Isolation of a Pseudomonas aeruginosa Aspartate Transcarbamoylase Mutant and the Investigation of Its Growth Characteristics, Pyrimidine Biosynthetic Enzyme Activities, and Virulence Factor Production

Hammerstein, Heidi Carol

12 1900

The pyrimidine biosynthetic pathway is an essential pathway for most organisms. Previous research on the pyrimidine pathway in Pseudomonas aeruginosa (PAO1) has shown that a block in the third step of the pathway resulted in both a requirement for exogenous pyrimidines and decreased ability to produce virulence factors. In this work an organism with a mutation in the second step of the pathway, aspartate transcarbamoylase (ATCase), was created. Assays for pyrimidine intermediates, and virulence factors were performed. Results showed that the production of pigments, haemolysin, and rhamnolipids were significantly decreased from PAO1. Elastase and casein protease production were also moderately decreased. In the Caenorhabditis elegans infection model the nematodes fed the ATCase mutant had increased mortality, as compared to nematodes fed wild type bacteria. These findings lend support to the hypothesis that changes in the pyrimidine biosynthetic pathway contribute to the organism's ability to effect pathogenicity.

Pyrimidine nucleotides -- Metabolism.

Pseudomonas aeruginosa.

Caenorhabditis elegans.

ATCase

pyrimidine

virulence

Genetic and Cellular Analysis of Anoxia-Induced Cell Cycle Arrest in Caenorhabditis elegans

Hajeri, Vinita A.

12 1900

The soil-nematode Caenorhabditis elegans survives oxygen deprivation (anoxia < 0.001 kPa of O2, 0% O2) by entering into a state of suspended animation during which cell cycle progression at interphase, prophase and metaphase stage of mitosis is arrested. I conducted cell biological characterization of embryos exposed to various anoxia exposure times, to demonstrate the requirement and functional role of spindle checkpoint gene san-1 during brief anoxia exposure. I conducted a synthetic lethal screen, which has identified genetic interactions between san-1, other spindle checkpoint genes, and the kinetochore gene hcp-1. Furthermore, I investigated the genetic and cellular mechanisms involved in anoxia-induced prophase arrest, a hallmark of which includes chromosomes docked at the nuclear membrane. First, I conducted in vivo analysis of embryos carried inside the uterus of an adult and exposed to anoxic conditions. These studies demonstrated that anoxia exposure prevents nuclear envelope breakdown (NEBD) in prophase blastomeres. Second, I exposed C. elegans embryos to other conditions of mitotic stress such as microtubule depolymerizing agent nocodazole and mitochondrial inhibitor sodium azide. Results demonstrate that NEBD and chromosome docking are independent of microtubule function. Additionally, unlike anoxia, exposure to sodium azide causes chromosome docking in prophase blastomeres but severely affects embryonic viability. Finally, to identify the genetic mechanism(s) of anoxia-induced prophase arrest, I conducted extensive RNA interference (RNAi) screen of a subset of kinetochore and inner nuclear membrane genes. RNAi analysis has identified the novel role of 2 nucleoporins in anoxia-induced prophase arrest.

oxygen deprivation

Cell cycle

checkpoints

Caenorhabditis elegans.

Anoxemia.

Cell cycle.

Investigations into a bHLH code for Caenorhabditis elegans somatic gonad regulatory cell fate and function

