1. Plant Structure, Growth, and Development
Chapter 35
Plant Structure, Growth, and Development

2. Overview: Plastic Plants?
To some people, the fanwort is an intrusive weed, but to others it is an attractive aquarium plant
This plant exhibits developmental plasticity, the ability to alter itself in response to its environment

3. Fig. 35-1
Figure 35.1 Why does this plant have two types of leaves?

4. Developmental plasticity:
Is more marked in plants than in animals
In addition to plasticity, plant species have by natural selection accumulated characteristics of morphology that vary little within the species

5. The plant body has a hierarchy of organs, tissues, and cells
Plants, like multicellular animals, have:
Organs
Organs are composed of:
Different tissues
Tissues are composed of:
Similar cells

6. The Three Basic Plant Organs: Roots, Stems, and Leaves
Basic morphology of vascular plants reflects:
Their evolution as organisms able to draw nutrients from below ground and above ground

7. Three basic organs evolved: They are organized into:
Roots, stems, and leaves
They are organized into:
A root system, and
A shoot system
Roots rely on:
Sugar produced by photosynthesis in the shoot system
Shoots rely on:
water and minerals absorbed by the root system

8. Reproductive shoot (flower)
Fig. 35-2
Reproductive shoot (flower)
Apical bud
Node
Internode
Apical
bud
Shoot
system
Vegetative
shoot
Blade
Leaf
Petiole
Axillary
bud
Stem
Figure 35.2 An overview of a flowering plant
Taproot
Lateral
branch
roots
Root
system

9. Roots are multicellular organs with important functions:
Anchoring the plant
Absorbing minerals and water
Storing organic nutrients

10. A taproot system consists of:
One main vertical root that gives rise to lateral roots, or branch roots
Adventitious roots arise from:
Stems or leaves
Seedless vascular plants & monocots:
Have a fibrous root system characterized by:
Thin lateral roots with no main root

11. In most plants,
Absorption of water & minerals occurs near the tips of roots
Vast numbers of tiny root hairs at root tips increase the surface area

12. Fig. 35-3
Figure 35.3 Root hairs of a radish seedling

13. Many plants have modified roots

14. Prop roots “Strangling” aerial roots Storage roots Buttress roots
Fig. 35-4
Prop roots
“Strangling”
aerial roots
Storage roots
Buttress roots
Figure 35.4 Modified roots
Pneumatophores

15. Fig. 35-4a
Figure 35.4 Modified roots
Prop roots

16. Fig. 35-4b
Figure 35.4 Modified roots
Storage roots

17. “Strangling” aerial roots
Fig. 35-4c
Figure 35.4 Modified roots
“Strangling” aerial roots

18. Fig. 35-4d
Figure 35.4 Modified roots
Pneumatophores

19. Fig. 35-4e
Figure 35.4 Modified roots
Buttress roots

20. A stem is an organ consisting of:
Stems
A stem is an organ consisting of:
An alternating system of nodes (the points of attachment of leaves)
Internodes, the stem segments between nodes

21. An axillary bud:
Is a structure that has the potential to form a lateral shoot, or branch
An apical (terminal) bud:
Is located near the shoot tip and causes elongation of a young shoot
Apical dominance:
Inhibition of axillary buds by an apical bud
helps maintains dormancy in nonapical buds

22. Many plants have modified stems

23. Rhizomes Bulbs Storage leaves Stem Stolons Stolon Tubers Fig. 35-5
Figure 35.5 Modified stems
Tubers

24. Fig. 35-5a
Figure 35.5 Modified stems
Rhizomes

25. Fig. 35-5b
Storage leaves
Figure 35.5 Modified stems
Stem
Bulb

26. Fig. 35-5c
Stolon
Figure 35.5 Modified stems
Stolons

27. Fig. 35-5d
Figure 35.5 Modified stems
Tubers

28. Leaves
Leaves are:
The main photosynthetic organs of most vascular plants
Generally consist of:
A flattened blade
A stalk called the petiole, which joins the leaf to a node of the stem

29. In classifying angiosperms, taxonomists may:
Monocots & eudicots differ in the arrangement of veins (the vascular tissue of leaves):
Most monocots have parallel veins
Most eudicots have branching veins
In classifying angiosperms, taxonomists may:
Use leaf morphology as a criterion

