@phdthesis{Heddergott2011,
  author    = {Heddergott, Niko},
  title     = {Zellbiologische Aspekte der Motilit{\"a}t von Trypanosoma brucei unter Ber{\"u}cksichtigung der Interaktion mit der Mikroumwelt},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-56791},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2011},
  abstract  = {Trypanosomen sind Protozoen, die Krankheiten bei Mensch und Tier verursachen, die unbehandelt infaust verlaufen. Die Zellen sind hoch motil, angetrieben von einem einzelst{\"a}ndigen Flagellum, welches entlang des Zellk{\"o}rpers angeheftet ist. Selbst in Zellkultur h{\"o}ren Trypanosomen niemals auf sich zu bewegen und eine Ablation funktioneller Bestandteile des Flagellarapparates ist letal f{\"u}r Blutstromformen. Es wurde gezeigt, dass Motilit{\"a}t notwendig ist f{\"u}r die Zellteilung, Organellenpositionierung und Infektiosit{\"a}t. Dies macht Trypanosomen zu besonders geeigneten Modellorganismen f{\"u}r die Untersuchung der Motilit{\"a}t. Dennoch ist erstaunlich wenig {\"u}ber die Motilit{\"a}t bei Trypanosomen bekannt. Dies gilt auch noch genereller f{\"u}r die Protozoen. Unl{\"a}ngst ist dieses Gebiet allerdings in den Fokus vieler Arbeiten ger{\"u}ckt, was bereits erstaunliche, neue Erkenntnisse hervorgebracht hat. Doch Vieles ist noch nicht abschliessend gekl{\"a}rt, so z.B. wie der Flagellarschlag genau reguliert wird, oder wie sich der Schlag des Flagellums entlang des Zellk{\"o}rpers ausbreitet. Die vorliegende Arbeit befasst sich besonders mit den Einfl{\"u}ssen, die die Mikroumgebung auf die Motilit{\"a}t von Blutstromform-Trypanosomen aus{\"u}bt. In ihrem nat{\"u}rlichen Lebensraum finden sich Trypanosomen in einer hoch komplexen Umgebung wieder. Dies gilt sowohl f{\"u}r den Blutkreislauf, als auch f{\"u}r den Gewebezwischenraum in ihrem S{\"a}ugerwirt. Die hohe Konzentration von Zellen, Gewebeverb{\"a}nden und extrazellul{\"a}ren Netzwerken k{\"o}nnte man als Ansammlung von Hindernissen f{\"u}r die Fortbewegung auffassen. Diese Arbeit zeigt dagegen, dass der Mechanismus der Bewegung eine Adaptation an genau diese Umweltbedingungen darstellt, so z.B. an die Viskosit{\"a}t von Blut. Es wird auch ein Bewegungsmodell vorgestellt, das erl{\"a}utert, worin diese Adaption besteht. Dies erkl{\"a}rt auch, warum die Mehrheit der Zellen einer Trypanosomenkultur eine ungerichtete Taumel-Bewegung aufweist in nieder-viskosem Medium, das keine solchen "Hindernisse" enth{\"a}lt. Die Zugabe von Methylcellulose in einer Konzentration von ca. 0,5\% (w/v) erwies sich als geeigneter Ersatz von Blut, um optimale Bedingungen f{\"u}r gerichtetes Schwimmen von Blutstromform Trypanosomen zu erreichen. Zus{\"a}tzlich wurden in dieser Arbeit unterschiedliche Arten von Hindernissen, wie Mikroperlen (Beads) oder molekulare Netzwerke, sowie artifizielle, geordnete Mikrostrukturen verwendet, um die Interaktion mit einer festen Matrix zu untersuchen. In deren Anwesenheit war sowohl die Schwimmgeschwindigkeit, als auch der Anteil an persistent schwimmenden Trypanosomen erh{\"o}ht. Zellen, die frei schwimmend in Fl{\"u}ssigkeiten vorkommen (wie Euglena oder Chlamydomonas), werden effizient durch einen planaren Schlag des Flagellums angetrieben. Trypanosomen hingegen mussten sich evolution{\"a}r an eine komplexe Umgebung anpassen, die mit einer zu raumgreifenden Welle interferieren w{\"u}rde. Der dreidimensionale Flagellarschlag des, an die Zelloberfl{\"a}che angehefteten, Flagellums erlaubt den Trypanosomen eine effiziente Fortbewegung durch die Interaktion mit Objekten in jedweder Richtung gleichermassen. Trypanosomen erreichen dies durch eine hydrodynamisch verursachte Rotation ihres Zellk{\"o}rpers entlang ihrer L{\"a}ngsachse, entgegen dem Uhrzeigersinn. Der Einfluss der Mikroumgebung wurde in fr{\"u}heren Untersuchungen bisher vernachl{\"a}ssigt, ist zum Verst{\"a}ndnis der Motilit{\"a}t von T. brucei jedoch unerl{\"a}sslich. Ein weiterer, bisher nicht untersuchter Aspekt der Beeinflussung der Motilit{\"a}t durch die Umwelt sind hydrodynamische Str{\"o}mungseffekte, denen Trypanosomen im kardiovaskul{\"a}ren System ausgesetzt sind. Diese wurden in dieser Arbeit mittels Mikrofluidik untersucht. Um unser Verst{\"a}ndnis der Motilit{\"a}t von Trypanosomen von 2D, wie {\"u}blich in der Motilit{\"a}tsanalyse mittels Lebend-Zell-Mikroskopie, auf drei Dimensionen auszudehnen, wurde als bildgebendes Verfahren auch die Holographie