Shoot system
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Shoot System
-Stem-
Prepared by:
Group III
BS Bio 1-C
-Stem-
Prepared by:
Group III
BS Bio 1-C
Stems
The main body of the
portion above the
ground of the tree,
shrub, herb, or other
plant; the ascending
axis, whether above or
below the ground of a
plant, in contradiction
to the descending axis
or root.
The main body of the
portion above the
ground of the tree,
shrub, herb, or other
plant; the ascending
axis, whether above or
below the ground of a
plant, in contradiction
to the descending axis
or root.
MAJOR FUNCTIONS
OF STEMS
-Stems support
-Stems Conduct
-Stem produce new ling tissue
OF STEMS
-Stems support
-Stems Conduct
-Stem produce new ling tissue
STEMS SUPPORT
Provides mechanical support and raise leaves into the
air, thus facilitating photosynthesis. Flowers and fruits
are also produced in position, for facilitating
pollination and seed dispersal.
STEMS CONDUCT
oProvides a pathway for movement of water and mineral
nutrients from roots to leaves and for transfer of foods ,
hormones and to other metabolites from one part to
another.
STEMS PRODUCE NEW LIVING TISSUE
oProvide new living tissue for normal metabolism of
plant.
Provides mechanical support and raise leaves into the
air, thus facilitating photosynthesis. Flowers and fruits
are also produced in position, for facilitating
pollination and seed dispersal.
STEMS CONDUCT
oProvides a pathway for movement of water and mineral
nutrients from roots to leaves and for transfer of foods ,
hormones and to other metabolites from one part to
another.
STEMS PRODUCE NEW LIVING TISSUE
oProvide new living tissue for normal metabolism of
plant.
EXTERNAL
PLANT
MORPHOLOGY
PLANT
MORPHOLOGY
A stemis an organ consisting of
An alternating system of nodes, the points at
which leaves are attached
Internodes, the stem segments between
nodes
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 non-apical buds
Lenticels are structure that permit the passage of
gas inward and outward.
Leaf scar are characteristic scar on stem axis
made by leaf abscission.
Bud scales are small modified leaves for
protection from desiccation.
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 non-apical buds
Lenticels are structure that permit the passage of
gas inward and outward.
Leaf scar are characteristic scar on stem axis
made by leaf abscission.
Bud scales are small modified leaves for
protection from desiccation.
Dormant shoot apex with its protective scales is a BUD.
Bud Scars are the scars left from the removal of bud.
Leaf primordium isan immature leaf of the
shoot.
Intercalary meristem the portion of the internodes
above the node . Made up of actively dividing cells
responsible for the elongation of the monocot stem.
Bud Scars are the scars left from the removal of bud.
Leaf primordium isan immature leaf of the
shoot.
Intercalary meristem the portion of the internodes
above the node . Made up of actively dividing cells
responsible for the elongation of the monocot stem.
Fig. 35-12
Apical bud
This year’s growth
(one year old)
Bud scale
Axillary buds
Leaf
scar
Bud
scar
Node
Internode
One-year-old side
branch formed
from axillary bud
near shoot tip
Last year’s growth
(two years old)
Leaf scar
Stem
Bud scar left by apical
bud scales of previous
winters
Leaf scar
Growth of two
years ago
(three years old)
Apical bud
This year’s growth
(one year old)
Bud scale
Axillary buds
Leaf
scar
Bud
scar
Node
Internode
One-year-old side
branch formed
from axillary bud
near shoot tip
Last year’s growth
(two years old)
Leaf scar
Stem
Bud scar left by apical
bud scales of previous
winters
Leaf scar
Growth of two
years ago
(three years old)
Shoot Apex
Organization
Organization
The outer group
consisting of one or
more peripheral cell
layer is known as the
TUNICA. These cells
divide anticlinally
(perpendicular to the
surface of the shoot
apex)
The CORPUS lies
below the tunica and
initially has a single
layer of cells. Corpus
cells divide anticlinally
and periclinally
(parallel to the surface
of the shoot apex.)
