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

2. The Three Basic Plant Organs: Roots, Stems, and Leaves
Three basic organs evolved: roots, stems, and leaves
They are organized into a root system and a shoot system
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3. Reproductive shoot (flower)
Figure 35.2
Reproductive shoot (flower)
Apical bud
Node
Internode
Apical bud
Shoot system
Vegetative shoot
Axillary bud
Blade
Leaf
Petiole
Stem
Figure 35.2 An overview of a flowering plant.
Taproot
Root system
Lateral (branch) roots

4. Roots A root is an organ with important functions:
Anchoring the plant
Absorbing minerals and water
Storing carbohydrates
Roots rely on sugar produced by photosynthesis in the shoot system, and shoots rely on water and minerals absorbed by the root system
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5. Most eudicots and gymnosperms have a taproot system:
A taproot, the main vertical root
Lateral roots, or branch roots, that arise from the taproot
Most monocots have a fibrous root system, which consists of:
Adventitious roots that arise from stems or leaves
Lateral roots that arise from the adventitious roots
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7. Absorption of water and minerals occurs near the root hairs, where vast numbers of tiny root hairs increase the surface area
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8. Many plants have root adaptations with specialized functions
Figure 35.4
Many plants have root adaptations with specialized functions
“Strangling” aerial roots
Storage roots
Prop roots
Buttress roots
Figure 35.4 Evolutionary adaptations of roots.
Pneumatophores

9. Stems A stem is an organ consisting of
An alternating system of nodes, the points at which leaves are attached
Internodes, the stem segments between nodes
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10. Apical dominance helps to maintain dormancy in most axillary buds
An axillary bud is a structure that has the potential to form a lateral shoot, or branch
An apical bud, or terminal bud, is located near the shoot tip and causes elongation of a young shoot
Apical dominance helps to maintain dormancy in most axillary buds
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11. Figure 35.5
Rhizomes
Rhizome
Many plants have modified stems (e.g., rhizomes, bulbs, stolons, tubers)
Root
Bulbs
Storage leaves
Stem
Stolons
Stolon
Figure 35.5 Evolutionary adaptations of stems.
Tubers

12. Leaves
The leaf is the main photosynthetic organ of most vascular plants
Leaves generally consist of a flattened blade and a stalk called the petiole, which joins the leaf to a node of the stem
Blade
Petiole
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13. Figure 35.7
Tendrils
Some plant species have evolved modified leaves that serve various functions
Spines
Storage leaves
Reproductive leaves
Figure 35.7 Evolutionary adaptations of leaves.
Bracts

14. Dermal, Vascular, and Ground Tissues
Each plant organ has dermal, vascular, and ground tissues
Dermal tissue
Ground tissue
Vascular tissue
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15. In nonwoody plants, the dermal tissue system consists of the epidermis and cuticle.
The vascular tissue system carries out long-distance transport of materials between roots and shoots
Xylem conveys water and dissolved minerals upward from roots into the shoots
Phloem transports organic nutrients from where they are made to where they are needed
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16. Tissues that are neither dermal nor vascular are the ground tissue system
Ground tissue internal to the vascular tissue is pith; ground tissue external to the vascular tissue is cortex
Ground tissue includes cells specialized for storage, photosynthesis, and support
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17. The major types of plant cells are:
Parenchyma
Collenchyma
Sclerenchyma
Water-conducting cells of the xylem
Sugar-conducting cells of the phloem
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18. 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 (indeterminate)
Parenchyma cells in Elodea leaf, with chloroplasts (LM)
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19. Collenchyma Cells
Collenchyma cells help support young parts of the plant shoot
These cells provide flexible support without restraining growth
Collenchyma cells (in Helianthus stem) (LM)
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20. Sclerenchyma Cells
Sclerenchyma cells are rigid because of thick secondary walls strengthened with lignin
They are dead at functional maturity
Sclereid cells in pear (LM)
Cell wall
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21. Water-Conducting Cells of the Xylem
Vessel
Tracheids
100 m
The two types of water-conducting cells, tracheids and vessel elements, are dead at maturity
Tracheids are found in the xylem of all vascular plants (Tracheophytes)
Tracheids and vessels (colorized SEM)
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22. Sugar-Conducting Cells of the Phloem
Sieve-tube elements are alive at functional maturity, though they lack organelles
Sieve plates are the porous end walls that allow fluid to flow between cells along the sieve tube
Each sieve-tube element has a companion cell whose nucleus and ribosomes serve both cells
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23. Sieve-tube elements: longitudinal view (LM) 3 m
Figure 35.10e
Sieve-tube elements: longitudinal view (LM)
3 m
Sieve plate
Sieve-tube element (left) and companion cell: cross section (TEM)
Companion cells
Sieve-tube elements
Plasmodesma
Figure Exploring: Examples of Differentiated Plant Cells
Sieve plate
30 m
Nucleus of companion cell
15 m
Sieve-tube elements: longitudinal view
Sieve plate with pores (LM)

