Engineering Reporter Tags in Flaviviruses to Probe Viral Structure and Morphogenesis

Matthew T Lerdahl (8726223)

24 April 2020

<div>The family Flaviviridae includes important genera such as flavivirus and hepacivirus which comprise significant human pathogens that affect hundreds of millions annually. The understanding of these viruses, the viral life cycle, and pathogenicity is vital when it comes to developing therapeutics. Flavivirus virions undergo major conformational rearrangements during the life cycle, including the assembly and maturation steps. In order to create a reagent to investigate these processes, luminescent reporter viruses have been constructed. Luminescent reporter tags have yet to be incorporated into the structural proteins of dengue virus (DENV) without significantly affecting replication or infectivity and successful tagging would allow for targeted studies examining access to specific structural epitopes. Engineering tags in DENV structural proteins is particularly difficult because most reporter tags involve large insertions which may create steric hindrance and inhibit proper protein folding. However, the reporter system described here, developed by Promega, is much smaller than a full-size luciferase protein. It involves an eleven amino acid subunit (HiBiT) tagged to a viral protein that creates measurable luminescence when incubated with the larger subunit (LgBiT). Using the structure of the virion as a guide, the HiBiT reporter tag was incorporated into the structural region of the DENV genome including sites in capsid (C) as well as the glycoproteins membrane (M) and envelope (E). Resulting recombinant viruses were characterized and tag sites within the C protein membrane anchor as well as the transmembrane domain of M protein were found to tolerate HiBiT insertion and produce infectious particles. The recombinant virus possessing HiBiT in C protein was found to be stable over three rounds of serial passaging while virus containing the M protein tag site was found to be unstable. HiBiT activity of the capsid tagged virus was also found to directly correlate with purified infectious particles, suggesting the capsid membrane anchor may remain associated with the virus even after polyprotein processing. Additionally, insert composition was found to be a key determinant for the production of infectious virus. The lessons learned from engineering HiBiT in the DENV system were then applied to hepatitis C virus (HCV). </div><div>The highly lipophilic and pleiomorphic nature of HCV has made structural studies particularly difficult. However, by constructing multi-tagged reporter viruses containing both HiBiT and various purification tags, researchers will save time and resources in preparation for structural studies which are vital for vaccine development. In this study, HiBiT was incorporated into sites within HCV previously shown to tolerate tags of various sizes. Different insert compositions were engineered within the genome and the construct containing both FLAG and HiBiT tags within the N-terminus of E2 yielded highly infectious and quantifiable, luminescent virus. The recombinant HCV containing FLAG and HiBiT displayed similar peak titer as compared to WT while also demonstrating HiBiT activity. Furthermore, the FLAG peptide was found to be partially surface exposed and capable of being used for virus purification purposes. The multi-tagged reporter virus characterized in this study provides a robust platform for quantification and purification of HCV, two facets of research that are critical for the determination of viral structure via cryo-EM and other imaging techniques. The findings from both the DENV and HCV studies provide a robust foundation for future tagging of viruses within the family Flaviviridae and offer insight on the structural proteins that compose the virion.</div>

Virology

flavivirus

hepacivirus

structure

virus

reporter tags

luminescence

cryo-EM

viral dynamics

morphogenesis

viral proteins

Relationship Between Physiological Umbilical Herniation and Liver Morphogenesis During the Human Embryonic Period: A Morphological and Morphometric Study / ヒト胚子期にみられる生理的臍帯ヘルニアの発生要因について‐肝形成との関連に基づいた形態及び形態計測学的検討

Kanahashi, Toru

23 March 2020

京都大学 / 0048 / 新制・論文博士 / 博士(人間健康科学) / 乙第13333号 / 論人健博第7号 / 新制||人健||5(附属図書館) / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 藤井 康友, 教授 岡 昌吾, 教授 長尾 美紀 / 学位規則第4条第2項該当 / Doctor of Human Health Sciences / Kyoto University / DGAM

physiological umbilical herniation

liver morphogenesis

liver malformation

total abdominal cavityvolume

intestinal volume

498

Sonic hedgehog expands neural stem cells in the neocortical region leading to an expanded and wrinkled neocortical surface / Sonic hedgehogは大脳新皮質領域の神経幹細胞数を増大させ、大脳新皮質表面積の拡大と皺形成をもたらす

