleep in \textit{Drosophila melanogater}, I manipulated the activity of MIP\textsuperscript{WÜ} cells by using newly generated \textit{Mip\textsuperscript{WÜ}-Gal4} lines. Thermogenetical activation or genetical silencing of MIP\textsuperscript{WÜ} celles did not affect feeding behaviour and resulted in changes in the sleep status. \par
My results are in contradiction to a recent research of Min Soohong and colleagues who demonstrated a role of MIPs in the regulation of food intake and body weight in \textit{Drosophila}. They showed that constitutive silencing of MIP\textsuperscript{KR} cells increased food intake and body weight, whereas thermogenetic activation of MIP\textsuperscript{KR} cells decreased food intake and body weight by using \textit{Mip\textsuperscript{KR}-Gal4} driver. Then I repeated the experiments with the \textit{Mip\textsuperscript{KR}-Gal4} driver, but could not reproduce the results. Interestingly, I just observed the opposite phenotype. When MIP\textsuperscript{KR} cells were silenced by expressing UAS-tetanus toxin (\textit{UAS-TNT}), the \textit{Mip\textsuperscript{KR}$>$TNT} flies showed reduced food intake. The thermogenetic activation of MIP\textsuperscript{KR} cells did not affect food intake. Furthermore, I observed that the thermogenetic activation of MIP\textsuperscript{KR} cells strongly reduced the sleep duration.\par
In the third part of the dissertation, I adapted and improved a method for metabolic labelling for \textit{Drosophila} peptides to quantify the relative amount of peptides and the released peptides by mass spectrometry under different physiological and behavioural conditions. qRT-PCR is a practical technique to measure the transcription and the corresponding mRNA level of a given peptide. However, this is not the only way to measure the translation and production of peptides. Although the amount of peptides can be quantified by mass spectrometry, it is not possible to distinguish between peptides stored in vesicles and released peptides in CNS extracts. I construct an approach to assess the released peptides, which can be calculated by comparing the relative amount of peptides between two timepoints in combination with the mRNA levels which can be used as semiquantitative proxy reflecting the production of peptides during this period. \par
After optimizing the protocol for metabolic labelling, I carried out a quantitative analysis of peptides before and after eclosion as a test. I was able to show that the EH- and SIFa-related peptides were strongly reduced after eclosion. This is in line with the known function and release of EH during eclosion. Since this test was positive, I next used the metabolic labelling in \textit{Drosophila} adult, which were either fed \textit{ad libitum} or starved for 24 hrs, and analysed the effects on the amount of AstA and MIPs. In the mRNA level, my results showed that in the brain \textit{AstA} mRNA level in the 24 hrs starved flies was increased compared to in the \textit{ad libitum} fed flies, whereas in the gut the \textit{AstA} mRNA level was decreased. Starvation induced the reduction of \textit{Mip} mRNA level in the brain and gut. Unfortunately, due to technical problems I was unable to analyse the metabolic labelled peptides during the course of this thesis.\par