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

25. Root with xylem and phloem in the center (typical of eudicots)
Figure 35.14aa
Epidermis
Key to labels
Cortex
Endodermis
Dermal
Vascular cylinder
Ground
Vascular
Pericycle
Xylem
Phloem
Figure Organization of primary tissues in young roots.
100 m
(a)
Root with xylem and phloem in the center (typical of eudicots)

26. 50 m Endodermis Pericycle Xylem Phloem Key to labels Dermal Ground
Figure 35.14ab
50 m
Endodermis
Pericycle
Xylem
Phloem
Key to labels
Figure Organization of primary tissues in young roots.
Dermal
Ground
Vascular

27. Core of parenchyma cells
Figure 35.14b
Epidermis
Key to labels
Cortex
Dermal
Endodermis
Ground
Vascular
Vascular cylinder
Pericycle
Core of parenchyma cells
Figure Organization of primary tissues in young roots.
Xylem
Phloem
100 m
(b)
Root with parenchyma in the center (typical of monocots)

28. Concept 35.2: Meristems generate cells for primary and secondary growth
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
Which of these types do animals typically exhibit?
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29. 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
Lateral meristems add thickness to woody plants, a process called secondary growth
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
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30. Primary growth in stems
Figure 35.11
Primary growth in stems
Epidermis
Cortex
Primary phloem
Shoot tip (shoot apical meristem and young leaves)
Primary xylem
Pith
Vascular cambium
Secondary growth in stems
Cork cambium
Lateral meristems
Cork cambium
Axillary bud meristem
Cortex
Periderm
Primary phloem
Figure An overview of primary and secondary growth.
Pith
Secondary phloem
Root apical meristems
Primary xylem
Vascular cambium
Secondary xylem

31. This year’s growth (one year old) Leaf scar
Figure 35.12
Apical bud
Bud scale
Axillary buds
This year’s growth (one year old)
Leaf scar
Node
Bud scar
One-year-old side branch formed from axillary bud near shoot tip
Internode
Last year’s growth (two year old)
Leaf scar
Stem
Figure Three years’ growth in a winter twig.
Bud scar
Growth of two years ago (three years old)
Leaf scar

32. Concept 35.3: Primary growth lengthens roots and shoots
Primary growth produces the parts of the root and shoot systems produced by apical meristems
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33. Primary Growth of Roots
Figure 35.13
Cortex
Vascular cylinder
Key to labels
Epidermis
Dermal
Zone of differentiation
Ground
Root hair
Vascular
Primary Growth of Roots
Zone of elongation
Figure Primary growth of a root.
Zone of cell division (including apical meristem)
Mitotic cells
100 m
Root cap

34. Figure
Lateral roots arise from within the pericycle, the outermost cell layer in the vascular cylinder
100 m
Epidermis
Emerging lateral root
Lateral root
Cortex
Vascular cylinder
Pericycle
Figure The formation of a lateral root. 1 2 3

35. 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
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36. Developing vascular strand
Figure 35.16
Shoot apical meristem
Leaf primordia
Young leaf
Developing vascular strand
Figure The shoot tip.
Axillary bud meristems
0.25 mm

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

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

39. Figure 35.17b
Ground tissue
In most monocot stems, the vascular bundles are scattered throughout the ground tissue, rather than forming a ring
Key to labels
Dermal
Ground
Vascular
Epidermis
Figure Organization of primary tissues in young stems.
Vascular bundles
1 mm
(b)
Cross section of stem with scattered vascular bundles typical of monocots)

