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Browsing by Author "Gillaspy, Glenda E."

Now showing 1 - 20 of 65
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    Analysis of Plant Homeodomain Proteins and the Inhibitor of Growth Family Proteins in Arabidopsis thaliana
    Safaee, Natasha Marie (Virginia Tech, 2009-08-18)
    Eukaryotic organisms require the ability to respond to their environments. They do so by utilizing signal transduction pathways that allow for signals to effect final biological responses. Many times, these final responses require new gene expression events that have been stimulated or repressed within the nucleus. Thus, much of the understanding of signal transduction pathways converges on the understanding of how signaling affects gene expression alterations (Kumar et al., 2004). The regulation of gene expression involves the modification of chromatin between condensed (closed, silent) and expanded (open, active) states. Histone modifications, such as acetylation, can determine the open versus closed status of chromatin. The PHD (Plant HomeoDomain) finger is a structural domain primarily found in nuclear proteins across eukaryotes. This domain specifically recognizes the epigenetic marks H3K4me2 and H3K4me3, which are di- and tri-methylated lysine 4 residues of Histone H3 (Loewith et al., 2000; Kuzmichev et al., 2002; Vieyra et al. 2002; Shiseki et al., 2003; Pedeux et al., 2005, Doyon et al., 2006). It is estimated that there are ~150 proteins that contain the PHD finger in humans (Solimon and Riabowol, 2007). The PHD finger is conserved in yeast and plants, however an analysis of this domain has only been performed done in Arabidopsis thaliana (Lee et al., 2009). The work presented in this report aims to extend the analysis of this domain in plants by identifying the PHD fingers of the crop species Oryza sativa (rice). In addition, a phylogenetic analysis of all PHD fingers in Arabidopsis and rice was undertaken. From these analyses, it was determined that there are 78 PHD fingers in Arabidopsis and 70 in rice. In addition, these domains can be categorized into classes and groups by defining features within the conserved motif. In a separate study, I investigated the function of two of the PHD finger proteins from Arabidopsis, ING1 (INhibitor of Growth1) and ING2. In humans, these proteins can be found in complexes associated with both open and closed chromatin. They facilitate chromatin remodeling by recruiting histone acetyltransferases and histone deacetylases to chromatin (Doyon et al., 2006, Pena et al., 2006). In addition, these proteins recognize H3K4me2/3 marks and are believed to be "interpreters" of the histone code (Pena et al., 2006, Shi et al., 2006). To understand the function of ING proteins in plants, I took a reverse genetics approach and characterized ing1 and ing2 mutants. My analysis revealed that these mutants are altered in time of flowering, as well as their response to nutrient and stress conditions. Lastly, I was able to show that ING2 protein interacts in vitro with SnRK1.1, a nutrient/stress sensor (Baena-Gonzalez et al., 2007). These results indicate a novel function for PHD proteins in plant growth, development and stress response.
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    Biochemical and Functional Characterization of Induced Terpene Formation in Arabidopsis Roots
    Sohrabi, Reza (Virginia Tech, 2013-08-13)
    Plants have evolved a variety of constitutive and induced chemical defense mechanisms against biotic stress. Emission of volatile compounds from plants facilitates interactions with both beneficial and pathogenic organisms. However, knowledge of the chemical defense in roots is still limited. In this study, we have examined the root-specific biosynthesis and function of volatile terpenes in the model plant Arabidopsis. When infected with the root rot pathogen Pythium irregulare, Arabidopsis roots release the acyclic C11-homoterpene (E)-4,8-dimethylnona-1,3,7-triene (DMNT), which is a common constituent of volatile blends emitted from insect-damaged foliage. We have identified a single cytochrome P450 monooxygenase of the CYP705 family that catalyzes a root-specific oxidative degradation of the C30-triterpene precursor arabidiol thereby causing the release of DMNT and a C19-degradation product named arabidonol. We found that DMNT shows inhibitory effects on P. irregulare mycelium growth and oospore germination in vitro, and that DMNT biosynthetic mutant plants were more susceptible to P. irregulare infection. We provide evidence based on genome synteny and phylogenetic analysis that the arabidiol biosynthetic gene cluster containing the arabidiol synthase (ABDS) and CYP705A1 genes possibly emerged via local gene duplication followed by de novo neofunctionalization. Together, our studies demonstrate differences and plasticity in the metabolic organization and function of terpenes in roots in comparison to aboveground plant tissues. Additionally, we demonstrated that the arabidiol cleavage product, arabidonol, is further modified by yet unknown enzymatic reactions into three products, which are found in root exudates. We suggested a pathway for their biosynthesis based on precursor feeding experiments and NMR analysis. Although DMNT biosynthetic genes are clustered on chromosome 4 along with several potential modification genes, we did not find a possible role of these genes in the derivatization of arabidonol. Preliminary experimental results using genetic and biochemical approaches for identifying genes involved in the modification steps are also presented. In summary, this study demonstrates an alternative route for volatile terpene formation belowground different from aboveground plant tissues via triterpene degradation and provides evidence for an unexplored triterpene catabolism pathway in Arabidopsis.
