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Thursday Lecture – Legumes. Reading: Textbook, Chapter 6. Optional Assignment - Due Tuesday March 1 Where do “baby carrots” come from? - How are they produced? [is there such a thing as a pregnant mama-carrot?!]. Quiz. Quiz What is a legume?
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Thursday Lecture – Legumes Reading: Textbook, Chapter 6
Optional Assignment - Due Tuesday March 1 Where do “baby carrots” come from? - How are they produced? [is there such a thing as a pregnant mama-carrot?!]
Quiz • What is a legume? • List two crop plants that are members of the legume family
Fabaceae = Leguminosae Legume family (also called bean family or pea family)
Fabaceae = Leguminosae Legume family (also called bean family or pea family) “legere” – Latin for “too gather”
Fabaceae = Leguminosae Legume family (also called bean family or pea family) “legere” – Latin for “too gather” 19,000+ species – 3d largest
Fabaceae = Leguminosae Legume family (also called bean family or pea family) “legere” – Latin for “too gather” 19,000+ species – 3d largest 41 crop species – most of any family
Fabaceae = Leguminosae Legume family (also called bean family or pea family) “legere” – Latin for “too gather” 19,000+ species – 3d largest 41 crop species – most of any family Cereal + Legume complete protein
Legume – Papilionoid flower See Fig. 6.1, 6.2, page 138
Legume – Papilionoid flower See Fig. 6.1, 6.2, page 138 Banner petal
Legume – Papilionoid flower See Fig. 6.1, 6.2, page 138 Banner petal wing
Legume – Papilionoid flower See Fig. 6.1, 6.2, page 138 Banner petal wing keel
Legume – Papilionoid flower See Fig. 6.1, 6.2, page 138 Banner petal wing keel Stamens: 9 + 1
See Fig. 6.1, page 137 Other Legumes Acacia - Mimosoideae
See Fig. 6.1, page 137 Other Legumes Acacia - Mimosoideae Senna - Caesalpinoideae
Nitrogen Fixation Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems
Nitrogen Fixation Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms
Nitrogen Fixation Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms How does nitrogen become available to living organisms?
Nitrogen Fixation • Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems • Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms • How does nitrogen become available to living organisms? • reaction is called “fixation”
Nitrogen Fixation • Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems • Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms • How does nitrogen become available to living organisms? • reaction is called “fixation” • can occur with input of energy (lightning strike)
Nitrogen Fixation • Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems • Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms • How does nitrogen become available to living organisms? • reaction is called “fixation” • can occur with input of energy (lightning strike) • some microorganisms can carry out this reaction
Nitrogen Fixation • Paradox – atmosphere is 80% nitrogen (N) yet N is a limiting factor for plant growth in almost all ecosystems • Resolution – atmospheric nitrogen is in a form (N2) that is not available for chemical reactions in biological organisms • How does nitrogen become available to living organisms? • reaction is called “fixation” • can occur with input of energy (lightning strike) • some microorganisms can carry out this reaction • mutualism between bacteria (Rhizobium etc.) and members of Fabaceae
Nitrogen-fixing Root Nodules N2 Fixing Nodules
Nitrogen-fixing Root Nodules N2 Fixing Nodules Bacteria in cells
Can we transfer N-fixation to other crops? See Box 6.1, page 141
Can we transfer N-fixation to other crops? • See Box 6.1, page 141 • Morphological changes – development of nodule
Can we transfer N-fixation to other crops? • See Box 6.1, page 141 • Morphological changes – development of nodule • - critically important because need to exclude O2
Can we transfer N-fixation to other crops? • See Box 6.1, page 141 • Morphological changes – development of nodule • - critically important because need to exclude O2 • Host/symbiont recognition
Can we transfer N-fixation to other crops? • See Box 6.1, page 141 • Morphological changes – development of nodule • - critically important because need to exclude O2 • Host/symbiont recognition • Chemical reactions to carry out N2 fixation
Can we transfer N-fixation to other crops? • See Box 6.1, page 141 • Morphological changes – development of nodule • - critically important because need to exclude O2 • Host/symbiont recognition • Chemical reactions to carry out N2 fixation • Multiple genes, multiple chromosome locations, not trivial
Nitrogen Cycle See Fig. 6.4, page 140 1. nitrogen fixation 2. ammonification 3. nitrification atmospheric fixation 4. denitrification ammonification nitrogen fixing bacteria nitrification denitrifying bacteria
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins)
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens)
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens) • Amino acid content of proteins – complements grains
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens) • Amino acid content of proteins – complements grains • High fiber levels
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens) • Amino acid content of proteins – complements grains • High fiber levels • Isoflavones – appear to lower cholesterol levels
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens) • Amino acid content of proteins – complements grains • High fiber levels • Isoflavones – appear to lower cholesterol levels • Phytoestrogens may help relieve menopause symptoms
Nutritional Aspects of Legumes See Box 6.2, page 142 • Legumes produce many N-containing compounds • - nutritious foods (proteins, vitamins) • - poisons (alkaloids, cyanogens) • Amino acid content of proteins – complements grains • High fiber levels • Isoflavones – appear to lower cholesterol levels • Phytoestrogens may help relieve menopause symptoms • Oligosaccharides (beans, beans, the musical fruit … - see Box 6.3, page 150)
A Poisonous Legume Abrus precatorius – Precatory Bean Abrin – toxin, one of most toxic substances known 1 crushed seed can be fatal if ingested
Legumes – Changes Under Domestication • Annual habit, selfing breeding system
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering • Greater seed size
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering • Greater seed size • Synchronous fruiting
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering • Greater seed size • Synchronous fruiting • Loss of dormancy
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering • Greater seed size • Synchronous fruiting • Loss of dormancy • - question: which came first, domestication or loss of dormancy?
Legumes – Changes Under Domestication • Annual habit, selfing breeding system • Less seed scattering • Greater seed size • Synchronous fruiting • Loss of dormancy • - question: which came first, domestication or loss of dormancy? • Recent studies – no common set of “domesticated genes”