MOHAMMED, J.M. SHQIRAT

24 September 2021

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23464号 / 医博第4771号 / 新制||医||1053(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 林 康紀, 教授 伊佐 正, 教授 高橋 淳 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Brain Morphogenesis

Mouse

Sonic Hedgehog

neocortical development

Neurogenesis

Neural Stem Cells

490

Phenotypic Variations In Animal Morphogenesis : Sea Urchin Twins And Cloned Rabbits / Variations phénotypiques de la morphogénèse animale : jumeaux d'oursins et lapins clonés

Fabrèges, Dimitri

11 January 2016

La variabilité est une propriété intrinsèque aux systèmes biologiques, essentielle pour l'évolution et l'embryogénèse. Souvent considérée comme du bruit, ce n'est que récemment que l'aléatoire des processus biologiques a commencé à être systématiquement étudié. Cette thèse pose les questions suivantes : qu'est-ce qu'un développement normal ? Quel est l'étendue et le rôle de la variabilité dans la robustesse et la résilience du développement embryonnaire ?Ces questions sont posées pour le lapin (Oryctolagus cuniculus) et l'oursin (Paracentrotus lividus et Sphaerechinus granularis).Nous nous sommes aussi intéressé à la quantification du déterminisme de la variabilité embryonnaire à l'aide d'oursins jumeaux et de lapins clonés.La mesure des comportements cellulaires est effectuée sur des lignages cellulaires obtenus à partir d'imagerie 3D+temps. Nous montrons que les oursins jumeaux peuvent se développer selon trois phénotypes différents, jamais observés chez le normal, avant de converger vers une blastula d'apparence normale. De plus, les comparaisons entre et au sein des pairs de jumeaux montrent que le phénotype et la survie ne dépend que de l'histoire individuelle des embryos.Nos mesures quantitatives des pairs de jumeaux amènent des questions ouvrant de nouveaux horizons de recherche : les jumeaux sont-ils robustes ou résilient ?Le développement pré-implantatoire des lapins a été étudié sur cinq embryons numériques (trois sauvages et deux clones), du stade 32-cellules à l'éclosion.Nous montrons que les divisions asymétriques internes et externes régulent la variation du nombre de cellules internes ainsi que la taille de la masse cellulaire.De plus, la variation du nombre de cellules internes est plus grande que pour les cellules externes, ce qui semble directement lié au taux de morts cellulaires.Notre hypothèse est que le potentiel de bon développement des clones est assuré par une grande plasticité épigénétique des cellules donneuses.Ce travail espère définir des méthodes et des concepts fondateurs pour une exploration quantitative et une modélisation multi-échelle de la morphogénèse animale. / Variability is an intrinsic characteristic of biological systems, essential for evolution and embryogenesis.Considered as noise for centuries, it is only recently that the stochasticity of biological processes has began to be systematically explored.The present thesis addresses the following questions: What is a normal development?What is the extent and role of variability in developmental robustness and resilience?We tackle these issues in rabbit (Oryctolagus cuniculus) and sea urchin (Paracentrotus lividus and Sphaerechinus granularis).We also aimed to quantify determinism and stochasticity of developmental variability by means of sea urchin twins and cloned rabbits.Variations in cell behaviors were investigated through reconstruction of cell lineage from 3D+time imaging.We showed that sea urchin twins can follow three different developmental paths never observed in normal embryo, before converging to normal looking blastula.Moreover, comparisons between and within pairs of twins revealed that phenotype and survival depend on individual history alone.Our quantitative observation of twin pairs raises question opening a future line of research: are twins robust or resilient?Rabbit preimplantation development was explored with five digital specimens (three wild-types and two clones) from the 32-cell stage to hatching.We showed that inner and outer asymmetric divisions regulate the variation of inner cell number and may control inner cell mass size.In addition, the variation of inner cell number in clones is higher than outer cells which seems to be directly correlated to their cell death ratio.Our current hypothesis is that the potential to lead to viable clones requires plasticity of donor's epigenetic state.This work is expected to ground concepts and methods for a quantitative exploration and further multilevel modeling of morphogenetic processes.