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    Biochemical Characterization of Arabidopsis Enzymes Involved in Inositol Pyrophosphate Biosynthesis
    Adepoju, Olusegun Adeboye (Virginia Tech, 2019-09-05)
    To compensate for the sessile nature of plants, thousands of years of evolution have led to the development of many sophisticated signaling pathways that help plants sense and respond appropriately to different environmental cues. One such signaling pathway is called inositol phosphate signaling. This research dissertation focuses on the inositol phosphate signaling pathway in plants, with emphasis on elucidating how a new class of signaling molecules collectively referred to inositol pyrophosphates are synthesized. Inositol pyrophosphates are an emerging class of "high-energy" intracellular signaling molecules containing one or two diphosphate groups attached to an inositol ring, with suggested roles in bioenergetic homeostasis and inorganic phosphate sensing. Information regarding the biosynthesis of this unique class of signaling molecules in plants is scarce, however the enzymes responsible for their biosynthesis in other eukaryotes have been well described. This work aims to characterize the biochemical activity of the kinase domain (KD) of the Arabidopsis plant diphosphoinositol pentakisphosphate kinase enzymes (AtVIP1 and AtVIP2), and elucidate the biosynthesis pathway of inositol pyrophosphates in plants. Our data indicate that AtVIP1-KD and AtVIP2-KD function primarily as diphosphoinositol pentakisphosphate 5 kinases that phosphorylate this substrate at the 1-position. We also discovered a previously unreported inositol hexakisphosphate kinase activity for the Arabidopsis inositol(1,3,4) triphosphate 5/6kinase enzymes, that can convert InsP6 to InsP7. Together, these enzymes can function in plants to produce inositol pyrophosphates, which have been implicated in signal transduction and phosphate sensing pathways. The significance and potential application of these findings in terms of reduced phytate content and phosphate pollution, improved plant fitness, and improved nutrient use efficiency are discussed. The future outlook of inositol phosphate signaling research is also discussed.
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    Biological rhythms in Aedes aegypti mosquitoes
    Eilerts, Diane Francine (Virginia Tech, 2021-06-03)
    Aedes aegypti mosquitoes are found globally and also act as the primary vector of Zika, dengue, and Chikungunya viruses, for which there are limited treatment options and no vaccines available. The use of insecticides as the main control strategy against diseases transmitted by this mosquito, is increasingly challenged by emerging resistance. Thus, there is a dire need for the development of novel approaches informed by an improved understanding of mosquito biology, to control mosquito populations and, ultimately, disease transmission. Rhythmic biological processes in mosquitoes help optimize resource exploitation by coordinating behaviors and physiology with fluctuating environmental conditions. Such synchronization enables organisms to adjust their physiology, metabolism, and behavior to predictable external cycles. In mosquitoes, circadian rhythmicity has been demonstrated in their biting and oviposition behavior, as well as their locomotor activity. However, little is known regarding how responses to long-range host cues are modulated by the circadian system. Here we show that both antennal sensitivity and olfactory behavior are time-of-day and odor-specific in Ae. aegypti females. Global transcriptomic analysis in whole heads of Ae. aegypti females reveal chemosensory genes differentially expressed throughout the day, providing insight into the molecular mechanisms behind daily variations in olfactory sensitivity and behaviors. We additionally show an odor-induced activation of mosquito behavior. Mosquito locomotion and behavior are also mediated by physiological state, and activity decreases after blood-feeding. Since the central clock components have been shown in other organisms to be redox-sensitive, we explored the role that diet heme plays in mediating behavioral changes following blood ingestion using artificial blood diets. We found that the transcription of the timekeeping gene period is reduced in the head immediately after feeding on a meal containing hemoglobin, but peripheral period transcription is reduced throughout the course of digestion following ingestion of a protein meal independent of hemoglobin inclusion. Overall, our results show that Ae. aegypti behavioral rhythms mediated by rhythmic gene expression are plastic and susceptible to external host cues and host blood digestion. This work can be leveraged for future studies investigating mosquito host-seeking and blood digestion to identify novel targets for vector control.
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    Biosynthesis and possible functions of inositol pyrophosphates in plants
    Williams, Sarah P.; Gillaspy, Glenda E.; Perera, Imara Y. (Frontiers, 2015-02-12)
    Inositol phosphates (InsPs) are intricately tied to lipid signaling, as at least one portion of the inositol phosphate signaling pool is derived from hydrolysis of the lipid precursor, phosphatidyl inositol (4,5) bisphosphate. The focus of this review is on the inositol pyrophosphates, which are a novel group of InsP signaling molecules containing diphosphate or triphosphate chains (i.e., PPx) attached to the inositol ring. These PPx-InsPs are emerging as critical players in the integration of cellular metabolism and stress signaling in non-plante ukaryotes. Most eukaryotes synthesize the precursor molecule, myo-inositol (1,2,3,4,5,6)-hexakisphosphate (InsP6), which can serve as a signaling molecule or as storage compound of inositol, phosphorus, and minerals( referred to as phytic acid). Even though plants produce huge amounts of precursor InsP6 in seeds, almost no attention has been paid to whether PPx-InsPs exist in plants, and if so, what roles these molecules play. Recent work has delineated that Arabidopsis has two genes capable of PP-InsP5 synthesis, and PPx-InsPs have been detected across the plant kingdom. This review will detail the known roles of PPx-InsPs in yeast and animal systems, and provide a description of recent data on the synthesis and accumulation of these novel molecules in plants, and potential roles in signaling.
