1. Figure 35.10 Review of General Plant Cell Structure

2. Shoot and Root Systems Shoot system produces sugars by photosynthesis
carries out reproduction
Shoot System
Root system
anchors the plant
penetrates the soil and absorbs water and minerals
stores food
Root System

3. Shoot and root systems are interdependent
water & minerals
sugar
SHOOT SYSTEM
ROOT SYSTEM

4. Plant Tissue Systems Ground tissue system Vascular tissue system
EPIDERMIS
Ground tissue system
Vascular tissue system
Dermal tissue system
VASCULAR TISSUES
GROUND TISSUES
SHOOT SYSTEM
ROOT SYSTEM

5. Meristems – Where Cells For New Organs Originate
Regions where cell divisions produce plant growth
Apical meristems
Lengthen stems and roots
Responsible for primary growth
Lateral meristems
Increase width of stems
Responsible for secondary growth

6. Apical Meristems Lengthen shoots and roots protoderm  epidermis
activity at
meristems
Cells that form at apical meristems:
new cells
elongate
and start to
differentiate
into primary
tissues
protoderm  epidermis
ground meristem  ground tissues
procambium  primary vascular tissues

7. Lateral Meristems Increases girth of older roots and stems
Cylindrical arrays of cells
vascular cambium  secondary vascular tissues
periderm  cork cambium
thickening

8. Figure 35.7 The three tissue systems
in Plants

9. Made up of only one type of cell
Simple Tissues
Made up of only one type of cell
Parenchyma
Collenchyma
Sclerenchyma

10. Morphology of Three Simple Tissue Types
parenchyma
collenchyma
sclerenchyma

11. Figure 35.11 The three major categories of plant cells

12. Parenchyma: A Simple Tissue
Comprises most of a plant’s soft primary growth
Cells are pliable, thin walled, many sided
Cells remain alive at maturity
and retain capacity to divide
Mesophyll is a type of
parenchyma that contains
chloroplasts

13. Collenchyma: A Simple Tissue
Specialized for support for primary tissues
Cells are elongated, with walls (especially corners)
thickened with pectin
Makes stems strong
but pliable
Cells are alive at maturity

14. Sclerenchyma: A Simple Tissue
Supports mature plant parts
Protects many seeds
Cells have thick, lignified walls and are dead at maturity
Two types:
Fibers: Long, tapered
cells
Sclereids: Stubbier cells

15. Composed of a mix of cell types
Complex Tissues
Composed of a mix of cell types
Xylem
Phloem
Epidermis

16. Xylem Conducts water and dissolved minerals
Conducting cells are dead and hollow at maturity
vessel member
tracheids

17. Figure 35.8 Water-conducting cells of xylem

18. Phloem: A Complex Vascular Tissue
sieve plate
Transports sugars
Main conducting cells are sieve-tube members
Companion cells assist in the loading of sugars
sieve-tube
member
companion
cell

19. Figure 35.9 Food-conducting cells of the phloem

20. Figure 36.17 Pressure flow in a sieve tube

21. Epidermis: A Complex Plant Tissue
- Covers and protects plant surfaces
- Secretes a waxy, waterproof cuticle
In plants with
secondary growth, periderm replaces epidermis

22. Monocots and Dicots – same tissues, different features
1 cotyledon
2 cotyledons
4 or 5 floral parts
3 floral parts
Netlike veins
Parallel veins
3 pores
1 pore
Vascular bundles dispersed
Vascular bundles in ring

23. organs consisting of an alternating
Stems –
organs consisting of an alternating
system of nodes, the points at which
leaves are attached, and internodes,
the stem segments between nodes.
the main functions of the stems include
conducting sugars and water and holding
leaves up into the sunlight

24. Monocot and Dicot Stems (Two Divisions of Angiosperms)
Monocot Stem

25. Bud = undeveloped shoot of meristematic tissue
Leaves
Internode
spaces between
leaf attachments
Axillary bud at node
(can form lateral
shoots)
Longitudinal section of terminal bud