Variabilité

Quantification

Morphogénèse

Lignage cellulaire

Oursins

Lapins

Variability

Quantification

Morphogenesis

Cell lineage

Sea urchins

Rabbits

Developmental Evolution of the Optic Region in the Cavefish Astyanax mexicanus / Évolution développementale de la région optique chez le poisson cavernicole, Astyanax mexicanus

Devos, Lucie

04 July 2018

L’espèce Astyanax mexicanus est composée de deux morphotypes de poissons radicalement différents : le très classique poisson de surface vivant dans des rivières et le poisson cavernicole (CF, cavefish) aveugle et dépigmenté. Ces deux morphotypes diffèrent sur de nombreux aspects, aussi bien en termes de modalités sensorielles, qu’en termes de physiologie ou de comportement. L’approche « Evo-Devo » consiste à tenter de relier des différences développementales précoces à des modifications phénotypiques plus tardives. Dans le cadre de ce travail, nous nous sommes concentrés sur les modifications précoces de l’hypothalamus et de l’œil du CF. Nous montrons que des modifications précoces de signalisation de morphogènes tels que Shh ou Fgf conduisent à une modification de la taille des groupes de neurones peptidergiques au sein de l’hypothalamus, via les facteurs de transcription Lhx, impliqués dans la spécification neuronale. Plus particulièrement, nous montrons l’augmentation de taille des groupes de neurones NPY ainsi qu’hypocretine, qui à son tour provoque une réduction du sommeil chez le CF.Nous nous sommes aussi intéressés à l’oeil du CF, qui commence par se développer avant de dégénérer. Une réduction du quadrant ventral de la rétine avait été précédemment décrit. Nous rafinons cette description grâce à une étude de la régionalisation de la coupe optique du CF qui suggère une réduction de la rétine temporale plus spécifiquement. Nous proposons également une première description de la morphogénèse de l’oeil du CF grace à l’imagerie live de lignées transgéniques fluorescentes. Cette étude révèle un défaut d’invagination de la coupe optique chez le CF. Globalement, ce travail ouvre la voie vers une meilleure compréhension de l’évolution de la tête du CF. / Astyanax mexicanus is a fish species comprising two strikingly different morphotypes : the classical river-dwelling surface fish and the blind depigmented cavefish. These two morphs differ in many aspects in terms of sensorial modalities, physiology and behaviour. In the Evo-Devo approach, we try to link early developmental differences to later phenotypic modifications. Here we focus on the early modification of the hypothalamus and the eye of the cavefish. We show that early signalling modification of morphogens such as Shh or Fgfs lead to the modification of neuropeptidergic clusters in the hypothalamus via the neuronal fate-specifying transcription factors Lhx. More particularly, we show an increase in NPY and hypocretin cluster size. In turn, this increased hypocretin cluster size triggers a reduction of sleep in the cavefish larva.We also examine the embryonic eye of the cavefish which first develops before degenerating. This eye was previously reported to have a reduced ventral retina. We refine this description by studying the regionalisation of the cavefish optic cup and suggest that this reduction concerns more specifically the temporal retina. We also attempt a first description of the cavefish eye morphogenesis by live imaging on fluorescent transgenic lines. This description reveals a defect in the optic cup invagination of the cavefish. Overall, this work started deciphering the developmental evolution of the cavefish head.

Oeil

Morphogénèse

Poisson Cavernicole

Hypothalamus

Neuropeptide

Evo-Devo

Eye

Morphogenesis

Cavefish

Hypothalamus

Neuropeptides

Evo-Devo

Spatio-temporal and quantitative control of Rho1 activity by GPCR signaling during tissue morphogenesis / Contrôle spatio-temporel et quantitatif de l'activité Rho1 par une signalisation GPCR

