Ground tissue

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Transcript Ground tissue

Plant Form
Chapter 36
Plant Body Organization
A vascular plant consists of:
1. Root system, which is underground
-Anchors the plant, and is used to
absorb water and minerals
2. Shoot system, which is above ground
-Consists of supporting stems,
photosynthetic leaves and reproductive
flowers
Each has an apex that extends growth
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Plant Body Organization
Plant cell walls consist of cellulose
-Primary cell wall
-Found in all cells
-Cellulose fibers parallel to microtubules
-Secondary cell wall
-Found in some cells
-Additional layers of cellulose and lignin
-Increase mechanical strength of wall
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Plant Body Organization
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Plant Body Organization
Roots, shoots and leaves contain three basic
tissue systems:
-Dermal tissue – For protection
-Wax and bark
-Ground tissue – For storage,
photosynthesis and secretion
-Vascular tissue – For conduction
-Xylem – Water and dissolved minerals
-Phloem – Nutrient-containing solution
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Plant Body Organization
Meristems are clumps of small cells with
dense cytoplasm and large nuclei
They act as stem cells do in animals
-One cell divides producing a differentiating
cell and another that remains meristematic
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Plant Body Organization
Apical meristems are located at the tips of
stems and roots
-Give rise to primary tissues which are
collectively called the primary plant body
-Three primary meristems
-Protoderm  Epidermis
-Procambium  1o vascular tissue
-Ground meristem  Ground tissue
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Plant Body Organization
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Plant Body Organization (Cont.)
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Plant Body Organization
Lateral meristems are found in plants that
exhibit secondary growth
-Give rise to secondary tissues which are
collectively called the secondary plant body
-Woody plants have two types
-Cork cambium  Outer bark
-Vascular cambium  2o vascular tissue
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Plant Tissues
As mentioned earlier, plants contain three
main types of tissue
-Dermal
-Ground
-Vascular
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Dermal Tissue
Forms the epidermis, which is usually one
cell layer thick
Covered with a fatty cutin layer constituting
the cuticle
Contains special cells, including guard cells,
trichomes and root hairs
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Dermal Tissue
Guard cells are paired sausage-shaped cells
-Flank a stoma, which is the passageway
for oxygen and carbon dioxide
Guard cell formation is the result of an
asymmetrical cell division that produces:
-A guard cell
-A subsidiary cell
-Aids in stoma opening and closing
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Dermal Tissue
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Dermal Tissue (Cont.)
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Dermal Tissue (Cont.)
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Dermal Tissue
Trichomes are cellular or multicellular hairlike
outgrowths of the epidermis
-Keep leaf surfaces cool and reduce
evaporation by covering stomatal openings
-Some are glandular,
secreting substances
that deter herbivory
Trichome patterning is
under genetic control
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Dermal Tissue
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Dermal Tissue (Cont.)
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Dermal Tissue
Roots hairs are tubular extensions of
individual epidermal cells
-Greatly increase
the root’s surface
area and efficiency
of absorption
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Ground Tissue
Consist of three types of cells
-Parenchyma
-Collenchyma
-Sclerenchyma
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Ground Tissue
Parenchyma cells are the most common
type of plant cell
-May live for many years, functioning in
storage, photosynthesis and secretion
-Some contain chloroplasts and are called
chlorenchyma
Collenchyma cells provide support for plant
organs, allowing bending but not breaking
-Have living protoplasts and may live for
many years
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Ground Tissue
Sclerenchyma cells have tough thick walls
-Lack living walls at maturity
-Two general types
-Fibers: Long, slender cells that are
usually grouped in strands
-Sclereids: Variable shape; branched;
may occur singly or in groups
-Both strengthen tissues
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Ground Tissue
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Ground Tissue (Cont.)