Die Evolution der Primaten zeigt eine Verbindung zwischen der zunehmenden Komplexität des sozialen Verhaltens und der Vergrößerung des humanen Gehirns, insbesondere des präfrontalen Cortex. Deshalb stellt der präfrontale Cortex bezüglich der Evolution des Menschen eine der interessantesten Strukturen im humanen Gehirn dar. Es wird angenommen, dass nicht allein die Größe, sondern auch die Funktion, vor allem das Zusammenspiel von Neuronen und nicht-neuronalen Zellen, wie z.B. Gliazellen, zur Differenzierung des menschlichen Gehirns von dem rezenter Primaten geführt hat. Daraus lässt sich schließen, dass die Gehirnfunktionen über eine ausgeglichene und gut aufeinander abgestimmte transkriptionelle Landschaft kontrolliert werden, die durch ein zugrundeliegendes genetisches und epigentisches Rückgrat organisiert ist. In dieser Studie wurden das Methylierungsprofil neuronaler und nicht-neuronaler Zellen des präfrontalen Cortex (Brodmann-Areal 10) von drei Menschen und drei Schimpansen miteinander verglichen. Die intra- und interspezifischen differenziell methylierten Regionen (DMRs) waren in bestimmten genomischen Regionen angereichert. Intraspezifische Methylierungsunterschiede zwischen neuronalen und nicht-neuronalen Zellen konnten dreimal häufiger beobachtet werden als interspezifische Unterschiede in den einzelnen Zelltypen. Rund 90% der humanen intraspezifischen DMRs wiesen eine Hypomethylierung in den neuronalen Zellen im Vergleich zu den nicht-neuronalen Zellen auf. In den intraspezifischen DMRs (Mensch und Schimpanse) waren Gene angereichert, die mit verschiedenen neuropsychiatrischen Erkrankungen assoziiert sind. Der Vergleich zwischen Menschen und Schimpanse in den neuronalen und nicht-neuronalen Zelltypen zeigte eine Anreicherung von Genen mit human-spezifischer Histonsignatur. In den nicht-neuronalen Zellen konnten mehr interspezifische DMRs (n=666) detektiert werden als in den neuronalen Zellen (n=96). Ungefähr 95% der nicht-neuronalen interspezifischen DMRs waren im Menschen, im Vergleich zum Schimpansen, hypermethyliert. Daraus ergibt sich der Eindruck, dass mehrere hundert der nicht-neuronalen Gene während der humanen Gehirnevolution einer Methylierungswelle unterlagen. Dies führt zu der Annahme, dass der Einfluss dieser Veränderungen in den nicht-neuronalen Zellen auf die Vergößerung des menschlichen Gehirns bisher stark unterschätzt wurde.
Die bekannteste genetische Ursache für erblichen Brust- und Eierstockkrebs sind Mutationen in den Tumorsuppressorgenen (TSG) BRCA1 und BRCA2. Dennoch können nur rund 20-25% der familiären Brustkrebserkrankungen über Keimbahnmutationen in BRCA1/BRCA2 erklärt werden, besonders bei Frauen, deren Erkrankung vor dem vierzigsten Lebensjahr auftritt. Epigenetische Veränderungen, die zu einer aberranten Genexpression führen, spielen ebenfalls eine wichtige Rolle bei der Karzinogenese und der Entwicklung einer Brustkrebserkrankung. Es ist bekannt, dass TSG nicht nur durch den Verlust der Heterozygotie (engl. loss of heterozygosity, LOH) oder homozygote Deletionen, sondern auch durch transkriptionelle Stilllegung via DNA-Methylierung inaktiviert werden können. Im Rahmen dieser Arbeit wurde überprüft, welchen Einfluss aberrante Methylierungsmuster im Promotorbereich von TSG auf die Brustkrebskarzinogenese und die Expression der Gene haben. Für die Quantifizierung der Epimutationen wurden die Promotorbereiche von acht TSG (BRCA1, BRCA2, RAD51C, ATM, PTEN, TP53, MLH1, RB1) und des estrogene receptor (ESR1) Gens, welches eine Rolle in der Tumorprogression spielt, mittels Deep Bisulfite Amplicon Sequencing (DBAS) analysiert. Es wurden Blutproben von zwei unabhängigen BRCA1/BRCA2-mutationsnegativen Brustkrebs (BC)-Patientenkohorten, sowie von zwei unabhängigen alters-gematchten, gesunden Kontrollkohorten untersucht. BC-Kohorte 1 beinhaltet early-onset (EO) BC-Patientinnen. Kohorte 2 enthält BC-Patientinnen mit einem Risiko von >95% eine heterozygote Mutation in BRCA1/BRCA2 (high-risk, HR) zu tragen. Allele mit >50% methylierten CpGs werden als funktionell relevante Epimutationen erachtet, da bekannt ist, dass TSG über eine Methylierung im Promotorbereich transkriptionell