Garcia De Las Bayonas, Alain

14 December 2018

La constriction apicale des cellules du mésoderme et l'intercalation des cellules de l'ectoderme sont contrôlées par des réseaux contractiles d'acto-myosine dans l'embryon de Drosophile. Le niveau d'activation et la polarisation du cytosquelette d'acto-myosine détermine la nature des déformations cellulaires observées. Nous montrons que le GPCR Smog et les protéines G (Gα,Gβγ) en aval, activent la signalisation Rho1 et donc la Myosine-II dans les deux tissus. Dans l'ectoderme, Gα12/13 active Rho1 à la membrane apicale (aussi appelé compartiment médio-apical) tandis que les sous-unités Gβ13F-Gγ1 activent Rho1 en médio-apical et aux jonctions cellulaires. Les mécanismes contrôlant l’activation polarisée de Rho1 dans ce tissu demeurent incompris. Nous montrons ici que deux RhoGEFs, RhoGEF2 et une nouvelle RhoGEF Wireless/p114RhoGEF, activent Rho1 sous le contrôle des protéines G dans l’ectoderme. RhoGEF2 stimule Rho1 en médio-apical sous la dépendance de Gα12/13 alors que Wireless/p114RhoGEF contrôle l’activité de Rho1 aux jonctions avec Gβ13F-Gγ1. RhoGEF2 est présente aux jonctions et en médio-apical tandis que Wireless/p114RhoGEF est uniquement jonctionnelle où elle est recrutée par Gβ13F-Gγ1. Pour finir, Wireless/p114RhoGEF est absente des jonctions dans les cellules du mésoderme. En résumé, des GPCRs contrôlent l’activité spatio-temporelle de Rho1 au moyen de deux modules régulatoires dans l’ectoderme. Les protéines G transduisent le signal en recrutant et en activant deux RhoGEFs complémentaires en médio-apical et aux jonctions. Une variation dans la nature des GPCRs, protéines G ou des RhoGEFs détermine le contrôle tissu-spécifique de Rho1 au cours de la morphogenèse. / Cell apical constriction in the mesoderm and cell intercalation in the ectoderm are controlled by contractile actomyosin networks in the developing Drosophila embryo. The extent of both actomyosin activation and polarization determines the nature of these cell deformations. We find that the GPCR Smog and the downstream G proteins (Gα,Gβγ) activate Rho1 signaling and thereby myosin-II in both tissues. In the ectoderm, Gα12/13 activates Rho1 at the apical membrane (also called medial-apical compartment) while Gβ13F-Gγ1 subunits promote Rho1 activity at the apical membrane and at cell junctions. How such a polarized activation of Rho1 is achieved remains unclear. Here, we show that two RhoGEFs, RhoGEF2 and a previously uncharacterized RhoGEF Wireless/p114RhoGEF, control Rho1 activity downstream of G proteins in the ectoderm. RhoGEF2 activates medial-apical Rho1 under control of Gα12/13 and Wireless/p114RhoGEF is required to mediate Gβ13F-Gγ1-dependent activation of Rho1 at junctions. RhoGEF2 is present both at junctions and at the apical membrane. In contrast, Wireless/p114RhoGEF only localizes at junctions together with Gβ13F-Gγ1 which recruit the GEF. Finally, we show that Wireless/p114RhoGEF is absent from junctions in the mesoderm. Collectively, GPCRs shape Rho1 activity through distinct biochemical modules in the ectoderm. Heterotrimeric G proteins transduce the signal by recruiting and activating two complementary RhoGEFs apically and at junctions. Variation in type of GPCRs, G proteins or RhoGEFs underlie the tissue-specific control of Rho1 signaling during morphogenesis.