Littleford, Hana Elisabeth

January 2021

The Caenorhabditis elegans somatic gonad is patterned by the activity of regulatory cell types, which govern its morphology, serve as the germline niche, and pattern its connection to the outside. All regulatory cell types are specified by activity of the basic helix-loop-helix gene hlh-2/E/Daughterless, and differences in how functions are assigned between the regulatory cells in males and hermaphrodites lead directly to their sexually-dimorphic gonads. Here, I present evidence that a code of bHLH genes function together with hlh-2 to promote the specification and function of each regulatory cell type except for the hermaphrodite anchor cell, which is specified by HLH-2 activity alone. Each regulatory cell type expresses an overlapping but distinct set of bHLH genes, which we find are required for its specification and associated functions. Notably, ectopic expression of regulatory cell bHLH complements are sufficient to transform cells with anchor cell potential into the expected regulatory cell, albeit transiently, suggesting that they are master regulators of regulatory cell fate. As all nematode species pattern their gonads through cognate regulatory cells and bHLH genes are highly conserved, we hypothesized that a similar bHLH code might function in specifying the regulatory cells of other species. In some nematode species the anchor cell, which remains stationary in C. elegans, is able to migrate. In C. elegans, the bHLH gene hlh-12 is necessary for proper migration of hermaphrodite distal tip cells and male linker cell, the two migrating regulatory cell types; addition of hlh-12 to the C. elegans anchor cell causes it to become displaced in a manner dependent on the endogenous hermaphrodite distal tip cell and male linker cell machinery, suggesting that the anchor cell gains the ability to migrate with the addition of hlh-12. We thus hypothesized that ectopic expression of an hlh-12 ortholog in these species might have led them to evolve migrating anchor cells. However, phylogenetic analysis of the bHLH genes of several other species, including the ones with migratory anchor cells, suggests that hlh-12 may be novel to the Caenorhabditis genus and does not have orthologs in the species with migrating anchor cells, raising the possibility that either these species use another bHLH gene for migration or that their regulatory cells are specified in a bHLH-independent manner.

Developmental biology

Genetics

Caenorhabditis elegans--Genetics

Genetic regulation

Effects of Berberine on Development in Caenorhabditis elegans

Qian, Zhuojia

18 December 2020

Berberine is an isoquinoline alkaloid found in some plants and has many bioactivities including anti-microbial, lipid- and glucose-lowering, anti-cancer, anti-inflammatory, etc. However, there is limited knowledge about berberine’s effects on development and locomotive activity. Herein, in vivo studies were conducted to determine these effects of berberine using Caenorhabditis elegans as an in vivo model. Treatment of berberine at 50 μM starting at L1 stage significantly retarded the growth rate of nematodes, and reduced the length, width and moving speed of worms by 19%, 12% and 29%, respectively, compared to the control. In addition, triglycerides (TG) and protein content in worms was reduced by 23% and 28%, respectively, after berberine treatment from L1 stage compared with the control group. However, no significance was observed when berberine was treated from young adult stage. These findings suggest that berberine has effects on development in C. elegans.

Caenorhabditis elegans

Berberine

Development

Growth rate

Food Science

Investigations into roles for endocytosis in LIN-12/Notch signaling and its regulation

Chan, Jessica Yu

January 2020

The LIN-12/Notch signaling pathway is highly conserved in all animals, and is crucial for proper development. It is a key pathway in specifying cell fate in many cellular contexts, and dysregulation of the pathway can have deleterious consequences. Therefore, understanding how LIN-12/Notch signaling is regulated in different contexts has been a main area of interest in the field. Previous studies in different model organisms have identified many modes of regulation of the signaling pathway, one of which is endocytosis of the ligand and receptor. Here, I further investigated the role of endocytosis in LIN-12/Notch signaling in multiple developmental contexts in Caenorhabditis elegans. Work in Drosophila and vertebrates had previously established that ligand-mediated activation of Notch requires ubiquitination of the intracellular domain of the transmembrane ligand and the activity of the endocytic adaptor Epsin in the signaling cell. The consensus in the field is that Epsin-mediated endocytosis of mono-ubiquitinated ligand generates a pulling force that exposes a cleavage site in Notch for an ADAM protease, a critical step in signal transduction. In contrast, in this thesis, I examined two different transmembrane ligands in several different cell contexts and found that activation of LIN-12/Notch and the paralogous GLP-1/Notch in C. elegans does not require either Epsin-mediated endocytosis or ubiquitination of the intracellular domain of the ligand. Results obtained by a collaborator indicate that C. elegans ligand and receptor interactions are tuned to a lower force threshold than are Drosophila ligand and receptor interactions, potentially accounting for these differences. I also looked at the role of endocytosis in regulating LIN-12 signaling in the context of vulval development. The cell fate pattern of six vulval precursor cells (VPCs) is mediated by EGFR and LIN-12/Notch signaling. Previous work using multicopy transgenes in fixed specimens indicated that LIN-12 is post-translationally downregulated via endocytosis in response to EGFR activation in the VPC named P6.p, an event that appeared essential for ligands to activate LIN-12/Notch in neighboring VPCs. In this thesis, I manipulate the endogenous lin-12 gene and examine live specimens to show that LIN-12 appears to be regulated transcriptionally in P6.p and evidence that there may be additional potential endocytic motifs that may regulate LIN-12 in this context.