26. Shoot Development shoot apical meristem procambrium ground meristem
protoderm
cortex
procambrium
pith
primary xylem
primary phloem

27. Internal Structure of a Dicot Stem
- Outermost layer is epidermis
- Cortex lies beneath epidermis
- Ring of vascular bundles separates the cortex from the pith
- The pith lies in the center of the stem

28. Internal Structure of a Monocot Stem
The vascular bundles are scattered throughout the ground tissue
No division of ground tissue into cortex and pith
Internal Structure of a Monocot Stem

29. Secondary Growth Occurs in perennials
A ring of vascular cambium produces secondary xylem and phloem
Wood is the accumulation of these secondary tissues, especially xylem

30. Woody Stem periderm (consists of secondary phloem cork, cork cambium,
and secondary cortex)
secondary
phloem
SAPWOOD
HEARTWOOD
BARK
vascular cambium

31. Figure 35.23 Anatomy of a tree trunk

32. Annual Rings Concentric rings of secondary xylem
Alternating bands of early and late wood
Early wood
Xylem cells with large diameter, thin walls
Late wood
Xylem cells with smaller diameter, thicker walls

35. Types of Wood Hardwood (oak, hickory) Dicot wood
Xylem composed of vessels, tracheids, and fibers
Softwood (pine, redwood)
Gymnosperm wood
Xylem composed mostly of tracheids
Grows more quickly

36. Adapted for Photosynthesis
Leaves are usually thin
High surface area-to-volume ratio
Promotes diffusion of carbon dioxide in, oxygen out
Leaves are arranged to capture sunlight
Are held perpendicular to rays of sun
Arrange so they don’t shade one another

37. Leaf Structure Stoma with guard cells cuticle xylem phloem UPPER
EPIDERMIS
cuticle
PALISADE
MESOPHYLL
xylem
SPONGY
MESOPHYLL
phloem
LOWER
EPIDERMIS
Stoma with
guard cells
CO2
one stoma O2

38. Figure Leaf anatomy

39. Mesophyll: Photosynthetic Tissue
A type of parenchyma tissue
Cells have chloroplasts
Two layers in dicots
Palisade mesophyll
Spongy mesophyll

40. Collenchyma
Parenchyma

41. Leaf Veins: Vascular Bundles
Xylem and phloem – often strengthened with fibers
In dicots, veins are netlike
In monocots, they are parallel

42. Root Structure Root cap covers tip Apical meristem produces the cap
Cell divisions at the apical meristem cause the root to lengthen
Farther up, cells differentiate and mature
root apical meristem
root cap

43. Fibrous
Tap
Root Systems
Lateral Roots
grow from the
Tap Root

44. Primary Growth of a Root

45. epidermis
endodermis
cortex
pericycle
root hair
phloem
xylem

46. Cross Section of a Root cortex epidermis endodermis pericycle xylem
phloem
Cross Section of a Root

47. Internal Structure of a Root
Outermost layer is epidermis
Root cortex is beneath the epidermis
Endodermis, then pericycle surround the vascular cylinder
In some plants, there is a central pith

48. Root Hairs and Lateral Roots
Both increase the surface area of a root system
Root hairs are tiny extensions of epidermal cells
Lateral roots arise from the pericycle and must push through the cortex and epidermis to reach the soil
new
lateral
root

49. Figure 35.16 The formation of lateral roots

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

51. Transport Proteins in the plasma membrane regulate traffic between the
Figure Compartments of plant cells and tissues and routes for lateral transport
Transport Proteins
in the plasma
membrane regulate
traffic between the
cytosol and the cell
wall
The symplast is the
continuum of cytosol
connected by
plasmodesmata.
The apoplast is the continuum
of cell walls and extracellular
spaces.

52. Figure 35.15 Organization of primary tissues in young roots

53. Prop
Roots

54. Pandanus Tree With
Prop Roots

55. Prop
Roots

56. Buttress Roots

58. Banyan
Tree With
Aerial
Roots