Morphogenèse tissulaire

Gpcr

Signalisation Rho1

RhoGEF

Tissue morphogenesis

Gpcr

Rho1 signaling

RhoGEF

571

Physical Aspects of Local Solid Tumor Growth

Kubitschke, Hans

05 June 2020

Krebszellen haben gemeinsame Eigenschaften, wie unbegrenztes Wachstumspotential und die Vermeidung von Apoptose. Krebs kann als systemische Erkrankung angesehen werden und es reicht daher nicht aus, molekulare Details von Krebs zu verstehen, sondern auch emergente physikalische Eigenschaften von Krebs auf mehreren Größenskalen von Genen über Zellen bis hin zu Geweben. Diese Arbeit konzentriert sich auf physikalische Eigenschaften die an der Krebsprogression, der Migration von Krebszellen und dem Krebswachstum beteiligt sind. Die Migration von Krebszellen führt zur Fähigkeit zur Metastasierung, der häufigsten Ursache für krebsbedingten Tod. Der Schlüssel zu diesem Prozess ist die Verformbarkeit von Krebszellen beim Durchqueren der dichten Mikroumgebung aus extrazellulärer Matrix und anderen Zellen. Der genaue Beitrag des Aktin- und Mikrotubuli-Netzwerks zur zellulären elastischen Verformung und Entspannung ist wichtig und wurde untersucht. Ein wichtiges Ergebnis ist, dass bei kleinen Verformungen (<5%) die Aktin-Filamente die viskoelastische Zellverformung unter mechanischer Belastung dominieren und Mikrotubuli die Zellrelaxation bestimmen, während bei größeren Verformungen (>5%) Aktin-Filamente und Mikrotubuli gleichermaßen zur Zellverformung und -relaxation beitragen. So sind die Mikrotubuli für die Migration in Mikroumgebungen von größerer Bedeutung, als es die aktuelle Literatur vermuten lässt. Ein initial gebildeter bösartiger Tumor tritt typischerweise in eine Wachstumsphase ein, in der das umgebende Gewebe verdrängt und eingedrungen wird. Für ein optimales klinisches Behandlungsergebnis sollte der Primärtumor so gut wie möglich entfernt werden, was die genaue Erkennung der Tumorfront und die Identifizierung der Gewebe mit dem Risiko einer Krebsinfiltration beinhaltet. In dieser Arbeit werden natürliche Hindernisse und Grenzen für das Krebswachstum, wie z.B. Fasziengewebsgrenzen oder Gewebekompartimentgrenzen, basierend auf klinischen Daten von Gebärmutterhalskrebs analysiert, die aus der pathologischen Untersuchung von chirurgisch resezierten Tumoren von 518 Patienten gewonnen wurden. Die Wachstumsgrenzen wurden als embryonale Gewebeentwicklungsgrenzen identifiziert und betonen, dass Krebs Entwicklungsmerkmale aufweist, die häufig in der Embryogenese vorkommen. Das gefundene Tumorwachstumsmuster und die -form widersprechen dem das das vorherrschende Dogma der isotropen Tumorwachstum, welches der chirurgischen Tumorresektion und Strahlentherapie zugrunde liegt. Die Tumorform-Distribution weist starke Abweichungen von sphärischer Symmetrie auf, was darauf hindeutet, dass Tumore durch entwicklungsbiologische Kompartimente und deren Kompartimentsgrenzen begrenzt und geformt werden. Computersimulationen liefern auch den Nachweis, dass die klinisch gefundene Tumorinfiltrationswahrscheinlichkeit von Geweben nicht auf der metrischen Entfernung des gefährdeten Gewebes zum Gewebe der Tumorherkunft basiert, sondern auf der ontogenetischen Verwandtschaft der Gewebe.

info:eu-repo/classification/ddc/530

ddc:530

Continuum mechanics of developing epithelia:: Shaping a fly wing

Popovic, Marko

24 May 2017

Developing tissues are out-of-equilibrium systems that grow and reshape to form organs in adult animals. They are typically composed of a large number of cells. The constitutive cells of a tissue perform different roles in tissue development and contribute to the overall tissue shape changes. In this thesis, we construct a hydrodynamic theory of developing epithelial tissues. We use it to investigate the developing wing of the fruit fly Drosophila melanogaster. This theory relates the coarse-grained cell scale properties to the large-scale tissue flows. We explicitly account for the active cellular processes in the tissue that drive tissue flows. In our description of the tissue, we also include the memory effects that are necessary to account for the experimental observations. These memory effects have a significant influence on the tissue rheology. Using this hydrodynamic theory we analyze shear flow in a developing fruit fly wing tissue. We find that the active cellular processes contribute to overall tissue flows and that memory effects are present in the wing tissue. We investigate consequences of these findings on the rheology of tissue shear flow. We find that the memory effects give rise to an inertial response that leads to oscillations in the tissue but it does not stem from the wing mass. Finally, we describe how the tissue rheology is affected by different boundary conditions. We then investigate the area changes during the pupal wing development and we construct a mechanosensitive model for the cell extrusion rate in the pupal wing. Analysis of cell extrusions in the context of this model also allows us to extract information about the cell division properties. Boundary connections between the wing tissue and surrounding cuticle are crucial for the proper development of the pupal wing. A dumpy mutant wing is strongly misshaped during the pupal wing morphogenesis. We use a simple model for the wing to show that the dumpy mutant wing can be described as a wild type wing with compromised boundary conditions. Finally, we analyze cell properties and tissue flows in a developing wing disc epithelium. Motivated by the observation of radially oriented active T1 transitions in the wing disc epithelium, we use the hydrodynamic theory to investigate the influence of such T1 transitions on stresses in the tissue. We show that sufficiently strong radially oriented active T1 transitions can contribute to the control of the tissue size. Results obtained in this thesis extend our understanding of the fly wing tissue rheology and the role of internal and external forces in the proper shaping of the wing epithelium. The hydrodynamic theory we use to describe the fly wing development provides a set of phenomenological parameters that characterize the tissue mechanics and can be experimentally measured. Therefore, we expect that future research will include and extend the hydrodynamic theory presented in this thesis.

