figure 35.0 the effect of submersion in water on leaf development in cabomba
TRANSCRIPT
- Slide 1
- Figure 35.0 The effect of submersion in water on leaf development in Cabomba
- Slide 2
- Figure 35.0x The effect of wind on plant form in fir trees
- Slide 3
- Figure 35.2 Morphology of a flowering plant: an overview
- Slide 4
- Figure 35.1 A comparison of monocots and dicots
- Slide 5
- Figure 35.3 Radish root hairs
- Slide 6
- Figure 35.4 Modified shoots: Stolons, strawberry (top left); rhizomes, iris (top right); tubers, potato (bottom left); bulb, onion (bottom right)
- Slide 7
- Figure 35.5 Simple versus compound leaves
- Slide 8
- Figure 35.6 Modified leaves: Tendrils, pea plant (top left); spines, cacti (top right); succulent (bottom left); brightly-colored leaves, poinsettia (bottom right)
- Slide 9
- Figure 35.6x Lithops, a stone-mimicking plant from South African deserts
- Slide 10
- Figure 35.7 The three tissue systems
- Slide 11
- Figure 35.8 Water-conducting cells of xylem
- Slide 12
- Figure 35.9 Food-conducting cells of the phloem
- Slide 13
- Figure 35.10 Review of general plant cell structure
- Slide 14
- Figure 35.11 The three major categories of plant cells
- Slide 15
- Figure 35.12 Locations of major meristems: an overview of plant growth
- Slide 16
- Figure 35.13 Morphology of a winter twig
- Slide 17
- Figure 36.18 Tapping phloem sap with the help of an aphid
- Slide 18
- Figure 35.14 Primary growth of a root
- Slide 19
- Figure 35.15 Organization of primary tissues in young roots
- Slide 20
- Figure 35.16 The formation of lateral roots
- Slide 21
- Figure 35.17 The terminal bud and primary growth of a shoot
- Slide 22
- Figure 35.18 Organization of primary tissues in young stems
- Slide 23
- Figure 35.19 Leaf anatomy
- Slide 24
- Figure 35.20 Production of secondary xylem and phloem by the vascular cambium
- Slide 25
- Figure 35.21 Secondary growth of a stem (Layer 1)
- Slide 26
- Figure 35.21 Secondary growth of a stem (Layer 2)
- Slide 27
- Figure 35.21 Secondary growth of a stem (Layer 3)
- Slide 28
- Figure 35.22 Anatomy of a three-year-old stem
- Slide 29
- Figure 35.22x Secondary growth of a stem
- Slide 30
- Figure 35.23 Anatomy of a tree trunk
- Slide 31
- Figure 35.24 A summary of primary and secondary growth in a woody stem
- Slide 32
- Figure 36.0 Eucalyptus trees
- Slide 33
- Figure 36.0x Trees
- Slide 34
- Figure 36.1 An overview of transport in whole plants (Layer 1)
- Slide 35
- Figure 36.1 An overview of transport in whole plants (Layer 2)
- Slide 36
- Figure 36.1 An overview of transport in whole plants (Layer 3)
- Slide 37
- Figure 36.1 An overview of transport in whole plants (Layer 4)
- Slide 38
- Figure 36.2 A chemiosmotic model of solute transport in plant cells
- Slide 39
- Figure 36.3 Water potential and water movement: a mechanical model
- Slide 40
- Figure 36.4 Water relations of plant cells
- Slide 41
- Figure 36.5 A watered tomato plant regains its turgor
- Slide 42
- Figure 36.6 Compartments of plant cells and tissues and routes for lateral transport
- Slide 43
- Figure 36.7 Lateral transport of minerals and water in roots
- Slide 44
- Figure 36.8 Mycorrhizae, symbiotic associations of fungi and roots
- Slide 45
- Figure 36.9 Guttation
- Slide 46
- Figure 36.12x Stomata on the underside of a leaf
- Slide 47
- Figure 35.19 Leaf anatomy
- Slide 48
- Figure 36.10 The generation of transpirational pull in a leaf
- Slide 49
- Figure 36.11 Ascent of water in a tree
- Slide 50
- Figure 36.12 An open (left) and closed (right) stoma of a spider plant (Chlorophytum colosum) leaf
- Slide 51
- Figure 36.13a The mechanism of stomatal opening and closing
- Slide 52
- Figure 36.13b The mechanism of stomatal opening and closing
- Slide 53
- Slide 54
- Figure 36.14 A patch-clamp study of guard cell membranes
- Slide 55
- Figure 36.15 Structural adaptations of a xerophyte leaf
- Slide 56
- Figure 36.15x Structural adaptations of a xerophyte leaf
- Slide 57
- Figure 36.16 Loading of sucrose into phloem
- Slide 58
- Figure 36.17 Pressure flow in a sieve tube
- Slide 59
- Figure 36.18 Tapping phloem sap with the help of an aphid
- Slide 60
- Figure 35.25 The proportion of Arabidopsis genes in different functional categories
- Slide 61
- Figure 37.0 Hyacinth
- Slide 62
- Figure 37.1 The uptake of nutrients by a plant: an overview
- Slide 63
- Figure 37.2 Using hydroponic culture to identify essential nutrients
- Slide 64
- Table 37.1 Essential Nutrients in Plants
- Slide 65
- Figure 37.3 Magnesium deficiency in a tomato plant
- Slide 66
- Figure 37.4 Hydroponic farming
- Slide 67
- Figure 37.5 Soil horizons
- Slide 68
- Figure 37.6 The availability of soil water and minerals
- Slide 69
- Figure 37.7 Poor soil conservation has contributed to ecological disasters such as the Dust Bowl
- Slide 70
- Figure 37.8 Contour tillage
- Slide 71
- Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 1)
- Slide 72
- Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 2)
- Slide 73
- Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 3)
- Slide 74
- Figure 37.10 Root nodules on legumes
- Slide 75
- Figure 37.10x Nodules
- Slide 76
- Figure 37.11 Development of a soybean root nodule
- Slide 77
- Figure 37.12 Crop rotation and green manure
- Slide 78
- Figure 37.13 Molecular biology of root nodule formation
- Slide 79
- Figure 37.14 Mycorrhizae
- Slide 80
- Figure 37.15a Parasitic plants: Cross section of dodder
- Slide 81
- Figure 37.15b Parasitic plants: Indian pipe
- Slide 82
- Figure 37.16 Carnivorous plants: Venus fly trap (left), pitcher plant (right)
- Slide 83
- Figure 37.16x Sundew with fruit fly
- Slide 84
- Figure 35.25x Arabidopsis thaliana
- Slide 85
- Figure 35.26 The plane and symmetry of cell division influence development of form
- Slide 86
- Figure 35.27 The preprophase band and the plane of cell division
- Slide 87
- Figure 35.28 The orientation of plant cell expansion
- Slide 88
- Figure 35.29 A hypothetical mechanism for how microtubules orient cellulose microfibrils
- Slide 89
- Figure 35.30 The fass mutant of Arabidopsis confirms the importance of cortical microtubules to plant growth
- Slide 90
- Figure 35.31 Establishment of axial polarity
- Slide 91
- Figure 35.32 Too much volume from a homeotic gene
- Slide 92
- Figure 35.33 Example of cellular differentiation
- Slide 93
- Figure 35.34 Phase change in the shoot system of Eucalyptus
- Slide 94
- Figure 35.35 Organ identity genes and pattern formation in flower development
- Slide 95
- Figure 35.36 The ABC hypothesis for the functioning of organ identity genes in flower development