Yee, Janet

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)

Crop losses due to pathogens, pests, and weeds account for 20–40% of global production, with fungal pathogens responsible for the most significant yield reductions and economic impact. The diseases caused by fungi spread through dormant spores, which protect its genetic material under adverse conditions. Dormancy is maintained until favorable germination conditions are met. Despite their importance in the fungal lifecycle, the molecular transitions from dormancy to germination remain poorly understood. The research presented uses the basidiomycete Ustilago maydis, the causal agent of Common Smut of Corn, to investigate fungal spore dormancy and germination. It aims to 1) identify the molecular transitions and stages of teliospore germination and 2) the roles of RNA helicases during teliospore germination. RNA-seq and respiration analyses were used to propose teliospore germination stages and a microdissection technique was developed for studying these stages. Transcriptomic analysis identified patterns of gene transcript level changes during germination, with GO term enrichment identifying genes involved in cell morphogenesis, metabolism, and RNA metabolism. Several RNA helicases were identified with potential roles during dormancy and germination. Previous work in the Saville Laboratory proposed that mRNAs are stored as dsRNA in dormant teliospores. I hypothesized that RNA helicases function to make these mRNAs available for translation upon germination. Forty-six RNA helicases were identified in U. maydis, and 28 RNA helicases were proposed to have roles in growth, pathogenesis, stress response, and teliospore dormancy and germination. The RNA helicases udbp3 and uded1 were selected for functional analysis by creating mutant strains. The results suggest that udbp3 negatively regulates osmotic stress response, potentially modulating stress-responsive genes during dormancy. The altered uded1 expression in mutant strains leads to slow and polarized growth and dsRNA formation. This suggests uded1 represses translation by stabilizing sense/antisense transcripts in dormant spores and then reactivates translation during germination. These findings increase our understanding of the molecular events during teliospore germination and offer insights into factors contributing to disease progression in fungal plant pathogens.

Author Keywords: gene expression, genome annotation, RNA helicases, RNA-seq, teliospore germination, Ustilago maydis

The TATA-binding protein (TBP) is a key regulator of eukaryotic transcription initiation. The TBP homolog from Giardia intestinalis (gTBP) is highly divergent among all TBPs; notably lacking three of the four phenylalanine residues to unwind double- stranded DNA. I show that gTBP preferentially binds to single-stranded DNA (ssDNA) in two modes based on sequence and protein concentration. The proposed A mode likely represents multimeric binding of gTBP to ssDNA with four or more consecutive guanine bases. The B mode involves monomeric binding utilizing the structural properties of the ssDNA. To demonstrate this, I developed a novel technique using base stacking energy potentials to approximate the per-nucleotide flexibility of ssDNA. I also attempted to create a polynomial regression model to predict binding; however, further work is required to improve accuracy. Overall, this thesis presents a new perspective on eukaryotic transcription regulation based on the discovery of unconventional binding between gTBP and ssDNA.

Author Keywords: computer modelling, DNA binding protein, DNA structure, DNA transcription, general transcription factor (GTF), parasite

Frog virus 3 (FV3) belongs to the genus Ranavirus within the Iridoviridae family.Its 105,903 base genome encodes 98 open reading frames (ORFs), including ORF 97R, a putative apoptosis regulator sharing 31% structural similarity with the anti-apoptotic Bcl- 2 family protein, myeloid cell leukemia 1 (Mcl-1). 97R contains a BH1 domain, implicated in apoptosis regulation, and a predicted C-terminal transmembrane domain, which acts as a membrane-anchoring domain, localizing 97R to the ER membrane. To study its role in host cell modulation, 97R was cloned into a vector and transfected into HeLa cells. Immunofluorescence revealed a time-dependent decrease in Protein Disulfide Isomerase (PDI) in 97R-transfected cells. Immunoprecipitation and western blotting revealed that 97R interacts with Prohibitin 1 (PHB1), a host protein involved in apoptosis regulation. This research provides insight into the novel functional role of 97R in host cells, enhancing our understanding of how FV3 may manipulate its host.

Author Keywords: Bcl-2 protein family, frog virus 3, Iridoviridae, ORF 97R, Protein-protein interactions, Ranavirus

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)

Amino acids make up proteins, which are the building blocks of life. A balance of amino acids is needed to maintain a healthy state. Tyrosine (Tyr) is synthesized from the metabolism of phenylalanine, which is an essential amino acid, meaning it can only be obtained from the diet. It is related to many metabolic and neurodegenerative diseases. Tyr can undergo post-translational modifications such as phosphorylation and nitration, which are implicated in cancer and nitrative stress, respectively. Although there are many methods to detect Tyr and its analogues, phosphotyrosine (pTyr) and nitrotyrosine (nTyr), these methods are time-consuming, involve expensive instruments and involve tedious process. This research proposes a new type of nanomaterials, carbon dots (CDs), to detect these amnio acids. Data indicate that CDs can be used to detect nTyr with a limit of detection of 34 μM in the linear range of 20 - 105 μM. The amenability of CD-nTyr assay was also tested in various biological matrices and biological molecules and was shown to be sensitive to nTyr. Nitration of Tyr was carried out in the presence of sodium nitrite and hydrogen peroxide catalyzed by either Cu(II) or Fe(III) to mimic biological reactions and CDs were tested as both inhibitors and indicators of Tyr nitration. Although CDs did not inhibit the nitration reaction of Tyr, they did not serve as indicators of Tyr nitration due to the quenching of CDs by the nitrating agents. This shows the importance of using CDs to detect nTyr and further use it for biological applications to detect diseased states.