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Vascular Tissue
Xylem
-Constitutes the main water- and mineralconducting tissue
-Vessels: Continuous tubes of dead
cylindrical cells arranged end-to-end
-Tracheids: Dead cells that taper at the
end and overlap one another
-Vessels are shorter & wider than tracheids
-And conduct water more efficiently 29
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Vascular Tissue
Xylem
-Also conducts inorganic ions such as
nitrates, and supports the plant body
-Typically includes parenchyma cells in
horizontal rows called rays
-Function in lateral conduction and food
storage
Note: The diffusion of water vapor from a
plant is termed transpiration
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Vascular Tissue
Phloem
-Constitutes the main food-conducting
tissue in vascular plants
-Contains two types of elongated cells:
sieve cells and sieve tube members
-Living cells that contain clusters of
pores called sieve areas or sieve plates
-Sieve-tube members are more
specialized
-Associated with companion cells 32
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Roots
Roots have a simpler pattern of organization
and development than stems
Four regions are commonly recognized:
-Root cap
-Zone of cell division
-Zone of elongation
-Zone of maturation
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Roots
Root cap
-Contains two types of cells that are formed
continuously by the root apical meristem
-Columella cells: Inner
-Root cap cells: Outer and lateral
-Functions mainly in protection of the
delicate tissues behind it
-Also in the perception of gravity
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Roots
Zone of cell division
-Contains mostly cuboidal cells, with small
vacuoles and large central nuclei
-Derived from rapid divisions of the root
apical meristem
-Quiescent center cells divide very
infrequently
-Apical meristem daughter cells soon
subdivide into the three primary tissues 37
Roots
Zone of cell division
-Patterning of these tissues begins in this
zone
-WEREWOLF (WER) gene
-Suppresses root hair development
-SCARECROW (SCR) gene
-Necessary for differentiation of
endodermal and ground cells
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Roots
Zone of elongation
-Roots lengthen because cells become
several times longer than wide
-No further increase occurs above this zone
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Roots
Zone of maturation
-The elongated cells become differentiated
into specific cell types
-Epidermal cells: Have very thin cuticle
-Include root hair and nonhair cells
-Cortex: Interior to the epidermis
-Parenchyma cells used for storage
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Roots
Zone of maturation
-Endodermis: Single-layered cylinder
-Impregnated with bands of suberin
called the Casparian strips
-Stele: All tissues interior to endodermis
-Pericycle: Multiple-layered cylinder
-Gives rise to lateral (branch) roots
or the two lateral meristems
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Roots
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Plant Tissue Differentiation
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Modified Roots
Most plants produce either/or:
-Taproot system: Single large root with
small branch roots
-Fibrous root system: Many small roots of
similar diameter
Some plants, however, produce modified
roots with specific functions
-Adventitious roots arise from any place
other than the plant’s root
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Modified Roots
Prop roots: Keep the plant upright
Aerial roots: Obtain water from the air
Pneumatophores: Facilitate oxygen uptake
Contractile roots: Pull plant deeper into soil
Parasitic roots: Penetrate host plants
Food storage roots: Store carbohydrates
Water storage roots: Weigh 50 or more kg
Buttress roots: Provide considerable stability
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Prop roots
Aerial roots
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Pneumatophores
Water storage roots
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Buttress roots
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Stems
Like roots, stems contain the three types of
plant tissue
-Also undergo growth from cell division in
apical and lateral stems
Shoot apical meristem initiates stem tissue
and intermittently produces primordia
-Develop into leaves, other shoots and
even flowers
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Stems
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Stems
Leaves may be arranged in one of three ways
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Stems
The spiral (alternate) arrangement is the
most common
-Sequential leaves tend to be placed
137.5o apart
-This is termed phyllotaxy
-May optimize the exposure of
leaves to the sun
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External Stem Structure
Node = Point of attachment of leaf to stem
Internode = Area of stem between two nodes
Blade = Flattened part of leaf
Petiole = Stalk of leaf
Axil = Angle between petiole/blade and stem
Axillary bud = Develops into branches with
leaves or may form flowers
Terminal bud = Extends the shoot system
during the growing season