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    Can Inositol Pyrophosphates Inform Strategies for Developing Low Phytate Crops?
    Freed, Catherine P.; Adepoju, Olusegun; Gillaspy, Glenda E. (MDPI, 2020-01-17)
    Inositol pyrophosphates (PP-InsPs) are an emerging class of “high-energy” intracellular signaling molecules, containing one or two diphosphate groups attached to an inositol ring, that are connected with phosphate sensing, jasmonate signaling, and inositol hexakisphosphate (InsP6) storage in plants. While information regarding this new class of signaling molecules in plants is scarce, the enzymes responsible for their synthesis have recently been elucidated. This review focuses on InsP6 synthesis and its conversion into PP-InsPs, containing seven and eight phosphate groups (InsP7 and InsP8). These steps involve two types of enzymes: the ITPKs that phosphorylate InsP6 to InsP7, and the PPIP5Ks that phosphorylate InsP7 to InsP8. This review also considers the potential roles of PP-InsPs in plant hormone and inorganic phosphate (Pi) signaling, along with an emerging role in bioenergetic homeostasis. PP-InsP synthesis and signaling are important for plant breeders to consider when developing strategies that reduce InsP6 in plants, as this will likely also reduce PP-InsPs. Thus, this review is primarily intended to bridge the gap between the basic science aspects of PP-InsP synthesis/signaling and breeding/engineering strategies to fortify foods by reducing InsP6.
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    Certain Malvaceae Plants Have a Unique Accumulation of myo-Inositol 1,2,4,5,6-Pentakisphosphate
    Phillippy, Brian Q.; Perera, Imara Y.; Donahue, Janet L.; Gillaspy, Glenda E. (MDPI, 2015-05-29)
    Methods used to quantify inositol phosphates in seeds lack the sensitivity and specificity necessary to accurately detect the lower concentrations of these compounds contained in the leaves of many plants. In order to measure inositol hexakisphosphate (InsP6) and inositol pentakisphosphate (InsP5) levels in leaves of different plants, a method was developed to concentrate and pre-purify these compounds prior to analysis. Inositol phosphates were extracted from leaves with diluted HCl and concentrated on small anion exchange columns. Reversed-phase solid phase extraction cartridges were used to remove compounds that give peaks that sometimes interfere during HPLC. The method permitted the determination of InsP6 and InsP5 concentrations in leaves as low as 10 µM and 2 µM, respectively. Most plants analyzed contained a high ratio of InsP6 to InsP5. In contrast, certain members of the Malvaceae family, such as cotton (Gossypium) and some hibiscus (Hibiscus) species, had a preponderance of InsP5. Radiolabeling of cotton seedlings also showed increased amounts of InsP5 relative to InsP6. Why some Malvaceae species exhibit a reversal of the typical ratios of these inositol phosphates is an intriguing question for future research.
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    Characterization of the Arabidopsis glutamine dumper1 mutant reveals connections between amino acid homeostasis and plant stress responses
    Yu, Shi (Virginia Tech, 2015-04-15)
    Amino acids constitute the major organic form of transported nitrogen in plants, elements for protein synthesis, and precursors of many plant secondary metabolites, such as lignin, hormones, and flavonoids. Furthermore, amino acid metabolism lies at the crossroad of carbon and nitrogen metabolism. The Arabidopsis glutamine dumper1 (gdu1) mutant secretes glutamine from hydathodes, a phenotype caused by the overexpression of Glutamine Dumper1 (GDU1). GDU1 is a small transmembrane protein presents only in higher plants. The gdu1-1D mutant shows a pleiotropic phenotype: perturbed amino acid metabolism, tolerance to exogenous toxic concentrations of amino acids, elevated amino acid export, and activated stress/defense responses, lesions, and smaller rosettes. The biochemical function of GDU1 remains elusive. To better elucidate the biological processes leading to the complex Gdu1D phenotype, two approaches were conducted: (1) An ethyl methanesulfonate suppressor screening of the Gdu1D phenotype, which led to the isolation of intragenic mutations in GDU1 and mutations in the ubiquitin ligase LOG2 (Loss Of Gdu1D 2). Study of the intragenic mutations in GDU1 helped to characterize its structure-function relationships. Characterization of LOG2 showed that LOG2 interacts with GDU1 and is necessary for the Gdu1D phenotype. (2) The responses of the plant to the dexamethasone-induced expression of GDU1 were studied over time. This experiment identified major signaling pathways contributing to different components of the Gdu1D phenotype and the early events triggered by the perturbation of amino acid homeostasis. Our results showed that GDU1 overexpression first increases amino acid export, which is followed by amino acid imbalance and stress responses. This study sheds light on how amino acid imbalance interacts with various plant signaling pathways and stress responses, and suggests that LOG2 is involved in this process.