stillgelegt werden. Im Vergleich zu ESR1 (Ø Methylierung, 3%), welches die Methylierungslevel eines durchschnittlichen Promotors wiederspiegelt, zeigten die TSG sehr geringe durchschnittliche Methylierungswerte von weniger als 1%. Zudem waren die durchschnittlichen Epimutationsraten (EMR; <0,0001-0,1%) der TSG sehr gering. Mit der Ausnahme von BRCA1, welches eine erhöhte EMR in der BC-Kohorte verglichen zu den Kontrollen (0,31% gegen 0,06%) zeigte, gab es keine signifikanten Gruppenunterschiede zwischen BC-Patientinnen und Kontrollen. Eine von 36 HR BC-Patientinnen zeigte im Vergleich zu den restlichen Proben eine stark erhöhte EMR von 14,7% in BRCA1. Rund ein Drittel (15/44) der EO BC-Patientinnen wiesen eine erhöhte Rate an Einzel-CpG Fehlern in mehreren TSG auf. Die nachfolgenden Expressionsanalysen ergaben eine erniedrigte Expression vieler TSG je analysierter Patientin. Diese Ergebnisse führen zu der Annahme, dass epigenetische Veränderungen in normalen Körperzellen als ein möglicher Indikator für einen gestörten Mechanismus, der für die Aufrechterhaltung des unmethylierten Status und der daraus resultierenden normalen Genexpression zuständig ist, angesehen werden können. Dies kann mit einem erhöhten BC-Risiko assoziiert werden.
Simkania negevensis (Sn) repliziert als Chlamydia-ähnliches obligat intrazelluläres Bakterium auch in einer membranumschlossenen Vakuole, die als SCV (engl. Simkania-containing vacuole) bezeichnet wird. Die SCV ist ein bis jetzt einzigartiges Kompartiment, das stark mit ER-Membranen assoziiert ist, wobei ER-Stress von den Bakterien blockiert wird. Die Morphologie der SCV scheint dabei in Epithelzellen (HeLa229, A549, HEp-2) als auch in Makrophagen (THP1) gleich zu sein. Die SCV stellt die erste intrazelluläre Berührungsfläche dar, an der Interaktionen zwischen Wirt und Pathogen erfolgen, und dient gleichzeitig als Replikationsnische. Mithilfe der Identifizierung von humanen und bakteriellen Faktoren, die mit der ER-SCV-Membran assoziiert sind, sollten die Zusammensetzung der SCV sowie mögliche Interaktionen mit dem ER oder zellulären Transportwegen ermittelt werden. Vergleichsstudien von SCV-assoziierten Proteinen sollten Ähnlichkeiten zur chlamydialen Inklusion aufzeigen, für die bereits einige interagierende Wirtszellfaktoren beschrieben wurden. In dieser Arbeit wurde ein Aufreinigungsprotokoll etabliert, das sowohl für ER-SCVMembranen aus HeLa229 als auch THP1 geeignet war und für spätere Proteom- oder Lipidomanalysen diente. Über markierungsfreie massenspektrometrische Messungen konnten 302 bakterielle und 1178 humane Proteine in ER-(SCV-) Membranen und 885 bakterielle Proteine in aufgereinigten Sn identifiziert werden. In ER-(SCV-) Membranen von nicht und Sn-infizierten HeLa229 Zellen befanden sich 51 unterschiedlich verteilte und 57 transportassoziierte humane Proteine, die auf infektionsinduzierte Unterschiede beim intrazellulären Proteintransport hindeuteten. Eine entgegengesetzte Regulation von retro- und anterograd transportierten Proteinen konnte mithilfe von RNA-Interferenz und dem Einsatz geeigneter Inhibitoren bestätigt werden, wobei sich zeigte, dass Clathrin-assoziierte und COPI-Vesikel eine zentrale Rolle spielen. Retro-Inhibitoren, die den retrograden Transport zwischen Endosomen zum Golgi oder zwischen frühen und späten Endosomen inhibieren, sowie Bafilomycin A1 (retrograd, späte Endosomen und Lysosomen) und Brefeldin A (anterograd, ER und Golgi), beeinflussten massiv die SCV-Ausbildung, SCV-Morphologie und den intrazellulären Lipidtransport. Über markierungsfreie massenspektrometrische und dünnschichtchromatographische Analysen konnten erste Unterschiede im Lipidvorkommen in Sn-infizierten Zellen, an ER-SCVMembranen und in