eingesetzt. Mikrofluidik und Holographie sind beides aufkommende Techniken mit großem Anwendungspotential in der Biologie, die zuvor noch nie f{\"u}r die Motilit{\"a}tsanalyse von Trypanosomen eingesetzt worden waren. Dies erforderte daher interdisziplin{\"a}re Kooperationen. Zus{\"a}tzlich wurde in dieser Arbeit auch ein vollst{\"a}ndig automatisiertes und Software-gesteuertes Fluoreszenzmikroskopiesystem entwickelt, das in der Lage ist, einzelne Zellen durch entsprechende Steuerung des Mikroskoptisches autonom zu verfolgen und somit eine Bewegungsanalyse in Echtzeit erm{\"o}glicht, ohne weitere Benutzerinteraktion. Letztendlich konnte dadurch auch die Bewegung der schlagenden Flagelle und des gesamten Zellk{\"o}rpers mit hoher zeitlicher und r{\"a}umlicher Aufl{\"o}sung mittels Hochgeschwindigkeits-Fluoreszenzmikroskopie aufgekl{\"a}rt werden.},
  subject      = {Trypanosoma brucei},
  language  = {de}
}
@article{CicovaDejungSkalickyetal.2016,
  author    = {Cicova, Zdenka and Dejung, Mario and Skalicky, Tomas and Eisenhuth, Nicole and Hanselmann, Steffen and Morriswood, Brooke and Figueiredo, Luisa M. and Butter, Falk and Janzen, Christian J.},
  title     = {Two flagellar BAR domain proteins in Trypanosoma brucei with stage-specific regulation},
  series = {Scientific Reports},
  volume    = {6},
  journal   = {Scientific Reports},
  doi       = {10.1038/srep35826},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-181021},
  year      = {2016},
  abstract  = {Trypanosomes are masters of adaptation to different host environments during their complex life cycle. Large-scale proteomic approaches provide information on changes at the cellular level, and in a systematic way. However, detailed work on single components is necessary to understand the adaptation mechanisms on a molecular level. Here, we have performed a detailed characterization of a bloodstream form (BSF) stage-specific putative flagellar host adaptation factor Tb927.11.2400, identified previously in a SILAC-based comparative proteome study. Tb927.11.2400 shares 38\% amino acid identity with TbFlabarin (Tb927.11.2410), a procyclic form (PCF) stage-specific flagellar BAR domain protein. We named Tb927.11.2400 TbFlabarin-like (TbFlabarinL), and demonstrate that it originates from a gene duplication event, which occurred in the African trypanosomes. TbFlabarinL is not essential for the growth of the parasites under cell culture conditions and it is dispensable for developmental differentiation from BSF to the PCF in vitro. We generated TbFlabarinL-specific antibodies, and showed that it localizes in the flagellum. Co-immunoprecipitation experiments together with a biochemical cell fractionation suggest a dual association of TbFlabarinL with the flagellar membrane and the components of the paraflagellar rod.},
  language  = {en}
}
@article{SchwedeJonesEngstleretal.2011,
  author    = {Schwede, Angela and Jones, Nicola and Engstler, Markus and Carrington, Mark},
  title     = {The VSG C-terminal domain is inaccessible to antibodies on live trypanosomes},
  series = {Molecular \& Biochemical Parasitology},
  volume    = {175},
  journal   = {Molecular \& Biochemical Parasitology},
  number    = {2},
  doi       = {10.1016/j.molbiopara.2010.11.004},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-142746},
  pages     = {201-204},
  year      = {2011},
  abstract  = {In the mammalian host, the Trypanosoma brucei cell surface is covered with a densely packed protein coat of a single protein, the variant surface glycoprotein (VSG). The VSG is believed to shield invariant surface proteins from host antibodies but there is limited information on how far antibodies can penetrate into the VSG monolayer. Here, the VSG surface coat was probed to determine whether it acts as a barrier to binding of antibodies to the membrane proximal VSG C-terminal domain. The binding of C-terminal domain antibodies to VSG221 or VSG118 was compared with antibodies recognising the cognate whole VSGs. The C-terminal VSG domain was inaccessible to antibodies on live cells but not on fixed cells. This provides further evidence that the VSG coat acts as a barrier and protects the cell from antibodies that would otherwise bind to some of the other externally disposed proteins.},
  language  = {en}
}
@article{GoosDejungJanzenetal.2017,
  author    = {Goos, Carina and Dejung, Mario and Janzen, Christian J. and Butter, Falk and Kramer, Susanne},
