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Description
The partitioning of photosynthates between their sites of production (source) and their sites of utilization (sink) is a major determinant of crop yield and the potential of regulating this translocation promises substantial opportunities for yield increases. Ubiquitous overexpression of the plant type I proton pyrophosphatase (H+-PPase) in crops improves several valuable traits including salt tolerance and drought resistance, nutrient and water use efficiencies, and increased root biomass and yield. Originally, type I H+-PPases were described as pyrophosphate (PPi)-dependent proton pumps localized exclusively in vacuoles of mesophyll and meristematic tissues. It has been proposed that in the meristematic tissues, the role of this enzyme would be hydrolyzing PPi originated in biosynthetic reactions and favoring sink strength. Interestingly, this enzyme has been also localized at the plasma membrane of companion cells in the phloem which load and transport photosynthates from source leaves to sinks. Of note, the plasma membrane-localized H+-PPase could only function as a PPi-synthase in these cells due to the steep proton gradient between the apoplast and cytosol. The generated PPi would favor active sucrose loading through the sucrose/proton symporter in the phloem by promoting sucrose hydrolysis through the Sucrose Synthase pathway and providing the ATP required to maintain the proton gradient. To better understand these two different roles of type I H+-PPases, a series of Arabidopsis thaliana transgenic plants were generated. By expressing soluble pyrophosphatases in companion cells of Col-0 ecotype and H+-PPase mutants, impaired photosynthates partitioning was observed, suggesting phloem-localized H+-PPase could generate the PPi required for sucrose loading. Col-0 plants expressed with either phloem- or meristem-specific AVP1 overexpression cassette and the cross between the two tissue specific lines (Cross) were generated. The results showed that the phloem-specific AVP1-overexpressing plants had increased root hair elongation under limited nutrient conditions and both phloem- and meristem-overexpression of AVP1 contributed to improved rhizosphere acidification and drought resistance. It was concluded that H+-PPases localized in both sink and source tissues regulate plant growth and performance under stress through its versatile enzymatic functions (PPi hydrolase and synthase).
ContributorsLi, Lin (Author) / Park, Yujin (Thesis advisor) / Mangone, Marco (Committee member) / Roberson, Robert (Committee member) / Vermaas, Willem (Committee member) / Arizona State University (Publisher)
Created2022
Description
Genome-wide, single nucleotide polymorphisms (SNPs) and germination data were analyzed to better understand species delimitation and salt-tolerance within the legume genus Medicago. Molecular phylogenies revealed that the widely-used, genomic model line R108 and two deeply divergent accessions of Medicago truncatula are in fact more closely related to Medicago littoralis than to other accessions representing Medicago truncatula. This result was supported by germination data wherein the two accessions representing deeply divergent Medicago truncatula demonstrated salt-tolerance that was more similar to Medicago littoralis than to other accessions of Medicago truncatula. Molecular phylogenies revealed that two additional accessions representing deeply divergent Medicago truncatula appear to be more closely related to Medicago italica than to other accessions representing Medicago truncatula. The results of the present study elucidate complex evolutionary relationships and contribute to the present understanding of existing salt-tolerance within Medicago.
ContributorsHopkins, Andrew David (Author) / Wojciechowski, Martin (Thesis advisor) / Park, Yujin (Committee member) / Steele, Kelly (Committee member) / Arizona State University (Publisher)
Created2023
Description
There is increasing interest in growing strawberries (Fragaria ×ananassa) in indoor environments such as vertical farms, as the continued sustainability of outdoor
production is threatened due to reductions in arable land, labor shortages, and an
increased frequency of drought. However, the optimal conditions for growing
strawberries hydroponically in sole-source lighting conditions have yet to be established.
The objectives of this research were to investigate the optimal lighting conditions and
nutrient concentrations for strawberry production in vertical farming. In the first study,
bare-root plants of two strawberry cultivars, ‘Albion’ and ‘Monterey’, were grown in an
indoor vertical farm under a 22 °C air temperature and an 18-h photoperiod with 90
μmol·m−2·s−1 of blue light and 250 μmol·m−2·s−1 of red light with and without 50
μmol·m−2·s−1 of additional far-red light from light-emitting diodes. Adding far-red light
increased the fruit number per plant by 36%, total fruit fresh mass by 48%, and total
soluble solids content by 12% in ‘Albion’, but not ‘Monterey’. In the second study, bare
root plants of strawberries ‘Monterey’ and ‘San Andreas’ were grown under a 23 °C air
temperature and an 18-h photoperiod with an extended photosynthetic photon flux
density of 350 μmol·m−2·s−1. Plants were subjected to four potassium to nitrogen ratios
(K:N) of 1.5:1, 2.5:1, 3.5:1, and 4.5:1 in a deep-water culture hydroponic system.
Increasing K:N from 1.5:1 to 4.5:1 increased the root dry mass of ‘Monterey’, but
generally had little to no effect on vegetative growth in either cultivar. In addition, in
both cultivars, increasing K:N from 1.5:1 to 4.5:1 decreased individual fruit size and
increased titratable acidity. These results suggest that for indoor strawberry production,
including far-red light in sole-source lighting can improve fruit production in some
strawberry cultivars. However, increasing K:N in the hydroponic nutrient solution
generally does not benefit plant growth, fruit production, and fruit quality.
ContributorsRies, Jonathan (Author) / Park, Yujin (Thesis advisor) / Sagers, Cynthia (Committee member) / Meng, Qingwu (Committee member) / Arizona State University (Publisher)
Created2024