Root anatomy
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Feb 15, 2021
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About This Presentation
Anatomy of Root, Primary and Secondary structure
Slide Content
DR. DILIP V. HANDE
PROFESSOR
DEPT OF BOTANY
SHRI SHIVAJI SCIENCE COLLEGE AMRAVATI
SEM-III
PROFESSOR
DEPT OF BOTANY
SHRI SHIVAJI SCIENCE COLLEGE AMRAVATI
SEM-III
EXTERNAL STRUCTURE OF ROOTS
▪Roots
cylindrical structures
no nodes and internodes
do not generally bear buds, leaves, flowers
and fruits
but the enlarged roots of sweet potato give
rise to adventitious buds
▪Roots
cylindrical structures
no nodes and internodes
do not generally bear buds, leaves, flowers
and fruits
but the enlarged roots of sweet potato give
rise to adventitious buds
EXTERNAL STRUCTURE OF ROOTS
▪Classification of Roots based on Origin:
Primary root–first root formed from the embryonic
root (radicle, growing tip of the hypocotyl)
Secondary root–roots arising from primary roots
Tertiary roots–arising from secondary roots
rootlets –branches of tertiary roots
Adventitious roots–arising from structures other than
the hypocotyl, such as stems and leaves
▪Classification of Roots based on Origin:
Primary root–first root formed from the embryonic
root (radicle, growing tip of the hypocotyl)
Secondary root–roots arising from primary roots
Tertiary roots–arising from secondary roots
rootlets –branches of tertiary roots
Adventitious roots–arising from structures other than
the hypocotyl, such as stems and leaves
EXTERNAL STRUCTURE OF ROOTS
▪Kinds of Root Systems
Taproot System
has prominent primary root
Fibrous (diffuse) System
Primary root is lost and replaced by numerous
adventitious roots arising from the lower portion of the
stem
Slender in form and are more or less equally prominent
▪Kinds of Root Systems
Taproot System
has prominent primary root
Fibrous (diffuse) System
Primary root is lost and replaced by numerous
adventitious roots arising from the lower portion of the
stem
Slender in form and are more or less equally prominent
Tap root system
Fibrous root system
Types of root systems
The fibrous root system of monocots is a
mass of slender roots and lateral branches
that hold the plant secure in the soil.
Tap root is common in dicots; the first or
primary root grows straight down and
remains dominant root of a plant; often fleshy
and adapted to store food (e.g., carrots, beets)
Fibrous root system
Types of root systems
The fibrous root system of monocots is a
mass of slender roots and lateral branches
that hold the plant secure in the soil.
Tap root is common in dicots; the first or
primary root grows straight down and
remains dominant root of a plant; often fleshy
and adapted to store food (e.g., carrots, beets)
EXTERNAL STRUCTURE: LONGITUDINAL REGIONS
ROOTS
▪Root cap region
thimble-shaped mass of cells at the tip of the root
for protective covering for the growing point as it
pushes its way through the soil
▪Embryonic (Meristematic) Region
actively dividing region (apical mersitem)
▪Region of Elongation or Cell Enlargement
Cells increase in size, particularly the length
ROOTS
▪Root cap region
thimble-shaped mass of cells at the tip of the root
for protective covering for the growing point as it
pushes its way through the soil
▪Embryonic (Meristematic) Region
actively dividing region (apical mersitem)
▪Region of Elongation or Cell Enlargement
Cells increase in size, particularly the length
EXTERNAL STRUCTURE: LONGITUDINAL REGIONS
ROOTS
▪Region of Maturation or Cell Differentiation
region where cells are differentiated (cells attain their
final structural characteristic and perform their
respective functions)
In Dicots: divided into 3 zones:
Root Hair Zone –numerous hairs; young root
Zone of Primary Permanent Tissue (young)
derived from apical meristems; fully differentiated (primary tissue)
Zone of Secondary Tissues (older)
Derived form the lateral meristems or cambia
In Monocots: only 2 zones:
Root Hair Zone (young)
Zone of Primary Permanent Tissue (young but old at the base)
ROOTS
▪Region of Maturation or Cell Differentiation
region where cells are differentiated (cells attain their
final structural characteristic and perform their
respective functions)
In Dicots: divided into 3 zones:
Root Hair Zone –numerous hairs; young root
Zone of Primary Permanent Tissue (young)
derived from apical meristems; fully differentiated (primary tissue)
Zone of Secondary Tissues (older)
Derived form the lateral meristems or cambia
In Monocots: only 2 zones:
Root Hair Zone (young)
Zone of Primary Permanent Tissue (young but old at the base)
Elongation region
Meristematic region
Root cap
protoderm
ground meristem
procambium
Actively dividing cells
Produces mucigel for
protection, lubrication,
water and nutrient absorption
Meristematic region
Root cap
protoderm
ground meristem
procambium
Actively dividing cells
Produces mucigel for
protection, lubrication,
water and nutrient absorption
ROOT HAIRS
Increase the surface area
for the absorption of water
Increase the surface area
for the absorption of water
Roots-External
Root cap -
indicates growth
of new cells
Root hairs -
absorb moisture
(water) and
minerals
Root cap -
indicates growth
of new cells
Root hairs -
absorb moisture
(water) and
minerals
Root development
Dicot Monocot
▪there is pith in the very center
composed of parenchyma.
