Chapter 5 Lecture Notes Cells and Tissues Cont. PDF

Summary

These lecture notes cover different plant tissues. Topics like parenchyma, collenchyma, and sclerenchyma are presented with relevant diagrams and images. The document also includes information on the structure and function of plant tissues, and their roles in plant growth and development. Also details on some modifications of leaves and stems.

Full Transcript

Tissues Primary Structures
and Introduction to
Development

Presented By: A. Rubio
 In the beginning….or in a
galaxy far, far, away!
 Plants began living on land 420 million years ago.
 Challenges of terrestrial life led to evolution of distinct, specialized tissues
and “organs”.
 All flowering plants have leaves, stems, and roots.
− These parts can be modified and may not be easily recognizable.
− No species exists for which roots, stems, or leaves have been completely lost
evolutionarily.
 Flowering plants are classified as the Division Magnoliophyta, informally as
angiosperms.
 You may have noticed that plants are placed in divisions and not phyla.
 It’s the same thing!!!!!!
  Stems, leaves, and roots all share a
Basic 
basic, simple organization.
All plant cells belong to just three
Types of classes based on the nature of their cell
wall.
Cells and − Parenchyma

Tissues − Collenchyma
− Sclerenchyma
 Parenchyma
Parenchyma cells have
only thin primary walls.
A mass of parenchyma
cells forms parenchyma
tissue.
− Active metabolically.
− Most remain alive after
they mature.

Special parenchyma
− Chlorenchyma
− Glandular cells
− Transfer cells
− Phloem
Specialized
Parenchyma
 Chlorenchyma cells
are photosynthetic
parenchyma cells.
− Thin walls allow
light and carbon
dioxide to pass
through to the
chloroplast.
 Pigmented cells are
parenchyma.
− Thin walls of
parenchyma cells
also allow
pigments to be
seen.
 Specialized Parenchyma
 Glandular cells secrete
− Nectar
− Fragrances
− Mucilage
− Resins
− Oils
 Specialized Parenchyma
 Transfer cells mediate short-distance transport of material.
− They have a large, extensive plasma membrane with numerous molecular
pumps.

Courtesy of W. W. Thomson and R. Balsamo, University of California, Riverside Courtesy of M. J. Talbot and C. E. Offler, University of Newcastle, Australia
 Phloem is parenchyma tissue that conducts
nutrients over long distances.

Some parenchyma cells function by dying at
Specialized maturity to open areas.
Parenchyma

Parenchyma cells are relatively inexpensive to
build.
Little glucose is
Most leaves are soft,
expended in They are not very
composed almost
constructing such thin expensive metabolically.
entirely of parenchyma.
walls.
Collenchyma
 Collenchyma cells have a thin primary wall that becomes
thickened in other areas.
 This allows plasticity.
 Collenchyma tends to exist:
− Beneath the epidermis
− Supporting vascular bundles
 Sclerenchyma
 Sclerenchyma has a primary wall and
a thick secondary wall that is usually
lignified.
 These walls are elastic.
 Sclerenchyma supports the plant by
its strength.
 Usually dead at maturity.
 Two types:
− Mechanical
− Conductive
 Sclerenchyma
 Mechanical sclerenchyma
− Fibers are long and flexible.
− Sclereids are short, isodiametric (cuboidal), inflexible, and
brittle
Sclerenchyma

 Conducting sclerenchyma
transports water.
− Tracheary elements of the
xylem
 Small, plasmodesmata-rich
areas must remain free of the
secondary wall.
− These become narrow pits in
the secondary wall.
− Two pits are called pit-pairs.
 Internal Organization of Stems:
Primary Tissues

 Epidermis is the outermost surface of an
herbaceous stem.
− A single layer of parenchyma cells.
− All interchange of material between a
plant and its environment occurs by
means of its epidermis.
− Functions in protection and preventing
water loss.
Primary Tissues: Epidermis
 Outer tangential walls are coated with waterproof cutin.
 It builds up as a layer called the cuticle.
 Under dry conditions a wax layer may be added external to
the cuticle.