aufgereinigten Sn im Vergleich zu nicht infizierten Zellen ermittelt werden. Dabei konnten neben An- und Abreicherungen in Gesamtzellextrakten sowie ER-SCVMembranen zwei infektionsspezifische Lipide, Cholesterol-ß-D-Glykosid und PE 30:0, identifiziert werden. Weiterführende umfangreiche RNA-Interferenzstudien weisen darauf hin, dass die Sn-Infektion vom Endosomen-zum-Golgi-Transport und vom Clathrin-assoziierten Vesikeltransport abhängig ist. Zusammenfassend konnten erste mögliche SCV-assoziierte Proteine und Lipide identifiziert werden, die mit der bakteriellen Infektion verbunden waren. Des Weiteren hängen eine stabile SCV-Ausbildung und Sn-Infektivität von verschiedenen retrograden Transportwegen und damit von dem Erwerb von Nährstoffen wie bspw. Lipiden ab.
Characterization of motility and erythrocyte adherence as virulence factors in African trypanosomes
(2018)
Pathogens causing African animal trypanosomiasis (AAT), the major livestock disease in sub-Saharan Africa, belong to the salivarian group of the African trypanosomes, which are transmitted by the bite of the tsetse fly (Glossina spec.). T. vivax, T. congolense and T. brucei brucei are major pathogens of cattle in particular, causing nagana, with dramatic socio-economic consequences for the affected regions. The parasites additionally have a huge reservoir of other livestock and wild animal hosts. T. brucei, the species which also includes the subspecies pathogenic to humans causing sleeping sickness, has been extensively studied as the cultivatable model trypanosome. But less is known about the other salivarian species, which are not routinely held in culture, if at all possible. A hallmark of trypanosomal lifestyle is the protozoan flagellates incessant motility, which enables them to populate an enormous range of habitats in very diverse hosts. We were now able to characterize, for the first time with high spatiotemporal resolution microscopy, the swimming behaviour and mechanism of the most relevant salivarian species isolated directly from blood. We show the influence of viscosity on the motility of bloodstream form (BSF) cells and simulate their movement between erythrocytes, giving a clear picture of how all analyzed species move under varying environmental conditions. We show that although the basic mechanism of flagellar motility applies to all analyzed species, there are clear morphological differences that produce different reactions to the physical environment. We could define specific conditions for highly increased swimming persistence and speed for compared to the behaviour in standard culture. These results have important implications for the parasites survival strategies in the host, e.g. regarding the capacity for antibody clearance. Although we show all species to effectively remove antibodies from the cell surface, T. congolense differed markedly in its motility behaviour, which gives rise to interesting questions about this species behaviour in the bloodstream. Most of the T. congolense parasites (and to a lesser extent T. vivax) adhere to sheep erythrocytes. Further in vitro studies showed that T. congolense and T. vivax adhered to rabbit, goat, pig and cattle erythrocytes- but binding behaviour was absent in murine blood. Notably, both T. brucei and T. evansi lacked adherence to all studied host erythrocytes. Generally, attachment to blood cells caused reduction of swimming velocities. Judging from its cell architecture, as well as the motility studies in higher media viscosity and in micropillar arrays, T. congolense is not adapted to swim at high speeds in the mammalian bloodstream. Low swimming speeds could allow these purely intravascular parasites to remain bound to the host erythrocytes.