Instead there is xylem tightly
packed with branching arms
looking somewhat like a star. The
phloem fills in the spaces in
between the arms
▪the phloem and xylem are in
loose rings. With the phloem
towards the outside and the
xylem towards the inside.
There is no pith in the center.
-The main difference is in the vascular cylinder or stele.
Dicot Monocot
▪there is pith in the very center
composed of parenchyma.
Instead there is xylem tightly
packed with branching arms
looking somewhat like a star. The
phloem fills in the spaces in
between the arms
▪the phloem and xylem are in
loose rings. With the phloem
towards the outside and the
xylem towards the inside.
There is no pith in the center.
-The main difference is in the vascular cylinder or stele.
Root development
Dicot Monocot
1. usually 3-5 groups of phloem
and xylem arranged
alternately
2. xylem endarch(relating to a
xylem whose early
development is toward the
center)
3. cambium present
1. there r many vascular
bundles alternately arranged
2. xylem exarch (relating to a
xylem whose early
development is away from
the center and toward the
periphery)
3. no cambium
Dicot Monocot
1. usually 3-5 groups of phloem
and xylem arranged
alternately
2. xylem endarch(relating to a
xylem whose early
development is toward the
center)
3. cambium present
1. there r many vascular
bundles alternately arranged
2. xylem exarch (relating to a
xylem whose early
development is away from
the center and toward the
periphery)
3. no cambium
INTERNAL STRUCTURE: CROSS SECTION OF A YOUNG
DICOT ROOTS
▪Three Regions:
Epidermal or Dermal Region (outer region)
Single layer of living cells; may or may not have root
hairs
Cortex (middle region)
Consists of 2 zones:
Outer zone consisting of several layers of parenchyma
Inner zone consisting of a single layer of thick-walled
living cells (endodermis)
Passage cells –cells of the endodermis opposite the
xylem rays
DICOT ROOTS
▪Three Regions:
Epidermal or Dermal Region (outer region)
Single layer of living cells; may or may not have root
hairs
Cortex (middle region)
Consists of 2 zones:
Outer zone consisting of several layers of parenchyma
Inner zone consisting of a single layer of thick-walled
living cells (endodermis)
Passage cells –cells of the endodermis opposite the
xylem rays
INTERNAL STRUCTURE: CROSS SECTION OF A YOUNG
DICOT ROOTS
▪Three Regions:
Stele or Vascular Cylinder(inner region)
Pericycle(outermost part)
Single layer of thin-walled living cells (parenchyma)
Primary Xylem
trachearyelements organized in the form of a star
direction of development from outer (tip of the xylem ray)
towards the inside –pattern called exarch
Primary Phloem
Patches of tissues located between the rays or radial arms
of the primary xylem
Vascular Cambium
Layer of meristematiccells between primary xylem and
phloem
DICOT ROOTS
▪Three Regions:
Stele or Vascular Cylinder(inner region)
Pericycle(outermost part)
Single layer of thin-walled living cells (parenchyma)
Primary Xylem
trachearyelements organized in the form of a star
direction of development from outer (tip of the xylem ray)
towards the inside –pattern called exarch
Primary Phloem
Patches of tissues located between the rays or radial arms
of the primary xylem
Vascular Cambium
Layer of meristematiccells between primary xylem and
phloem
INTERNAL STRUCTURE: CROSS SECTION OF A OLD
DICOT ROOTS
▪Two groups of tissue which enter into the tissue
composition of old dicot root:
Secondary vascular tissues
consists of secondary xylem and phloem
Periderm
Phellogen (cork cambium)
Phellem (cork)
Phelloderm (secondary parenchyma)
DICOT ROOTS
▪Two groups of tissue which enter into the tissue