Author Keywords: amino acids, carbon dots, nanomaterials, sensor, spectroscopy, tyrosine

Giardia intestinalis is a waterborne enteric parasite that lacks mitochondria and the capacity for heme biosynthesis. Despite this, Giardia encodes several heme proteins, including four cytochrome b5 isotypes (gCYTB5-I – IV) of unknown function. The aim of this thesis is to gain insight into the function of the Giardia cytochrome b5 isotype III (gCYTB5-III) that is found in the nucleus, as first reported by our laboratory using immunofluorescence microscopy experiments with an isotype-III specific antibody. Nuclear localization of isotype-III is supported by two of my experiments: i) immunoblot analysis of crude cytoplasmic and nuclear enriched fractions of Giardia trophozoites; ii) association of gCYTB5-III with the insoluble fraction of Giardia lysates crosslinked with formaldehyde is reversed by DNase I treatment. To gain an understanding of the possible roles of gCYTB5-III, I performed immunoprecipitation (IP) experiments on lysates from Giardia trophozoites to identify its protein partners. Mass spectroscopy analysis of the immunoprecipitate identified proteins localized to the nucleus (RNA polymerase, DNA topoisomerase, histones, and histone modifying enzymes). Intriguingly, over 40% of the known mitosomal proteome, which functions in iron-sulfur (Fe-S) cluster assembly was also associated with gCYTB5-III. One of these proteins, the flavoenzyme GiOR-1, has been shown to mediate electron transfer from NADPH to recombinant gCYTB5-III. These IP results provide evidence that GiOR-1 and gCYTB5-III interact in vivo, and furthermore, suggest that some proteins in the mitosome could interact with those in the nucleus. I also found that DNA stress, caused by low concentrations of formaldehyde (0.1 – 0.2%) resulted in the increased expression of gCYTB5-III. Collectively these findings suggest a role of gCYTB5-III in Giardia's response to DNA stress and perhaps the formation of Fe/S clusters.

Author Keywords: cluster, cytochrome, heme, iron, mitosome, nuclear

Ustilago maydis (DC) Corda is the causal agent of 'common smut of corn'. Completion of the U. maydis lifecycle is dependent on development inside its host, Zea mays. Symptoms of U. maydis infection include chlorosis and the formation of tumours on all aerial corn tissues. Within the tumours, thick-walled diploid teliospores form; these are the reproductive and dispersal agent for the fungus. U. maydis is the model to study basidiomycete biotrophic plant-pathogen interactions. It holds this status in part because of the completely sequenced 20.5 Mb genome; however, thorough genome annotation is required to fully realize the value of this resource. The research presented here improved U. maydis genome annotation through the analysis of cDNA library sequences and comparative genomics. These analyses identified and characterized pathogenesis-related genes, and identified putative meiosis genes. This enabled the use of U. maydis as a model for investigating 'host-induced' meiosis. Further, the cDNA library analyses identified non-coding RNAs (ncRNAs) and natural antisense transcripts (NATs). NATs are endogenous RNA molecules with regions complementary to a protein-coding transcript. Although NATs have been identified in a wide variety of mammals, plants, and fungi, very few have been functionally characterized. Over 200 U. maydis NATs were annotated by analyzing full-length cDNA sequences. NAT structural features were characterized. Strand-specific RT-PCR was used to detect NATs in U. maydis and in a related smut fungus, U. hordei. The data supported a common role for NATs in smut teliospore development, independent of the RNA interference pathway. Analysis of the expression of one U. maydis NAT, as-um02151, in haploid cells, led to a model for NAT function in U. maydis during teliospore dormancy. This model proposed NATs facilitate the maintenance of stored mRNAs through the formation of double-stranded RNA. In testing this model, it was determined that the deletion of two separate upstream regulatory regions, one of which contained a ncRNA (ncRNA1), altered NAT levels and decreased pathogenesis. These studies strengthened U. maydis as a model organism, and began the functional investigation of NATs in U. maydis, which identified a new class of fungal pathogenesis genes.

Author Keywords: cDNA library analysis, genome annotation, mRNA stability, natural antisense transcripts, pathogenesis, Ustilago maydis