Cellular biology

Cytokinins (CKs) are a pervasive group of growth-promoting signaling molecules spanning every kingdom of life. Their roles are best known in plants, where they act as phytohormones controlling nearly all aspects of plant growth and development. CKs continue to be detected in new organisms, posing questions about their roles in such widespread forms of life. The research presented in this thesis, therefore, investigated CK dynamics in a non-plant system using the simple eukaryotic model, Dictyostelium discoideum. Prior to this thesis, CKs were established as key intercellular signals necessary for proper development of D. discoideum – specifically in the induction of sporulation and maintenance of spore dormancy. However, there were no documented roles of CKs prior to the late stages of multicellular development. Comprehensive mass spectrometric screening for CKs detected six novel CK forms during all stages of D. discoideum growth and development. Based on these findings, a model was proposed that mapped CK biosynthesis in D. discoideum. The CK profiles indicate that there are differing dominant CK forms during vegetative growth and early development compared to those detected during late multicellular development. This led to the hypothesis that CKs have different roles during the distinctive life cycle stages of D. discoideum. This hypothesis was tested by generating knockout and overexpression strains of the key, primary CK biosynthesis gene, iptA, to investigate potential expanded roles for CKs during growth and the early stages of D. discoideum development. iptA-deficiency resulted in cytokinesis defects and both iptA-deficiency and overexpression caused altered mitochondrial morphology, dysregulated TCA cycle and amino acid metabolism, as well as increased levels of the energy metabolite, AMP. These combined phenotypes were suggestive of mitochondrial-associated dysfunction in vegetative growth and provided the first evidence of expanded roles of CKs during the D. discoideum life cycle. This was the first metabolomics-based evidence of CKs influencing mitochondrial function in D. discoideum. Lastly, a key CK-activating enzyme was functionally characterized, DdLOG, and additional CK biosynthesis enzymes were identified for future examination. Together, the findings of this thesis provide insights into: CK biosynthesis in a non-plant associated model; new roles for CKs during the D. discoideum life cycle; and CK interactions with mitochondria. The methods established as part of this thesis can be used as a foundation for characterizing further CK biosynthesis enzymes and as a guide for detecting subtle sub-cellular phenotypes related to CK metabolism in D. discoideum and other CK-producing organisms.

Author Keywords: cytokinin biosynthesis, cytokinins, Dictyostelium discoideum, IptA, mass spectrometry, mitochondria

Giardia intestinalis is the causative agent of a diarrheal disease in mammals, but the mechanisms of disease pathogenesis are unclear. While proteins secreted by Giardia affect the host cells, the potential of hormone secretion has not been investigated to date. Cytokinins (CKs) are classified as phytohormones, but little is known about their role beyond plants. Mass spectrometry-based intracellular analysis revealed CKs typical of tRNA degradation, and extracellular analysis showed CK-riboside scavenging by Giardia with concurrent secretion of CK-free bases. Metabolomics profiling of culture supernatants showed similar trends where nucleosides were up taken, and nucleobases were secreted. The dynamics of amino acids, nucleosides and nucleobases were altered by CK-supplementation during encystation, along with inhibition of encystation. In summary, this is the first study to report CK synthesis and metabolism by Giardia along with the effects of CKs on the metabolite secretome of Giardia, while establishing a link between CK and nucleoside metabolism.

Author Keywords: Cytokinins, Giardia, mass spectrometry, metabolomics, parasite, secretome

The neuronal ceroid lipofuscinoses (NCLs), commonly known as Batten disease, are a family of fatal neurodegenerative disorders that primarily affect children. Several subtypes of NCLs have been reported, each being caused by a mutation in a distinct ceroid lipofuscinosis neuronal (CLN) gene; this results in aberrant lysosome function and the accumulation of lipoprotein aggregates (known as ceroid lipofuscin) within cells. Several innate cellular pathways exist to alleviate the stress caused by the buildup of aggregates. The endoplasmic reticulum (ER) is an essential organelle in this process because it is responsible for maintaining cellular homeostasis through protein production, quality control, and regulating several signalling pathways. The unfolded protein response (UPR) consists of several conserved pathways devoted to attenuating ER stress caused by an accumulation of misfolded proteins or aggregates; at the center of this stress response is GRP78, a molecular chaperone that binds to misfolded proteins to facilitate proper folding. The social amoeba Dictyostelium discoideum is an excellent model system for studying NCLs as it encodes more CLN-like proteins when compared to other classical model organisms (e.g., yeast, worm, fruit fly). In this study, D. discoideum was used to elucidate the effects of ER stress and build an understanding of how cells cope with increased stress. Beyond this, ER stress in D. discoideum models for CLN3 disease and CLN5 disease were evaluated. First and foremost, during the induction of ER stress by tunicamycin, there was an increase in intracellular and extracellular amounts of Grp78 accompanied by an increase in stress-related changes to the ER. Furthermore, models of CLN3 disease and CLN5 disease displayed increased amounts of Grp78 as well as a disrupted ER morphology. Interestingly, wildtype D. discoideum, AX3 cells, treated with tunicamycin displayed a similarly disrupted ER when compared to CLN models. Finally, when subjected to tunicamycin-induced ER stress, these NCL models displayed a trend towards increased Grp78 amounts, however, these cells appear to have a reduced sensitivity to tunicamycin-induced stress compared to wild-type cells. In summary, this study highlights D. discoideum as a model for studying ER stress through the conserved role of Grp78 in the stress response and concludes that an aberrant ER stress underlies the pathology of the NCLs.