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    Characterization of the inositol monophosphatase gene family in Arabidopsis
    Nourbakhsh, Aida; Collakova, Eva; Gillaspy, Glenda E. (Frontiers, 2015-01-09)
    Synthes is of myo-inositol is crucial in multicellular eukaryote for production of phosphatidylinositol and inositol phosphate signaling molecules. The myo-inositol monophosphatase (IMP) enzyme is required for the synthesis of myo-inositol, breakdown of inositol (1,4,5)-trisphosphate, a second messenger involved in Ca2+ signaling, and synthesis of L-galactose, a precursor of ascorbic acid. Two myo-inositol monophosphatase-like (IMPL) genes in Arabidopsis encode chloroplast proteins with homology to the prokaryotic IMPs and one of these, IMPL2, can complement a bacterial histidinol 1-phosphate phosphatase mutant defective in histidine synthesis, indicating an important role for IMPL2 in amino acid synthesis. To delineate how this small gene family functions in inositol synthesis and metabolism, we sought to compare recombinant enzyme activities, expression patterns, and impact of genetic loss-of-function mutations for each. Our data show that purified IMPL2 protein is an active histidinol-phosphate phosphatase enzyme in contrast to the IMPL1 enzyme, which has the ability to hydrolyze D-galactose 1-phosphate, and D-myo-inositol 1-phosphate, a breakdown product of D-inositol (1,4,5) trisphosphate. Expression studies indicated that all three genes are expressed in multiple tissues, however, IMPL1 expression is restricted to above-ground tissues only. Identification and characterization of impl1 and impl2 mutants revealed no viable mutants for IMPL1, while two different impl2 mutants were identified and shown to be severely compromised in growth, which can be rescued by histidine. Analyses of metabolite levels in impl2 and complemented mutants reveals impl2 mutant grow this impacted by alterations in the histidine biosynthesis pathway, but does not impact myo-inositol synthesis. Together, these data indicate that IMPL2 functions in the histidine biosynthetic pathway, while IMP and IMPL1 catalyze the hydrolysis of inositol- and galactose-phosphates in the plant cell.
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    Connections Between Inositol Phosphate Signaling and Energy Responses in Plants
    Williams, Sarah Phoebe (Virginia Tech, 2015-11-19)
    The ability for an organism to sense and respond appropriately to its environment is often critical for survival. One mechanism for this is the inositol phosphate (InsP) signaling pathway. This work focuses on the role of InsP signaling in maintaining energy homeostasis in the plant. InsP signaling is connected to energy sensing in plants via a protein complex containing both the inositol polyphosphate 5-phosphatases (5PTase13) and the Sucrose non-Fermenting Related Kinase 1 (SnRK1). SnRK1 is considered a fuel gauge for the plant cell that senses energy status and reprograms growth appropriately. While the SnRK1.1 gene has been well studied, the role other SnRK1 isoforms play in energy or stress signaling is less well understood. This work examined the role of 3 SnRK1 isoforms in energy signaling, finding that SnRK1.1 and SnRK1.2 are regulated and function differently in Arabidopsis. The second part of this work focuses on the inositol pyrophosphates, which are a novel group of InsP signaling molecules containing diphosphate or triphosphate chains (i.e. PPx) attached to the inositol ring. These PPx-InsPs are emerging as critical players in the integration of cellular metabolism and stress signaling in non-plant eukaryotes. Most eukaryotes synthesize the precursor molecule, myo-inositol (1,2,3,4,5,6)-hexakisphosphate (InsP6), which can serve as a signaling molecule or as storage compound of inositol, phosphorus, and minerals. Even though plants produce huge amounts of InsP6 in seeds, almost no attention has been paid to whether PPx-InsPs exist in plants, and if so, what roles these molecules play. This work details the presence of PPx-InsPs in plants and delineates two Arabidopsis gene products (AtVip1 and AtVip2) capable of PP-InsP5 synthesis. We further examined the subcellular location of enzymes connected to PPx-InsP synthesis as well as the developmental and tissue specific patterns of expression of the genes that encode these enzymes. We localized the enzymes involved in InsP6 and PPx-InsP production to the nucleus and endoplasmic reticulum (ER). The subcellular compartmentalization of PPx-InsP signaling may be unique to plants. An increased understanding in the pathways involved in energy sensing and metabolic response may reveal novel strategies to improve crops for yield and viability in the future.
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    Cross-Species Translocation of mRNA from Host Plants into the Parasitic Plant Dodder
    Flagg, Jeannine K. (Virginia Tech, 2006-04-11)
    Dodders (Cuscuta spp.) are parasitic plants that live by tapping into the vascular tissue of a host plant. Contents of the host phloem translocate readily into the parasite, and shared plasmodesmata have been documented between host cortical cells and dodder searching hyphae. Dodder is known to transmit viruses from one host to another, which is consistent with viral ability to traverse plasmodesmata (PD) with the aid of movement proteins (MPs). Plant endogenous mRNAs may also associate with specific proteins to pass through PD and traffic long distances in the phloem, a process that appears to play a role in coordination of development. We have evaluated the hypothesis that dodder is able to accumulate host phloem-mobile mRNAs by assaying lespedeza dodder (C. pentagona) for the presence of host transcripts. Reverse transcriptase PCR (RT-PCR) and tomato microarrays were used to probe RNA from dodder parasitizing tomato. Transcripts from four tomato genes were detected in dodder grown on tomato, but were not detected in control dodder grown on other hosts. Notable among these was LeGAI, a transcript previously shown to be phloem translocated. In addition, RT-PCR of RNA from dodder grown on pumpkin detected three mobile pumpkin mRNAs (CmNACP, CmSUTP1, and CmWRKYP). These results imply the existence of an extraordinary situation in which mobile mRNAs move from one plant into another, and raise questions about the role of this phenomenon in plant development and parasite pathogenicity.
