TY - JOUR A1 - Krüger, Timothy A1 - Maus, Katharina A1 - Kreß, Verena A1 - Meyer-Natus, Elisabeth A1 - Engstler, Markus T1 - Single-cell motile behaviour of Trypanosoma brucei in thin-layered fluid collectives JF - The European Physical Journal E N2 - 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. KW - Trypanosoma brucei KW - motile behaviour KW - fluid collectives Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-273022 SN - 1292-895X VL - 44 IS - 3 ER - TY - JOUR A1 - Krüger, Timothy A1 - Engstler, Markus T1 - The fantastic voyage of the trypanosome: a protean micromachine perfected during 500 million years of engineering JF - Micromachines N2 - The human body is constantly attacked by pathogens. Various lines of defence have evolved, among which the immune system is principal. In contrast to most pathogens, the African trypanosomes thrive freely in the blood circulation, where they escape immune destruction by antigenic variation and incessant motility. These unicellular parasites are flagellate microswimmers that also withstand the harsh mechanical forces prevailing in the bloodstream. They undergo complex developmental cycles in the bloodstream and organs of the mammalian host, as well as the disease-transmitting tsetse fly. Each life cycle stage has been shaped by evolution for manoeuvring in distinct microenvironments. Here, we introduce trypanosomes as blueprints for nature-inspired design of trypanobots, micromachines that, in the future, could explore the human body without affecting its physiology. We review cell biological and biophysical aspects of trypanosome motion. While this could provide a basis for the engineering of microbots, their actuation and control still appear more like fiction than science. Here, we discuss potentials and challenges of trypanosome-inspired microswimmer robots. KW - trypanosoma KW - microswimmer KW - parasite KW - flagellate KW - microenvironment KW - cellular waveform KW - tsetse KW - microbot KW - trypanobot Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-175944 VL - 9 IS - 2 ER - TY - JOUR A1 - Schuster, Sarah A1 - Krüger, Timothy A1 - Subota, Ines A1 - Thusek, Sina A1 - Rotureau, Brice A1 - Beilhack, Andreas A1 - Engstler, Markus T1 - Developmental adaptations of trypanosome motility to the tsetse fly host environments unravel a multifaceted in vivo microswimmer system JF - eLife N2 - The highly motile and versatile protozoan pathogen Trypanosoma brucei undergoes a complex life cycle in the tsetse fly. Here we introduce the host insect as an expedient model environment for microswimmer research, as it allows examination of microbial motion within a diversified, secluded and yet microscopically tractable space. During their week-long journey through the different microenvironments of the fly´s interior organs, the incessantly swimming trypanosomes cross various barriers and confined surroundings, with concurrently occurring major changes of parasite cell architecture. Multicolour light sheet fluorescence microscopy provided information about tsetse tissue topology with unprecedented resolution and allowed the first 3D analysis of the infection process. High-speed fluorescence microscopy illuminated the versatile behaviour of trypanosome developmental stages, ranging from solitary motion and near-wall swimming to collective motility in synchronised swarms and in confinement. We correlate the microenvironments and trypanosome morphologies to high-speed motility data, which paves the way for cross-disciplinary microswimmer research in a naturally evolved environment. KW - none KW - tsetse fly KW - Trypanosoma KW - biophysics KW - microswimmer KW - sleeping sickness KW - structural biology Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-158662 VL - 6 ER - TY - JOUR A1 - Bargul, Joel L. A1 - Jung, Jamin A1 - McOdimba, Francis A. A1 - Omogo, Collins O. A1 - Adung'a, Vincent O. A1 - Krüger, Timothy A1 - Masiga, Daniel K. A1 - Engstler, Markus T1 - Species-Specific Adaptations of Trypanosome Morphology and Motility to the Mammalian Host JF - PLoS Pathogens N2 - African trypanosomes thrive in the bloodstream and tissue spaces of a wide range of mammalian hosts. Infections of cattle cause an enormous socio-economic burden in sub-Saharan Africa. A hallmark of the trypanosome lifestyle is the flagellate’s incessant motion. This work details the cell motility behavior of the