30. (a) Simple leaf Petiole Axillary bud Leaflet (b) Compound leaf Petiole
Fig. 35-6
(a) Simple leaf
Petiole
Axillary bud
Leaflet
(b)
Compound
leaf
Petiole
Axillary bud
Figure 35.6 Simple versus compound leaves
(c)
Doubly
compound
leaf
Leaflet
Petiole
Axillary bud

31. (a) Simple leaf Petiole Axillary bud Fig. 35-6a
Figure 35.6 Simple versus compound leaves
Axillary bud

32. Leaflet (b) Compound leaf Petiole Axillary bud Fig. 35-6b
Figure 35.6 Simple versus compound leaves
Axillary bud

33. (c) Doubly compound leaf Leaflet Petiole Axillary bud Fig. 35-6c
Figure 35.6 Simple versus compound leaves
Axillary bud

34. Some plant species have:
Evolved modified leaves
Such leaves serve various functions

35. Tendrils Spines Storage leaves Reproductive leaves Bracts Fig. 35-7
Figure 35.7 Modified leaves
Bracts

36. Fig. 35-7a
Figure 35.7 Modified leaves
Tendrils

37. Fig. 35-7b
Figure 35.7 Modified leaves
Spines

38. Fig. 35-7c
Figure 35.7 Modified leaves
Storage leaves

39. Fig. 35-7d
Figure 35.7 Modified leaves
Reproductive leaves

40. Fig. 35-7e
Figure 35.7 Modified leaves
Bracts

41. Dermal, Vascular, and Ground Tissues
Each plant organ has the following tissues:
Dermal
Ground
Vascular
Each of these three categories forms:
A tissue system

42. Dermal tissue Ground tissue Vascular tissue Fig. 35-8
Figure 35.8 The three tissue systems
Dermal
tissue
Ground
tissue
Vascular
tissue

43. In nonwoody plants: In woody plants: Trichomes:
The dermal tissue system consists of the epidermis
A waxy coating called the cuticle helps prevent water loss from the epidermis
In woody plants:
Protective tissues called periderm replace the epidermis
This occurs in older regions of stems & roots
Trichomes:
Are outgrowths of the shoot epidermis
Can help with insect defense

44. EXPERIMENT Very hairy pod (10 trichomes/ mm2) Slightly hairy pod
Fig. 35-9
EXPERIMENT
Very hairy pod
(10 trichomes/
mm2)
Slightly hairy pod
(2 trichomes/
mm2)
Bald pod
(no trichomes)
RESULTS
Very hairy pod:
10% damage
Slightly hairy pod:
25% damage
Bald pod:
40% damage
Figure 35.9 Do soybean pod trichomes deter herbivores?

45. The vascular tissue system:
Transports materials between roots & shoots
Consists of two vascular tissues:
The xylem:
Conveys water & dissolved minerals from roots into the shoots
The Phloem:
Transports organic nutrients from where they are made to where they are needed

46. The vascular tissue of a stem or root is collectively called the stele
The stele arrangement varies depending on species & organ
In angiosperms:
The root stele is a solid central vascular cylinder of xylem & phloem
The stele of stems & leaves consists of vascular bundles, separate strands of xylem & phloem

47. Ground tissue system:
Tissues that are neither dermal nor vascular
The tissue includes cells specialized for:
Storage
Photosynthesis
Support
Pith:
Ground tissue internal to the vascular tissue
Cortex:
Ground tissue external to the vascular tissue

48. Common Types of Plant Cells
Like any multicellular organism, a plant is characterized by:
Cellular differentiation, the specialization of cells in structure and function

49. Some major types of plant cells:
Parenchyma
Collenchyma
Sclerenchyma
Water-conducting cells of the xylem
Sugar-conducting cells of the phloem

50. BioFlix: Tour of a Plant Cell
Parenchyma Cells
Mature parenchyma cells:
Have thin and flexible primary walls
Lack secondary walls
Are the least specialized
Perform the most metabolic functions
Retain the ability to divide and differentiate
BioFlix: Tour of a Plant Cell

51. Parenchyma cells in Elodea leaf, with chloroplasts (LM) 60 µm
Fig a
Figure Examples of differentiated plant cells
Parenchyma cells in Elodea leaf,
with chloroplasts (LM)
60 µm

52. Collenchyma Cells:
Grouped in strands
Help support young parts of the plant shoot
Have thicker and uneven cell walls
Lack secondary walls
Provide flexible support without restraining growth