The present work investigates the influence of environmental stimuli on the building behavior of workers of the leaf-cutting ant Atta vollenweideri. It focuses on cues related to the airflow-driven ventilation of their giant underground nests, i.e., air movements and their direction, carbon dioxide concentrations and humidity levels of the nest air. First, it is shown that workers are able to use airflow and its direction as learned orientation cue by performing learning experiments with individual foragers using a classical conditioning paradigm. This ability is expected to allow workers to also navigate inside the nest tunnels using the prevailing airflow directions for orientation, for example during tasks related to nest construction and climate control.
Furthermore, the influence of carbon dioxide on the digging behavior of workers is investigated. While elevated CO2 levels hardly affect the digging rate of the ants, workers prefer to excavate at locations with lower concentrations and avoid higher CO2 levels when given a choice. Under natural conditions, shifting their digging activity to soil layers containing lower carbon dioxide levels might help colonies to excavate new or to broaden existing nest openings, if the CO2 concentration in the underground rises.
It is also shown that workers preferably transport excavated soil along tunnels containing high CO2 concentrations, when carbon dioxide levels in the underground are elevated as well. In addition, workers prefer to carry soil pellets along outflow tunnels instead of inflow tunnels, at least for high humidity levels of the air. The material transported along tunnels providing outflow of CO2-rich air might be used by workers for the construction of ventilation turrets on top of the nest mound, which is expected to promote the wind-induced ventilation and the removal of carbon dioxide from the underground.
The climatic conditions inside the nest tunnels also influence the structural features of the turrets constructed by workers on top the nest. While airflow and humidity have no effect on turret structure, outflow of CO2-rich air from the nest causes workers to construct turrets with additional openings and increased aperture, potentially enhancing the airflow-driven gas exchanges within the nest.
Finally, the effect of airflow and ventilation turrets on the gas exchanges in Atta vollenweideri nests is tested experimentally on a physical model of a small nest consisting of a single chamber and two nest tunnels. The carbon dioxide clearance rate from the underground was measured depending on both the presence of airflow in the nest and the structural features of the built turrets. Carbon dioxide is removed faster from the physical nest model when air moves through the nest, confirming the contribution of wind-induced flow inside the nest tunnels to the ventilation of Atta vollenweideri nests. In addition, turrets placed on top of one of the tunnel openings of the nest further enhance the CO2 clearance rate and the effect is positively correlated with turret aperture.
Taken together, climatic variables like airflow, carbon dioxide and humidity levels strongly affect the building responses of Atta vollenweideri leaf-cutting ants. Workers use these environmental stimuli as orientation cue in the nest during tasks related to excavation, soil transport and turret construction. Although the effects of these building responses on the microclimatic conditions inside the nest remain elusive so far, the described behaviors are expected to allow ant colonies to restore and maintain a proper nest climate in the underground.
Altersassoziierte und strahleninduzierte Veränderungen des genomweiten DNA-Methylierungs-Profils
(2018)
Der Prozess des Alterns ist ein komplexer multifaktorieller Vorgang, der durch eine sukzessive Verschlechterung der physiologischen Funktionen charakterisiert ist. Ein hohes Alter ist der Hauptrisikofaktor für die meisten Krankheiten, einschließlich Krebs und Herz-Kreislauf-Erkrankungen. Das Verständnis der epigenetischen Mechanismen, die in den Prozess des Alterns involviert sind, könnte zur Entwicklung pharmakologischer Interventionen beitragen, die nicht nur die Lebenserwartung erhöhen, sondern auch den Beginn des altersassoziierten funktionellen Abbaus verzögern könnten. Durch die Langzeit-Kultivierung primärer humaner Fibroblasten wurde ein in vitro Modell für das Altern etabliert, das die Identifizierung altersassoziierter DNA-Methylierungs-Veränderungen ermöglichte. Die in vitro Alterung konnte mit einer globalen Hypomethylierung und einer erhöhten DNA-Methylierung der ribosomalen DNA assoziiert werden. Darüber hinaus konnten DNA-Methylierungs-Veränderungen in Genen und Signalwegen, die für das Altern relevant sind, und ein erhöhtes epigenetisches Alter nachgewiesen werden.