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    DD34E DNA Transposable Elements of Mosquitoes: Whole-Genome Survey, Evolution, and Transposition
    Coy, Monique Royer (Virginia Tech, 2007-06-13)
    Transposable elements (TEs) are mobile genetic elements capable of replicating and spreading within, and in some cases, between genomes. I describe a whole-genome analysis of DD34E TEs, which belong to the IS630-Tc1-mariner superfamily of DNA transposable elements, in the African malaria mosquito, Anopheles gambiae. Twenty-six new transposons as well as a new family, gambol, were identified. The gambol family shares the DD34E catalytic motif with Tc1-DD34E transposons, but is distinct from these elements in their phylogenetic relationships. Although gambol appears to be related to a few DD34E transposons from cyanobacteria and fungi, no gambol elements have been reported in any other insects or animals thus far. This discovery expands the already expansive diversity of the IS630-Tc1-mariner TEs, and raises interesting questions as to the origin of gambol elements and their apparent diversity in An. gambiae. Several DD34E transposons discovered in An. gambiae possess characteristics that are associated with recent transposition, such as high sequence identity between copies, and intact terminal-inverted repeats and open reading frames. One such element, AgTango, was also found in a distantly related mosquito species, Aedes aegypti, at high amino acid sequence identity (79.9%). It was discovered that Tango transposons have patchy distribution among twelve mosquito species surveyed using PCR as well as genomic searches, suggesting a possible case for horizontal transfer. Additionally, it was discovered that in some mosquito genomes, there are several Tango transposons. These observations suggest differential evolutionary scenarios and/or TE-host interaction of Tango elements between mosquito species. This strengthened the case that AgTango may be a functional transposase, and I sought to test its potential activity in a cell culture-based inter-plasmid transposition assay using the Herves plasmids as a positive control (Arensburger et al., 2005). AgTango constructs were successfully constructed; however, no transposition events were detected for Tango or Herves. Because the positive control failed to work, no assessment can be made concerning Tango's transposase. Possible causes and solutions for these results, alternative means to detect transposition, as well as future directions with Tango are discussed.
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    Discovery, Characterization, and Functional Analysis of micro RNAs in Culicidae
    Mead, Edward (Virginia Tech, 2009-05-13)
    MicroRNAs (miRNAs) are non-coding RNAs that often play a fundamental role in gene regulation. Currently, hundreds to over a thousand miRNAs are predicted to be present in many eukaryote species, with many to be discovered; the functions of most are unknown. While much attention has gone towards model organisms, a much greater depth of understanding remains to be gained for the miRNAs of many organisms directly important to humans. There are few verified miRNAs for any mosquito species, despite the role of mosquitoes in many of humanity’s worst diseases. Anopheles gambiae and Aedes aegypti, carriers of malaria and dengue, respectively, are responsible for over a million deaths a year. To date, there are sixty-six microRNAs in An. gambiae in miRBase, a central repository for miRNA sequences. Many of these are based on homology to primarily Drosophila miRNAs. While sequence conservation suggests an important function for these miRNAs, expression has not been experimentally verified for most mosquito miRNAs. Using small RNA cloning and northern blots, I discovered and analyzed 27 different microRNAs in aged female An. stephensi mosquitoes, the age group responsible for transmission of malarial parasites. Three of these miRNAs are only found in mosquitoes (miR-1889, -1890, and –1891). Cloning and northern analysis revealed an abundance of a miRNA that is linked to longevity in flies, miR-14, across different life stages of mosquitoes. It was also shown that miR-989 was expressed almost exclusively in the adult ovary and its expression fluctuated in response to bloodfeeding, suggesting a possible role in reproduction, an area of great importance to controlling mosquito populations. Building upon the above cloning experiment, a later high-throughput sequencing effort uncovered 98 miRNA precursors from Ae. aegypti. There are a total of 13 novel miRNAs that have not been found in other organisms by bioinformatic predictions or experiments. These “mosquito-specific” miRNAs may play a role in processes such as blood-feeding or vector-host interactions. A detailed examination of the expression of eight of these miRNAs was conducted in An. gambiae, An. stephensi, Ae. aegypti, and T. amboinensis to determine their expression profile, conservation, and provide hints to their function. My work revealed conserved and sometime stage-specific expression profiles of some of the mosquito-specific miRNAs. I also provided evidence for three lineage-specific miRNAs that may shed light on the divergence of different mosquito lineages. Extending the finding that miR-989 may be involved in mosquito reproduction, we conducted a detailed analysis of its evolution, expression, possible targets and regulation. miR-989 is conserved in holometabolous insects. miR-989 expression in female An. stephensi and Ae. aegypti dramatically rises following pupal emergence until strong signal is observed, until a blood meal is taken. Expression remains quite strong then begins a steep decline in expression at 32-40 hours post blood meal (PBM), and even by 96 hours PBM, remains weak. Bioinformatic predictions of miR-989 targets coupled with a PCR-based approach uncovered three potential target leads, though preliminary results were artifacts. Although the miR-989 post-emergence expression profile correlates with the expression of Juvenile Hormone, a key reproductive hormone in mosquitoes, no observable induction occurred when abdominal ligation samples were administered methoprene, a JH analog. However, methoprene impacted a number of other miRNAs, with up to a 3.87 fold induction (miR-1891), and a 3.15 fold suppression (miR-9a) of signal. Subsequent northern analysis provided visual confirmation of observable fold changes for miR-1891 and miR-9a, but not for miRNAs that showed changes below two fold. This analysis provides a foundation to study Juvenile Hormone regulation of miRNAs in mosquitoes. In summary, we have expanded the understanding of microRNAs in mosquitoes. An improved understanding of mosquito physiology can assist in efforts to control mosquito-borne infectious diseases.
