1. Figure 35.0 The effect of submersion in water on leaf development in Cabomba

2. Figure 35.0x The effect of wind on plant form in fir trees

3. Figure 35.2 Morphology of a flowering plant: an overview

4. Figure 35.1 A comparison of monocots and dicots

5. Figure 35.3 Radish root hairs

6. Figure 35.4 Modified shoots: Stolons, strawberry (top left); rhizomes, iris (top right); tubers, potato (bottom left); bulb, onion (bottom right)

7. Figure 35.5 Simple versus compound leaves

8. Figure 35.6 Modified leaves: Tendrils, pea plant (top left); spines, cacti (top right); succulent (bottom left); brightly-colored leaves, poinsettia (bottom right)

9. Figure 35.6x Lithops, a stone-mimicking plant from South African deserts

10. Figure 35.7 The three tissue systems

11. Figure 35.8 Water-conducting cells of xylem

12. Figure 35.9 Food-conducting cells of the phloem

13. Figure 35.10 Review of general plant cell structure

14. Figure 35.11 The three major categories of plant cells

15. Figure 35.12 Locations of major meristems: an overview of plant growth

16. Figure 35.13 Morphology of a winter twig

17. Figure 36.18 Tapping phloem sap with the help of an aphid

18. Figure 35.14 Primary growth of a root

19. Figure 35.15 Organization of primary tissues in young roots

20. Figure 35.16 The formation of lateral roots

21. Figure 35.17 The terminal bud and primary growth of a shoot

22. Figure 35.18 Organization of primary tissues in young stems

23. Figure 35.19 Leaf anatomy

24. Figure 35.20 Production of secondary xylem and phloem by the vascular cambium

25. Figure 35.21 Secondary growth of a stem (Layer 1)

26. Figure 35.21 Secondary growth of a stem (Layer 2)

27. Figure 35.21 Secondary growth of a stem (Layer 3)

28. Figure 35.22 Anatomy of a three-year-old stem

29. Figure 35.22x Secondary growth of a stem

30. Figure 35.23 Anatomy of a tree trunk

31. Figure 35.24 A summary of primary and secondary growth in a woody stem

32. Figure 36.0 Eucalyptus trees

33. Figure 36.0x Trees

34. Figure 36.1 An overview of transport in whole plants (Layer 1)

35. Figure 36.1 An overview of transport in whole plants (Layer 2)

36. Figure 36.1 An overview of transport in whole plants (Layer 3)

37. Figure 36.1 An overview of transport in whole plants (Layer 4)

38. Figure 36.2 A chemiosmotic model of solute transport in plant cells

39. Figure 36.3 Water potential and water movement: a mechanical model

40. Figure 36.4 Water relations of plant cells

41. Figure 36.5 A watered tomato plant regains its turgor

42. Figure 36.6 Compartments of plant cells and tissues and routes for lateral transport

43. Figure 36.7 Lateral transport of minerals and water in roots

44. Figure 36.8 Mycorrhizae, symbiotic associations of fungi and roots

45. Figure 36.9 Guttation

46. Figure 36.12x Stomata on the underside of a leaf

47. Figure 35.19 Leaf anatomy

48. Figure 36.10 The generation of transpirational pull in a leaf

49. Figure 36.11 Ascent of water in a tree

50. Figure 36.12 An open (left) and closed (right) stoma of a spider plant (Chlorophytum colosum) leaf

51. Figure 36.13a The mechanism of stomatal opening and closing

52. Figure 36.13b The mechanism of stomatal opening and closing

54. Figure 36.14 A patch-clamp study of guard cell membranes

55. Figure 36.15 Structural adaptations of a xerophyte leaf

56. Figure 36.15x Structural adaptations of a xerophyte leaf

57. Figure 36.16 Loading of sucrose into phloem

58. Figure 36.17 Pressure flow in a sieve tube

59. Figure 36.18 Tapping phloem sap with the help of an aphid

60. Figure 35.25 The proportion of Arabidopsis genes in different functional categories

61. Figure 37.0 Hyacinth

62. Figure 37.1 The uptake of nutrients by a plant: an overview

63. Figure 37.2 Using hydroponic culture to identify essential nutrients

64. Table 37.1 Essential Nutrients in Plants

65. Figure 37.3 Magnesium deficiency in a tomato plant

66. Figure 37.4 Hydroponic farming

67. Figure 37.5 Soil horizons

68. Figure 37.6 The availability of soil water and minerals

69. Figure 37.7 Poor soil conservation has contributed to ecological disasters such as the Dust Bowl

70. Figure 37.8 Contour tillage

71. Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 1)

72. Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 2)

73. Figure 37.9 The role of soil bacteria in the nitrogen nutrition of plants (Layer 3)

74. Figure 37.10 Root nodules on legumes

75. Figure 37.10x Nodules

76. Figure 37.11 Development of a soybean root nodule

77. Figure 37.12 Crop rotation and “green manure”

78. Figure 37.13 Molecular biology of root nodule formation

79. Figure 37.14 Mycorrhizae

80. Figure 37.15a Parasitic plants: Cross section of dodder

81. Figure 37.15b Parasitic plants: Indian pipe

82. Figure 37.16 Carnivorous plants: Venus fly trap (left), pitcher plant (right)

83. Figure 37.16x Sundew with fruit fly

84. Figure 35.25x Arabidopsis thaliana

85. Figure 35.26 The plane and symmetry of cell division influence development of form

86. Figure 35.27 The preprophase band and the plane of cell division

87. Figure 35.28 The orientation of plant cell expansion

88. Figure 35.29 A hypothetical mechanism for how microtubules orient cellulose microfibrils

89. Figure 35.30 The fass mutant of Arabidopsis confirms the importance of cortical microtubules to plant growth

90. Figure 35.31 Establishment of axial polarity

91. Figure 35.32 Too much “volume” from a homeotic gene

92. Figure 35.33 Example of cellular differentiation

93. Figure 35.34 Phase change in the shoot system of Eucalyptus

94. Figure 35.35 Organ identity genes and pattern formation in flower development

95. Figure 35.36 The ABC hypothesis for the functioning of organ identity genes in flower development