Das in vitro Modell für das Altern wurde verwendet, um neben den direkten Effekten ionisierender Strahlung auf die DNA-Methylierung auch deren Langzeit-Effekte zu untersuchen. Die Strahlentherapie ist ein entscheidendes Element der Krebstherapie, hat aber auch negative Auswirkungen und kann unter anderem das Risiko für die Entwicklung eines Zweittumors erhöhen. Bei externer Bestrahlung wird neben dem Tumor auch gesundes Gewebe ionisierender Strahlung ausgesetzt. Daher ist es wichtig zu untersuchen, wie Zellen mit intakten DNA-Reparatur-Mechanismen und funktionierenden Zellzyklus-Checkpoints durch diese beeinflusst werden. In der frühen Phase der DNA-Schadensantwort auf Bestrahlung wurden in normalen Zellen keine wesentlichen DNA-Methylierungs-Veränderungen beobachtet. Mehrere Populations-Verdoppelungen nach Strahlenexposition konnten dagegen eine globale Hypomethylierung, eine erhöhte DNA-Methylierung der ribosomalen DNA und ein erhöhtes epigenetisches Alter detektiert werden. Des Weiteren zeigten Gene und Signalwege, die mit Krebs in Verbindung gebracht wurden, Veränderungen in der DNA-Methylierung. Als Langzeit-Effekte ionisierender Strahlung traten somit die mit der in vitro Alterung assoziierten DNA-Methylierungs-Veränderungen verstärkt auf und ein epigenetisches Muster, das stark an das DNA-Methylierungs-Profil von Tumorzellen erinnert, entstand. Man geht davon aus, dass Veränderungen der DNA-Methylierung eine aktive Rolle in der Entwicklung eines Tumors spielen. Die durch ionisierende Strahlung induzierten DNA-Methylierungs-Veränderungen in normalen Zellen könnten demnach in die Krebsentstehung nach Strahlenexposition involviert sein und zu dem sekundären Krebsrisiko nach Strahlentherapie beitragen. Es ist bekannt, dass Patienten unterschiedlich auf therapeutische Bestrahlung reagieren. Die Ergebnisse dieser Arbeit weisen darauf hin, dass die individuelle Sensitivität gegenüber ionisierender Strahlung auch auf epigenetischer Ebene beobachtet werden kann.
In einem zweiten Projekt wurden Gesamtblutproben von Patienten mit Werner-Syndrom, einer segmental progeroiden Erkrankung, und gesunden Kontrollen analysiert, um mit dem vorzeitigen Altern in Verbindung stehende DNA-Methylierungs-Veränderungen zu identifizieren. Werner-Syndrom konnte nicht mit einer globalen Hypomethylierung, jedoch mit einer erhöhten DNA-Methylierung der ribosomalen DNA und einem erhöhten epigenetischen Alter assoziiert werden. Das vorzeitige Altern geht demzufolge mit spezifischen epigenetischen Veränderungen einher, die eine Beschleunigung der mit dem normalen Altern auftretenden DNA-Methylierungs-Veränderungen darstellen.
Im Rahmen dieser Arbeit konnte die Bedeutung epigenetischer Mechanismen im Prozess des Alterns hervorgehoben werden und gezeigt werden, dass sowohl exogene Faktoren, wie ionisierende Strahlung, als auch endogene Faktoren, wie das in Werner-Syndrom-Patienten mutiert vorliegende WRN-Gen, altersassoziierte DNA-Methylierungs-Veränderungen beeinflussen können.