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Book of Abstracts First Legume Society Conference 2013: A Legume Odyssey Novi Sad, Serbia, 9-11 May 2013 _________________________________________________________________________________________ KEYNOTE LECTURE Genetic and molecular analysis of sustainable biofuel production from the legume tree Pongamia pinnata Peter M. Gresshoff Centre for Integrative Legume Research, SAFS, The University of Queensland, St Lucia, Brisbane, Australia Pongamia trees are sourced from tropical and subtropical regions of the world (India, Indonesia, northern Australia, and other localities in that general region). They are rich with seeds about 1.5- 3.0 gm dry weight after 2 to 4 years. These seeds contain 35-50% plant oil which contains mainly C18:1 oleic acid (50-55%). Pongamia oil is suitable for both biodiesel as well as aviation fuel production. Mature trees with 20,000 seeds are not uncommon. The estimated oil yield per hectare per annum is between 3 to 5 tons. Pongamia, despite its warm weather natural habitat, is very adaptable. They grow, then have a winter dormancy period of about 3-4 months, and yield good seed in central Queensland, where winter night temperatures are -5 to -6 degrees C). They also are deep-rooted and thus very drought-tolerant. Plants grow on salty soil and even next to the ocean in beach environments. Pongamia is outcrossing with a diploid chromosome number of 22. Its genome size is about 600-700 Mbp, based on comparison to soybean chromosomes. Because of the outbreeding the progeny seed are heterogeneous and variable. We have developed ISSR DNA markers to determine genetic diversity. We have initiated multi-faceted analyses of Pongamia to facilitate the domestication of elite mother trees. Deep sequencing of its genome has allowed gene isolation using orthologous soybean genes for fatty acid, nodulation and ureide metabolism. The chloroplast (152 kbp) and mitochondrial (425 kbp) genomes were sequenced, assembled and annotated. Great similarity exists to those organelle genomes from Lotus japonicus. We developed classical clonal propagation procedures by rooted cutting, tissue culture and grafting to evaluate the genetic versus the environmental influence on traits in different parent genotypes. We have Life Cycle Analysis data of Pongamia grown in plantation style for 4 years since seed germination. Above ground biomass exceeds 13 kg per tree with 4 m height trees and 10-15 cm diameter stems. Analysis of nodulation and nitrogen fixation indicated determinate development progressing to lobed nodules with greater age. Parameters of nodulation appear to be similar to those seen in other annual legumes such as soybean. We strongly believe that the use of a high seed number, high oil legume tree is optimal for sustainable production of biofuel and co-products for the future biofuel industry. 227
Book of Abstracts First Legume Society Conference 2013: A Legume Odyssey Novi Sad, Serbia, 9-11 May 2013 _________________________________________________________________________________________ The effect of legume cover crops on soil phosphorus availability Margarida Arrobas, Ermelinda L Pereira, Isabel Q Ferreira, M Ângelo Rodrigues Mountain Research Centre – Polytechnic Institute of Bragança, Bragança, Portugal Legume can fix atmospheric N and sequester carbon. Some legumes are able to uptake sparingly soluble soil phosphorus. Additionally, all those effects may contribute to a beneficial increase in soil microbial activity. In this work three ground-cover treatments were imposed to an olive orchard located in NE Portugal: Natural vegetation (Nat veg); Natural vegetation fertilized with 60 kg N ha -1 yr -1 (Nat veg +N); and a mixture of self-reseeding annual legumes (Legumes). Three years after the establishment of the ground-cover treatments, soil samples were taken from the 0- 10 and 10-20 cm depths. Extractable soil P was determined by the Olsen and Egner-Riehm methods, the acid phosphatase activity accordingly to Tabatabai and Bremner and soil organic carbon by the Walkley-Black method. In the 0-10 cm soil layer, the acid phosphatase activity was significantly higher in the treatments Legumes and Nat veg+N (7.81 and 7.30 µg p-Nitrophenol g -1 ) than in the Nat veg (4.73 µg p-N g -1 ). Considering both soil layers, there was observed a significant linear relationship between oxidizable organic C and the acid phosphatase activity (R 2 =0.69). The P extracted by the Egner-Riehm method was better correlated with the acid phosphatase activity (R 2 =0.42) than P extracted by the Olsen method (R 2 =0.31) when all samples were taken into account. It seems that a similar effect of the legumes species on the acid phosphate activity may be achieved with the natural vegetation if fertilized with N. 228
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Programme 9 Session 1 Achievements
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