Plant Morphology PDF

Summary

This document is a lecture on Plant Morphology. It details the structure of a typical flower, pollination, fertilization, and seed germination. It's suitable for undergraduate-level botany or biology courses.

Full Transcript

PLANT MORPHOLOGY

Dr. Ashraf Tawfiek Soliman
Cellphone: 01203305553
E-mail: [email protected]
 Dr. Ashraf T. Soliman

Plant morphology
It is the study of the physical form and external
structure of plants.
It represents a study of the development, form,
and structure of plants

Here, we are dealing with the flowering plants
(Angiospermae)

2
 Dr. Ashraf T. Soliman
Structure of a typical flower
The flower is a compressed shoot (compact
lateral branch), serving for purposes of sexual
reproduction.
It is composed of a stalk called pedicel, with an
expanded swollen end known as receptacle on
which the floral leaves are inserted. These
floral leaves are usually found in whorls one
inside the other:
a. Calyx: is the outermost whorl of leaves. It is
composed of sepals which are usually green.
pedicel
b. Corolla: it follows usually the calyx
internally. It is formed of leaf-like colored
structures called the petals.
3
 Dr. Ashraf T. Soliman

c. Androecium: it lies inside the
corolla and represents the male
sexual organ. It is made up of a
number of stamens. Each stamen is
composed of a slender part the
filament, ending in a lobe-like
structure named the anther.
Dehiscence (bursting) of the anther
Stamen
usually takes place for the liberation
of pollen grains.
4
 Dr. Ashraf T. Soliman
d. Gynoecium: the innermost whorl, located inside the
androecium and represents the female sexual organ. The Carpel
gynoecium is composed of one to many carpels. The carpel of structure
angiosperms encloses the ovules. The carpel (pistil) is
composed of a swollen basal part called the ovary extending in
short or long slender part named the style which ends in a
globular or lobed papillated structure called the stigma.
Structure of the ovule:
The edges protrude inside the cavity of the carpel forming the
placenta on which the ovules arise, each ovule is attached to
the placenta by a stalk called the funicle. The central part of the
ovule is known as the embryo sac. The embryo sac is
surrounded by a tissue called the nucellus which is covered
externally by one or two investments known as the inner and
outer integuments. The gap left by the integuments at the top of
the ovule is called the micropyle.
5 Cross section through ovule
 Dr. Ashraf T. Soliman

Pollination
When the pollen grains are fully developed, the pollen sacs of
the anther burst exposing the pollen grains. The transfer of the
pollen grains from the stamen to the stigma (the receptive organ
of the carpel) is called the pollination.
Pollination includes wind (the most common type of
pollination) or water pollination especially in water plants. Biotic
pollination includes insect, animal or even man as pollinators.

6
Fertilization: Dr. Ashraf T. Soliman

fertilization involves not only the union of the
egg cell with the sperm cell but, in addition,
the union of a second sperm cell with the
endosperm mother cell to form the primary
endosperm cell. Since there are two nuclei in
the endosperm mother cell, the nucleus of the
primary endosperm cell will have three sets
of chromosomes. The fusions of two sperm
cells, one with the egg, the second with the
endosperm mother cell, is known as double
fertilization.
7
Dr. Ashraf T. Soliman

8
 Dr. Ashraf T. Soliman
The resulting zygote generally
develops directly into a small pro-
embryo, from one end of which a
typical embryo develops. The fate of
the primary endosperm cell depends
on the species. This cell gives rise to
an endosperm that plays some role in
nourishing the developing embryo. In
a few genera, notably the grasses, the
endosperm enlarges and persists in the
seed to form the source of
nourishment for the young seedling.
9
 Dr. Ashraf T. Soliman
Seeds and seed germination
The seed can be defined as the mature fertilized ovule. The
seed possesses only one scar (the hilum) which is the point of
attachment to its stalk (funicle).
Seeds of flowering plants differ greatly in form, color, size and
other characteristics. They may be spherical, ovoid, elliptical,
elongate, disc-like, or irregular in shape. The size ranges from the
dust-like, very light seed e.g. orchids to the huge seeds of coconut.
The outer wall of the seed may be smooth, rough or sculptured. It
may be also provided with outgrowths in the form of spines,
hooks or fibers which help in seed dispersal.
10
 Dr. Ashraf T. Soliman

Structure of the seeds:
The mature seed consists of: (1) seed coat, (2) an embryo and (3)
storage tissue.
1. Seed Coat:
It is the protective wall surrounding the embryo and storage
tissue. It is developed from the integuments of the ovule. The seed
coat is usually called testa. The hilum is the point of attachment of
the seed to the funicle. The micropyle is a minute pore and is mostly
present in the testa of many seeds.