Author Keywords: Batten disease, Dictyostelium discoideum, ER stress, GRP78, neuronal ceroid lipofuscinoses (NCLs)

The neuronal ceroid lipofuscinoses (NCLs), commonly known as Batten disease, are a family of inherited neurodegenerative lysosomal storage disorders. CLN7 disease is a subtype of NCL that is caused by mutations in the MFSD8 gene. MFSD8 encodes a lysosomal transmembrane protein that is predicted to play a role in transporting small substrates across membranes. However, little is known about its role and substrate specificity. Previous work identified an ortholog of human MFSD8 in the social amoeba Dictyostelium discoideum and reported its localization to endocytic compartments. In this study, the effects of mfsd8 loss during Dictyostelium growth and multicellular development were further characterized. Dictyostelium mfsd8- cells displayed increased rates of proliferation and pinocytosis in liquid media. During growth, loss of mfsd8 altered lysosomal enzymatic activities and reduced the intracellular and extracellular levels of autocrine proliferation repressor A. mfsd8- cells grown on a lawn of bacteria formed plaques in a shorter period of time compared to WT cells, providing additional support for the enhanced growth of mfsd8- cells. Upon starvation, the aggregation of mfsd8- cells was delayed, and mfsd8- cells formed more mounds that were smaller in size, which may be attributed to the reduced cell-substrate adhesion and altered lysosomal enzymatic activities observed for mfsd8- cells. Following aggregation, tipped mound formation was delayed, however, loss of mfsd8 did not affect the timing of slug/finger and fruiting body formation. Additionally, slug migration was reduced in mfsd8- cells. These aberrant phenotypes, excluding fruiting body formation, were effectively or partially rescued when Mfsd8-GFP was introduced into mfsd8- cells. Overall, these results show that Mfsd8 plays a role in regulating growth and developmental processes in Dictyostelium via lysosomal-associated functions.

Author Keywords: CLN7, Dictyostelium discoideum, Lysosomes, MFSD8, Neuronal Ceroid Lipofuscinoses

The emergence of fungal hybrid pathogens threatens sustainable crop production worldwide. To investigate hybridization, the related smut fungi, Ustilago maydis and Sporisorium reilianum, were selected because they infect a common host (Zea mays), can hybridize, and tools are available for their analysis. Hybrid dikaryons exhibited filamentous growth on plates but reduced virulence and limited colonization in Z. mays. Select virulence genes in the hybrid had similar transcript levels on plates and altered levels during infection of Z. mays relative to each parental dikaryon. Virulence genes were constitutively expressed in the hybrid to determine if its pathogenic development could be influenced. Little impact was observed in hybrids with increased expression of effectors known to modify host response and metabolism. However, increased expression of transcriptional regulators of stage specific pathogenic development increased the hybrid's capacity to induce symptoms. These results establish a base for investigating molecular aspects of fungal hybrid pathogen emergence.

Author Keywords: effectors, hybrid pathogenesis assays, Sporisorium reilianum, transcription factors, Ustilago maydis, virulence factors

Giardia intestinalis possesses four isotypes of cytochrome b5 (gCYTB-I-IV) that differ from their mammalian counterparts, suggesting different functions in this protozoan parasite. Although the recently discovered Giardia flavoenzyme, GiOR-1, reduces these cytochromes, its properties have not been thoroughly studied, owing to the difficulty in its expression. Here I describe successful conditions for expression of GiOR-1 using autoinduction. GiOR-1 is obtained with flavins bound as indicated by its UV-visible spectrum. Its ability to catalyze electron transfer from donors (NADH, NADPH) to acceptors (oxygen, ferricyanide, cytochrome c, gCYTB5-III) were studied in spectrophotometric rate assays. NADPH is the preferred electron donor, while cytochromes are the preferred electron acceptors. Interestingly, the His-tag used to purify gCYTB5-III decreases its reaction rate with GiOR-1, as an untagged version has slightly faster rates. These findings establish the appropriate conditions for further studies on GiOR-1, including the identification of endogenous electron acceptors.

Author Keywords: Autoinduction, Cytochrome b5, Cytochrome P450 oxidoreductase, Giardia intestinalis, GiOR-1, Polyhistidine tag

This study investigated the role of the JNK signaling pathway in cadmium-treated mouse embryo forelimb bud cells in vitro. Primary cultures of forelimb bud cells harvested at day 11 of gestation were pre-treated with JNK inhibitor SP600125, and incubated with or without CdCl2 for 15, 30, 60, 120 minutes and 24, 48 hours or 5 days. Endpoints of toxicity were measured through cell differentiation by Alcian Blue Assay and phosphorylation of JNK proteins by Western blot. The results demonstrated that, in the cell differentiation assay, inhibiting JNK activation by 20 μM SP600125 causes an enhanced toxic effect in limb cells and inhibits cell differentiation, whereas 2 μM decreases differentiated nodule numbers under both cadmium stress and normal conditions. In conclusion, the JNK pathway has an essential role in the differentiation processes of limb bud cells in normal growth conditions.