Courtesy of Urs Eggli, Municipal Succulent Collection, Zurich
 Primary Tissues: Epidermis
 The cuticle prevents desiccation but it
also prevents gas exchange.
 This critical function is accomplished by
stomata.
− Guard cells
− Stomatal pore
 Primary Tissues: Epidermis
 Guard cells swell by absorbing water.
− The pore between them opens,
permitting entry of carbon dioxide and
exit of oxygen.
 Water is lost through stomata.
− Guard cells regulate when the pores are
open/closed.
− Remain closed after sunset or during
periods of water stress.
− Stomata Animation

Courtesy of Urs Eggli, Municipal Succulent Collection, Zurich
Primary
Tissues:
Epidermis
 Some epidermal cells
elongate outward and
become trichomes
(hairs).
 Protective roles
− Deter herbivory.
− Minimize water
loss.
− Protect for over
exposure to
sunlight.
Primary Tissues:
Cortex
 Cortex is interior to the
epidermis.
− Often homogenous,
composed of photosynthetic
parenchyma and sometimes
collenchyma.
− Cells are typically tightly fitted,
but some plants have a cortex
of aerenchyma, loosely
packed with large intercellular
air spaces.
Primary Tissues: Vascular Tissues

 Vascular tissues are responsible for the
conduction of materials throughout the plant.
 Two types of vascular tissues occur in plants.
− Xylem conducts water and minerals.
− Phloem distributes sugars and minerals.
 Xylem is dead and hollow at maturity.
 Phloem remains alive at maturity.
Vascular Tissues: Xylem

Xylem consists of tracheids and vessel
elements.
Collectively referred to as tracheary elements

Strength of cells due to the secondary cell
walls.
Annular Scalarifor
Helical Reticulate
thickening m
thickening thickening
s thickening
Vascular
Tissues: Xylem

 The most derived and
strongest tracheary
elements have
circular bordered pits.
− The primary wall
is underlain by
secondary wall.
− The pits are weak
points in the wall.
− The weakness is
reduced by a
border of extra
wall material.
Vascular
Tissues: Xylem

 Water moves between
tracheids through pit
membranes.
 Vessel elements
provide a way to move
water with less friction.
− Perforations form
between vertically
stacked vessel
elements.
− A stack of vessel
elements is called
a vessel.
  All plants with vascular tissue have
tracheids.
Vascular
− Conifers have only tracheids.
Tissues: − Also found in leaf veins of flowering plants.
Xylem  Only flowering plants have vessel elements
and tracheids.
− Perform long-distance water conduction in
roots and stems.
Vascular Tissues: Phloem

 Phloem has two types of conducting cells.
− Sieve cells
− Sieve tube members
 The term “sieve element” refers to either.
 Develop from parenchyma cells that remain alive.
 Plasmodesmata enlarge to become sieve pores.
 The sieve pores aggregate in sieve areas.
Vascular
Tissues:
Phloem
 A sieve cell is similar
in shaped to a
tracheid.
− It is elongated
and tapered.
 Sieve areas are
distributed over its
surface.
 This type is found in
older fossils and in
non-flowering
vascular plants.
Vascular
Tissues:
Phloem
 Sieve tube members are
similar to the vessel
members of the xylem.
− Sieve plates on
each end-wall.
− Align vertically to
form a sieve tube.
− More effective flow
of sap.
 All angiosperms have
sieve tubes.
− None of the non-
angiosperms have
them.
Vascular Tissues: Phloem
 Nuclei of sieve elements degenerate.
− No complex metabolism without the nucleus.
− They are associated with neighboring cells that exert
nuclear control.
 Sieve cells are associated with albuminous cells.
 Sieve tube members are controlled by companion cells.
 Companion cells are involved in loading sugars.
 They are often smaller than the accompanying conducting
cell.
 They have a prominent nucleus and dense cytoplasm filled
with ribosomes.

