Seedling vigour in winter grain legumes / by Jafar Kamboozia.

Kamboozia, Jafar

January 1994

Bibliography: leaves 186-202. / xvii, 202 leaves : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Science, 1994

Legumes Seeds.

Legumes Seedlings.

Legumes Growth.

Seedling vigour in winter grain legumes

Kamboozia, Jafar.

January 1994

Bibliography: leaves 186-202.

Legumes Seeds

Legumes Seedlings

Legumes Growth

Determining factors that contribute to the propagation, growth and establishment of Burkea Africana trees

Nemadodzi, Lufuno Ethel

10 1900

Burkea africana Hook. (wild syringa) is an average sized leguminous tree, 10-12 m in height occasionally reaching over 20m. This monotypic genus is dominant and codominant in Zambia, and is present throughout Africa as far north as Ethopia and west to Nigeria, and south to South Africa especially Limpopo, North West, Gauteng and Mpumalanga. It inhabits dry, non–calcareous sandy soils in savanna and woodlands up to 1500 m altitude or gentle slope of 1080 m elevation. Burkea africana produces a relatively large number of seeds, which is unusual for a resprouting species. Several studies conducted on B. africana trees paid more attention to the medicinal attributes, however little or nothing is known regarding the factors and dynamics that contribute to the growth and existence of these trees, particularly because these trees grow naturally in nutrient-poor savanna soils. Although B. africana trees have been in existence for a very long period of time, propagating it through thinning and transplanting of seedlings for regeneration and/ or re-establishment of seedlings to survive until sexual maturity still remains a mystery. It is hypothesized that factors controlling establishment and development of B. africana trees are related to microbial activities in the soil, very complex and species specific but poorly understood. This study aimed to identify, if there is a symbiotic relationship between the soil and mycorhizal fungi, and rhizobium bacteria or other growth stimulating activities, in the Burkea soils, which will accelerate and assist effective growth of B. africana trees to reach reproductive stage and produce pods without dying. The chemical composition of Burkea soil and non-Burkea soils was analysed using HCl extraction method.). The results indicated the similar values (p>0.05) were observed for all micro and macro minerals as well as total nitrogen, pH and organic matter. However, total ions nitrate and ammonium concentration levels of Burkea soils were higher (p<0.05) than those found in non-Burkea soils. The use of advanced metabolomics tool using1H-NMR was used to determine and identify soil metabolites which may be responsible for successful growth and establishment of the Burkea africana trees. The findings of this study indicated that metabolomic analysis showed different metabolites in the respective soils. Growth-promoting metabolites (GPM) such as trehalose and betaine were found to be in higher concentrations in the Burkea soils. Conversely, acetate, lactate and formate, were found in higher concentrations in the non-Burkea soils. Furthermore, LC-MS was used to determine the soil components present in Burkea soil as compared to non-Burkea soil using. The results indicated that a total of 22 compounds consisted of essential amino acids such as phenylalamine, threonine, tryptophan, leucine, isoleucine and lysine; conditional essential amino acids such as arginine, cysteine, glycine, glutamine, proline and tyrosine; non-essential amino acids such as citruline, alinine, aspartic acids, asparagine, glutamic acid and serine; nucleobased amino acids such as guanosine, adenine, adenosine, cytindine; dicarboxylic acid such as fumaric acid as well as common non-proteinogenic amino acids such as 4-hydroxyproline compounds were found in both Burkea and nonBurkea soils. The study investigated the microbial communities in the soil where Burkea africana trees grows successfully (Burkea soils) and how it varies from the soils where they do not grow (non-Burkea soils). DNA was extracted from the soil and a high throughput sequence bask local assignment search tool (BLAST) was used to analyze the microbial diversity (bacterial and fungal) and composition found in both soils, for a comprehensive understanding of the soil microflora. The results revealed that Penicillum sp is prevalent in Burkea soils and was the main discriminant between the two soils. On the contrary, non-cultured fungi, which could not be identified, dominated the non-Burkea soils. The variances in soil composition suggests that species supremacy play a role in the growth of B. africana trees. Lastly, the current study investigated and also identified what attracts caterpillars known as Cirina forda to invade and feed on B. africana trees. In addition, to determining if there is a symbiotic relationship between the plant-growth metabolites; growth-promoting fungi (Penicilium sp) and the caterpillars. The results of the study, revealed that the fungus Pleurostomophora richardsiae was predominant in the leaves of B. africana trees as well as in the caterpillars. It is proposed that Pl. richardsiae is a volatile compound which attracts caterpillars and makes B. africana trees susceptible to caterpillars’ outbreaks. The second largest percentage of fungi found in the caterpillars was Aspergillus nomius. / School of Agriculture and Life Sciences / Ph. D. (Agriculture)

635.933634

Caesalpiniaceae -- Growth

Legumes -- Growth

Savanna ecology

Mycorrhizal effects on 15N-transfer from legume to grass intercrops, plant growth and interspecific competition

Hamel, Chantal

January 1990

N-transfer from legume to grass when the two were intercropped in the field and the mechanisms of this transfer were studied. Studies involving either alfalfa-grasses or soybean-corn intercrops, were undertaken. Mycorrhizal and P-supplemented (to compensate for the lack of mycorrhizae) intercrops were compared. In these studies, the legume component of intercrops was labelled with $ sp{15}$N and any excess of the label was looked for in the associated grass plants. / There was no reversal of N transport at the legume-fungus interface. N-transfer from legume to grass must therefore, proceed via excretion of N by legume roots and subsequent uptake by grass roots. Soil microorganisms and proximity of plant root systems are important factors affecting N-transfer. Mycorrhizae enhance the transfer by increasing the absorptive efficiency of the receiver plants. / Mycorrhizal fungi enhance the competitiveness of the most mycotrophic component of the mixtures by either improving P uptake or the general nutrient balance of the plant. Mycorrhizal inoculation can decrease the level of P competition between corn and soybean by increasing the availability of P. / The observation that mycorrhizal plants differ in many regards from P-supplemented plants, emphasize the generally poor comprehension of the mycorrhizal symbiosis.

Intercropping.

Crops and nitrogen.

Mycorrhizas.

Grasses -- Growth.

Legumes -- Growth.

Mycorrhizal effects on 15N-transfer from legume to grass intercrops, plant growth and interspecific competition

Hamel, Chantal

January 1990

No description available.

Intercropping.

Mycorrhizas.

Legumes -- Growth.

Crops and nitrogen.

Grasses -- Growth.