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    Effect of Ploidy Elevation, Copy Number and Parent-Of-Origin on Transgene Expression in Potato
    Johnson, Alexander Arthur Theodore (Virginia Tech, 2001-08-09)
    Recent advances in plant genetic engineering offer substantial benefits to farmers throughout the world. Genetic research has identified many exogenous genes that could considerably decrease production costs through transgene-mediated resistance to insect, viral, fungal and bacterial pathogens. Potato can be produced from true potato seed (TPS) through a sexual polyploidization step, known as 4x-2x hybridization. Little is known regarding the stability of transgenes through sexual polyploidization in potato, although studies have associated ploidy elevation with transgene silencing in plants such as Arabidopsis thaliana. In the present study, potato was transformed with two different transgenes, cry3Aa and PVYo cp, and transgene expression was analyzed through 4x-2x hybridization. Transgene introgression did not affect fertility or agronomic performance (tuber set, average tuber weight, total tuber yield) of the resulting 4x-2x hybrids; however, reduced seed germination was observed for several transgenic lines in an in vitro study. Ploidy elevation did not affect a highly expressed single copy cry3Aa transgene, simplex or duplex, transmitted through pollen to 4x-2x hybrids. By contrast, multiple copies of cry3Aa triggered significant transgene silencing in diploids and silencing was further pronounced upon pollen transmission to 4x-2x hybrids. Crosses between two, single insert plants demonstrated additional evidence that multiple cry3Aa transgenes resulted in reduced expression, as well as provided evidence for maternal effects on expression of the cry3Aa transgene. Finally, Cry3Aa expression levels of progeny derived from low expressing, multiple copy 4x-2x hybrids indicated that reduction of transgene number in progeny, through meiotic segregation, could increase Cry3Aa expression. The results suggest that 4x-2x hybridization using single copy, male parents can result in high expressing, transgenic 4x-2x hybrids while segregating for a low frequency of non-transgenic hybrids that create a "refuge" to inhibit development of resistance to transgenes in pest populations.
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    Effects of Drought on Gene Expression in Maize Reproductive and Leaf Meristem Tissues as Revealed by Deep Sequencing
    Kakumanu, Akshay (Virginia Tech, 2012-06-28)
    Drought is a major environmental stress factor that poses a serious threat to food security. The effects of drought on early reproductive tissue at 1-2 DAP (days after pollination) is irreversible in nature and leads to embryo abortion, directly affecting the grain yield production. We developed a working RNA-Seq pipeline to study maize (Zea mays) drought transcriptome sequenced by Illumina GSIIx technology to compare drought treated and well- watered fertilized ovary (1-2DAP) and basal leaf meristem tissue. The pipeline also identified novel splice junctions - splice variants of previously known gene models and potential novel transcription units. An attempt was also made to exploit the data to understand the drought mediated transcriptional events (e.g. alternative splicing). Gene Ontology (GO) enrichment analysis revealed massive down-regulation of cell division and cell cycle genes in the drought stressed ovary only. Among GO categories related to carbohydrate metabolism, changes in starch and sucrose metabolism-related genes occurred in the ovary, consistent with a decrease in starch levels, and in sucrose transporter function, with no comparable changes occurring in the leaf meristem. ABA-related processes responded positively, but only in the ovaries. GO enrichment analysis also suggested differential responses to drought between the two tissues in categories such as oxidative stress-related and cell cycle events. The data are discussed in the context of the susceptibility of maize kernel to drought stress leading to embryo abortion, and the relative robustness of actively dividing vegetative tissue taken at the same time from the same plant subjected to the same conditions. A hypothesis is formulated, proposing drought-mediated intersecting effects on the expression of invertase genes, glucose signaling (hexokinase 1-dependent and independent), ABA-dependent and independent signaling, antioxidant responses, PCD, phospholipase C effects, and cell cycle related processes. This work was supported by the National Science Foundation Plant Genome Research Pro- gram (grant no. DBI0922747), iPlant Collaborative (NSF DBI-0735191) and also NSF ABI1062472.
