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Storage and mobilization of nitrogen in the peach tree / by B.K. Taylor.Taylor, Brian Kenwyn January 1966 (has links)
Typescript / 298 leaves : ill. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / The accumulation, chemical composition, and distribution of storage nitrogen in young peach trees (Golden queen on Elberta rootstock), and the importance of this stored nitrogen for new growth, were investigated in this thesis. In addition, the metabolic stability of constituents of the storage nitrogen of dormant peach trees was studied. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Physiology, Waite Agricultural Research Institute, 1966
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The influence of time and path of supply of nitrogen on the growth response of wheat (Triticum aestivum L)Lungley, David Rolfe January 1974 (has links)
xvii, 255 leaves : ill. ; 26 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.1974) from the Dept. of Agronomy, University of Adelaide
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Nitrogen fertility studies on the buffalo gourd (Cucurbita foetidissima) grown as an annual root cropMcGriff, Terry Lee, 1952- January 1989 (has links)
A fertility study was initiated at the Maricopa Agricultural Center in 1984 to determine how nitrogen levels influenced growth, development, and root yield of the potential domesticate, buffalo gourd (Cucurbita foetidissima). Nitrogen had little or no effect upon the following parameters: seedling emergence, early growth rates, specific leaf weights, individual root weights, consumptive water use, canopy organic N content, and nitrate and ash content of all organs. Percent root dry matter and total carbohydrate content dropped linearly as N was increased, whereas canopy dry matter production, root organic N content, petiole nitrate concentration, and leaf area indices exhibited a positive linear response. A quadratic response curve best fitted fresh weight root yields, total root dry matter and carbohydrate production, water use efficiencies, and final plant populations. A modest amount of N (84 kg ha⁻¹) provided maximum yield response in this feral species grown at 405,000 plants ha⁻¹.
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EFFECT OF NITROGEN AND IRRIGATION LEVEL ON YIELD OF SAFFLOWERJones, James Preston, 1935- January 1966 (has links)
No description available.
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NITROGEN ABSORPTION AND UTILIZATION BY GOSSYPIUM HIRSUTUM AS INFLUENCED BY NITROGEN SOURCERauschkolb, Roy S. January 1968 (has links)
No description available.
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EFFECTS OF NITROGEN ON GROWTH AND FLOWERING OF BOUGAINVILLEA COMMERSIbrahim, Ali Mohamed January 1983 (has links)
No description available.
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Molecular studies of genes required for nitrate assimilation in fungi and higher plantsKana'n, Ghassan Jadou Mousa January 1997 (has links)
Nitrate assimilation is an extremely important part of the nitrogen cycle and is carried out by most bacteria, fungi and plants. A relatively short catalytic pathway reduces nitrate to nitrite (via nitrate reductase activity) and then nitrite to ammonium ions (via nitrite reductase activity) which are converted into organic nitrogen by further metabolic pathways. A considerable amount of information is known about the biochemistry, genetics and recently, the molecular biology of these two enzymes. Much less is known about the transport of nitrate and nitrite into cells as well as the synthesis of the molybdenum cofactor needed for nitrate reductase catalytic activity. Research work reported in this thesis focus on these latter two processes in the eukaryotic model organisms. Aspergillus nidulans and to a lesser extent Arahidopsis thaliana. Genetic characterisation of 47 crn mutants shows that there are three additional genes (i.e. to the original identified crnA gene) likely to be involved in nitrate transport. These additional genes are unlinked to each other or to crnA. Although it was shown that the nitrate uptake into cells of these mutants are lower than the wild-type, their exact involvement in nitrate transport requires their molecular cloning. Certain mutations generated in the crnA gene have been investigated at the molecular level and the disruptions in the protein determined. During the genetic studies of crn mutants, two other genes were postulated. The first is chlA, mutation which results in resistance to chlorate (unlike the wild-type) and caesium (like the wild-type). The second is cesA mutation. These latter mutants lead to caesium sensitivity but are chlorate sensitive like the wild-type. These two genes are unlinked to crnA, crnB, crnC and crnD genes. The bases of