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Proteins in gymnosperm pollination drops.Prior, Natalie Annastasia 18 December 2014 (has links)
Most gymnosperms produce a pollination drop that captures and transports pollen into the ovule. Pollination drops have other functions. These include influencing pollen germination and pollen tube growth, defending the ovule from pathogens and providing a food reward in insect-pollinated gymnosperms. Mineral and organic molecules, including proteins, are responsible for these additional functions. To date, pollination drops from a handful of conifers and one non-conifer gymnosperm, Welwitschia mirabilis, have been subjected to proteomic analysis. In the present study, tandem mass spectrometry was used to detect proteins in all gymnosperm lineages: cycads (Ceratozamia hildae, Cycas rumphii, Zamia furfuracea); Gnetales (Ephedra compacta, E. distachya, E. foeminea, E. likiangensis, E. minuta, E. monosperma, E. trifurca; Gnetum gnemon; Welwitschia mirabilis); Ginkgo biloba; conifers (Taxus x media). PEAKS 6 DB (Bioinformatics Solutions, Waterloo, ON, Canada) was used to make protein identifications. Proteins were detected in all gymnosperm species analyzed. The numbers of proteins identified varied between samples as follows: one protein in Welwitschia female; nine proteins in Cycas rumphii; 13 proteins on average in Ephedra spp.; 17 proteins in Gnetum gnemon; 38 proteins on average in Zamia furfuracea; 57 proteins in Ginkgo biloba; 61 proteins in Ceratozamia hildae; 63 in Taxus x media; 138 proteins in Welwitschia male. The types of proteins identified varied widely. Proteins involved in carbohydrate modification, e.g. galactosidase, chitinase, glycosyl hydrolase, glucosidase, were present in most gymnosperms. Similarly, defence proteins, e.g. reduction-oxidation proteins, lipid-transfer proteins and thaumatin-like proteins, were identified in many gymnosperms. Gymnosperms that develop a deep pollen chamber as the nucellus degrades, e.g., cycads, Ginkgo, Ephedra, generally contained higher proportions of proteins localized to intracellular spaces. These proteins represent the pollination drop degradome. Gymnosperms that either lack a pollen chamber, e.g. Taxus, or have a shallow pollen chamber, e.g. Gnetum, had greater proportions of extracellular proteins. These proteins represent the pollination drop secretome. Our proteomic analyses support the hypothesis that the pollination drops of all extant gymnosperms constitute complex reproductive secretions. / Graduate
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Functional analysis of proteins in the conifer ovular secretionCoulter, Andrea Elizabeth 31 August 2020 (has links)
Almost all conifer ovules produce a liquid secretion as part of reproduction. This secretion, termed an ovular secretion, is produced during ovule receptivity and is involved in pollen capture and transport. Historically, examinations of the ovular secretion have focused on how they are part of pollination mechanisms. As a result, the chemical composition of the ovular secretion has not been examined systematically. Investigations into the constituents of the ovular secretion were limited to analyses for simple water soluble compounds such as sugars, minerals, amino acids and organic acids. More recently, the protein component of the secretion has been investigated using mass spectrometry-based proteomics. Proteins involved in processes such as carbohydrate modification, proteolysis, and defence have been identified in conifer ovular secretions. This biochemical complexity suggests a broader view of the function of the ovular secretion is warranted. However, protein identifications only provide putative information on function. Functional characterization of these proteins is needed in order to fully understand how they contribute to ovular secretion function. The research outlined in this dissertation describes the first functional characterizations of proteins found in conifer ovular secretions. Three proteins - invertase, chitinase, and thaumatin-like protein - were characterized in the ovular secretions of Douglas-fir (Pseudotsuga menziesii) and hybrid yew (Taxus × media). The Douglas-fir ovular secretion is capable of converting sucrose to glucose and fructose, confirming that invertases present in the secretion are functional. The invertase activity was maximal at pH 4.0. Activity was 77% of maximal at pH 4.5, the physiological pH. This indicates that post-secretory hydrolysis of sucrose occurs in situ in the Douglas-fir ovular secretion. Invertases in the ovular secretion are likely involved in controlling the movement of carbohydrates to developing pollen and could facilitate pollen selection. Chitinases present in the Douglas-fir ovular secretion are functional at physiological conditions. All three modes of chitinolytic activity, i.e. endochitinase, chitobiosidase and β-N-acetylglucosaminidase, were detected at physiological pH. β-N-acetylglucosaminidase activity was 80 % of maximal at physiological pH. Chitinases are pathogenesis-related proteins capable of hydrolysing chitin in fungal cell walls. These results suggest the ovular secretion is capable of defending the ovule against infection by phytopathogens. Thaumatin-like protein was immunolocalized to the cell wall and amyloplasts in Douglas-fir and yew nucellar tissue in a pattern consistent with a defensive role. It was also localized to the cell wall of fungal spores and germinating hyphae that were present in the micropyle of a yew ovule. These results provide additional evidence for an antifungal role for the ovular secretion. Functioning enzymes involved in pollen-ovule interactions and ovule defence are present in the conifer ovular secretion. The ovular secretion has functions beyond pollen capture. A revised functional model for the conifer ovular secretion is proposed. / Graduate / 2021-08-17
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