Plant Structure, Growth, and Development (2) (1).pptx

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Plant Structure, Growth,
and Development
 Plant Structure, Growth, and
Development
I. Plant Organization
II. Meristems
III. Primary Growth
IV. Secondary Growth
 Learning Objectives
1. Describe the purpose of root structures including root
hairs, lateral roots, tap roots and adventicious roots.
2. Describe the structure and types of stems
3. Explain the difference between apical and axillary
buds in relationship to apical dominance
4. Describe the dermal tissues of a plant
5. Describe leaf structures and types
6. Compare and contrast the structures of xylem and
phloem
7. Explain ground tissue and its cell types: Parenchyma,
collenchyma and sclerenchyma
Learning Objectives (Contd.)
8. Describe the role of apical meristems and leaf
primordia in the primary growth stems
9. Identify and organize the cell and tissue types of
stems of monocots and eudicots
10. Describe the role of the pericycle in the
development of lateral roots
11. Identify and label the root tissues in monocot and
eudicot roots
12. Compare and contrast the role of vascular and cork
cambium during secondary growth
13. Identify and label the parts of a cross sectioned
woody stem showing secondary growth.
 I. Plant Organization
A. Plants have organs
composed of different tissues,
which in turn are composed of
different cell types
1. A tissue is a group of cells
consisting of one or more
cell types that together
perform a specialized
function
2. An organ consists of several
types of tissues that
together carry out particular
functions
3. Three basic organs evolved:
roots, stems, and leaves
B. Roots
1. A root is an organ with
important functions:
– Anchoring the plant
– Absorbing minerals and
water
– Storing carbohydrates
2. In most plants, absorption
of water and minerals
occurs near the root hairs,
where vast numbers of tiny
root hairs increase the
surface area
3. Most eudicots and
gymnosperms have
a taproot system,
which consists of:
A taproot, the
main vertical root
Lateral roots, or
branch roots,
that arise from
the taproot
4. 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
C. Stems
1. 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
 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
Many plants have modified
stems (e.g., rhizomes,
bulbs, stolons, tubers)
D. Leaves
1. The leaf is the main
photosynthetic organ
of most vascular
plants
2. Leaves generally
consist of a flattened
blade and a stalk
called the petiole,
which joins the leaf
to a node of the stem
3. Monocots and eudicots
differ in the arrangement
of veins, the vascular
tissue of leaves
– Most monocots have
parallel veins
– Most eudicots have
branching veins
4. In classifying
angiosperms,
taxonomists may use leaf
morphology as a criterion
E. Tissue Types
1. Dermal Tissues
In nonwoody plants, 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 in
older regions of stems and
roots
Trichomes are outgrowths of
the shoot epidermis and can
help with insect defense
2. Vascular Tissues
The two vascular tissues
are xylem and phloem
The vascular tissue of a
stem or root is
collectively called the
stele
In angiosperms the stele
of the root is a solid
central vascular cylinder
The stele of stems and
leaves is divided into
vascular bundles, strands
of xylem and phloem
3. Ground Tissue
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
As a woody stem grows, the cells and function of the
epidermis are taken over by the

a) pericycle.
b) periderm.
c) ground tissue.
d) vascular cambium.

© 2014 Pearson Education, Inc.
A difference between a stem and a root in secondary
growth is that the root often lacks

a) vascular cambium.
b) phloem.
c) cork.
d) parenchyma rays.
e) pith.

© 2014 Pearson Education, Inc.
F. Cell Types
1. 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
2. Collenchyma Cells
Are grouped in strands
and help support young
parts of the plant shoot
They have thicker and
uneven cell walls
They lack secondary
walls
These cells provide
flexible support without
restraining growth
3. Sclerenchyma Cells
Are rigid because of thick
secondary walls strengthened
with lignin
They are dead at functional
maturity
There are two types:
– Sclereids are short and
irregular in shape and have
thick lignified secondary
walls
– Fibers are long and slender
and arranged in threads
4. Water Conducting
Xylem
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
Vessel elements align end
to end to form long
micropipes called vessels
5. Sugar Conducting 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
Which of the following adaptations allows for
transporting water in woody stems?

a) vessel elements
b) the pericycle
c) pneumatophores
d) sieve-tube elements
e) bundle sheath cells

© 2014 Pearson Education, Inc.
Sugars formed in the leaves through photosynthesis get
to the roots through the

a) pith.
b) epidermis.
c) heartwood.
d) phloem.
e) cortex.