four livestock-parasites Trypanosoma vivax, T. brucei, T. evansi and T. congolense. The trypanosomes feature distinct swimming patterns, speeds and flagellar wave frequencies, although the basic mechanism of flagellar propulsion is conserved, as is shown by extended single flagellar beat analyses. Three-dimensional analyses of the trypanosomes expose a high degree of dynamic pleomorphism, typified by the ‘cellular waveform’. This is a product of the flagellar oscillation, the chirality of the flagellum attachment and the stiffness of the trypanosome cell body. The waveforms are characteristic for each trypanosome species and are influenced by changes of the microenvironment, such as differences in viscosity and the presence of confining obstacles. The distinct cellular waveforms may be reflective of the actual anatomical niches the parasites populate within their mammalian host. T. vivax displays waveforms optimally aligned to the topology of the bloodstream, while the two subspecies T. brucei and T. evansi feature distinct cellular waveforms, both additionally adapted to motion in more confined environments such as tissue spaces. T. congolense reveals a small and stiff waveform, which makes these parasites weak swimmers and destined for cell adherence in low flow areas of the circulation. Thus, our experiments show that the differential dissemination and annidation of trypanosomes in their mammalian hosts may depend on the distinct swimming capabilities of the parasites. KW - swimming KW - viscosity KW - flagella KW - host-pathogen interactions KW - cell motility KW - blood KW - parasitic diseases KW - trypanosoma brucei gambiense Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-146513 VL - 12 IS - 2 ER - TY - JOUR A1 - Alizadehrad, Davod A1 - Krüger, Timothy A1 - Engstler, Markus A1 - Stark, Holger T1 - Simulating the complex cell design of Trypanosoma brucei and its motility JF - PLOS Computational Biology N2 - The flagellate Trypanosoma brucei, which causes the sleeping sickness when infecting a mammalian host, goes through an intricate life cycle. It has a rather complex propulsion mechanism and swims in diverse microenvironments. These continuously exert selective pressure, to which the trypanosome adjusts with its architecture and behavior. As a result, the trypanosome assumes a diversity of complex morphotypes during its life cycle. However, although cell biology has detailed form and function of most of them, experimental data on the dynamic behavior and development of most morphotypes is lacking. Here we show that simulation science can predict intermediate cell designs by conducting specific and controlled modifications of an accurate, nature-inspired cell model, which we developed using information from live cell analyses. The cell models account for several important characteristics of the real trypanosomal morphotypes, such as the geometry and elastic properties of the cell body, and their swimming mechanism using an eukaryotic flagellum. We introduce an elastic network model for the cell body, including bending rigidity and simulate swimming in a fluid environment, using the mesoscale simulation technique called multi-particle collision dynamics. The in silico trypanosome of the bloodstream form displays the characteristic in vivo rotational and translational motility pattern that is crucial for survival and virulence in the vertebrate host. Moreover, our model accurately simulates the trypanosome's tumbling and backward motion. We show that the distinctive course of the attached flagellum around the cell body is one important aspect to produce the observed swimming behavior in a viscous fluid, and also required to reach the maximal swimming velocity. Changing details of the flagellar attachment generates less efficient swimmers. We also simulate different morphotypes that occur during the parasite's development in the tsetse fly, and predict a flagellar course we have not been able to measure in experiments so far. KW - multiparticle collision dynamics KW - human african trypanosomiasis KW - biology KW - cytoskeleton KW - flow KW - flagellar motility KW - tsetse fly KW - propulsion KW - cytokinesis KW - parasites Y1 - 2015 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-144610 VL - 11 IS - 1 ER - TY - JOUR A1 - Heddergott, Niko A1 - Krüger, Timothy A1 - Babu, Sujin B. A1 - Wei, Ai A1 - Stellamanns, Erik