info:eu-repo/classification/ddc/570

ddc:570

Biophysik

Molecular, Cellular and Mechanical basis of Epithelial Morphogenesis during Tribolium Embryogenesis

Jain, Akanksha

11 September 2018

Embryonic development entails a series of morphogenetic events which require a precise coordination of molecular mechanisms coupled with cellular dynamics. Phyla such as arthropods show morphological and gene expression similarities during middle embryogenesis (at the phylotypic germband stage), yet early embryogenesis adopts diverse developmental strategies. In an effort towards understanding patterns of conservation and divergence during development, investigations are required beyond the traditional model systems. Therefore, in the past three decades, several insect species representing various insect orders have been established as experimental model systems for comparative developmental studies. Among these, the red flour beetle Tribolium castaneum has emerged as the best studied holometabolous insect model after the fruit fly Drosophila melanogaster. Unlike Drosophila, Tribolium is a short-germ insect that retains many ancestral characters common to most insects. The early embryogenesis of Tribolium shows dynamic epithelial rearrangements with an epibolic expansion of the extraembryonic tissue serosa over the embryo, the folding of the embryo in between the serosa and the second extra embryonic tissue amnion and the folding of the amnion underneath the embryo. These extensive tissues are evolutionarily conserved epithelia that undergo different tissue movements and are present in varying proportions in different insects, providing exceptional material to compare and contrast morphogenesis during early embryogenesis. However, most of the previous work on insects including Tribolium have largely focused on the conservation and divergence of gene expression patterns and on gene regulatory interactions. Consequently, very little studies on dynamic cell behaviour have been done and we lack detailed information about the cellular and tissue dynamics during these early morphogenetic events. During my PhD, I first established a live imaging and data analysis pipeline for studying Tribolium embryogenesis in 4-D. I combined live confocal and lightsheet imaging of transgenic or transiently labelled embryos with mechanical or genetic perturbations using laser ablations and gene knockdowns. Using this pipeline quantifications of cell dynamics and tissue behaviours can be done to compare different regions of the embryo as the development proceeds. In the second and third part of my thesis, I describe the actomyosin dynamics and associated cell behaviours during the stages of serosa epibolic expansion, amniotic fold formation and serosa window closure. I cloned and characterised the cellular dynamics of the Tribolium spaghetti squash gene (Tc-squash) - the non-muscle Myosin II regulatory light chain, which is the main molecular force generator in epithelial cells. Interestingly, the analysis of Tc-squash dynamics indicates a conserved role of Myosin II in controlling similar cell behaviours across short germ and long germ embryos. In the last part of the thesis, I report the dynamics of an actomyosin cable that emerges at the interface of the serosa and amnion. This cable increases in tension during development, concomitant with serosa tissue expansion and increased tensions in the serosa. It behaves as a modified purse string as it’s circumference shrinks due to a decrease in the number of cable forming cells over time. This shrinkage is an individual contractile property of the cells forming the cable. This indicates that a supracellular and contractile actomyosin cable might be functional during serosa window closure in insects with distinct serosa and amnion tissues. Further, the tension in the cable might depend on the relative proportion of the serosa, amnion and embryonic regions. Using these integrated approaches, I have correlated global cellular dynamics during early embryogenesis with actomyosin behaviours, and then performed a high-resolution analysis and perturbations of selected events. The established imaging, image processing and perturbation tools can serve as an important basis for future investigations into the tissue mechanics underlying Tribolium embryogenesis and can also be adapted for comparisons of morphogenesis in other insect embryos. More