53. Collenchyma cells (in Helianthus stem) (LM)
Fig b
5 µm
Figure Examples of differentiated plant cells
Collenchyma cells (in Helianthus stem) (LM)

54. Are rigid because of thick secondary walls strengthened with lignin
Sclerenchyma Cells
Are rigid because of thick secondary walls strengthened with lignin
Dead at functional maturity
There are two types:
Sclereids:
Short & irregular in shape
Have thick lignified secondary walls
Fibers:
Long & slender and
Arranged in threads

55. Sclereid cells in pear (LM)
Fig c
5 µm
Sclereid cells in pear (LM)
25 µm
Cell wall
Figure Examples of differentiated plant cells
Fiber cells (cross section from ash tree) (LM)

56. Water-Conducting Cells of the Xylem
Two types of water-conducting cells (dead at maturity):
Tracheids:
Found in the xylem of all vascular plants
Vessel elements:
Common to most angiosperms and a few gymnosperms
Align end to end to form long micropipes called vessels

57. Vessel Tracheids Pits Tracheids and vessels (colorized SEM)
Fig d
Vessel
Tracheids
100 µm
Pits
Tracheids and vessels
(colorized SEM)
Figure Examples of differentiated plant cells
Perforation
plate
Vessel
element
Vessel elements, with
perforated end walls
Tracheids

58. 100 µm Vessel Tracheids Tracheids and vessels (colorized SEM)
Fig d1
100 µm
Vessel
Tracheids
Figure Examples of differentiated plant cells
Tracheids and vessels
(colorized SEM)

59. Pits Perforation plate Vessel element Vessel elements, with
Fig d2
Pits
Figure Examples of differentiated plant cells
Perforation
plate
Vessel
element
Vessel elements, with
perforated end walls
Tracheids

60. Sugar-Conducting Cells of the Phloem
Sieve-tube elements:
Are alive at functional maturity, though they lack organelles
Each element has a companion cell whose nucleus and ribosomes serve both cells
Sieve plates:
Are the porous end walls allowing fluid to flow between cells along the sieve tube

61. longitudinal view (LM) 3 µm
Fig e
Sieve-tube elements:
longitudinal view (LM)
3 µm
Sieve plate
Sieve-tube element (left)
and companion cell:
cross section (TEM)
Companion
cells
Sieve-tube
elements
Plasmodesma
Sieve
plate
Figure Examples of differentiated plant cells
30 µm
10 µm
Nucleus of
companion
cells
Sieve-tube elements:
longitudinal view
Sieve plate with pores (SEM)

62. Sieve-tube element (left) and companion cell: cross section (TEM)
Fig e1
3 µm
Figure Examples of differentiated plant cells
Sieve-tube element (left)
and companion cell:
cross section (TEM)

63. longitudinal view (LM)
Fig e2
Sieve-tube elements:
longitudinal view (LM)
Sieve plate
Companion
cells
Sieve-tube
elements
Figure Examples of differentiated plant cells
30 µm

64. Sieve plate with pores (SEM)
Fig e3
Sieve-tube
element
Plasmodesma
Sieve
plate
10 µm
Nucleus of
companion
cells
Figure Examples of differentiated plant cells
Sieve-tube elements:
longitudinal view
Sieve plate with pores (SEM)

65. Break Slide Resume editing from here Sunday, July 21, 2013

66. Concept 35.2: Meristems generate cells for new organs
A plant can grow throughout its life; this is called indeterminate growth
Some plant organs cease to grow at a certain size; this is called determinate growth
Annuals complete their life cycle in a year or less
Biennials require two growing seasons
Perennials live for many years

67. Meristems are perpetually embryonic tissue and allow for indeterminate growth
Apical meristems are located at the tips of roots and shoots and at the axillary buds of shoots
Apical meristems elongate shoots and roots, a process called primary growth

68. Lateral meristems add thickness to woody plants, a process called secondary growth
There are two lateral meristems: the vascular cambium and the cork cambium
The vascular cambium adds layers of vascular tissue called secondary xylem (wood) and secondary phloem
The cork cambium replaces the epidermis with periderm, which is thicker and tougher

69. Primary growth in stems
Fig
Primary growth in stems
Epidermis
Cortex
Shoot tip (shoot
apical meristem
and young leaves)
Primary phloem
Primary xylem
Pith
Lateral meristems:
Vascular cambium
Secondary growth in stems
Cork cambium
Axillary bud
meristem
Periderm
Cork
cambium
Cortex
Figure An overview of primary and secondary growth
Pith
Primary
phloem
Primary
xylem
Root apical
meristems
Secondary
phloem
Secondary
xylem
Vascular cambium