  title     = {The nuclear proteome of Trypanosoma brucei},
  series = {PLoS ONE},
  volume    = {12},
  journal   = {PLoS ONE},
  number    = {7},
  doi       = {10.1371/journal.pone.0181884},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-158572},
  pages     = {e0181884},
  year      = {2017},
  abstract  = {Trypanosoma brucei is a protozoan flagellate that is transmitted by tsetse flies into the mammalian bloodstream. The parasite has a huge impact on human health both directly by causing African sleeping sickness and indirectly, by infecting domestic cattle. The biology of trypanosomes involves some highly unusual, nuclear-localised processes. These include polycistronic transcription without classical promoters initiated from regions defined by histone variants, trans-splicing of all transcripts to the exon of a spliced leader RNA, transcription of some very abundant proteins by RNA polymerase I and antigenic variation, a switch in expression of the cell surface protein variants that allows the parasite to resist the immune system of its mammalian host. Here, we provide the nuclear proteome of procyclic Trypanosoma brucei, the stage that resides within the tsetse fly midgut. We have performed quantitative label-free mass spectrometry to score 764 significantly nuclear enriched proteins in comparison to whole cell lysates. A comparison with proteomes of several experimentally characterised nuclear and non-nuclear structures and pathways confirmed the high quality of the dataset: the proteome contains about 80\% of all nuclear proteins and less than 2\% false positives. Using motif enrichment, we found the amino acid sequence KRxR present in a large number of nuclear proteins. KRxR is a sub-motif of a classical eukaryotic monopartite nuclear localisation signal and could be responsible for nuclear localization of proteins in Kinetoplastida species. As a proof of principle, we have confirmed the nuclear localisation of six proteins with previously unknown localisation by expressing eYFP fusion proteins. While proteome data of several T. brucei organelles have been published, our nuclear proteome closes an important gap in knowledge to study trypanosome biology, in particular nuclear-related processes.},
  language  = {en}
}
@phdthesis{Wedel2018,
  author    = {Wedel, Carolin},
  title     = {The impact of DNA sequence and chromatin on transcription in \(Trypanosoma\) \(brucei\)},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-173438},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {For cellular viability, transcription is a fundamental process. Hereby, the DNA plays the most elemental and highly versatile role. It has long been known that promoters contain conserved and often well-defined motifs, which dictate the site of transcription initiation by providing binding sites for regulatory proteins. However, research within the last decade revealed that it is promoters lacking conserved promoter motifs and transcribing constitutively expressed genes that constitute the majority of promoters in eukaryotes. While the process of transcription initiation is well studied, whether defined DNA sequence motifs are required for the transcription of constitutively expressed genes in eukaryotes remains unknown. In the highly divergent protozoan parasite Trypanosoma brucei, most of the proteincoding genes are organized in large polycistronic transcription units. The genes within one polycistronic transcription unit are generally unrelated and transcribed by a common transcription start site for which no RNA polymerase II promoter motifs have been identified so far. Thus, it is assumed that transcription initiation is not regulated but how transcription is initiated in T. brucei is not known. This study aimed to investigate the requirement of DNA sequence motifs and chromatin structures for transcription initiation in an organism lacking transcriptional regulation. To this end, I performed a systematic analysis to investigate the dependence of transcription initiation on the DNA sequence. I was able to identify GT-rich promoter elements required for directional transcription initiation and targeted deposition of the histone variant H2A.Z, a conserved component during transcription initiation. Furthermore, nucleosome positioning data in this work provide evidence that sites of transcription initiation