Shoot Apex
organization
consisting of one or
more peripheral cell
layer is known as the
TUNICA. These cells
divide anticlinally
(perpendicular to the
surface of the shoot
apex)
The CORPUS lies
below the tunica and
initially has a single
layer of cells. Corpus
cells divide anticlinally
and periclinally
(parallel to the surface
of the shoot apex.)
Shoot Apex
organization
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
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
Fig. 35-16
Shoot apical meristem Leaf primordia
Young
leaf
Developing
vascular
strand
Axillary bud
meristems
0.25 mm
Shoot apical meristem Leaf primordia
Young
leaf
Developing
vascular
strand
Axillary bud
meristems
0.25 mm
Primary Meristems
Protoderm-the outermost layer of cells.
It develops into epidermis---the special
primary tissue that covers and protects all
underlying primary tissues. The epidermis
prevents excessive water loss and yet
allows for exchange of gases necessary for
respiration and photosynthesis.
Protoderm-the outermost layer of cells.
It develops into epidermis---the special
primary tissue that covers and protects all
underlying primary tissues. The epidermis
prevents excessive water loss and yet
allows for exchange of gases necessary for
respiration and photosynthesis.
Primary Meristems
Ground meristem-Comprises the
greater portion of meristematictissue of
the shoot tip. Primary tissues forming
from the ground meristemare:
a)Pith-in the very center of stem
b)Cortex-in a cylinder just beneath the
epidermis and surrounding the vascular
tissues. Sometimes pith and cortex are
connected by pith rays.
Ground meristem-Comprises the
greater portion of meristematictissue of
the shoot tip. Primary tissues forming
from the ground meristemare:
a)Pith-in the very center of stem
b)Cortex-in a cylinder just beneath the
epidermis and surrounding the vascular
tissues. Sometimes pith and cortex are
connected by pith rays.
Primary Meritsems
Procambiumcells give rise to
primary vascular tissues
namely;
a)Primary phloem
b)Primary xylem
Procambiumcells give rise to
primary vascular tissues
namely;
a)Primary phloem
b)Primary xylem
STEM ANATOMY,
PRIMARY
STRUCTURE
PRIMARY
STRUCTURE
•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
•Apical meristems elongate shoots and roots, a
process called primary growth
allow for indeterminate 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
Stems undergo primary growth
which results in the formation of
primary tissues. These include the
Epidermis
Ground tissue
primary vascular tissues
(primary xylem and primary
phloem)
which results in the formation of
primary tissues. These include the
Epidermis
Ground tissue
primary vascular tissues
(primary xylem and primary
phloem)
The young dicot stem
Summary of Primary Development
Protoderm Epidermis
Ground meristemCortex
Apical Meristem Pith and pith
rays
ProcambiumPhloem
Vascular Cambium
Xylem
Protoderm Epidermis
Ground meristemCortex
Apical Meristem Pith and pith
rays
ProcambiumPhloem
Vascular Cambium
Xylem
Primary Growth development
The term steleis applied to the part of the stemthat includes
primary vascular tissues, pith, and pith rays. The primary plant
body is composed of the above primary tissues.
The main functions of these primary tissues may be
summarized as shown below.
Epidermis: Protects underlying tissues.
Vascular tissues
Phloem: Conducts Food
Vascular Cambium: produces secondary phloem and secondary
xylem
The term steleis applied to the part of the stemthat includes
primary vascular tissues, pith, and pith rays. The primary plant
body is composed of the above primary tissues.
The main functions of these primary tissues may be
summarized as shown below.
Epidermis: Protects underlying tissues.
Vascular tissues
Phloem: Conducts Food
Vascular Cambium: produces secondary phloem and secondary
xylem
Xylem: conducts water and mineral salts , and gives
strength to stem.
Cortex: Stores food and in young stems, manufactures
food, strengthens and protects.
Pith: Stores food
Pith rays: Store food, and conduct water, mineral salts,
and food radically.
strength to stem.