broadly, correlating the existing genetic, mechanical and biochemical understanding of developmental processes from Drosophila with species such as Tribolium, could help identify deeply conserved design principles that lead to different morphologies through differences in underlying regulation.:Page List of Tables v List of Figures vii 1 Introduction 1 1.1 Evo-Devo of insects 3 1.2 Tribolium castaneum 5 1.3 Fluorescence live imaging and lightsheet microscopy 10 1.4 Morphogenesis 15 1.5 Thesis objective 29 2 4D lightsheet imaging and analysis pipeline of Tribolium embryos 33 2.1 Standardisation of an injection protocol for sample mounting and imaging with the Zeiss LZ1 SPIM 35 2.2 Double labelling of Tribolium embryos 37 2.3 Image processing with Fiji 37 2.4 Long term timelapse imaging of Tribolium embryogenesis with SPIM 44 2.5 2D cartographic projections of 3D data as a method to visualise and analyse SPIM data 47 2.6 Summary 59 3 Cellular dynamics of the non muscle Myosin II regulatory light chain - Tc-Squash 61 3.1 Tc-Squash dynamics during Tribolium embryogenesis 64 3.2 Myosin drives basal cell closure during blastoderm cellularisation 66 3.3 Myosin shows planar polarity in the embryonic tissue 69 3.4 Myosin accumulation and apical constriction of putative germ cells at the posterior pole 71 3.5 Myosin pulses during apical constriction of mesoderm cells 74 3.6 Myosin accumulates at the extraembryonic-embryonic boundary to form a contractile supracellular cable 77 3.7 Summary 77 4 A supracellular actomyosin cable operates during serosa epiboly 79 4.1 Actin and Myosin accumulate at the extraembryonic-embryonic boundary 81 4.2 The actomyosin assembly migrates ventrally till it forms the rim of the serosa window 82 4.3 The actomyosin cable shows dynamic shape changes during serosa window closure 87 4.4 Serosa cells increase in area till circular serosa window stage 89 4.5 Tension in the serosa tissue increases during epibolic expansion 89 4.6 Serosa cells decrease their apical areas after laser ablation 92 4.7 Tension in the actomyosin cable increases during serosa epiboly 93 4.8 Myosin dynamics at the cable changes between early and serosa window stage 96 4.9 Individual cell membrane shrinkage and cell rearrangements decrease the cable circumference 98 4.10 Myosin dynamics at the cable during serosa window closure 101 4.11 Tension in the cable is not relieved after multiple laser cuts 103 4.12 Analysis of the actomyosin cable in Tc-zen 1 knockdown 105 4.13 Summary 109 5 Discussion 111 5.1 Reconstruction of insect embryogenesis using lightsheet microscopy and tissue cartography 111 5.2 Conserved Myosin II behaviours and its implications on morphogenesis across insects 114 5.3 A contractile supracellular actomyosin cable functions serosa window closure in Tribolium 119 6 Materials and Methods 123 6.1 Tribolium stock maintenance 123 6.2 RNA extraction and cDNA synthesis 124 6.3 Cloning of templates for mRNA synthesis and transgenesis 124 6.4 dsRNA synthesis for RNAi experiments 126 6.5 Capped, single stranded RNA synthesis 126 6.6 Fluorescence image acquisition 27 A Appendix 131 Bibliography 143

info:eu-repo/classification/ddc/570

ddc:570

Evoluční a teoreticko-biologické aspekty díla Bohumila Němce / Evolutionary and theoretical aspects of the biological work of Bohumil Němec

Loginov, Ivan

January 2020

Plant physiologist Bohumil Němec is one of the most important people in the history of Czech science. In this thesis, crucial concepts and theories that B. Němec developed in his scientific and popularizing publications are described and put in context. In addition, materials from the personal fond of B. Němec located in the Archive of the CAS were used. Particular questions tackled in this thesis are those of stimuli transmission in plants, the starch-statolith theory of gravitropism, morphaesthesia, organogenes, Němec's approach to evolutionary theory, and genetics, and the division of organisms in two groups. Moreover, Němec's role in the contemporary debates about vitalism, mechanism, and the effect of these two philosophies on the approach towards scientific research is indicated. By that, Němec's transition from the mechanism to the so-called physiology of stimuli (Rheizphysiologie) is illustrated. The outcome of the thesis is broadening the knowledge in the history of plant physiology, especially the history of the natural sciences in the Czech context.