11
 Dr. Ashraf T. Soliman
a. The testa:
It develops from the integuments of the ovule. The integumentary tissues
harden, their cells become thick-walled and serve only for protection of the
embryo and the stored food. The inner integument may persist in some seeds as
a distinct layer of the testa known as tegmen.
The testa may be leathery (broad bean); hard brittle and sculptured (castor oil
seed); fleshy (Magnolia); Membranous and easily detached as in peanut
(Arachis) or it is woody (apricot).
In maize (Zea mays) grains, there is no testa. The developing embryo
consumes all the tissues of the integument. The seed is only protected by the
developed and hardened ovary wall i.e. the pericarp of the fruit. While, the grain
coat of wheat (Triticum) includes some of the layers of the integument fused
with the pericarp of the fruit.
12
 Dr. Ashraf T. Soliman
b. The hilum:
It is the scar which marks the point of attachment to the funicle. During
maturation of the fruit, the funicle gradually dries up, a separating layer is
developed between the funicle and the base of the seed which helps abscission
(falling off) of the seed.

13
 Dr. Ashraf T. Soliman

c. The micropyle:
Is a very minute pore resulting from the incomplete fusion of the
integuments of the ovule and is usually locates between hilum and the radicle.
The micropyle allows for communication between the nucellus and the outer
surface of the ovule. The pollen tube penetrates through the micropyle to the
embryo sac for fertilization of the ovule.
At germination of the seed, water absorption takes place mainly through the
micropyle, especially when the testa is impermeable.
The micropyle may be concealed (hidden) in some seeds due to the
occurrence of outgrowths called Caruncle as in castor oil seed or it may be
absent as in Zea mays.

14
 Dr. Ashraf T. Soliman
2. The embryo:
The embryo axis is the elongated portion of the embryo, at one of this axis there is a plumule
and at the other there is the radicle. One or two cotyledons are attached to the embryo axis by
very fine and short cotyledonary stalks.
a. The plumule: is the terminal upper portion of the embryo axis.
It is considered as the first bud of the young embryonic plant.
Apex is the growing shoot apex including embryonic meristem (or
apical meristem of the shoot).
Epicotyl: is the small portion of the plumule above the
cotyledonary stalk, it is considered as the main axis of the
plumule.
b. The radicle: is the terminal lower portion of the embryo axis.
From the radicle arises the primary root of the plant. It usually
grows downward the soil and away from light.
Hypocotyl: is the small portion of the radicle below the
cotyledonary stalk, it is considered as the main axis of the radicle.

15
 Dr. Ashraf T. Soliman

c. The cotyledons: they are the young leaves of the embryo. They are
termed as seed leaves.
The number, size and shape of cotyledons varies in different groups of the
flowering plants. Accordingly, higher plants may be:
- Monocotyledonous plants: the seed possesses only one cotyledon (e.g.
corn (Zea mays) & date palm (Phoenix dactylifera).
- Dicotyledonous plants: the seed possesses two cotyledons, e.g. broad
bean (Vicia faba) & castor oil bean (Ricinus communis).

16
 Dr. Ashraf T. Soliman
3. The storage tissue:
There are two types of seeds according to the food storage tissue. The
storage tissue is termed as endosperm.
a. Exendospermous (Exabluminous) seeds: are the seeds lacking
endosperm in the mature state. The embryo is large in relation to the seed
and the food reserves are stored in the cotyledons. Exalbuminous seeds
usually possess large and stout cotyledons as they store much food (e.g.
Vicia faba, & Phaseolus vulgaris).
b. Endospermous (Albuminous) seeds: are the seeds with endosperm. In the
seeds of such type, the embryo is comparatively small and varies in
relation to the amount of endosperm left at maturity. Albuminous seeds
possess papery cotyledons; they do not store food (e.g. Ricinus communis
& Gossypium barbadense).
17
 Seed Germination Dr. Ashraf T. Soliman
The growth and development of seed into seedling: Growth is the increment of size
and dry weight of the growing structures. Development is the differentiation of the
embryo into the different organs of mature plant
Conditions necessary for seed germination
A. Internal conditions:
1-Vitality
Vitality or Viability is the germinating capacity of the seeds & the ability
of a seed to germinate when provided with optimum condition, it is
dependent upon its stored food, size, health, etc.
Environmental factors and storage conditions will have a decisive effect
on the life span of any given seed, whether the seed will remain viable for the
longest period of time or whether it loses its viability at some earlier stage.
Most of the crop plants lose their viability within 2-5 years. Some seeds may
remain viable for more than hundreds of years.
18
 Dr. Ashraf T. Soliman

2- Dormancy
It is the failure of fully developed, mature, viable seed to
germinate even under favorable physical conditions (moisture and
temperature). These internal restrictions must be offset before seed
germination.
There are several types of dormancy exhibited by seed at
maturity, they are: Physiological (e.g., presence of some inhibiting
chemicals), Physical (e.g., hard testa, impermeable to water),
Morphological (e.g., immature embryo) and Morphophysiological.