70. Meristems give rise to initials, which remain in the meristem, and derivatives, which become specialized in developing tissues
In woody plants, primary and secondary growth occur simultaneously but in different locations

71. Apical bud Bud scale Axillary buds This year’s growth (one year old)
Fig
Apical bud
Bud scale
Axillary buds
This year’s growth
(one year old)
Leaf
scar
Bud
scar
Node
One-year-old side
branch formed
from axillary bud
near shoot tip
Internode
Last year’s growth
(two years old)
Leaf scar
Figure Three years’ growth in a winter twig
Stem
Bud scar left by apical
bud scales of previous
winters
Growth of two
years ago
(three years old)
Leaf scar

72. Concept 35.3: Primary growth lengthens roots and shoots
Primary growth produces the primary plant body, the parts of the root and shoot systems produced by apical meristems

73. Primary Growth of Roots
The root tip is covered by a root cap, which protects the apical meristem as the root pushes through soil
Growth occurs just behind the root tip, in three zones of cells:
Zone of cell division
Zone of elongation
Zone of maturation
Video: Root Growth in a Radish Seed (Time Lapse)

74. Cortex Vascular cylinder Epidermis Key to labels Zone of
Fig
Cortex
Vascular cylinder
Epidermis
Key
to labels
Zone of
differentiation
Root hair
Dermal
Ground
Vascular
Zone of
elongation
Figure Primary growth of a root
Apical
meristem
Zone of cell
division
Root cap
100 µm

75. The primary growth of roots produces the epidermis, ground tissue, and vascular tissue
In most roots, the stele is a vascular cylinder
The ground tissue fills the cortex, the region between the vascular cylinder and epidermis
The innermost layer of the cortex is called the endodermis

76. Figure 35.14 Organization of primary tissues in young roots
Epidermis
Cortex
Endodermis
Vascular
cylinder
Pericycle
Core of
parenchyma
cells
Xylem
100 µm
Phloem
(a)
Root with xylem and phloem in the center
(typical of eudicots)
100 µm
(b)
Root with parenchyma in the center (typical of
monocots)
Endodermis
Key
to labels
Figure Organization of primary tissues in young roots
Pericycle
Dermal
Ground
Vascular
Xylem
Phloem
50 µm

77. Root with xylem and phloem in the center (typical of eudicots)
Fig a1
Epidermis
Key
to labels
Cortex
Dermal
Endodermis
Ground
Vascular
Vascular
cylinder
Pericycle
Figure Organization of primary tissues in young roots
Xylem
100 µm
Phloem
(a)
Root with xylem and phloem in the center
(typical of eudicots)

78. Root with xylem and phloem in the center (typical of eudicots)
Fig a2
(a)
Root with xylem and phloem in the center
(typical of eudicots)
Endodermis
Key
to labels
Pericycle
Dermal
Ground
Vascular
Xylem
Phloem
Figure Organization of primary tissues in young roots
50 µm

79. Root with parenchyma in the center (typical of monocots)
Fig b
Epidermis
Cortex
Endodermis
Vascular
cylinder
Key
to labels
Pericycle
Dermal
Core of
parenchyma
cells
Ground
Vascular
Figure Organization of primary tissues in young roots
Xylem
Phloem
100 µm
(b)
Root with parenchyma in the center (typical of
monocots)

80. Lateral roots arise from within the pericycle, the outermost cell layer in the vascular cylinder

81. Emerging lateral root Cortex Vascular cylinder 100 µm 1 Fig. 35-15-1
Figure The formation of a lateral root 1
Vascular
cylinder

82. Epidermis Emerging lateral Lateral root root Cortex Vascular cylinder
Fig
100 µm
Epidermis
Emerging
lateral
root
Lateral root
Cortex
Figure The formation of a lateral root 1
Vascular
cylinder 2

83. Epidermis Emerging lateral Lateral root root Cortex Vascular cylinder
Fig
100 µm
Epidermis
Emerging
lateral
root
Lateral root
Cortex
Figure The formation of a lateral root 1
Vascular
cylinder 2 3

84. Primary Growth of Shoots
A shoot apical meristem is a dome-shaped mass of dividing cells at the shoot tip
Leaves develop from leaf primordia along the sides of the apical meristem
Axillary buds develop from meristematic cells left at the bases of leaf primordia