are rather characterized by broad regions of open and more accessible chromatin than narrow nucleosome depleted regions as it is the case in other eukaryotes. These findings highlight the importance of chromatin during transcription initiation. Polycistronic RNA in T. brucei is separated by adding an independently transcribed miniexon during trans-splicing. The data in this work suggest that nucleosome occupancy plays an important role during RNA maturation by slowing down the progressing polymerase and thereby facilitating the choice of the proper splice site during trans-splicing. Overall, this work investigated the role of the DNA sequence during transcription initiation and nucleosome positioning in a highly divergent eukaryote. Furthermore, the findings shed light on the conservation of the requirement of DNA motifs during transcription initiation and the regulatory potential of chromatin during RNA maturation. The findings improve the understanding of gene expression regulation in T. brucei, a eukaryotic parasite lacking transcriptional Regulation.},
  subject      = {Transkription},
  language  = {en}
}
@phdthesis{Subota2011,
  author    = {Subota, Ines},
  title     = {Switches in trypanosome differentiation: ALBA proteins acting on post-transcriptional mRNA control},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85707},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2011},
  abstract  = {Trypanosoma brucei is a digenetic eukaryotic parasite that develops in different tissues of a mammalian host and a tsetse fly. It is responsible for sleeping sickness in sub-saharan Africa. The parasite cycle involves more than nine developmental stages that can be clearly distinguished by their general morphology, their metabolism and the relative positioning of their DNA-containing organelles. During their development, trypanosomes remain exclusively extracellular and encounter changing environments with different physico-chemical properties (nutritional availability, viscosity, temperature, etc.). It has been proposed that trypanosomes use their flagellum as a sensing organelle, in agreement with the established role of structurally-related cilia in metazoa and ciliates. Recognition of environmental triggers is presumed to be at the initiation of differentiation events, leading to the parasite stage that is the best suited to the new environment. These changes are achieved by the modification of gene expression programmes, mostly underlying post-transcriptional control of mRNA transcripts. We first demonstrate that the RNA-binding proteins ALBA3/4 are involved in specific differentiation processes during the parasite development in the fly. They are cytosolic and expressed throughout the parasite cycle with the exception of the stages found in the tsetse fly proventriculus, as shown by both immunofluorescence and live cell analysis upon endogenous tagging with YFP. Knock-down of both proteins in the developmental stage preceding these forms leads to striking modifications: cell elongation, cell cycle arrest and relocalization of the nucleus in a posterior position, all typical of processes acting in parasites found in the proventriculus region. When ALBA3 is over-expressed from an exogenous copy during infection, it interferes with the relocalization of the nucleus in proventricular parasites. This is not observed for ALBA4 over-expression that does not visibly impede differentiation. Both ALBA3/4 proteins react to starvation conditions by accumulating in cytoplasmic stress granules together with DHH1, a recognized RNA-binding protein. ALBA3/4 proteins also partially colocalize with granules formed by polyA+ RNA in these conditions. We propose that ALBA are involved in trypanosome differentiation processes where they control a subset of developmentally regulated transcripts. These processes involving ALBA3/4 are likely to result from the specific activation of sensing pathways. In the second part of the thesis, we identify novel flagellar proteins that could act in sensing mechanisms. Several protein candidates were selected from a proteomic analysis of intact flagella performed in the host laboratory. This work validates their flagellar localization with high success (85\% of the proteins examined) and defines multiple different patterns of protein distribution in the flagellum. Two proteins are analyzed during development, one of them showing down-regulation in proventricular stages. The functional analysis of one novel flagellar membrane protein reveals its rapid dynamics within the flagellum but does not yield a visible phenotype in culture. This is coherent with sensory function that might not be needed in stable culture conditions, but could be required in natural conditions during development. In conclusion, this work adds new pieces to the puzzle of identifying molecular switches involved in developmental mRNA control and environmental sensing in trypanosome stages in the tsetse fly.},