 Phloem Loading
 Organization of Vascular Tissues
 Xylem and phloem occur together in
vascular bundles interior to the
cortex.
− Arrangement of bundles differs
between monocots and other
angiosperms.
 Each bundle includes xylem and
phloem running parallel to each
other.
Organization of
Vascular
Tissues
 In eudicots, vascular
bundles are arranged
in one ring
surrounding the pith.
− Pith is a central
region of
parenchyma
similar to the
cortex.
 In monocots, they are
distributed as a
complex network
throughout the inner
part of the stem.
Organization of Vascular Tissues

 The xylem of a vascular bundle is primary xylem.
 In addition to the tracheary elements there are:
− A large proportion of xylem parenchyma
− Xylem fibers
 The phloem of a vascular bundle is primary phloem.
 In addition to the sieve elements and their associate cells,
there are
− Storage parenchyma
− Phloem fibers or sclerids
Stem Growth and
Differentiation

 Stems grow longer by
creating new cells at their
tips.
− Regions known as
apical meristems.
− Cells here retain
their ability to divide.
− Expanding daughter
cells push the apical
meristem upward.
− Subapical meristems
contain cells dividing
and growing,
producing cells for
the region below.
Stem Growth and
Differentiation
 In the subapical meristem, differentiation begins as
some cells stop dividing.
 Some differentiate in protoxylem—the first xylem to
appear.
− Protoxylem must be extensible while cells around them
continue to elongate.
− This limits their 2nd wall thickenings to annular and
helical.
 Some of the elongating cells will differentiate and
mature into metaxylem.
− Since the cells around it have stopped elongating
producing one of the stronger 2nd wall types is feasible.
Stem Growth and
Differentiation
 A similar process occurs in the outer part of each
vascular bundle.
− Exterior cells mature as protophloem.
− Cells closest to the metaxylem become metaphloem.
 Other tissues also differentiate in the subapical region.
− Epidermis
− Pith
− Cortex
Stem Growth and
Differentiation
 Protoderm is epidermal cells that are in the early
stages of differentiation.
 Young xylem and phloem cells are provascular tissues.
 The equivalent stages of pith and cortex are ground
meristem.
 Primary tissues are produced by apical meristems.
 Primary growth is the growth and tissue formation that
results from apical meristem activity.
Stem Growth and Differentiation
 Several groups within Magnoliophyta
Basal angiosperms
Eudicots (broadleaf plants)
Monocots (narrow-leaved)

There are two types of plant bodies.
General
The primary plant body is herbaceous.
Random The secondary plant body is woody.
Info, and An herb is a plant that never
becomes woody and is covered with
never too bark.
It is often an annual.
early for Can be monocots or eudicots.
this!
 External Organization of Stems
 The shoot is a stem with
included leaves.
− Leaves are attached
at nodes.
− Internodes are the regions
between nodes.
 External Organization of Stems
 The stem area just above the point
where a leaf attaches is the leaf axil.

− It contains:
 An axillary bud
 A miniature shoot with
a dormant apical
meristem
 Several young leaves
 At the extreme tip of
each stem is a terminal bud.
 External Organization of Stems
 Although the axil of every leaf contains a bud, only a few buds ever develop
into a branch.
− Others remain dormant or produce flowers.
 For most plants, most axillary buds are not needed as long as the apical
meristem is healthy.
− If the apical meristem is killed axillary buds become active and replace it.
 External Organization of Stems

 Phyllotaxy is the arrangement of
leaves on the stem.
 So they do not shade each other
− Alternate phyllotaxy
− Opposite phyllotaxy
− Whorled
Stem Modification

 The stems of some plants are modified.
 Stolons have especially long and thin internodes allowing
dispersal of daughter plants.
 Nutrient storage is important in some shoots.
− Bulbs are short shoots that have thick, fleshy leaves.
− Corms are vertical, thick stems that have thin, papery leaves.
− Rhizomes are fleshy horizontal stems that allow a plant to
spread underground.
− Tubers are horizontal like rhizomes, but they grow for only a
short period and are mainly a means of storing nutrients.
Stem Modification
Taro Corm Onion Bulb
Examples of Root
Modifications