© 2014 Pearson Education, Inc.
 II. Meristems
A. Plant 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
Meristems are
perpetually embryonic
tissue and allow for
indeterminate growth
B. Primary 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
C. Secondary Growth
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
D. Life Cycle Length
Flowering plants can be
categorized based on
the length of their life
cycle
– Annuals complete
their life cycle in a
year or less
– Biennials require two
growing seasons
– Perennials live for
many years
 III. Primary Growth
A. Root Growth
1. The root tip is covered by
a root cap, which
protects the apical
meristem as the root
pushes through soil
2. Growth occurs just
behind the root tip, in
three zones of cells:
– Zone of cell division
– Zone of elongation
– Zone of differentiation,
or maturation
3. The primary growth of
roots produces the
epidermis, ground
tissue, and vascular
tissue
4. In angiosperm roots,
the stele is a vascular
cylinder
5. In most eudicots, the
xylem is starlike in
appearance with
phloem between the
“arms”
6. In many
monocots, a core
of parenchyma
cells is surrounded
by rings of xylem
then phloem
7. The ground tissue,
mostly parenchyma cells,
fills the cortex, the region
between the vascular
cylinder and epidermis
8. The innermost layer of
the cortex is called the
endodermis
9. The endodermis
regulates passage of
substances from the soil
into the vascular cylinder
10. Lateral roots arise from within the
pericycle, the outermost cell layer in
the vascular cylinder
B. Shoot Growth
1. A shoot apical meristem
is a dome-shaped mass
of dividing cells at the
shoot tip
2. Leaves develop from
leaf primordia along
the sides of the apical
meristem
3. Axillary buds develop
from meristematic cells
left at the bases of leaf
primordia
C. Tissue Organization
of Stems
1. Lateral shoots
develop from
axillary buds on the
stem’s surface
2. In most eudicots,
the vascular tissue
consists of vascular
bundles arranged
in a ring
3. In most monocot
stems, the vascular
bundles are
scattered
throughout the
ground tissue,
rather than forming
a ring
D. Tissue Organization of
Leaves
1. The epidermis in leaves is
interrupted by stomata,
which allow CO2 and O2
exchange between the air
and the photosynthetic
cells in a leaf
2. Each stomatal pore is
flanked by two guard
cells, which regulate its
opening and closing
3. The ground tissue in a
leaf, called mesophyll, is
sandwiched between the
upper and lower
epidermis
4. The mesophyll of
eudicots has two
layers:
The palisade
mesophyll in the
upper part of the leaf
The spongy
mesophyll in the
lower part of the leaf;
the loose
arrangement allows
for gas exchange
5. The vascular tissue of
each leaf is continuous
with the vascular tissue
of the stem
6. Veins are the leaf’s
vascular bundles and
function as the leaf’s
skeleton
7. Each vein in a leaf is
enclosed by a protective
bundle sheath
 IV. Secondary Growth
A. Secondary growth occurs
in stems and roots of
woody plants but rarely in
leaves
1. The secondary plant body
consists of the tissues
produced by the vascular
cambium and cork
cambium
2. Secondary growth is
characteristic of
gymnosperms and many
eudicots, but not
monocots
B. Vascular Cambium
1. The vascular cambium is a cylinder of meristematic cells
one cell layer thick
2. It develops from undifferentiated parenchyma cells
3. In cross section, the vascular cambium appears as a ring
of initials (stem cells)
4. The initials increase the vascular cambium’s
circumference and add secondary xylem to the inside and
secondary phloem to the outside
5. Secondary xylem accumulates as wood and consists of
tracheids, vessel elements (only in angiosperms), and fibers
6. Early wood, formed in the spring, has thin cell walls to
maximize water delivery
7. Late wood, formed in late summer, has thick-walled cells
and contributes more to stem support
8. In temperate regions, the vascular cambium of perennials is
inactive through the winter
9. As a tree or woody
shrub ages, the older
layers of secondary
xylem, the heartwood,
no longer transport
water and minerals
10. The outer layers,
known as sapwood,
still transport materials
through the xylem
11. Older secondary
phloem sloughs off and
does not accumulate
C. Cork Cambium
1. Cork cambium gives rise to two tissues:
Phelloderm is a thin layer of parenchyma cells that forms to the
interior of the cork cambium
Cork cells accumulate to the exterior of the cork cambium
2. Cork cells deposit waxy suberin in their walls, then die
3. Periderm consists of the cork cambium, phelloderm,
and cork cells it produces
4. Lenticels in the
periderm allow for
gas exchange
between living
stem or root cells
and the outside air
5. Bark consists of
all the tissues
external to the
vascular cambium,
including
secondary phloem