  subject      = {Trypanosoma brucei},
  language  = {en}
}
@phdthesis{Schwebs2024,
  author    = {Schwebs, Marie},
  title     = {Structure and dynamics of the plasma membrane: a single-molecule study in \(Trypanosoma\) \(brucei\)},
  doi       = {10.25972/OPUS-27569},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-275699},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {The unicellular, flagellated parasite Trypanosoma brucei is the causative agent of human African sleeping sickness and nagana in livestock. In the last decades, it has become an established eukaryotic model organism in the field of biology, as well as in the interdisciplinary field of biophysics. For instance, the dense variant surface glycoprotein (VSG) coat offers the possibility to study the dynamics of GPI-anchored proteins in the plasma membrane of living cells. The fluidity of the VSG coat is not only an interesting object of study for its own sake, but is critically important for the survival of the parasite in the mammalian host. In order to maintain the integrity of the coat, the entire VSG coat is recycled within a few minutes. This is surprisingly fast for a purely diffusive process with the flagellar pocket (FP) as the sole site for endo- and exocytosis. Previous studies characterising VSG dynamics using FRAP reported diffusion coefficients that were not sufficient to to enable fast turnover based on passive VSG randomisation on the trypanosome surface. In this thesis, live-cell single-molecule fluorescence microscopy (SMFM) was employed to elucidate whether VSG diffusion coefficients were priorly underestimated or whether directed forces could be involved to bias VSGs towards the entrance of the FP. Embedding the highly motile trypanosomes in thermo-stable hydrogels facilitated the investigation of VSG dynamics on living trypanosomes at the mammalian host's temperature of 37°C. To allow for a spatial correlation of the VSG dynamics to the FP entrance, a cell line was employed harbouring a fluorescently labelled structure as a reference. Sequential two-colour SMFM was then established to allow for recording and registration of the dynamic and static single-molecule information. In order to characterise VSG dynamics, an algorithm to obtain reliable information from short trajectories was adapted (shortTrAn). It allowed for the quantification of the local dynamics in two distinct scenarios: diffusion and directed motion. The adaptation of the algorithm to the VSG data sets required the introduction of an additional projection filter. The algorithm was further extended to take into account the localisation errors inherent to single-particle tracking. The results of the quantification of diffusion and directed motion were presented in maps of the trypanosome surface, including an outline generated from a super-resolved static structure as a reference. Information on diffusion was displayed in one map, an ellipse plot. The colour code represented the local diffusion coefficient, while the shape of the ellipses provided an indication of the diffusion behaviour (aniso- or isotropic diffusion). The eccentricity of the ellipses was used to quantify deviations from isotropic diffusion. Information on directed motion was shown in three maps: A velocity map, representing the amplitude of the local velocities in a colour code. A quiver plot, illustrating the orientation of directed motion, and a third map which indicated the relative standard error of the local velocities colour-coded. Finally, a guideline based on random walk simulations was used to identify which of the two motion scenarios dominated locally. Application of the guideline to the VSG dynamics analysed by shortTrAn yielded supermaps that showed the locally dominant motion mode colour-coded. I found that VSG dynamics are dominated by