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

41. (a) Cutaway drawing of leaf tissues
Figure 35.18a
Key to labels
Sclerenchyma fibers
Dermal
Cuticle
Stoma
Ground
Vascular
Upper epidermis
Palisade mesophyll
Spongy mesophyll
Bundle- sheath cell
Figure Leaf anatomy.
Lower epidermis
Xylem
Vein
Cuticle
Phloem
Guard cells
(a) Cutaway drawing of leaf tissues

42. Figure 35.19
Concept 35.4: Secondary growth increases the diameter of stems and roots in woody plants
(a)
Primary and secondary growth in a two-year-old woody stem
Epidermis
Pith
Cortex
Primary xylem
Primary phloem
Vascular cambium
Epidermis
Primary phloem
Cortex
Vascular cambium
Primary xylem
Growth
Vascular ray
Pith
Primary xylem
Secondary xylem
Vascular cambium
Secondary phloem
Primary phloem
First cork cambium
Cork
Periderm (mainly cork cambia and cork)
Growth
Figure Primary and secondary growth of a woody stem.
Secondary phloem
Bark
Vascular cambium
Primary phloem
Secondary xylem
Late wood
Cork cambium
Early wood
Periderm
Secondary phloem
Cork
Secondary xylem (two years of production)
Vascular cambium
0.5 mm
Secondary xylem
Vascular cambium
Bark
Secondary phloem
Primary xylem
Most recent cork cambium
Layers of periderm
Vascular ray
Growth ring
Cork
(b)
Cross section of a three-year- old Tilia (linden) stem (LM)
Pith
0.5 mm

43. Cross section of a three-year- old Tilia (linden) stem (LM)
Figure 35.19b
Secondary phloem
Bark
Vascular cambium
Cork cambium
Late wood
Secondary xylem
Periderm
Early wood
Cork
0.5 mm
Figure Primary and secondary growth of a woody stem.
Vascular ray
Growth ring
(b)
Cross section of a three-year- old Tilia (linden) stem (LM)
0.5 mm

44. After one year of growth After two years of growth
Figure 35.20
Vascular cambium
Growth
Vascular cambium
Secondary phloem
Secondary xylem
Figure Secondary growth produced by the vascular cambium.
After one year of growth
After two years of growth

45. Tree rings are visible where late and early wood meet, and can be used to estimate a tree’s age
Dendrochronology is the analysis of tree ring growth patterns and can be used to study past climate change
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46. RESULTS 2 1.5 Ring-width indexes 1 0.5 1600 1700 1800 1900 2000 Year
Figure 35.21
RESULTS 2
1.5
Ring-width indexes 1
0.5
1600
1700
1800
1900
2000
Figure Research Method: Using Dendrochronology to Study Climate
Year

47. Figure 35.22
As a tree or woody shrub ages, the older layers of secondary xylem, the heartwood, no longer transport water and minerals
Growth ring
Vascular ray
Heartwood
Secondary xylem
Sapwood
Figure Anatomy of a tree trunk.
Vascular cambium
Secondary phloem
Bark
Layers of periderm

48. Figure 35.23
Figure Is this tree living or dead?

49. Genetic Control of Flowering
Figure 35.34
Sepals
Genetic Control of Flowering
Petals
Stamens
(a) A
A schematic diagram of the ABC hypothesis B
Carpels C
C gene activity
B  C gene activity
Carpel
A  B gene activity
Petal
A gene activity
Stamen
Sepal
Active genes: B B B B B B B B A A A A A A C C C C A A C C C C C C C C A A C C C C A A A B B A A B B A
Whorls:
Figure The ABC hypothesis for the functioning of organ identity genes in flower development.
Carpel
Stamen
Petal
Sepal
Wild type
Mutant lacking A
Mutant lacking B
Mutant lacking C
(b) Side view of flowers with organ identity mutations

50. (a) Normal Arabidopsis flower Pe
Figure 35.33 Pe Ca St Se Pe Se
(a) Normal Arabidopsis flower Pe Pe
Figure Organ identity genes and pattern formation in flower development. Se
Abnormal Arabidopsis flower
(b)