Cortex: Stores food and in young stems, manufactures
food, strengthens and protects.
Pith: Stores food
Pith rays: Store food, and conduct water, mineral salts,
and food radically.
The young dicot stem
The stellar type exhibited by a dicot
stem is a EUSTELE.
The type of xylem maturation is
known as Endarch.
Secondary growth is present.
The stellar type exhibited by a dicot
stem is a EUSTELE.
The type of xylem maturation is
known as Endarch.
Secondary growth is present.
THE MONOCOT
STEM
STEM
Fig. 35-17b
Ground
tissue
Epidermis
Key
to labels
Cross section of stem with scattered vascular bundles
(typical of monocots)
Dermal
Ground
Vascular
(b)
Vascular
bundles
1 mm
Ground
tissue
Epidermis
Key
to labels
Cross section of stem with scattered vascular bundles
(typical of monocots)
Dermal
Ground
Vascular
(b)
Vascular
bundles
1 mm
The monocot stem
The vascular bundles are scattered
throughout the ground tissue. The type of
stele exhibit is ATACTOSTELE.
In most monocot stems, the vascular
bundles are scattered throughout the
ground tissue, rather than forming a ring.
They do not have secondary growth.
The vascular bundles are scattered
throughout the ground tissue. The type of
stele exhibit is ATACTOSTELE.
In most monocot stems, the vascular
bundles are scattered throughout the
ground tissue, rather than forming a ring.
They do not have secondary growth.
Fig. 35-17
Phloem Xylem
Sclerenchyma
(fiber cells)
Ground tissue
connecting
pith to cortex
Pith
Cortex
1 mm
Epidermis
Vascular
bundle
Cross section of stem with vascular bundles forming
a ring (typical of eudicots)
(a)
Key
to labels
Dermal
Ground
Vascular
Cross section of stem with scattered vascular bundles
(typical of monocots)
(b)
1 mm
Epidermis
Vascular
bundles
Ground
tissue
Phloem Xylem
Sclerenchyma
(fiber cells)
Ground tissue
connecting
pith to cortex
Pith
Cortex
1 mm
Epidermis
Vascular
bundle
Cross section of stem with vascular bundles forming
a ring (typical of eudicots)
(a)
Key
to labels
Dermal
Ground
Vascular
Cross section of stem with scattered vascular bundles
(typical of monocots)
(b)
1 mm
Epidermis
Vascular
bundles
Ground
tissue
Eustele vs. Atactostle
STEM
ANATOMY, SECONDA
RY STRUCTURE
ANATOMY, SECONDA
RY STRUCTURE
•Secondary growth occurs in stems and
roots of woody plants but rarely in leaves
•The secondary plant body consists of the
tissues produced by the vascular cambium
and cork cambium
•Secondary growth is characteristic of
gymnosperms and many eudicots, but not
monocots
roots of woody plants but rarely in leaves
•The secondary plant body consists of the
tissues produced by the vascular cambium
and cork cambium
•Secondary growth is characteristic of
gymnosperms and many eudicots, but not
monocots
Woody dicot (Tillia sp.)
Stem anatomy, secondary structure
These tissue layers form the Periderm.
The outermost layer is the phellem,
consisting of cork cells.
Immediately inner to it is thephellogen, or
the cork cambium, consisting of flattened
dividing cells.
The third layer is the pheloderm, few cell
layers in thickness.
These tissue layers form the Periderm.
The outermost layer is the phellem,
consisting of cork cells.
Immediately inner to it is thephellogen, or
the cork cambium, consisting of flattened
dividing cells.
The third layer is the pheloderm, few cell
layers in thickness.