19
 Dr. Ashraf T. Soliman
B. External ‘Environmental’ conditions
1. Water:
It is required for germination. Mature seeds are often extremely dry and need to take
in significant amounts of water, relative to the dry weight of the seed, before cellular
metabolism and growth can resume.
Most seeds need enough water to moisten the seeds but not enough to soak them.
The uptake of water by seeds is called imbibition, which leads to the swelling and the
breaking of the seed coat.
When seeds are formed, most plants store a food reserve with the seed, such as
starch, proteins, or oils. This food reserve provides nourishment to the growing embryo.
When the seed imbibes water, hydrolytic enzymes are activated which break down these
stored food resources into metabolically useful chemicals.
After the seedling emerges from the seed coat and starts growing roots and leaves,
the seedling's food reserves are typically exhausted; at this point photosynthesis
provides the energy needed for continued growth and the seedling now requires a
continuous supply of water, nutrients, and light.
20
 Dr. Ashraf T. Soliman
B. External ‘Environmental’ conditions
2. Oxygen
is required by the germinating seed for metabolism. Oxygen is used
in aerobic respiration, the main source of the seedling's energy until it
grows leaves.
Oxygen is an atmospheric gas that is found in soil pore spaces; if a
seed is buried too deeply within the soil or the soil is waterlogged, the
seed can be oxygen starved.
Some seeds have impermeable seed coats that prevent oxygen from
entering the seed, causing a type of physical dormancy which is
broken when the seed coat is worn away enough to allow gas
exchange and water uptake from the environment.
21
 Dr. Ashraf T. Soliman
B. External ‘Environmental’ conditions

3. Temperature affects cellular metabolic and growth rates. Seeds
from different species and even seeds from the same plant germinate
over a wide range of temperatures. Seeds often have a temperature
range within which they will germinate, and they will not do so above
or below this range (maximum and minimum values).
Temperature also affects the degree of viscosity of water and leads
to tenderness of the testa which becomes more easily ruptured by the
developing embryo. Seeds may be named after the seasons that they
prefer to grow into summer seeds that prefer warmer months of the
year to germinate as maize and cotton or winter seeds that prefer cold
months of the year as bean, wheat and clover.
22
 Dr. Ashraf T. Soliman
B. External ‘Environmental’ conditions
4. Light or darkness can be an environmental trigger for germination and is
a type of physiological dormancy. Most seeds are not affected by light or
darkness, but many seeds, including species found in forest settings, will not
germinate until an opening in the canopy allows sufficient light for growth
of the seedling. Accordingly, seeds are classified into 3 types:
a. Light seeds: Germination of these seeds is favored by their exposure to
light even for short period. These are known as positively photoblastic
seeds.
b. Dark seeds: that will not germinate at all in the presence of light, e.g.,
mistletoe (Viscum album). These are termed negatively photoblastic seeds.
c. Indifferent seeds: these are indifferent towards light or darkness, e.g.,
many cereals and legumes. These are known as non-photoblastic seeds.
23
 Dr. Ashraf T. Soliman

Changes occurring during seed germination
Several changes occur growth and development of the embryo of
a germinated seed:
1. Physical changes: these include
a. Swelling up of the embryo.
b.Rupture of the testa due to the imbibition of water. It is to be
noticed that viable and dead seeds behave the same during the
first period of water imbibition.

24
 Dr. Ashraf T. Soliman
Changes occurring during seed germination
2. Biochemical changes:
Transformation of complex and insoluble reserve materials of the
seed to simple and easily soluble substances are purely chemical
changes.
Hydrolysis of complex stored food through the activity of enzymes
present in the viable embryo of the seed, e.g. Amylases, proteases and
lipases. The soluble products of enzymatic reactions are translocated to
the growing apices of the radicles and plumules for building up the
primary body of the young plant.
Other biochemical changes are the partial consumption and
combustion of the hydrolyzed or degraded complex material for
obtaining the energy needed for other vital processes e.g. respiration.
25
 Dr. Ashraf T. Soliman

Changes occurring during seed germination
3. Biotic changes:
These include changes occurring seed germination e.g. growth
and development of the embryo. The plumule and radicle
increase in size, become gradually differentiated to shoot and
root systems.
Seedling is the young plant from the time the radicle emerges out
of the seed coat to the time it becomes independent in its nutrition.

26
 Dr. Ashraf T. Soliman

- Hypogeal germination “below ground”: the hypocotyl
doesn’t elongate or its elongation is insignificant, the
cotyledons remain under the soil surface. For example,
broad bean (Vicia faba), maize (Zea mays).

27
 Dr. Ashraf T. Soliman
- Epigeal Germination “above ground”: here the hypocotyl
elongates carrying the cotyledons together with the plumule
above the soil surface. For example, kidney bean (Phaseolus
vulgaris) and castor oil bean (Ricinus communis).

28
Dr. Ashraf T. Soliman

29