Theses and Dissertations from UMD

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New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a give thesis/dissertation in DRUM

More information is available at Theses and Dissertations at University of Maryland Libraries.

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    ARABIDOPSIS THALIANA GLUTAMATE RECEPTOR-LIKE 3.7 UNDERLIES ROOT MORPHOLOGY AND SIGNALING VIA MEMBRANE POTENTIAL HOMEOSTASIS
    (2021) Barbosa-Caro, Juan Camilo; Feijó, José A; Biology; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Plants perceive highly variable environments and biotic interactions through membrane receptors like the GLutamate Receptor-like (GLR) family, related to the ionotropic Glutamate Receptors that underlie information transmission in neurons. GLRs underpin information transduction and morphological adaptations in plants. However, mechanistic understanding is scarce. In Arabidopsis thaliana roots, we investigated how GLRs underlie amino acid-induced electric and Ca2+ excitability. We also assessed the contribution of GLR3.7 in root hair elongation. We present GLRs as mediators of a local, glutamate-induced electric and Ca2+ response in roots, with the same initiation kinetics of wound-induced Slow Wave Potentials (SWP). We identify GLR3.7 as mediator of root hair elongation through maintenance of membrane depolarization at the growing cell apex. These results propose a parallel between glutamate-triggered signals and SWP initial phase as local and chemically induced, and posit GLR3.7 as a possible contributor to Ca2+ homeostasis in root hair apical growth.
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    SPATIO-TEMPORAL ANALYSIS OF PHOTOTROPISM IN ARABIDOPSIS SEEDLINGS
    (2019) Pritchard, Candace; Murphy, Angus S; Plant Science and Landscape Architecture (PSLA); Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Optimization of light capture during seedling development is a major determinant of plant fitness. As seedlings emerge from the soil, the processes of photomorphogenesis and phototropism optimize deployment of structures that capture light for photosynthesis. Photomorphogenesis produces hypocotyl thickening, cotyledon expansion, and chloroplast maturation. Concurrent phototropic responses initiated by blue light position the expanding cotyledons to maximize photosynthesis. The mechanisms underlying both processes have been explored for more than 140 years, but are still not fully understood. This dissertation seeks to provide a better understanding of phototropism by exploring the timing and localization of the constituent mechanisms downstream of the well-characterized perception of blue light by the PHOTOTROPIN photoreceptors. The experiments described herein characterize temporally and spatially distinct processes involved in asymmetric auxin accumulations that lead to differential hypocotyl elongation. To better identify the link between early perception and later auxin transport and elongation events, an open-air system was used to remove seedling hindrance and provide better spatio-temporal resolution. These experiments confirmed the more rapid bending conferred by loss of the ATP Binding Cassette class B (ABCB) 19 auxin efflux transporter and loss of differential elongation in the mid hypocotyl elongation zone in higher order pinformed mutants. However, apart from the enhancement of phototropic bending observed in abcb19 and pin4 mutants, no auxin transport mutants tested showed alterations in early phototropic responses, and no mutant exhibited a delay in the onset of phototropic bending. Recently identified CBC1 and CBC2 (CONVERGENCE OF BLUE LIGHT (BL) AND CO2 1/2) have been shown to act in downstream signaling during phot1-mediated regulation of stomatal conductance. Similarly, during phototropism cbc1cbc2 double mutants show early defects in phot1-mediated phototropism. Further, CBC1 and CBC2 have been shown to regulate S-type anion channels. Analysis of S-type anion channel mutants also reveals defects in early bending responses. These results point to blue light-dependent regulation of anion channel activity having an important role during the earliest stages of phototropism.
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    MOLECULAR MECHANISMS OF PLANT RESPONSES TO COLD, HEAT AND SALT STRESSES IN ARABIDOPSIS
    (2013) Guan, Qingmei; Zhu, Jianhua; Plant Science and Landscape Architecture (PSLA); Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Abiotic stresses, such as temperature extremes and salinity adversely affect plant productivity and distribution worldwide. Resistant or susceptible to stresses is a complex trait because more than one stress may occur simultaneously, for example, salinity is accompanied with ion toxicity and water deficit. To survive in a fixed environment, plants have to adjust their metabolisms and developmental programs to adapt to the stress or acclimate to the transitory stress. The responses of plants to different abiotic stresses are extremely complex, involving stress perception, signaling transduction, and response induction. We took a forward genetic analysis approach and identified three novel proteins in the reference plant Arabidopsis thaliana, Regulator of CBF Gene Expression 1 (RCF1), Regulator of CBF Gene Expression 3 (RCF3), and Short Root in Salt Medium 3 (RSA3), which are critical for plant tolerance to cold, heat and salinity, respectively. RCF1 is a cold-inducible DEAD box RNA helicase protein which is localized in the nucleus. RCF1 is a positive regulator for chilling and freezing tolerance. RCF1 functions to maintain proper splicing of pre-mRNAs because many cold-responsive genes are mis-spliced in rcf1-1 mutant plants under cold stress. RCF3 encodes a KH-domain containing putative RNA-binding protein. RCF3 is a negative regulator of most heat stress transcription factors (HSFs). Consistent with the overall increased accumulation of heat-responsive genes, the rcf3 mutants are heat-tolerant. RSA3, a xylogluscan galactosyltransferase, is essential for salt stress tolerance. rsa3-1 mutant plants are hypersensitive to NaCl and LiCl but not to CsCl or to general osmotic stress. RSA3 controls expression of many genes including genes encoding proteins for reactive oxygen species (ROS) detoxification under salt stress. RSA3 functions to maintaining the proper organization of actin microfilaments in order to minimize damage caused by excessive ROS. miRNAs play important regulatory roles in plants by targeting messenger RNAs (mRNAs) for cleavage or translational repression. We determined role of the heat-inducible miR398 in plant heat stress tolerance. Our results suggest that plants use a previously unrecognized strategy to achieve thermotolerance, especially for the protection of reproductive tissues. This strategy involves the down-regulation of two copper/zinc superoxide dismutase (CSDs) and their copper chaperone CCS through the heat-inducible miR398.