Transcript 05 - Plant Structure, Growth Development (Ch.35)

Lecture 5 Outline (Ch. 35)
I. Overview – Plant Systems
II. Plant cell types & tissues
Cell Types: Parenchyma, Collenchyma, Sclerenchyma
A. Dermal
B. Vascular
C. Ground
III. Plant organs
A. Roots
B. Stems
C. Leaves
IV. Plant Growth
A. Meristems
B. Primary vs. secondary
V. Preparation for next lecture
Plant Structure, Growth, Development
Plants are notably different from animals:
1. SA:V ratio
2. Mobility
3. Growth
4. Response to environment
5. Cell structure
Setting the scene - animal bodies
Cells  Tissues  Organs  Systems
Plant “bodies”
Plants, like multicellular
animals, have organs
composed of different
tissues, which in turn
are composed of cells
Shoot
system
Leaf
Stem
Three Basic Plant Organs:
Roots, Stems, and Leaves
(also flowers, branches)
Root
system
Plant Tissues
• Each plant organ has
dermal, vascular, and
ground tissues
• Each of these three
categories forms a
system
– Roots
– Shoots
– Vascular
Dermal
tissue
Ground
tissue Vascular
tissue
Plant Tissues
1) Dermal Tissues
• Outer covering
• Protection
2) Vascular Tissues
• “Vessels” throughout plant
• Transport materials
3) Ground Tissues
• “Body” of plant
• Photosynthesis; storage; support
Three basic cell types:
Parenchyma
Collenchyma
Sclerenchyma
What type of tissue transports fluids in plants?
A.
B.
C.
D.
E.
Dermal
Roots
Vascular
Stems
Ground
Plant Cell Types
Plant cell structure recap
Cell wall, plasmodesmata
Primary wall (some have
secondary wall), middle lamella
Plant Cell Types
1) Parenchyma (most abundant):
Flexible, thin-walled cells; living
• plant metabolism:
Photosynthesis;
hormone secretion;
sugar storage
Parenchyma cells in
Elodea leaf,(w/chloroplasts)
• thin wall permeable to gasses
• large central vacuole
• able to divide and differentiate
Plant Cell Types
2) Collenchyma:
Thick-walled (uneven); living
• Offers support
(flexible & strong)
• Able to elongate
• Grouped in
strands, lack
secondary wall
Collenchyma cells sunflower
Plant Cell Types
3) Sclerenchyma: Thick, hard-walled; Dead
• Offer support (e.g. hemp
Sclereid cells
in pear (LM)
Cell wall
Fiber cells in ash tree
fibers; nut shells)
• Thick secondary walls
with lignin
• Rigid (cannot elongate)
• Two types –
sclereids and fibers
Which is a plant cell type?
A.
B.
C.
D.
E.
secondary
vascular
ground
collenchyma
leaves
Plant Tissues - Dermis
Dermal Tissue System (Covering of Plant):
1) Epidermal Tissue
(epidermis): Outer layer
Cuticle: Waxy covering reduces evaporation/ predation
Root Hairs: extended root
surface - Increase absorption
2) Peridermal Tissue (periderm):
• Only in woody plants (“bark = dead cells”)
• Protection; support
Plant Tissues - Dermis
Special Dermal Cells – Trichomes & Root hairs
• Trichomes
– Hairlike outgrowths of
epidermis
– Keep leaf surfaces cool
and reduce evaporation
• Roots hairs
– Tube extensions from
epidermal cells
– Greatly increase the root’s
surface area for absorption
Plant Tissues - Dermis
Special Dermal Cells – Guard Cells
Stomata
Guard cells
Epidermal cell
a.
4 µm
Stoma
Epidermal cell
Guard cells
b.
71 µm
c.