diffusion, but several times faster than previously determined. The diffusion behaviour was additionally characterised by spatial heterogeneity. Moreover, isolated regions exhibiting the characteristics of round and elongated traps were observed on the cell surface. Additionally, VSG dynamics were studied with respect to the entrance of the FP. VSG dynamics in this region displayed similar characteristics compared to the remainder of the cell surface and forces biasing VSGs into the FP were not found. Furthermore, I investigated a potential interference of the attachment of the cytoskeleton to the plasma membrane with the dynamics of VSGs which are anchored to the outer leaflet of the membrane. Preliminary experiments were conducted on osmotically swollen trypanosomes and trypanosomes depleted for a microtubule-associated protein anchoring the subpellicular microtubule cytoskeleton to the plasma membrane. The measurements revealed a trend that detachment of the cytoskeleton could be associated with a reduction in the VSG diffusion coefficient and a loss of elongated traps. The latter could be an indication that these isolated regions were caused by underlying structures associated with the cytoskeleton. The measurements on cells with an intact cytoskeleton were complemented by random walk simulations of VSG dynamics with the newly determined diffusion coefficient on long time scales not accessible in experiments. Simulations showed that passive VSG randomisation is fast enough to allow for a turnover of the full VSG coat within a few minutes. According to an estimate based on the known rate of endocytosis and the newly determined VSG diffusion coefficient, the majority of exocytosed VSGs could escape from the FP to the cell surface without being immediately re-endocytosed.},
  subject      = {Trypanosoma brucei},
  language  = {en}
}
@phdthesis{Glogger2018,
  author    = {Glogger, Marius},
  title     = {Single-molecule fluorescence microscopy in live \(Trypanosoma\) \(brucei\) and model membranes},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-169222},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {Der eukaryotische Parasit Trypanosoma brucei hat komplexe Strategien entwickelt um der Immunantwort eines Wirtes zu entkommen und eine persistente Infektion innerhalb dessen aufrechtzuerhalten. Ein zentrales Element seiner Verteidigungsstrategie st{\"u}tzt sich auf die Schutzfunktion seines Proteinmantels auf der Zelloberfl{\"a}che. Dieser Mantel besteht aus einer dichten Schicht aus identischen, Glykosylphosphatidylinositol (GPI)-verankerten variablen Oberfl{\"a}chenglykoproteinen (VSG). Der VSG Mantel verhindert die Erkennung der darunterliegenden, invarianten Epitope durch das Immunsystem. Obwohl es notwendig ist die Funktionsweise des VSG Mantels zu verstehen, vor allem um ihn als m{\"o}gliches Angriffsziel gegen den Parasiten zu verwenden, sind seine biophysikalischen Eigenschaften bisher nur unzureichend verstanden. Dies ist vor allem der Tatsache geschuldet, dass die hohe Motilit{\"a}t der Parasiten mikroskopische Studien in lebenden Zellen bisher weitestgehend verhinderten. In der vorliegenden Arbeit wird nun hochmoderne Einzelmolek{\"u}l-Fluoreszenzmikroskopie (EMFM) als M{\"o}glichkeit f{\"u}r mikroskopische Untersuchungen im Forschungsbereich der Trypanosomen vorgestellt. Die Arbeit umfasst Untersuchungen der VSG Dynamik unter definierten Bedingungen k{\"u}nstlicher Membransysteme. Es wurde zuerst der Einfluss der lateralen Proteindichte auf die VSG Diffusion untersucht. Experimente mittels Fluoreszenz- Wiederkehr nach irreversiblem Photobleichen und komplement{\"a}re Einzelmolek{\"u}l- Verfolgungs Experimente offenbarten, dass ein molekularer Diffusionsschwellenwert existiert. {\"U}ber diesem Schwellenwert wurde eine dichteabh{\"a}nige Reduzierung des Diffusionskoeffizienten gemessen. Eine relative Quantifizierung der rekonstituierten VSGs verdeutlichte, dass der Oberfl{\"a}chenmantel der Trypanosomen sehr nahe an diesem Schwellenwert agiert. Der VSG Mantel ist optimiert um eine hohe Proteindichte bei gleichzeitiger hoher Mobilit{\"a}t der VSGs zu gew{\"a}hrleisten. Des Weiteren wurde der Einfluss der VSG N-Glykosylierung auf die Diffusion des Proteins quantitativ untersucht. Die Messungen ergaben, dass die N-Glykosylierung dazu beitr{\"a}gt eine hohe Mobilit{\"a}t bei hohen Proteindichten aufrechtzuerhalten. Eine detaillierte