these phenotypes is unclear and need further investigation. A study of nitrite uptake was undertaken which showed that wild-type A. nidulans has an active nitrite transport system. The activity of this system is repressed by ammonium and is nitrate induced. Mutants which are hypersensitive to chlorate taken up much higher levels of nitrite as compared to wild-type. 2,082 cnx mutants were isolated and 456 of these were classified as cnxA, cnxB, cnxC, cnxE, cnxF, cnxG and cnxH mutants on the basis of phenotypic complementation. No novel cnx genes were found. More importantly a number of temperature -conditional mutants were isolated, 10 mutants were found to be temperature-sensitives and 10 cryo-sensitives. Of the isolated temperature-sensitives 1 located in cnxA, 1 in cnxB, 2 in cnxC, 1 cnxE, 2 in cnxF and 3 in cnxH. Of the crysosensitives 4 in cnxB, 3 in cnxC and 3 in cnxF. These mutants will be particularly useful to relate structure and function when data is forthcoming regarding their protein sequence. Two temperature-sensitive mutants, cnxH255 and cnxH261 showed reduced nitrate reductase thermostability which indicates that the cnxH product could be associated with the NR protein. One of the Aspergillus nidulans genes required for the synthesis of the molybdenum cofactor was isolated using molecular self-cloning transformation approaches. This gene, cnxH, was sequenced at the nucleotide level as well as three mutant alleles (one temperature sensitive and two temperature non-conditional). The results show that the cnxH product is the homologue of Escherichia, coli moaE whose role is in the synthesis of the molybdenum cofactor specifically to convert the large subunit to active converting factor. Sequence analysis of the two non-conditional mutants indicates that such mutants generated stop codons which provides little or no information about the structure / function relationships. The mutation in the temperature-sensitive mutant lead to a glycine insertion at position +443 and it is postulated that this additional amino acid caused the heat liability of the NR enzyme. Studies of cnxH expression show that the cnxH is in very low abundance and not regulated at the transcriptional level at least since similar transcript levels were seen in both nitrate and ammonium grown cells- conditions, which making difference for nitrate reductase activity. Finally attempts at isolating Arabidopsis thaliana cnx genes failed.
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Biochemistry, genetics and molecular biology of nitrite reduction in barleyWard, Michael Patrick January 1997 (has links)
Nitrite reduction is the third step of the nitrate assimilation pathway in higher plants and is catalysed by nitrite reductase. The whole-plant barley mutants STA1010, STA2760 and STA4169 accumulate nitrite in the leaf after treatment with nitrate and, like the nir1 mutant STA3999 (Duncanson et al, 1993), lack detectable nitrite reductase cross-reacting material in the leaf and root. STA1010, STA2760 and STA4169 carry a recessive mutation in a single nuclear gene, identified as the Nir1 locus. RFLP analysis of the nir1 mutant STA3999 has allowed the Nir1 locus to be mapped to within 0.3cM of the nitrite reductase apoprotein gene, Nii. Studies to confirm the identity of the Nir1 locus as Nii, by establishing the full-length Nii cDNA sequences from STA3999 and from its wild-type cv Tweed for comparative purposes, were unsuccessful as attempts to isolate a Nii cDNA clone from a barley cv Tweed cDNA library yielded only partial-length Nii clones. These nirl mutants display greatly reduced nitrite reductase activity and increased NADH-nitrate reductase activity in the leaf, as compared to wild-type plants, suggesting a regulatory perturbation in the expression of the Nar1 gene. Northern analysis shows that the nir1 mutants possess nitrite reductase apoprotein (nii) transcript of wild-type size (2.3kb) and at approximately wild-type levels. Since nir1 mutants possess a phenotype that might be anticipated for a Nii mutant, it is likely that the nir1 mutation is present in the nitrite reductase apoprotein gene Nii and affects translation of the nii transcript. Studies of barley wild-type cv Golden Promise have demonstrated that nitrite reductase in leaf tissue is up-regulated by a coaction of nitrate and light which acts, at least partly, at the transcriptional level.
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Effects of nitrogen sprays on the growth of lettuceFazio, Steve, 1916- January 1951 (has links)
No description available.
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Effect of plant population and nitrogen on short-season, narrow- row upland cottonWatkins, Steven Douglas, 1945- January 1974 (has links)
No description available.
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