200 µm
Paired sausage-shaped cells
Flank a stoma – epidermal
opening
• Passageway for
oxygen, carbon dioxide,
and water vapor
Plant Tissues - Vascular
Vascular tissues made up of multiple cell types:
Arranged in multiple bundles
or central cylinder
Xylem – water and nutrients
Phloem – dissolved sugars and metabolites
Plant Tissues - Vascular
1) Xylem (dead at maturity): water and minerals roots to shoots
A)
B)
C)
Tracheids: Narrow, tube-like cells
Vessel Elements: Wide, tube-like cells
Fibers
Plant Tissues - Vascular
1) Xylem:
Tracheids:
- Most vascular plants
- Long, thin, tapered ends, lignified
secondary walls
- Water moves cell to cell through pits
Vessel elements:
- Wider and shorter
- Perforation plates ends of vessel
elements
- water flows freely though perforation
plates
Plant Tissues - Vascular
2) Phloem (living at maturity) cells:
A) Sieve Tubes: Wide, tube-like cells
B) Companion Cells: support and regulate sieve tubes
Plant Tissues - Vascular
2) Phloem (living at maturity)
- Moves water, sugar, amino acids
& hormones
Sieve tube elements/members
• Living parenchyma
• Long narrow cells stack end to end
• Pores in end walls (sieve plates)
• Lack most cellular structures including:
• Distinct vacuole, Some cytoskeletal
elements, Nucleus, Ribosomes
Companion Cells:
• Adjacent to every sieve tube
element
• Non-conducting.
• Regulate both cells
• Connected by numerous
plasmodesmata
Vasculature - Comparisons
Monocots and dicots differ in the arrangement of
vessels in the roots and stems
Dicots
Monocots
Stem
Root
Plant Tissues – Ground Tissue
• Tissues that are neither
dermal nor vascular are
ground tissue
• 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
Roots - Overview
• Roots need sugars from photosynthesis;
• Shoots rely on water and
minerals absorbed by the
root system
• Root Roles:
- Anchoring the plant
- Absorbing minerals and water
- Storing organic nutrients
Roots - Comparisons
Taproots:
Typical of dicots,
primary root forms
and small branch
roots grow from it
Fibrous roots:
In monocots mostly,
primary root dies,
replaced by new
roots from stem
Roots – Structure and Development
• Four regions:
– Root cap
Protection, gravity detection
– Zone of cell division
Mitotic divisions
– Zone of elongation
Cells lengthen, no division
– Zone of maturation
Cells differentiate, outer layer
becomes dermis
Roots – Structure and Development
In maturation zone, Casparian strip forms –
waterproof barrier material surrounding vasculature
Roots – Structure and Development
Epidermis
Cortex
Monocot
Endodermis
Location of
Casparian strip
Primary phloem
Pericycle
Primary xylem
Pith
1250 µm
385 µm
Endodermis
Location of
Casparian strip
Endodermis
Eudicot
Primary xylem
Cortex
Primary phloem
Epidermis
Pericycle
48 µm
8 µm
Prop roots
Roots – Many Plants Have
Modified Roots
“Strangling”
aerial roots
Storage roots
Buttress
roots
Pneumatophores
Water storage
Stems - Overview
Stem: an organ made of
– An alternating system
of nodes, points at
which leaves attach
– Internodes, stem length
between nodes
• Axillary bud - structure
that can form a lateral
shoot, or branch
• Apical/terminal bud located near the shoot
tip, lengthens a shoot
• Apical dominance
maintains dormancy in
most nonapical buds
Apical bud
Node
Internode
Apical
bud
Vegetative
shoot
Axillary
bud
Stem
Shoot
system
Vasculature - Stems
• In most monocot stems, the vascular bundles are scattered
throughout the ground tissue, rather than forming a ring
Phloem
Xylem
Sclerenchyma
(fiber cells)
Ground
tissue
Ground tissue
connecting
pith to cortex
Pith
Epidermis
Key
to labels
Cortex
Epidermis
Vascular
bundle
Dermal
Vascular
bundles
Ground
1 mm
(a) Cross section of stem with vascular bundles forming
a ring (typical of eudicots)
Dicot
Vascular
1 mm
(b) Cross section of stem with scattered vascular bundles
(typical of monocots)
Monocot
Stems – Structure and Development
• Stems have all three types of
plant tissue
• Grow by division at meristems
– Develop into leaves, other
shoots, and even flowers
• Leaves may be arranged in
one of three ways
Stems – Many Plants
Have Modified Stems
Rhizomes
Bulbs
Storage leaves
Stem
Stolons
Stolon
Tubers
Leaves - Overview
The leaf is the main photosynthetic