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Internal Stem Structure
Monocot vascular bundles are usually
scattered throughout ground tissue system
Eudicot vascular tissue is arranged in a ring
with internal ground tissue (pith) and
external ground tissue (cortex)
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Internal Stem Structure
Vascular tissue arrangement is directly related
to the stem’s ability for secondary growth
-In eudicots, a vascular cambium develops
between the primary xylem and phloem
-Connects the ring of primary vascular
bundles
-In monocots, there is no vascular cambium
-Therefore, no secondary growth
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Internal Stem Structure
Rings in the stump of a tree reveal annual
patterns of vascular cambium growth
-Cell size depends on growth conditions
In woody eudicots and gymnosperms, the
cork cambium arises in the outer cortex
-Produces boxlike cork cells on outside and
parenchyma-like phelloderm cells on inside
-Collectively called the periderm
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Internal Stem Structure
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Internal Stem Structure
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Internal Stem Structure
Cork tissue cells get impregnated with
suberin shortly after they are formed
-They then die and constitute the outer
bark
The cork cambium also produces
unsuberized cells called lenticels
-Permit gas exchange to continue
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Internal Stem Structure
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Modified Stems
Bulbs = Swollen underground stems,
consisting of fleshy leaves
Corms = Superficially resemble bulbs, but
have no fleshy leaves
Rhizomes = Horizontal underground stems,
with adventitious roots
Runners and stolons = Horizontal stems
with long internodes that grow along the
surface of the ground
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Modified Stems
Tubers = Swollen tips of rhizomes that
contain carbohydrates
Tendrils = Twine around supports and aid in
climbing
Cladophylls = Flattened photosynthetic
stems resembling leaves
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Modified Stems
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Modified Stems (Cont.)
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Modified Stems (Cont.)
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Leaves
Leaves are the main site of photosynthesis
-They are determinate structures whose
growth stops at maturity
Exist in two morphologies
-Microphyll = Have one vein which does
not extend the full length of the leaf
-Found mainly in the phylum Lycophyta
-Megaphylls = Have several to many veins
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Leaves
The flattening of the leaf blade reflects a shift
from radial to dorsal-ventral symmetry
-It increases the photosynthetic surface
The mechanism of this shift is becoming
clearer through the analysis of mutants that
lack distinct tops and bottoms
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Leaves
Veins consist of both xylem and phloem and
are distributed throughout the leaf blades
-Monocot leaves
have parallel
veins
-Eudicot leaves have
netted or reticulate
veins
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Leaves
Leaf blades come in a variety of forms
-Simple leaves contain undivided blades
-May have teeth, indentations or lobes
-Compound leaves have blades that are
divided into leaflets
-Pinnate = Leaflets in pairs along an axis
-Palmate = Leaflets radiate out from a
common point
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Leaves
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Leaves (Cont.)
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Leaves
The leaf’s surface is covered by transparent
epidermal cells, most having no chloroplasts
Epidermis has a waxy cuticle
-The lower epidermis contains numerous
mouth-shaped stomata flanked by guard
cells
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Leaves
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Leaves
The mesophyll is the tissue between the
upper and lower epidermis
-Most eudicot leaves have two types
-Palisade mesophyll = Usually two rows
of tightly packed chlorenchyma cells
-Spongy mesophyll = Loosely arranged
cells with many air spaces in between
-Monocot leaves mesophyll is usually not
differentiated into palisade/spongy layers 85
Leaves
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Leaves (Cont.)
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Modified Leaves
Floral leaves (bracts) = Surround true
flowers and behave as showy petals
Spines = Reduce water loss and may deter
predators
Reproductive leaves = Plantlets capable of
growing independently into full-sized plant
Window leaves = Succulent, cone-shaped
leaves that allow photosynthesis
underground
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Modified Leaves
Shade leaves = Larger in surface area but
with less mesophyll than sun-lit leaves
Insectivorous leaves = Trap insects
-Pitcher plants have cone-shaped leaves
that accumulate rainwater
-Sundews have glands that secrete sticky
mucilage
-Venus flytrap have hinged leaves that
snap shut
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