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    Elucidating essential roles of oomycee effector proteins in immune suppression and in targeting hormonal pathways in the host plant
    Deb, Devdutta (Virginia Tech, 2013-09-25)
    Effector proteins are exported to the interior of host cells by numerous plant pathogens. Effector proteins have been well characterized in bacteria. However, the mechanisms through which these effectors promote virulence are largely unknown. Bioinformatic analysis of genome sequences from oomycete pathogens Phytophthora sojae, P. ramorum, P. infestans and Hyaloperonospora arabidopsidis (Hpa) have led to the identification of a large number of candidate effector genes. These effector genes have characteristic motifs (signal peptide, RxLR and dEER) that target the effectors into plant cells. Although these effector genes are very diverse, certain genes are conserved between P. sojae and H. arabidopsidis, suggesting that they play important roles in pathogenicity. The goal of my first project was to characterize a pair of conserved effector candidates from Hpa and P. sojae. We hypothesized that these effectors have important conserved roles with regard to infection. We found that the Hpa effector was expressed early during the course of infection of Arabidopsis and triggered an ecotype-specific defense response in Arabidopsis, suggesting that it was recognized by host surveillance proteins. Both the effectors from Hpa and P. sojae respectively could suppress immunity triggered by pathogen associated molecular patterns (PTI) and by effectors (ETI) in planta. They also enhanced bacterial virulence in Arabidopsis when delivered by the Type III secretion system. Similar results were seen with experiments with transgenic Arabidopsis expressing the effectors. My second project showed that a different Hpa effector protein, HaRxL10, targets the Jasmonate-Zim Domain (JAZ) proteins that repressed responses to the phytohormone jasmonic acid (JA). This manipulation activates a regulatory cascade that reduces accumulation of a second phytohormone, salicylic acid (SA) and thereby attenuates immunity. This virulence mechanism is functionally equivalent to but mechanistically distinct from activation of JA-SA crosstalk by the bacterial JA mimic coronatine. These results reveal a new mechanism underpinning oomycete virulence and demonstrate that the JA-SA crosstalk is an Achilles\' heel that is manipulated by unrelated pathogens through distinct mechanisms.
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    Elucidating the function of inositol pyrophosphate signaling pathways in Arabidopsis thaliana
    Cridland, Caitlin A. (Virginia Tech, 2022-04-12)
    Phosphate (Pi) is an essential nutrient for plants, required for plant growth and seed viability. When Pi is limited, plants undergo dynamic morphological and metabolic changes to leverage available Pi, known as the Phosphate Starvation Response (PSR). The inositol phosphate (InsP) signaling pathway is a crucial element of the plant's ability to regulate the PSR and respond to changing energy conditions. InsPs are synthesized from the cyclic 6-carbon polyol scaffold, myo-inositol. Inositol hexakisphosphate (InsP6) is the most abundant InsP signaling molecule and can be phosphorylated by the multifunctional inositol tetrakisphosphate 1-kinase 1 (ITPK1) and diphosphoinositol pentakisphosphate (VIP) kinases, resulting in inositol pyrophosphates (PP-InsPs). PP-InsPs have high energy bonds and have been linked to Pi maintenance and energy homeostasis in yeast, plants, and mammals. However, the precise mechanism(s) by which PP-InsPs act within plant signaling pathways remains to be determined. Two approaches to understand the role of PP-InsPs in plants are described within this dissertation. The first approach analyzes genetic loss-of-function vip1/vip2 double mutants, and their responses to low Pi conditions. Specifically, vip1/vip2 double mutant gene expression and lipid remodeling patterns in response to low Pi were characterized. We found that vip1-2/vip2-2 had an impacted lipid remodeling response under low Pi conditions, whereas ipk1 had altered lipid composition under Pi-replete conditions. In a complementary approach, a gain-of-function in either the ITPK1 or the kinase domain of VIP (VIP2KD) were constructed in transgenic Arabidopsis thaliana plants. Both ITPK1 and VIP2KD transgenic plants contain elevated levels of the specific inositol pyrophosphate, InsP8. Elevated InsP8 in both types of plants results in changes in growth and senescence phenotypes, delayed time to flowering, Pi accumulation, and altered PSR gene expression. The data from both approaches suggest new roles for PP-InsPs in the regulation of the PSR and other signaling pathways in plants. To enhance my teaching and leadership skills, I participated in the Graduate Teaching Scholars (GTS) program. As a GTS, I worked with the Virginia Tech Research and Extension Experiential Learning (VT-REEL) program where I developed a structured mentorship program for undergraduate and graduate students and created a professional development workshop series. During the COVID-19 pandemic, I developed an online version of the VT-REEL program. Using inclusive pedagogy practices and surveys from the participants, we compiled the best practices for moving a summer undergraduate research program online. These practices come from surveyed participants in the 2020 and provides strategies that can be tailored to various online research experiences and be implemented in both online and in-person formats.