composition of old dicot root:
Secondary vascular tissues
consists of secondary xylem and phloem
Periderm
Phellogen (cork cambium)
Phellem (cork)
Phelloderm (secondary parenchyma)
INTERNAL STRUCTURE: CROSS SECTION OF AN OLD
DICOT ROOTS
▪What happens? ---once differentiated:
Cambium gives rise to the secondary phloem outwardly
and secondary xylem inwardly
Secondary xylem would eventually occupy the places
formerly occupied by primary phloem
Secondary xylem →vascular cambium →secondary
phloem
Pericycle becomes meristematic and gives rise to cork
cambium (phellogen)
Cork cambium produces phelloderminwardly and phellem
or corkoutwardly (serves as the outermost tissue)
DICOT ROOTS
▪What happens? ---once differentiated:
Cambium gives rise to the secondary phloem outwardly
and secondary xylem inwardly
Secondary xylem would eventually occupy the places
formerly occupied by primary phloem
Secondary xylem →vascular cambium →secondary
phloem
Pericycle becomes meristematic and gives rise to cork
cambium (phellogen)
Cork cambium produces phelloderminwardly and phellem
or corkoutwardly (serves as the outermost tissue)
INTERNAL STRUCTURE: CROSS SECTION OF A
MONOCOT ROOTS
▪Three Regions:
Epidermal or Dermal Region (outer region)
Cortex (middle region)
Stele (inner region) –consists of
Pericycle
Xylem–star-shaped like of a young dicot, except for:
star-shaped xylem has more radial arms (polyarch)
center of star-shaped xylem may be occupied by
sclerenchyma fibers and parenchyma; tracheary elements
are found only within the radial arms
Phloem–occupies the spaces between the radial arms
of xylem
No vascular cambium
MONOCOT ROOTS
▪Three Regions:
Epidermal or Dermal Region (outer region)
Cortex (middle region)
Stele (inner region) –consists of
Pericycle
Xylem–star-shaped like of a young dicot, except for:
star-shaped xylem has more radial arms (polyarch)
center of star-shaped xylem may be occupied by
sclerenchyma fibers and parenchyma; tracheary elements
are found only within the radial arms
Phloem–occupies the spaces between the radial arms
of xylem
No vascular cambium
Fig. 35-7, p. 753
Young dicot root
epidermis
cortex
vascular cylinder
endarch relating to a xylem whose early
development is toward the center)
there is pith in the very center composed of
parenchyma. Instead there is xylem tightly packed
with branching arms looking somewhat like a
star. The phloem fills in the spaces in between
the arms
epidermis
cortex
vascular cylinder
endarch relating to a xylem whose early
development is toward the center)
there is pith in the very center composed of
parenchyma. Instead there is xylem tightly packed
with branching arms looking somewhat like a
star. The phloem fills in the spaces in between
the arms
Monocot root
actinostelepolyarch
exarch
exarch
metaxylem
vessel
protoxylem
vessel
exarch -xylem whose early development is away from the center and toward the periphery
actinostelepolyarch
exarch
exarch
metaxylem
vessel
protoxylem
vessel
exarch -xylem whose early development is away from the center and toward the periphery
Monocot root
-there are many vascular bundles alternately arranged
-the phloem and xylem are in loose rings. With the phloem towards the
outside and the xylem towards the inside. There is no pith in the center.
-there are many vascular bundles alternately arranged
-the phloem and xylem are in loose rings. With the phloem towards the
outside and the xylem towards the inside. There is no pith in the center.
Dicotroot
usually 3-5 groups of phloem and xylem
arranged alternately
usually 3-5 groups of phloem and xylem
arranged alternately
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