1. The fanwort has two types of leaves -- developmental plasticity
Figure 35.1 Why does this plant have two types of leaves?

2. Flowering Plant Morphology
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

3. Root Hairs of a radish seedling
Figure 35.3 Root hairs of a radish seedling

4. Prop roots “Strangling” aerial roots Storage roots Buttress roots
Many plants have modified roots
Prop roots
“Strangling”
aerial roots
Storage roots
Buttress roots
Figure 35.4 Modified roots
Pneumatophores

5. Prop roots - support tall top heavy plants
Modified roots
Figure 35.4 Modified roots
Prop roots - support tall top heavy plants

6. Pneumatophores - “air roots” enable root systems to capture oxygen
Modified Roots
Figure 35.4 Modified roots
Pneumatophores - “air roots” enable root systems to capture oxygen

7. Modified Roots
Figure 35.4 Modified roots
Buttress roots - support tall trunks of some tropical trees “like butresses.”

8. Many Plants have Modified Stems
Rhizomes
Bulbs
Storage leaves
Stem
Stolons
Stolon
Figure 35.5 Modified stems
Tubers

9. Simple vs. Compound Leaves
(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

10. Spines “prickly” Photosynthesis is
Some plant species have evolved modified leaves that serve various functions
Tendrils
cling
Spines “prickly” Photosynthesis is
carried out mainly by the fleshy stems
Storage Leaves succulent
plant leaves store water
Reproductive leaves
Little plantlets fall off
and take root in the soil
Figure 35.7 Modified leaves
Bracts
Look like petals
Attract pollinators

11. Tendrils = Modified Leaves
Figure 35.7 Modified leaves
Tendrils -- cling --> thigmotropism

12. Ice Plant Leaves Store Water: Succulent Plants: Desert Adaptation
Figure 35.7 Modified leaves
Storage leaves

13. Tissue System: Each plant organ has:. dermal. vascular and
Tissue System: Each plant organ has: * dermal * vascular and * ground tissues
Figure 35.8 The three tissue systems
Dermal
tissue
Ground
tissue
Vascular
tissue

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

15. 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)

16. Vessel element Tracheids
Differentiated Plant Cells in the Xylem - Dead at Maturity
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

17. Differentiated Plant Cells
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)

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

19. Sieve plate with pores (SEM)
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)

20. An overview of primary and secondary growth
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

21. Primary growth of a root
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

22. 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
Organization of primary tissues
in young roots
50 µm

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

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

25. Leaf anatomy 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)

26. Secondary growth produced by the vascular cambiumX X C P P
Secondary
phloem
Secondary
xylem X X C P X C P C C C C C X C C
Figure Secondary growth produced by the vascular cambium
After one year
of growth
After two years
of growth C C C

27. Anatomy of a tree trunk Growth ring Vascular ray Heartwood Secondary
xylem
Sapwood
Fig Anatomy of a tree trunk
Vascular cambium
Secondary phloem
Bark
Layers of periderm

28. Is this tree living or dead?
Figure Is this tree living or dead?

29. The plane and symmetry of cell division influence development of form
Plane of
cell division
(a) Planes of cell division
Figure The plane and symmetry of cell division influence development of form
Developing
guard cells
Unspecialized
epidermal cell
Guard cell
“mother cell”
(b) Asymmetrical cell division

30. The plane and symmetry of cell division influence development of form
Cellulose
microfibrils
Figure The orientation of plant cell expansion
5 µm
Nucleus
Vacuoles

31. Morphogenesis in plants, as in other multicellular organisms, is often controlled by homeotic genes
Figure Overexpression of a homeotic gene in leaf formation

32. Phase change in the shoot system
Leaves produced
by adult phase
of apical meristem
Figure Phase change in the shoot system of Acacia koa
Leaves produced
by juvenile phase
of apical meristem

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

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

35. Growth regions
Shoot tip
(shoot apical
meristem and
young leaves)
Vascular
cambium
Lateral
meristems
Cork
cambium
Axillary bud
meristem
Root apical
meristems

36. You should now be able to:
Compare the following structures or cells:
Fibrous roots, taproots, root hairs, adventitious roots
Dermal, vascular, and ground tissues
Monocot leaves and eudicot leaves
Parenchyma, collenchyma, sclerenchyma, water-conducting cells of the xylem, and sugar-conducting cells of the phloem
Sieve-tube element and companion cell.

37. Explain the phenomenon of apical dominance.
Distinguish between determinate and indeterminate growth.
Describe in detail the primary and secondary growth of the tissues of roots and shoots.
Describe the composition of wood and bark.

38. Distinguish between morphogenesis, differentiation, and growth.
Explain how a vegetative shoot tip changes into a floral meristem.