Analyse von VSG Trajektorien offenbarte, dass zwei unterschiedliche Populationen frei diffundierender VSGs in der k{\"u}nstlichen Membran vorlagen. K{\"u}rzlich wurde entdeckt, dass VSGs zwei strukturell unterschiedliche Konformationen annehmen k{\"o}nnen. Die Messungen in der Arbeit stimmen mit diesen Beschreibungen {\"u}berein. Die Ergebnisse der EMFM in k{\"u}nstlichen Membranen wurden durch VSG Einzelmolek{\"u}l- Verfolgungs Experimente auf lebenden Zellen erg{\"a}nzt. Es wurde eine hohe Mobilit{\"a}t und Dynamik einzelner VSGs gemessen, was die allgemein dynamische Natur des VSG Mantels verdeutlicht. Dies f{\"u}hrte zu der Schlussfolgerung, dass der VSG Mantel auf lebenden Trypanosomen ein dichter und dennoch dynamischer Schutzmantel ist. Die F{\"a}higkeit der VSGs ihre Konformation flexibel anzupassen, unterst{\"u}tzt das Erhalten der Fluidit{\"a}t bei variablen Dichten. Diese Eigenschaften des VSG Mantels sind elementar f{\"u}r die Aufrechterhaltung einer presistenden Infektion eines Wirtes. In dieser Arbeit werden des Weiteren verschiedene, auf Hydrogel basierende Einbettungsmethoden vorgestellt. Diese erm{\"o}glichten die Zellimmobilisierung und erlaubten EMFM in lebenden Trypanosomen. Die Hydrogele wiesen eine hohe Zytokompatibilit{\"a}t auf. Die Zellen {\"u}berlebten in den Gelen f{\"u}r eine Stunde nach Beginn der Immobilisierung. Die Hydrogele erf{\"u}llten die Anforderungen der Superresolution Mikroskopie (SRM) da sie eine geringe Autofluoreszenz im Spektralbereich der verwendeten Fluorophore besaßen. Mittels SRM konnte nachgewiesen werden, dass die Hydrogele die Zellen effizient immobilisierten. Als erstes Anwendungsbeispiel der Methode wurde die Organisation der Plasmamembran in lebenden Trypanosomen untersucht. Die Untersuchung eines fluoreszenten Tracers in der inneren Membranschicht ergab, dass dessen Verteilung nicht homogen war. Es wurden spezifische Membrandom{\"a}nen gefunden, in denen das Molek{\"u}l entweder vermehrt oder vermindert auftrat. Dies f{\"u}hrte zu der Schlussfolgerung, dass diese Verteilung durch eine Interaktion des Tracers mit Proteinen des zellul{\"a}ren Zytoskeletts zustande kam. Die in dieser Arbeit pr{\"a}sentierten Ergebnisse zeigen, dass EMFM erfolgreich f{\"u}r verschiedene biologische Untersuchungen im Forschungsfeld der Trypanosomen angewendet werden kann. Dies gilt zum Beispiel f{\"u}r die Untersuchung von der VSG Dynamik in k{\"u}nstlichen Membransystemen, aber auch f{\"u}r Studien in lebenden Zellen unter Verwendung der auf Hydrogelen basierenden Zelleinbettung.},
  subject      = {Trypanosoma brucei},
  language  = {en}
}
@article{KruegerMausKressetal.2021,
  author    = {Kr{\"u}ger, Timothy and Maus, Katharina and Kreß, Verena and Meyer-Natus, Elisabeth and Engstler, Markus},
  title     = {Single-cell motile behaviour of Trypanosoma brucei in thin-layered fluid collectives},
  series = {The European Physical Journal E},
  volume    = {44},
  journal   = {The European Physical Journal E},
  number    = {3},
  issn      = {1292-895X},
  doi       = {10.1140/epje/s10189-021-00052-7},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-273022},
  year      = {2021},
  abstract  = {We describe a system for the analysis of an important unicellular eukaryotic flagellate in a confining and crowded environment. The parasite Trypanosoma brucei is arguably one of the most versatile microswimmers known. It has unique properties as a single microswimmer and shows remarkable adaptations (not only in motility, but prominently so), to its environment during a complex developmental cycle involving two different hosts. Specific life cycle stages show fascinating collective behaviour, as millions of cells can be forced to move together in extreme confinement. Our goal is to examine such motile behaviour directly in the context of the relevant environments. Therefore, for the first time, we analyse the motility behaviour of trypanosomes directly in a widely used assay, which aims to evaluate the parasites behaviour in collectives, in response to as yet unknown parameters. In a step towards understanding whether, or what type of, swarming behaviour of trypanosomes exists, we customised the assay for quantitative tracking analysis of motile behaviour on the single-cell level. We show that the migration speed of cell groups does not directly depend on single-cell velocity and that the system remains to be simplified further, before hypotheses about collective motility can be advanced.},
