PROTECTIVE SYSTEMS
Objectives:
Study the anatomical
features that serve to protect plants against potentially harmful elements
in their environments.
I. Protection against desiccation.
The outer cell
walls of epidermal cells of aerial parts of plants are cutinized and covered
with thick cuticle layers and a layer of wax of variable thickness.
All these features serve to inhibit loss of water from the plants' interior.
1. Examine
free hand sections of the various aerial parts
of the plants provided to assess the relative thickness
of the wax and cuticle layers between different organs
and between species.
2. Perform
the following experiments on Kalanchoe and
Picea pungens leaves to assess the degree to which
wax and the epidermal layers inhibit water loss.
a. Obtain at least three leaves of comparable
size for each species.
b. Remove the wax layers of one leaf using
xylenes, followed by a water rinse.
c. Surgically remove the epidermal layer from one
leaf.
d. Use the other leaf as an untreated control.
e. Seal the petiole end of each leaf with petroleum
jelly.
f. Record the fresh weight of each leaf then place
them on the side bench where they'll remain
undisturbed.
g. During the next two weeks, weigh each leaf on a
periodic basis.
h. Calculate the rate of water loss for each leaf
and compare the effects of each treatment. You
may wish to pool data with your colleagues to
obtain an adequate statistical sample.
�Plant Anatomy VI
page 26
Many perennial
plant stems and roots expand in circumference over time. In some
cases the continuity of the protective epidermal layer is interrupted.
To compensate for this the phellogen produces phellem which replaces the
protective role of the lost epidermis. These tissues plus any included
phloem and cortex tissue comprise the periderm.
3. Study
Pelargonium (2.03), Tilia (3.05,3.055) and Pinus (3.06,
3.061) stems with respect to the place of origin and
the structure of the periderm. Compare these systems
with the periderm of Glycine (6.04) and Actea (6.05) roots.
4. Perform
the following experiment on Solanum tubers
to assess the degree to which the periderm inhibits
water loss.
a. Obtain at least two tubers of comparable size.
b. Carefully peel the periderm from one tuber.
Examine what you have peeled using free hand
sectioning and histological techniques.
c. Record the fresh weight of each tuber then place
them on the side bench where they'll remain
undisturbed.
d. Calculate the rate of water loss as in 2 above.
Deciduous trees loose their leaves at the
end of the growing season in
an organized manner. The stem interior
is sealed off from the outside
environment prior to leaf fall via a periderm
which forms in the
abscission zone.
5. Study the periderm
formed in the abscission zone of
Fraxinus (6.06) and Acer (6.07). Can you deduce where
the phellogen first forms?
6. Many
aerial plant organs are involved in gaseous
exchange which is necessary for photosynthesis and
transpiration. Slowing the rate of water loss can be
critical to plants' well being under certain environ-
mental conditions.
a. Dissect Aesculus hippocastanum shoot buds. Tight
seals between winter bud scales serve to limit
water loss from shoot apical meristems. Note the
special trichomes called colleters which secrete
the resinous material that seals the bud scales.
The dense trichomes on the leaf primordia within
the bud probably protect the young leaves from
excessive insolation by reflecting sunlight.
�Plant Anatomy VI
Page 27
b. Examine the dense mats of trichomes on the surface
of Cephalocepeus. Dense mats of trichomes are
interpreted to protect organs against desiccation
by providing a layer of still air above surfaces of
the organs.
III. Protection against predation.
Various anatomical
features of plants are interpreted as providing protection against herbivory
and seed predation.
1. Examine
the stiff trichomes on the leaf surfaces of
Pelargonium, Begonia and African Violet. These
appear to function by mechanically preventing many
insects from reaching the epidermis of these leaves.
In some cases insects may become entangled in these
trichomes and starve to death millimeters from a
potential food source.
2. The specialized
stinging hairs of Urtica have
silicified distal cell walls which readily break
away from the calcified proximal part of the hair
to provide a jagged hypodermic needle which injects
histamine and acetyl choline plus unidentified
substances into the offending animal's epidermis.
Study the prepared slides of these species to learn
how this defense mechanism works.
3. The sharp
stiff prickles of many Rosaceous species
and stiff spines of many Cactaceae species provide
strong deterrents to potential herbivores.
Carefully prepare hand sections of the examples
provided to study the cellular details of these
structures. What makes these structures so stiff?
4. Many
seeds are resistant to the digestive enzymes
of animals that eat the fruit in which they are
found. Make free hand sections of Phaseolus (3.128) and
Pisum testa to study the epidermal macrosclereids
and subepidermal brachysclereids and
osteosclereids which convey this resistance to
these seeds.
�Plant Anatomy VI
Page 28
Materials
Prepared Slides
Fresh Material
Pelargonium (2.03)
Kalanchoe leaves
Tilia (3.05,3.055)
Picea pungens leaves
Pinus (3.06,3.061)
Pelargonium stems w/cork
Glycine (6.04)
Tilia stems w/cork
Actea (6.05)
Pinus stems w/cork
Phaseolus (3.128)
Solanum tubers
Faxinus (6.06)
Fagus shoot buds
Acer (6.07)
Cephalocepeus plant
Pelargonium leaves
Begonia leaves
African Violet leaves
Urtica stems and leaves
Rosaceous stems
Cactaceae stems
Phaseolus seeds
Pisum seeds
Other
Petri dishes
Digital scale