Fig. 35-19a1
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Fig. 35-19a2
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Vascular ray
Secondary xylem
Secondary phloem
First cork cambium
Cork
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Vascular ray
Secondary xylem
Secondary phloem
First cork cambium
Cork
Fig. 35-19a3
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Vascular ray
Secondary xylem
Secondary phloem
First cork cambium
Cork
Cork
Bark
Most recent cork
cambium
Layers of
periderm
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Primary and secondary growth
in a two-year-old stem
(a)
Periderm (mainly
cork cambia
and cork)
Secondary phloem
Secondary
xylem
Epidermis
Cortex
Primary phloem
Vascular cambium
Primary xylem
Pith
Vascular ray
Secondary xylem
Secondary phloem
First cork cambium
Cork
Cork
Bark
Most recent cork
cambium
Layers of
periderm
Fig. 35-19b
Secondary phloem
Vascular cambium
Secondary xylem
Bark
Early wood
Late wood
Cork
cambium
Cork
Periderm
0
.
5
mm
Vascular rayGrowth ring
Cross section of a three-year-
old Tilia(linden) stem (LM)
(b)
0.5 mm
Secondary phloem
Vascular cambium
Secondary xylem
Bark
Early wood
Late wood
Cork
cambium
Cork
Periderm
0
.
5
mm
Vascular rayGrowth ring
Cross section of a three-year-
old Tilia(linden) stem (LM)
(b)
0.5 mm
The Vascular Cambium and Secondary
Vascular Tissue
The vascular cambium is a cylinder of meristematic
cells one cell layer thick
It develops from undifferentiated parenchyma cells
Vascular Tissue
The vascular cambium is a cylinder of meristematic
cells one cell layer thick
It develops from undifferentiated parenchyma cells
In cross section, the vascular cambium appears
as a ring of initials
The initials increase the vascular cambium’s
circumference and add secondary xylem to the
inside and secondary phloem to the outside
as a ring of initials
The initials increase the vascular cambium’s
circumference and add secondary xylem to the
inside and secondary phloem to the outside
Secondary xylem accumulates as wood, and
consists of tracheids, vessel elements (only in
angiosperms), and fibers
Early wood, formed in the spring, has thin cell walls
to maximize water delivery
Late wood, formed in late summer, has thick-walled
cells and contributes more to stem support
In temperate regions, the vascular cambium of
perennials is dormant through the winter
consists of tracheids, vessel elements (only in
angiosperms), and fibers
Early wood, formed in the spring, has thin cell walls
to maximize water delivery
Late wood, formed in late summer, has thick-walled
cells and contributes more to stem support
In temperate regions, the vascular cambium of
perennials is dormant through the winter
Tree rings are visible where late and early
wood meet, and can be used to estimate a
tree’s age
Dendrochronologyis the analysis of tree ring
growth patterns, and can be used to study
past climate change
wood meet, and can be used to estimate a
tree’s age
Dendrochronologyis the analysis of tree ring
growth patterns, and can be used to study
past climate change
As a tree or woody shrub ages, the older
layers of secondary xylem, the heartwood,
no longer transport water and minerals
The outer layers, known as sapwood, still
transport materials through the xylem
Older secondary phloem sloughs off and
does not accumulate
layers of secondary xylem, the heartwood,
no longer transport water and minerals
The outer layers, known as sapwood, still
transport materials through the xylem
Older secondary phloem sloughs off and
does not accumulate
Fig. 35-22
Growth
ring
Vascular
ray
Secondary
xylem
Heartwood
Sapwood
Bark
Vascular cambium
Secondary phloem
Layers of periderm
Growth
ring
Vascular
ray
Secondary
xylem
Heartwood
Sapwood
Bark
Vascular cambium
Secondary phloem
Layers of periderm
The Cork Cambium and the
Production of Periderm
The cork cambium gives rise to the secondary
plant body’s protective covering, or periderm
Periderm consists of the cork cambium plus the
layers of cork cells it produces
Barkconsists of all the tissues external to the
vascular cambium, including secondary phloem
and periderm
Lenticelsin the periderm allow for gas
exchange between living stem or root cells and
the outside air
Production of Periderm
The cork cambium gives rise to the secondary
plant body’s protective covering, or periderm
Periderm consists of the cork cambium plus the
layers of cork cells it produces
Barkconsists of all the tissues external to the
vascular cambium, including secondary phloem
and periderm
Lenticelsin the periderm allow for gas
exchange between living stem or root cells and
the outside air
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
Annuals complete their life cycle in a year
or less
Biennials require two growing seasons
Perennials live for many years
called indeterminate growth
Some plant organs cease to grow at a certain
size; this is called determinate growth
Annuals complete their life cycle in a year
or less
Biennials require two growing seasons
Perennials live for many years
Sequoia sempervirens
Pinusaristata
Monocot vs.Dicot
Parameter Monocot Dicot
Extent of cortex No distinct cortex Cortex found at the
outer part of ground
tissue
Presence or absence of
pith
Absent Present
Type of stele Atactostele Eustele
Presence or absence of
vascular cambium
Absent Present
Parameter Monocot Dicot
Extent of cortex No distinct cortex Cortex found at the
outer part of ground
tissue
Presence or absence of
pith
Absent Present
Type of stele Atactostele Eustele
Presence or absence of
vascular cambium
Absent Present
Modified Stem
Modification of the stem would depend on
the need of the plant to survive…
… like the animals it learns how to
adapt.