  language  = {en}
}
@phdthesis{BakariSoale2024,
  author    = {Bakari Soale, Majeed},
  title     = {Regulation of the Variant Surface Glycoprotein (VSG) Expression and Characterisation of the Nucleolar DExD/H box Protein Hel66 in \(Trypanosoma\) \(brucei\)},
  doi       = {10.25972/OPUS-25809},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-258090},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {The variant surface glycoprotein (VSG) of African trypanosomes plays an essential role in protecting the parasites from host immune factors. These trypanosomes undergo antigenic variation resulting in the expression of a single VSG isoform out of a repertoire of around 2000 genes. The molecular mechanism central to the expression and regulation of the VSG is however not fully understood. Gene expression in trypanosomes is unusual due to the absence of typical RNA polymerase II promoters and the polycistronic transcription of genes. The regulation of gene expression is therefore mainly post-transcriptional. Regulatory sequences, mostly present in the 3´ UTRs, often serve as key elements in the modulation of the levels of individual mRNAs. In T. brucei VSG genes, a 100 \% conserved 16mer motif within the 3´ UTR has been shown to modulate the stability of VSG transcripts and hence their expression. As a stability-associated sequence element, the absence of nucleotide substitutions in the motif is however unusual. It was therefore hypothesised that the motif is involved in other essential roles/processes besides stability of the VSG transcripts. In this study, it was demonstrated that the 100 \% conservation of the 16mer motif is not essential for cell viability or for the maintenance of functional VSG protein levels. It was further shown that the intact motif in the active VSG 3´ UTR is neither required to promote VSG silencing during switching nor is it needed during differentiation from bloodstream forms to procyclic forms. Crosstalk between the VSG and procyclin genes during differentiation to the insect vector stage is also unaffected in cells with a mutated 16mer motif. Ectopic overexpression of a second VSG however requires the intact motif to trigger silencing and exchange of the active VSG, suggesting a role for the motif in transcriptional VSG switching. The 16mer motif therefore plays a dual role in VSG in situ switching and stability of VSG transcripts. The additional role of the 16mer in the essential process of antigenic variation appears to be the driving force for the 100 \% conservation of this RNA motif. A screen aimed at identifying candidate RNA-binding proteins interacting with the 16mer motif, led to the identification of a DExD/H box protein, Hel66. Although the protein did not appear to have a direct link to the 16mer regulation of VSG expression, the DExD/H family of proteins are important players in the process of ribosome biogenesis. This process is relatively understudied in trypanosomes and so this candidate was singled out for detailed characterisation, given that the 16mer story had reached a natural end point. Ribosome biogenesis is a major cellular process in eukaryotes involving ribosomal RNA, ribosomal proteins and several non-ribosomal trans-acting protein factors. The DExD/H box proteins are the most important trans-acting protein factors involved in the biosynthesis of ribosomes. Several DExD/H box proteins have been directly implicated in this process in yeast. In trypanosomes, very few of this family of proteins have been characterised and therefore little is known about the specific roles they play in RNA metabolism. Here, it was shown that Hel66 is involved in rRNA processing during ribosome biogenesis. Hel66 localises to the nucleolus and depleting the protein led to a severe growth defect. Loss of the protein also resulted in a reduced rate of global translation and accumulation of rRNA processing intermediates of both the small and large ribosomal subunits. Hel66 is therefore an essential nucleolar DExD/H protein involved in rRNA processing during ribosome biogenesis. As very few protein factors involved in the processing of rRNAs have been described in trypanosomes, this finding represents an important platform for future investigation of this topic.},
  subject      = {Trypanosoma brucei},
  language  = {en}
}