85. Shoot apical meristem Leaf primordia Young leaf Developing vascular
Fig
Shoot apical meristem
Leaf primordia
Young
leaf
Developing
vascular
strand
Figure The shoot tip
Axillary bud
meristems
0.25 mm

86. Tissue Organization of Stems
Lateral shoots develop from axillary buds on the stem’s surface
In most eudicots, the vascular tissue consists of vascular bundles that are arranged in a ring

87. Figure 35.17 Organization of primary tissues in young stems
Phloem
Xylem
Sclerenchyma
(fiber cells)
Ground
tissue
Ground tissue
connecting
pith to cortex
Pith
Epidermis
Key
to labels
Figure Organization of primary tissues in young stems
Epidermis
Cortex
Vascular
bundles
Dermal
Vascular
bundle
Ground
1 mm
Vascular
1 mm
(a)
Cross section of stem with vascular bundles forming
a ring (typical of eudicots)
(b)
Cross section of stem with scattered vascular bundles
(typical of monocots)

88. Cross section of stem with vascular bundles forming
Fig a
Phloem
Xylem
Sclerenchyma
(fiber cells)
Ground tissue
connecting
pith to cortex
Pith
Figure Organization of primary tissues in young stems
Key
to labels
Epidermis
Cortex
Dermal
Vascular
bundle
Ground
1 mm
Vascular
(a)
Cross section of stem with vascular bundles forming
a ring (typical of eudicots)

89. Cross section of stem with scattered vascular bundles
Fig b
Ground
tissue
Epidermis
Key
to labels
Figure Organization of primary tissues in young stems
Vascular
bundles
Dermal
Ground
Vascular
1 mm
(b)
Cross section of stem with scattered vascular bundles
(typical of monocots)

90. In most monocot stems, the vascular bundles are scattered throughout the ground tissue, rather than forming a ring

91. Tissue Organization of Leaves
The epidermis in leaves is interrupted by stomata, which allow CO2 exchange between the air and the photosynthetic cells in a leaf
Each stomatal pore is flanked by two guard cells, which regulate its opening and closing
The ground tissue in a leaf, called mesophyll, is sandwiched between the upper and lower epidermis

92. Below the palisade mesophyll in the upper part of the leaf is loosely arranged spongy mesophyll, where gas exchange occurs
The vascular tissue of each leaf is continuous with the vascular tissue of the stem
Veins are the leaf’s vascular bundles and function as the leaf’s skeleton
Each vein in a leaf is enclosed by a protective bundle sheath

93. Fig. 35-18 Figure 35.18 Leaf anatomy Guard cells Key to labels
Stomatal
pore
50 µm
Dermal
Epidermal
cell
Ground
Cuticle
Sclerenchyma
fibers
Vascular
Stoma
(b)
Surface view of a spiderwort
(Tradescantia) leaf (LM)
Upper
epidermis
Palisade
mesophyll
Bundle-
sheath
cell
Spongy
mesophyll
Figure Leaf anatomy
Lower
epidermis
100 µm
Cuticle
Xylem
Phloem
Vein
Guard
cells
Vein
Air spaces
Guard cells
(a) Cutaway drawing of leaf tissues
(c)
Cross section of a lilac
(Syringa)) leaf (LM)

94. (a) Cutaway drawing of leaf tissues
Fig a
Key
to labels
Dermal
Ground
Cuticle
Sclerenchyma
fibers
Vascular
Stoma
Upper
epidermis
Palisade
mesophyll
Bundle-
sheath
cell
Spongy
mesophyll
Figure Leaf anatomy
Lower
epidermis
Cuticle
Xylem
Phloem
Vein
Guard
cells
(a) Cutaway drawing of leaf tissues

95. Surface view of a spiderwort (Tradescantia) leaf (LM)
Fig b
Guard
cells
Stomatal
pore
50 µm
Epidermal
cell
Figure Leaf anatomy
(b)
Surface view of a spiderwort
(Tradescantia) leaf (LM)

96. Cross section of a lilac (Syringa) leaf (LM)
Fig c
Upper
epidermis
Key
to labels
Palisade
mesophyll
Dermal
Ground
Vascular
Spongy
mesophyll
Lower
epidermis
100 µm
Figure Leaf anatomy
Vein
Air spaces
Guard cells
(c)
Cross section of a lilac
(Syringa) leaf (LM)