Modification of the stem would depend on
the need of the plant to survive…
… like the animals it learns how to
adapt.
Bulb–consist of small amount
of vertical stem and a massive
quantity of thick, fleshy storage
leaves.
-most of them consist of
concentric rings of scales
attached to a basalplate.
.
of vertical stem and a massive
quantity of thick, fleshy storage
leaves.
-most of them consist of
concentric rings of scales
attached to a basalplate.
.
Other bulbous plants
Daffodil Reticulate iris
Daffodil Reticulate iris
Stolon / runner = with long
internodes just below the
surface of the ground that
typically terminating in a new
plant
= use for propagation
internodes just below the
surface of the ground that
typically terminating in a new
plant
= use for propagation
Fig. 35-5c
Stolons
Stolon
Stolons
Stolon
Corm -formed from a swollen bases
of stems.
-A corm consists of one or
more internodes with at least one
growing point
of stems.
-A corm consists of one or
more internodes with at least one
growing point
Examples of Corm
Crocuses Gladioli
Crocuses Gladioli
Rhizome= the stem is
horizontal and underground
with short internodes and
bearing with scale-like leaves.
horizontal and underground
with short internodes and
bearing with scale-like leaves.
Other rhizome plants
Johnson grass
Sorghum halepense
Cogon grass
Imperata cylindrica
Johnson grass
Sorghum halepense
Cogon grass
Imperata cylindrica
Tuber = a thick under ground
storage stem, usually not upright
= bearing outer buds
= lacking protective scales
storage stem, usually not upright
= bearing outer buds
= lacking protective scales
Fig. 35-5d
Tubers
Tubers
Aerial MODIFICATIONS OF STEM
•TENDRILS
IN grapes
Axillary bud is modified
into tendrils.
•CLADOPHYLL /
PHYLLOCLADE
The entire shoot is
flattend& leaf like.
•TENDRILS
IN grapes
Axillary bud is modified
into tendrils.
•CLADOPHYLL /
PHYLLOCLADE
The entire shoot is
flattend& leaf like.
References
•Campbell, N.A., J.B Reece and L.G. Mitchell.
1999. Biology. 5
th
ed. USA: The
Benjamin/Cummings Publishing Co. Inc.
•Weier, E.T., R.C Stocking., M. G Barbour and Rost
T. L.1982. Botany an Introduction to Plant
Biology. 6
th
ed. USA: John Willey and Sons Inc.
•Campbell, N.A., J.B Reece and L.G. Mitchell.
1999. Biology. 5
th
ed. USA: The
Benjamin/Cummings Publishing Co. Inc.
•Weier, E.T., R.C Stocking., M. G Barbour and Rost
T. L.1982. Botany an Introduction to Plant
Biology. 6
th
ed. USA: John Willey and Sons Inc.
THE END
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