A1 - Uppaluri, Sravanti A1 - Pfohl, Thomas A1 - Stark, Holger A1 - Engstler, Markus T1 - Trypanosome Motion Represents an Adaptation to the Crowded Environment of the Vertebrate Bloodstream JF - PLoS Pathogens N2 - Blood is a remarkable habitat: it is highly viscous, contains a dense packaging of cells and perpetually flows at velocities varying over three orders of magnitude. Only few pathogens endure the harsh physical conditions within the vertebrate bloodstream and prosper despite being constantly attacked by host antibodies. African trypanosomes are strictly extracellular blood parasites, which evade the immune response through a system of antigenic variation and incessant motility. How the flagellates actually swim in blood remains to be elucidated. Here, we show that the mode and dynamics of trypanosome locomotion are a trait of life within a crowded environment. Using high-speed fluorescence microscopy and ordered micro-pillar arrays we show that the parasites mode of motility is adapted to the density of cells in blood. Trypanosomes are pulled forward by the planar beat of the single flagellum. Hydrodynamic flow across the asymmetrically shaped cell body translates into its rotational movement. Importantly, the presence of particles with the shape, size and spacing of blood cells is required and sufficient for trypanosomes to reach maximum forward velocity. If the density of obstacles, however, is further increased to resemble collagen networks or tissue spaces, the parasites reverse their flagellar beat and consequently swim backwards, in this way avoiding getting trapped. In the absence of obstacles, this flagellar beat reversal occurs randomly resulting in irregular waveforms and apparent cell tumbling. Thus, the swimming behavior of trypanosomes is a surprising example of micro-adaptation to life at low Reynolds numbers. For a precise physical interpretation, we compare our high-resolution microscopic data to results from a simulation technique that combines the method of multi-particle collision dynamics with a triangulated surface model. The simulation produces a rotating cell body and a helical swimming path, providing a functioning simulation method for a microorganism with a complex swimming strategy. KW - simulation KW - multiparticle collision dynamics KW - propulsion KW - viscosity KW - flagellar KW - motility KW - solvent KW - model KW - hydrodynamics KW - spiroplasma Y1 - 2012 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-134595 VL - 8 IS - 11 ER - TY - JOUR A1 - Heddergott, Nico A1 - Krüger, Timothy A1 - Babu, Sujin B. A1 - Wei, Ai A1 - Stellamanns, Erik A1 - Uppaluri, Sravanti A1 - Pfohl, Thomas A1 - Stark, Holger A1 - Engstler, Markus T1 - Trypanosome Motion Represents an Adaptation to the Crowded Environment ofthe Vertebrate Bloodstream N2 - Blood is a remarkable habitat: it is highly viscous, contains a dense packaging of cells and perpetually flows at velocities varying over three orders of magnitude. Only few pathogens endure the harsh physical conditions within the vertebrate bloodstream and prosper despite being constantly attacked by host antibodies. African trypanosomes are strictly extracellular blood parasites, which evade the immune response through a system of antigenic variation and incessant motility. How the flagellates actually swim in blood remains to be elucidated. Here, we show that the mode and dynamics of trypanosome locomotion are a trait of life within a crowded environment. Using high-speed fluorescence microscopy and ordered micro-pillar arrays we show that the parasites mode of motility is adapted to the density of cells in blood. Trypanosomes are pulled forward by the planar beat of the single flagellum. Hydrodynamic flow across the asymmetrically shaped cell body translates into its rotational movement. Importantly, the presence of particles with the shape, size and spacing of blood cells is required and sufficient for trypanosomes to reach maximum forward velocity. If the density of obstacles, however, is further increased to resemble collagen networks or tissue spaces, the parasites reverse their flagellar beat and consequently swim backwards, in this way avoiding getting trapped. In the absence of obstacles, this flagellar beat reversal occurs randomly resulting in irregular waveforms and apparent cell tumbling. Thus, the swimming behavior of trypanosomes is a