Genetics

Endocytosis

Ligands (Biochemistry)

Caenorhabditis elegans

Vulva

Cellular signal transduction

Diversity and mobility of transposons in Arabidopsis thaliana

Le, Quang Hien, 1972-

January 2002

No description available.

Transposons

Disruption of LDL receptor-like gene function in Caenorhabditis elegans

Oviedo Landaverde, Irene

January 2004

No description available.

Low density lipoproteins.

Blood lipoproteins -- Metabolism.

The mechanism of Ivermectin-induced cytotoxicity in C. elegans /

Kaul, Aamna

January 2004

No description available.

Chloride channels

Drug resistance

Ivermectin

Association between GLC-4 and AVR-14 : role of GluCl subunit composition in Caenorhabditis elegans ivermectin sensitivity and behaviour

Pellegrino, Mark

January 2002

No description available.

Ivermectin.

Chloride channels.

Drug resistance.

Enriching the understanding of synaptic architecture from single synapses to networks with advanced imaging techniques / Vertiefung des Verständnisses synaptischer Architektur von der einzelnen Synapse bis zum Netzwerk mit modernsten bildgebenden Verfahren

Markert, Sebastian Matthias

January 2021

Because of its complexity and intricacy, studying the nervous system is often challenging. Fortunately, the small nematode roundworm Caenorhabditis elegans is well established as a model system for basic neurobiological research. The C. elegans model is also the only organism with a supposedly complete connectome, an organism-wide map of synaptic connectivity resolved by electron microscopy, which provides some understanding of how the nervous system works as a whole. However, the number of available data-sets is small and the connectome contains errors and gaps. One example of this concerns electrical synapses. Electrical synapses are formed by gap junctions and difficult to map due to their often ambiguous morphology in electron micrographs, leading to misclassification or omission. On the other hand, chemical synapses are more easily mapped, but many aspects of their mode of operation remain elusive and their role in the C. elegans connectome is oversimplified. A comprehensive understanding of signal transduction of neurons between each other and other cells will be indispensable for a comprehensive understanding of the nervous system. In this thesis, I approach these challenges with a combination of advanced light and electron microscopy techniques. First, this thesis describes a strategy to increase synaptic specificity in connectomics. Specifically, I classify gap junctions with a high degree of confidence. To achieve this, I utilized array tomography (AT). In this thesis, AT is adapted for high-pressure freezing to optimize for structure preservation and for super-resolution light microscopy; in this manner, I aim to bridge the gap between light and electron microscopy resolutions. I call this adaptation super-resolution array tomography (srAT). The srAT approach made it possible to clearly identify and map gap junctions with high precision and accuracy. The results from this study showcased the feasibility of incorporating electrical synapses into connectomes in a systematic manner, and subsequent studies have used srAT for other models and questions. As mentioned above, the C. elegans connectomic model suffers from a shortage of datasets. For most larval stages, including the special dauer larval stage, connectome data is completely missing up to now. To obtain the first partial connectome data-set of the C. elegans dauer larva, we used focused ion-beam scanning electron microscopy (FIB-SEM). This technique offers an excellent axial resolution and is useful for acquiring large volumes for connectomics. Together with our collaborators, I acquired several data-sets which enable the analysis of dauer stage-specific “re-wiring” of the nervous system and thus offer valuable insights into connectome plasticity/variability. While chemical synapses are easy to map relative to electrical synapses, signal transduction via chemical transmitters requires a large number of different proteins and molecular processes acting in conjunction in a highly constricted space. Because of the small spatial scale of the synapse, investigating protein function requires very high resolution, which electron tomography provides. I analyzed electron tomograms of a worm-line with a mutant synaptic protein, the serine/threonine kinase SAD-1, and found remarkable alterations in several architectural