organ of most vascular plants
Shoot
system
Leaves generally have
Leaf
Blade
Petiole
a flattened blade
and a stalk called the
petiole, which joins the leaf
to a node of the stem
Leaves – Structure and Development
• Leaves are
several layers
thick – each
with different
cell types
Leaves – Structure and Development
• Most dicots have 2
types of mesophyll
– Palisade mesophyll
high photosynthesis
– Spongy mesophyll
air spaces for gas
& water exchange
• Monocot leaves have
1 type of mesophyll
Leaves
• Leaf epidermis contains stomata - allow CO2 exchange
• Stomata flanked by two guard cells, control open vs. closed
Guard
cells
Key
to labels
Dermal
Ground
Cuticle
Vascular
50 µm
Stomatal
pore
Epidermal
cell
Sclerenchyma
fibers
Stoma
(b) Surface view of a spiderwort
(Tradescantia) leaf (LM)
Upper
epidermis
Palisade
mesophyll
100 µm
Spongy
mesophyll
Bundlesheath
cell
Lower
epidermis
Cuticle
Xylem
Vein
Phloem
(a) Cutaway drawing of leaf tissues
Guard
cells
Vein
Air spaces Guard cells
(c) Cross section of a lilac
(Syringa)) leaf (LM)
Leaves - Comparisons
Monocots and dicots differ in the arrangement of veins,
the vascular tissue of leaves
Most dicots have
branch-like veins and
palmate leaf shape
Monocots have parallel
leaf veins and longer,
slender blades
Leaves – Plants have
modified leaves for
various functions
Tendrils
Spines
Storage
leaves
Reproductive leaves
Bracts
Plant Classification – Monocots vs. Dicots
Basic categories of plants based on structure and function
Plant Growth
Plant Growth:
1) Indeterminate: Grow throughout life
2) Growth at “tips” (length) and at
“hips” (girth)
Growth patterns in plant:
1) Meristem Cells: Dividing Cells
2) Differentiated Cells: Cells specialized in structure & role
• Form stable, permanent part of plant
Plant Growth
1) Primary Growth:
• Apical Meristems:
Mitotic cells at “tips” of roots / stems
length
1) Increased length
2) Specialized structures (e.g. fruits)
2) Secondary Growth:
girth
• Lateral Meristems:
Mitotic cells “hips” of plant
Responsible for increases in stem/root diameter
Plant Growth
Shoot apical meristem
Leaf primordia
Young
leaf
Developing
vascular
strand
Axillary bud
meristems
Plant Growth
Two lateral meristems: vascular cambium and cork cambium
Primary growth in stems
Epidermis
Cortex
Shoot tip (shoot
apical meristem
and young leaves)
Primary phloem
Primary xylem
Pith
Lateral meristems:
Vascular cambium
Cork cambium
Secondary growth in stems
Periderm
Axillary bud
meristem
Cork
cambium
Cortex
Root apical
meristems
Pith
Primary
xylem
Secondary
xylem
Vascular cambium
Primary
phloem
Secondary
phloem
Plant Growth
Stem – Secondary Growth:
• thicker, stronger stems
Vascular Cambium: between
primary xylem and phloem
primary phloem
vascular cambium
primary xylem
epidermis
Produces inside stem:
A) Secondary xylem
- moves H2O, inward
B) Secondary phloem
- moves sugars, outward
pith
cortex
primary xylem
dividing
vascular
cambium
primary phloem
Vascular Cambium:
Plant Growth
Secondary growth
secondary phloem
primary phloem
primary xylem
secondary xylem
primary
xylem
new
secondary
xylem
new
secondary
phloem
vascular cambium
dividing
vascular
cambium
primary
phloem
pith
cortex
Vascular cambium
Growth
X X C P P
X X C P
Vascular
cambium
Secondary
xylem
Secondary
phloem
X C P
C
X C
C
C
After one year
of growth
After two years
of growth
A cross section of what tissue is pictured?
A.
B.
C.
D.
Monocot root
Dicot root
Monocot stem
Dicot stem
Things To Do After Lecture 5…
Reading and Preparation:
1.
Re-read today’s lecture, highlight all vocabulary you do not
understand, and look up terms.
2.
Ch. 35 Self-Quiz: #1, 3, 6, 7 (correct answers in back of book)
3.
Read chapter 35, focus on material covered in lecture (terms,
concepts, and figures!)
4.
Skim next lecture.
“HOMEWORK” (NOT COLLECTED – but things to think about for studying):
1.
Compare and contrast monocots and dicots.
2.
List the different types of plant cells and describe which tissues and
organs they make up, including roles for each organ.
3.
Explain the different between apical and lateral meristems and how
growth occurs.
4.
Discuss the composition of bark and it’s function for plants (do all plants
have this tissue?)