surprising example of micro-adaptation to life at low Reynolds numbers. For a precise physical interpretation, we compare our high-resolution microscopic data to results from a simulation technique that combines the method of multi-particle collision dynamics with a triangulated surface model. The simulation produces a rotating cell body and a helical swimming path, providing a functioning simulation method for a microorganism with a complex swimming strategy KW - Biologie Y1 - 2012 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-78421 ER - TY - THES A1 - Krüger, Timothy T1 - Zur funktionellen Architektur des Nukleolus in lebenden Zellen T1 - Functional architecture of the nucleolus in living cells: Dynamics of nucleolar proteins. N2 - In der vorliegenden Arbeit wurden Fusionsprodukte aus verschiedenen nukleolären Proteinen mit fluoreszierenden Proteinen (GFP und dsRed: rot fluoreszierendes Protein) in lebenden Zellen von Säugern und Xenopus laevis exprimiert und lokalisiert. Dadurch standen "Marker" für die drei Hauptkomponenten des Nukleolus zur Verfügung. Die dynamischen Eigenschaften dieser Fusionsproteine wurden quantitativ mit Hilfe von "Photobleaching"-Experimenten analysiert (FRAP: fluorescence recovery after photobleaching). Im einzelnen wurde durch die Untersuchung von RNA-Polymerase I der rDNA Transkriptionsort im fibrillären Zentrum des Nukleolus bestätigt. Die kinetischen Analysen von zwei pol I-Untereinheiten (RPA194 und RPA53) durch FRAP in transkriptionell aktiven und inaktiven Nukleoli erlaubten direkte Rückschlüsse auf die Transkriptionsdauer der rRNA-Gene in vivo. Die individuellen pol I-Untereinheiten bewegen sich rasch zwischen Nukleoplasma und Nukleolus und interagieren in den fibrillären Zentren mit dem rDNA-Promoter. Dann werden sie in produktive Transkriptionskomplexe integriert, die während der Elongationsphase, die bei Raumtemperatur etwa fünf Minuten dauert, stabil bleiben und erst nach der Termination dissoziieren. Zumindest ein Teil der Untereinheiten wandert anschließend in das Nukleoplasma. Die Ergebnisse widersprechen Modellen, welche die dichte fibrilläre Komponente als Transkriptionsort ansehen oder immobile RNA Polymerase I-Moleküle postulieren. Die Identifizierung des fibrillären Zentrums als rDNA-Transkriptionsort wurde durch die Koexpression der pol I-Untereinheiten mit Fibrillarin, einem Leitprotein der dichten fibrillären Komponente, ermöglicht. Durch die Expression der beiden Proteine als unterschiedlich fluoreszierende Fusionsproteine konnten die Orte der Transkription (die fibrillären Zentren) und die Orte der ersten Prozessierungsschritte, an denen Fibrillarin beteiligt ist (die dichte fibrilläre Komponente), in lebenden Zellen als direkt benachbarte, aber räumlich getrennte Kompartimente identifiziert werden. Die Rolle der granulären Komponente als Ort späterer Prozessierungschritte und Integration ribosomaler Proteine wurde durch die Expression von B23 und der ribosomalen Proteine L4, L5 und L10 verdeutlicht. Dabei wurde die nukleoläre Lokalisation von L10 erstmals belegt. In der Literatur wurde bisher angenommen, L10 würde erst im Cytoplasma mit Ribosomen assoziieren. Dies ist nicht der Fall, wie insbesondere Experimente mit Leptomycin B gezeigt haben. Diese Droge hemmt den CRM1-abhängigen Kernexport und führte zu einer deutlichen Akkumulation von L10-haltigen Präribosomen im Nukleoplasma von menschlichen Zellen. Schließlich sollte ein neues nukleoläres Protein von Xenopus laevis molekular charakterisiert werden, das mit verschiedenen Antikörpern in der granulären Komponente des Nukleolus lokalisiert wurde. Durch massenspektrometrische Analysen nach zweidimensionaler Gelelektrophorese wurden die Antigene überraschenderweise als Cytokeratin-Homologe identifiziert. Im Verlauf dieser Arbeit wurden drei bisher unveröffentlichte Cytokeratin 19 Isoformen von Xenopus kloniert, sequenziert und als GFP-Fusionsproteine exprimiert. Diese wurden allerdings wie reguläre Cytokeratine in cytoplasmatische Intermediärfilamente integriert und konnten, auch nach Translokation in den Zellkern durch ein experimentell eingefügtes Lokalisationssignal, nicht im Nukleolus nachgewiesen werden. Nach der Kotransfektion mit verschiedenen Zellkern-Proteinen wurde Cytokeratin 19 mit diesen in den Zellkern und mit nukleolären Proteinen in den Nukleolus transportiert. Obwohl diese Versuche auf einen "Huckepack"-Transportmechanismus für ein normalerweise cytoplasmatisches Protein hinweisen, konnte Cytokeratin 19 nicht spezifisch in der granulären Komponente des Nukleolus lokalisiert werden. Daher konnte bisher, trotz intensiver Bemühungen, die Identität des in der Immunfluoreszenz nachgewiesenen nukleolären Proteins leider nicht aufgeklärt werden. N2 - In the present work, nucleolar proteins were expressed as fusions with fluorescent proteins (GFP: green fluorescent protein or dsRed: red fluorescent protein) in living mammalian and Xenopus laevis cells. These tagged proteins were used as markers for the three main components of the nucleolus. The dynamic properties of the fusion proteins were analyzed quantitatively in photobleaching experiments (FRAP: fluorescence recovery after photobleaching). The analysis of RNA polymerase I allowed the conclusion that the fibrillar centers are the site of rDNA transcription. The kinetic FRAP analysis of two pol I subunits (RPA194 and RPA53) in transcriptionally active and inactive nucleoli allowed an estimate of the transcription time of rDNA genes in vivo. The individual pol I subunits move rapidly between the nucleoplasm and the nucleolus and associate at rDNA promoter sites. Then they are integrated into productive transcription complexes, which remain stable for the elongation phase of about five minutes at room temperature, and dissociate after termination. At least part of the subunits migrate to the nucleoplasm. The obtained results disagree with models that assume the site of transcription to be in the dense fibrillar component, as well as proposing immobile RNA Polymerase I molecules. The designation of the fibrillar center as site of rDNA transcription was further corroborated by the coexpression of pol I subunits with fibrillarin, a major protein of the dense fibrillar component. Using two differently fluorescing tags, the sites of transcription (fibrillar centers) and the sites of early processing steps, in which fibrillarin participates (dense fibrillar components), could be identified in living cells as closely neighboured but clearly separated compartments. The granular component as the site of late processing steps and assembly of ribosomal proteins was visualized by the expression of B23 and ribosomal proteins L4, L5 and L10. In the course of this work L10 was shown to be localized in the nucleolus for the first time. In the literature, human L10 was assumed to associate with ribosomes only in the cytoplasm. This is not the case, as was shown in particular by experiments with Leptomycin B. This drug inhibits the CRM1 dependent nuclear export pathway and resulted in a clear accumulation of L10 containing preribosomes in the nucleoplasm of human cells. Finally, a novel nucleolar protein (p52) of Xenopus laevis was studied in detail. Antigens of various p52 antibodies, localized in the granular component of nucleoli by immunofluorescence were surprisingly identified as cytokeratin homologs by two-dimensional immunoblot analysis and mass spectrometry. In the course of this work three hitherto unpublished Cytokeratin 19 isoforms of Xenopus were cloned, sequenced and expressed as GFP-fusion proteins. However, these proteins behaved like regular cytokeratins and were integrated into intermediate filaments. They were not detectable in the nucleolus, even after translocation into the nucleus by means of an experimentally added localization signal. Following cotransfection with various nuclear RFP-fusion proteins, GFP-CK19 was transported into the nucleus and localized with ist coexpressed partner. When coexpressed with nucleolar proteins, Cytokeratin 19 was also transported into the nucleolus. Although these experiments indicate a possible piggyback transport mechanism for a normally cytoplasmic protein, Cytokeratin 19 was not specifically located in the granular component of the nucleolus. Therefore, despite all efforts, until now the identity of the nucleolar protein originally identified by immunofluorescence remains to be clarified. KW - Nucleolus KW - Grün fluoreszierendes Protein KW - RNS-Polymerase I KW - Ribosomenproteine KW - Cytokeratine KW - Nukleolus KW - GFP KW - RNA-Polymerase I KW - ribosomale Proteine KW - Cytokeratin KW - nucleolus KW - GFP KW - RNA-Polymerase I KW - ribosomal proteins KW - cytokeratin Y1 - 2002 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-4000 ER -