features. My results confirm and re-contextualize previous findings and provide new insight into the functions of this protein at the chemical synapse. Finally, I investigated the effectiveness of our methods on “malfunctioning,” synapses, using an amyotrophic lateral sclerosis (ALS) model. In the putative synaptopathy ALS, the mechanisms of motor neuron death are mostly unknown. However, mutations in the gene FUS (Fused in Sarcoma) are one known cause of the disease. The expression of the mutated human FUS in C. elegans was recently shown to produce an ALS-like phenotype in the worms, rendering C. elegans an attractive disease model for ALS. Together with our collaboration partners, I applied both srAT and electron tomography methods to “ALS worms” and found effects on vesicle docking. These findings help to explain electrophysiological recordings that revealed a decrease in frequency of mini excitatory synaptic currents, but not amplitudes, in ALS worms compared to controls. In addition, synaptic endosomes appeared larger and contained electron-dense filaments in our tomograms. These results substantiate the idea that mutated FUS impairs vesicle docking and also offer new insights into further molecular mechanisms of disease development in FUS-dependent ALS. Furthermore, we demonstrated the broader applicability of our methods by successfully using them on cultured mouse motor neurons. Overall, using the C. elegans model and a combination of light and electron microscopy methods, this thesis helps to elucidate the structure and function of neuronal synapses, towards the aim of obtaining a comprehensive model of the nervous system. / Das Nervensystem ist ein definierendes Merkmal aller Tiere, unter anderem verantwortlich für Sinneswahrnehmung, Bewegung und „höhere“ Hirnfunktionen. Wegen dessen Komplexität und Feingliedrigkeit stellt das Erforschen des Nervensystems oft eine Herausforderung dar. Jedoch ist der kleine Fadenwurm Caenorhabditis elegans als Modellsystem für neurobiologische Grundlagenforschung gut etabliert. Erbesitzt eines der kleinsten und unveränderlichsten bekannten Nervensysteme. C.elegans ist auch das einzige Modell, für das ein annähernd vollständiges Konnektom vorliegt, eine durch Elektronenmikroskopie erstellte Karte der synaptischen Verbindungen eines gesamten Organismus, die Einblicke in die Funktionsweise des Nervensystems als Ganzes erlaubt. Allerdings ist die Anzahl der verfügbaren Datensätze gering und das Konnektom enthält Fehler und Lücken. Davon sind beispielsweise elektrische Synapsen betroffen. Elektrische Synapsen werden von Gap Junctions gebildet und sind auf Grund ihrer oft uneindeutigen Morphologie in elektronenmikroskopischen Aufnahmen schwierig zu kartieren, was dazu führt, dass einige falsch klassifiziert oder übersehen werden. Chemische Synapsen sind dagegen einfacher zu kartieren, aber viele Aspekte ihrer Funktionsweise sind schwer zu erfassen und ihre Rolle im Konnektom von C.elegans ist daher zu vereinfacht dargestellt. Ein umfassendes Verständnis der Signaltransduktion von Neuronen untereinander und zu anderen Zellen wird Voraussetzung für ein vollständiges Erfassen des Nervensystems sein. In der vorliegenden Arbeit gehe ich diese Herausforderungen mithilfe einer Kombination aus modernsten licht- und elektronenmikroskopischen Verfahren an. Zunächst beschreibt diese Arbeit eine Strategie, um die synaptische Spezifität in der Konnektomik zu erhöhen, indem ich Gap Junctions mit einem hohen Maß an Genauigkeit klassifiziere. Um dies zu erreichen, nutzte ich array tomography (AT), eine Technik, die Licht- und Elektronenmikrokopie miteinander korreliert. In dieser Arbeit wird AT adaptiert für Hochdruckgefrierung, um die Strukturerhaltung zu optimieren, sowie für ultrahochauflösende Lichtmikroskopie; so wird die Kluft zwischen den Auflösungsbereichen von Licht- und Elektronenmikroskopie überbrückt. Diese Adaption nenne ich super-resolution array tomography (srAT). Der srATAnsatz machte es möglich, Gap Junctions mit hoher Präzision und Genauigkeit klar zu identifizieren. Für diese Arbeit konzentrierte ich mich dabei auf Gap Junctions des retrovesikulären Ganglions von C.elegans. Die Ergebnisse dieser Studie veranschaulichen, wie es möglich wäre, elektrische Synapsen systematisch in Konnektome aufzunehmen. Nachfolgende Studien haben srAT auch auf andere Modelle und Fragestellungen angewandt ...

Caenorhabditis elegans

Synapse

Elektronenmikroskopie

Myatrophische Lateralsklerose

ddc:573