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    Engineering of the RTB Lectin as a Carrier Platform for Proteins and Antigens
    Reidy, Michael James (Virginia Tech, 2007-01-26)
    The major obstacle many promising drugs struggle to overcome is the barrier imposed by the outer cell membrane. In addition to technologies such as liposomes and cell-penetrating peptides, more attention is being given to the class of proteins known as lectins to deliver therapeutic and antigenic proteins to the interiors of cells. Lectins bind to but do not modify sugars, and provide an efficient route to endocytosis. The galactose/N-acetyl-galactosamine specific lectin ricin B-chain (RTB) is especially attractive in possibly fulfilling a carrier role due to its well-characterized endocytotic trafficking and its efficacy over a wide range of cell types. By producing RTB recombinantly in plants it is possible to create a fully active, non-toxic carrier that does not rely on the processing of large amounts of toxic material (e.g. castor bean). Payload molecules such as small molecules and proteins can be attached to RTB via chemical conjugation at primary amine groups, without the loss of lectin or uptake activities. The biotin/streptavidin interaction and direct genetic fusion of polypeptides also provide efficient mechanisms for the attachment of payload proteins to RTB. An immunoglobulin domain-based scaffolding mechanism bridges modified RTB and payload proteins when co-expressed in Agrobacterium-infiltrated plant leaves. Carrier and payload proteins expressed in plants and E. coli, respectively, and purified independently are not able to assemble into an efficient carrier/payload arrangement. These findings show that plant cells are able to correctly produce the two components of the carrier/payload system and assemble them into an efficient and flexible capture and carry technology.
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    Enzymatic Characterization of N-Acetyl-1-D-myo-inosityl-2-amino-2-deoxy-alpha-D-glucopyranoside Deacetylase (MshB)
    Huang, Xinyi (Virginia Tech, 2013-06-06)
    Mycobacterium species, which contain the causative agent for human tuberculosis (TB), produce inositol derivatives including mycothiol (MSH).  MSH is a unique and dominant cytosolic thiol that protects mycobacterial pathogens against the damaging effects of reactive oxygen species and is involved in antibiotic detoxification.  Therefore, MSH is considered a potential drug target.  The deacetylase MshB catalyzes the committed step in MSH biosynthesis by converting N-acetyl-1-D-myo-inosityl-2-amino-2-deoxy-alpha-D-glucopyranoside (GlcNAc-Ins) to 1-D-myo-inosityl-2-amino-2-deoxy-alpha-D-glucopyranoside (GlcN-Ins).  In this dissertation, we present detailed functional analysis of MshB.  Our work has shown that MshB is activated by divalent metal ions that can switch between Zn2+ and Fe2+ depending on environmental conditions, including  metal ion availability and oxidative conditions.  MshB employs a general acid-base catalyst mechanism wherein the Asp15 functions as a general base to activate the metal-bound water nucleophile for attack of the carbonyl carbon on substrate.  Proton-transfer from a general acid catalyst facilitates breakdown of the tetrahedral intermediate and release of products.  A dynamic tyrosine was identified that regulates access to the active site and participates in catalysis by stabilizing the oxyanion intermediate.  Molecular docking simulations suggest that the GlcNAc moiety on GlcNAc-Ins is stabilized by hydrogen bonding interactions with active site residues, while a hydrophobic stacking interaction between the inositol ring and Met98 also appears to contribute to substrate affinity for MshB.  Additional binding interactions with side chains in a hydrophobic cavity adjacent to the active site were suggested when the docking experiments were carried out with large amidase substrates.  Together the results from this study provide groundwork for the rational design of specific inhibitors against MshB, which may circumvent current challenges with TB treatment.
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    Expanding Genetic and Genomic Resources for Sex Separation and Mosquito Control Strategies
    Compton, Austin (Virginia Tech, 2021-10-26)
    Mosquitoes belonging to the genera Anopheles transmit malaria parasites, attributing the highest mortality of any vector-borne disease worldwide. Mosquitoes belonging to the genera Aedes transmit arboviruses including dengue, which has become the most important vector-borne virus due to a drastic surge in disease incidence. The scope of the studies in this dissertation is broad, with investigations bringing together elements of classical genetics, recent advances in sequencing and genome-editing technologies, and the use of modern forward genetics approaches. Chapter 2 of this dissertation explores the use of the Oxford Nanopore Sequencing Technology for the first time in mosquitoes. This new technology provides long reads that were used to piece together the AabS3 chromosomal assembly for Anopheles albimanus. The utility of this genomic resource is demonstrated by the discovery of novel telomeric repeats at the ends of the chromosomes that could have important implications in mosquito biology and control. Chapter 3 describes a forward genetics strategy called 'Marker-Assisted Mapping' (MAM) that enables high-resolution mapping of the causal gene locus of a mutant phenotype. The principle and effectiveness of MAM is first demonstrated by mapping a known transgene insertion. MAM is then used to identify cardinal as a candidate causal gene for the spontaneous red-eye (re) mutation. Genetic crosses between the re mutant and cardinal knocking out individuals generated using CRISPR/Cas9 confirmed that cardinal indeed is the causal gene for re mutation. Chapter 4 explores three innovative strategies for mosquito sex separation by exploiting several sex-linked marker lines. We show that by linking a transgenic marker to the male-determining locus (M locus), or by linking the male-determining Nix gene to a marker, males can be precisely separated from females. We also produce a two-marker transgenic line that allows for both non-transgenic male separation and for efficient line maintenance. Finally, we discuss further applications of the resources generated and future directions stemming from these findings. Altogether, the studies described in this dissertation contribute to the overall goal of understanding mosquito biology and of controlling mosquito-borne infectious diseases.