Author Keywords: Cadmium, Cell Signaling, JNK, Limbs, Mouse Embryo, Teratology

This thesis investigated the role of the neuronal ceroid lipofuscinosis protein, Cln5, during autophagy. This was accomplished by performing well-established assays in a Dictyostelium cln5 knockout model (cln5-). In this study, cln5- cells displayed a reduced maximum cell density during growth and impaired cell proliferation in autophagy-stimulating media. cln5- cells had an increased number of autophagic puncta (autophagosomes and lysosomes), suggesting that autophagy is induced when cln5 is absent. cln5- cells displayed increased amounts of ubiquitin-positive proteins but had no change in proteasome protein abundance. During the development of cln5- cells, fruiting bodies developed precociously and cln5- slug size was reduced. Lastly, when cln5- cells were developed on water agar containing ammonium chloride (NH4Cl), a lysosomotropic agent, the formation of multicellular structures was impaired, and the small slug phenotype was exaggerated. In summary, these results indicate that Cln5 plays a role in autophagy in Dictyostelium. The cellular processes that regulate autophagy in Dictyostelium are similar to those that regulate the process in mammalian cells. Thus, this research provides insight into the undefined pathological mechanism of CLN5 disease and could identify cellular pathways for targeted therapeutics.

Author Keywords: Autophagy, Batten disease, Cln5, Dictyostelium discoideum, NCL

The rapid expansion of the worldwide population has caused an urgent need for the development of new, more environment-conscious, food sources. In this context, algae, such as Euglena, are of interest thanks to their capacity to naturally produce essential nutrients such as proteins and oils commonly found in animals and plant sources. While these processes are currently being investigated, underlying measures affecting growth of Euglena gracilis like hormonal influences and growth stress like nutrient deprivation are poorly understood. From this vantage point, this thesis seeks to understand the role of phytohormones cytokinin (CKs) and abscisic acid (ABA) in complex mechanisms underlying heterotrophic growth of Euglena gracilis under recycled, organic media conditions with no supplementation. Hormone profiles were quantified by HPLC-ESI-MS/MS and compared to culture growth dynamics of pH, weight accumulation, glucose content, cell count and morphology. It was expected that ABA acted as an inhibitory hormone and this was confirmed by its higher levels when CKs where low and vice versa. Contrastingly, it was expected that CKs stimulated growth, in which this was shown not to be the case. Interestingly, it was revealed that both hormone groups increase with increasing recycling. Other key findings include: E. gracilis synthesizes CKs via the tRNA-degradation pathway and is cZ and iP dominated, recycling E. gracilis medium is viable for growth, however, the percentage (25% or less) is crucial to cell viability and markedly no ABA was detected in E. gracilis pellet fractions from recycled media. Therefore, this data revealed that recycled media has a striking influence on physiological aspects of growth and illustrated unique changes in hormone profiles of which could be manipulated to help the food industry.

Author Keywords: cytokinin, endogenous hormones, Euglena gracilis, heterotrophic, large scale microalgae cultivation, recycled medium

To study the Giardia intestinalis cell cycle, counterflow centrifugal elutriation (CCE) was used to separate an asynchronous trophozoite culture into fractions enriched for cells at the different stages of the cell cycle. For my first objective, I characterized the appearance of a third peak (Peak iii) in our flow cytometry analysis of the CCE fractions that initially suggested the presence of 16N cells that are either cysts or the result of endoreplication of Giardia trophozoites. I determined that this third peak consists of doublets of the 8N trophozoites at the G2 stage of the cell cycle that were not removed effectively by gating parameters used in the analysis of the flow cytometry data. In the second objective, I tested the use of a spike with RNA from the GS isolate of Giardia as an external normalizer in RT-qPCR on RNA from CCE fractions and encystation cultures of Giardia from the WB isolate. My results showed that the GS RNA spike is as effective as the use of previously characterized internal normalizer genes for these studies. For the third objective, I prepared two sets of elutriation samples for RNA seq analysis to determine the transcriptome of the Giardia trophozoite cell cycle. I confirmed the results of the cell cycle specific expression of several genes we had previously tested by RT-qPCR. Furthermore, our RNA-seq identified many genes in common with those identified from a microarray analysis of the Giardia cell cycle conducted by a collaborator. Finally, I observed an overall <4 fold change in differentially expressed genes during the G1/S and G2/M phase of the cell cycle. This is a modest change in gene expression compared to 10 - 30 fold changes for orthologous genes in mammalian cell cycles.

Author Keywords: Cell cycle, Counterflow Centrifugal Elutriation, Flow Cytometry, RNA-sequencing, RT-qPCR