Plant Growth, Development and Reproduction PDF

Summary

This document provides notes on plant growth, development, and reproduction. It covers concepts like growth, differentiation, plant development, and different phases of growth. The document discusses seed germination, factors affecting it, and types of seed dormancy. It also explains various plant movements such as tropisms and nasties, and concludes with a discussion on seed viability and storage.

Full Transcript

CHAPTER IV

PLANT GROWTH, DEVELOPMENT AND
REPRODUCTION
 CONCEPTS OF GROWTH AND DEVELOPMENT

❖Growth
- An irreversible change in the size of a cell, organ or whole
organism.
- It includes increase in number of cells, and weight and
enlargement of the cells in terms of width, length, diameter or
area.
❖Differentiation
- Cells taking on specialized form and function.
❖Plant Development
- The orderly and progressive change from seed germination
through juvenility, maturity, flowering and fruiting.
Phases of Plant Growth and Development
 I. VEGETATIVE PHASE
1.Germination stage
Germination refers to the presumption of active growth on the part
of the embryo, leading to the rapture of the seed coat and the
subsequent emergence of the young plant.

Water imbibition Enzyme activation Initiation of embryo growth
- Water is absorbed in - Water absorbed in seed - New materials begin to be
the hilum tissues activates the synthesized, reflected by an
- Cells become turgid various enzyme increase in the size of the
- Seed grows in volume systems. root-shoot axis.
- Seed coat becomes - Break down stored food
more permeable. - Transfer of nutrients from Rapture of seed coat and
cotyledons to the emergence of young plant
growing points
- Synthesis of new
materials through
respiration
 Factors affecting seed germination
1. Seed maturity
There is a higher percent of germination in matured seed than in
immature seeds.

2. Environmental factors
a. Water
This is essential for enzyme activation, thus permitting breakdown,
translocation and use of reserve storage material.
c. Temperature
The optimum temperature for germination of most seeds is
between 15°C and 30°C.
The maximum temperature for most species is from 35°C and
45°C.
……..requirements for seed germination

c. Air
Oxygen is required for germination of most species, carbon
dioxide concentration higher than 0.03% retards germination
and nitrogen gas has no influence.
Respiration increases sharply during seed germination.
If oxygen concentration is reduced, germination of most
seeds is retarded.

d. Light
Both light intensity and light quality influence germination.
The chemical reaction is controlled by the wavelength of light
absorbed in plant cells by the same chemical pigment
controlling floral induction – the Phytochrome (a photo
reversible protein pigment).
2. Seedling stage
The stage of plant growth and development just after
germination and before the juvenile stage of the plant.
Two kinds of Growth
Epigeal growth Hypogeal growth
Growth in dicot plants Growth in monocot plants
Both the cotyledon and hypocotyl is The plumule and the hypocotyl
raised above the ground. The emerges above the soil
cotyledon will serve as the food for surface leaving the cotyledon
the new plant during its early stage. below the soil.
3. Juvenile Stage
A stage of vigorous growth during which the plant cannot be
readily induced to a reproductive type of growth.
Growth is very fast because meristematic cells divide and
elongates very fast.

Description
a. Exponential type of growth
b. Not capable of reproductive type of growth
c. Has the ability to rejuvenate
d. It develops morphological characteristics – e.g. thorniness
e. Not receptive to external stimuli
4. Transition Stage
The plant gradually losses the characteristics of a juvenile
plant and slowly acquires the characteristics of a mature plant.
Descriptions:
a. Decrease in growth rate
b. It becomes receptive to external conditions
c. The plant decreases the ability to rejuvenate

5. Maturity Stage
The stage when the plant becomes potentially capable of
flowering.
 II. REPRODUCTIVE PHASE
This is the stage where the plant normally produces flowers,
fruits and seeds.
 Microsporogenesis
It refers to the formation of microspores or pollen grains inside the
microsporangium.
Sporogenous tissue The Sporogenous tissue undergo
(diploid-2n)
meiotic divisions (I and II) to form
microspore tetrads (4 microspores)
Tube/Vegetative
Meiosis
Cell which are haploid (n).

Generative Cell These microspores mature to form
pollen grains (male gametes).

Pollens or microspores are very tiny
round structures. After the formation,
they dry up and become powdery and
Each microspore will develop into are liberated from the anther to the
pollen grain containing the generative environment.
nucleus and tube nucleus.
Megasporogenesis & Megagametogenesis

During megasporogenesis, the
megasporocyte (diploid) divides
meiotically to form four megaspores.
Out of these four megaspores, three
degenerates and only one remains
functional.

Then, the functional megaspores
divide mitotically to form 2-celled
embryo sac.
Further subsequent mitotic division
finally forms the embryo sac.
 The Embryo Sac
Six of the eight nuclei are surrounded by cell walls and
organized into cells.
The two cells (polar nuclei) are situated in the large central cell.

Three cells at the micropylar
end forms the egg apparatus.
It is made up of two synergids
and one egg cell.

Three cells at the chalazal
end is known as antipodals.

The matured embryo sac is 7 celled and 8 nucleated.
 Pollination
- It is the transfer of the pollen from the stamen of a plant to the
stigma of the flower.

Upon reaching the stigma of the flower,
pollen grain germinates. It then absorbs
nutrients secreted by the stigma and
the pollen tube begins to grow.

The tube nucleus remains close to the
growing tip of the pollen tube and
eventually disintegrates.

Meanwhile the generative nucleus
divides into two male gametes or nuclei
and will enter the embryo sac through
the pollen tube.
 Methods of Pollination
a. Self-Pollination (augamy)
- It is the transfer of pollen from the stamens to the pistils within
the same flower or between flowers in the same plant.
- Examples of self-pollinated crops: bunch grapes, peach, plum,
strawberry, orange, lemon, tomato, pepper, eggplant, legumes
and snapdragon.

b. Cross Pollination (heterogamy)
- It is the transfer of pollens from the stamens of a flower of one
plant to the pistil of the flower of another plant.
- Examples: apple, peach, cabbage, lettuce, onion, carrot,
cucumber, aster, azalea, zinnia, etc.
 Fertilization
Fertilization is the fusion of the nuclei of male and female
gametes to form a zygote.

The generative One male sperm cell fuses The second male sperm
nucleus divides with the egg cell and forms cell fuses with the two polar
mitotically producing the fertilized egg or zygote. nuclei and forms the
two haploid sperm The zygote develops into endosperm nucleus, which
cells/nuclei. embryo. will eventually develops
into endosperm of the
seed.
 Double Fertilization
In flowering plants, two sets of
fertilization takes place.
✓ One occurs between the first
sperm nucleus and egg cell;
✓ The other takes place between
the second sperm nucleus and
the 2 polar nuclei.
Thus, fertilization in flowering
plants is referred to as double
fertilization.
❖ If, for some reasons the egg cell fails to be fertilized, the synergids (also
called help cells) assume the role of the egg cell. In case fertilization
occurs between the egg cell and the male nuclei, the synergids
disintegrate soon after fertilization. The antipodal cells also get
disorganized, sometimes even before fertilization.
 Summary of Double Fertilization in Plants

After fertilization, the egg cell
surrounds itself with a cell
wall and is known as oospore
 Fate of floral parts after fertilization

Floral Part Fate after fertilization
a. Sepals*, petals & stamens Will wither and drop off
b. Ovary Becomes the fruit
i. Ovary wall Fruit wall
ii. Ovule Seed
iii. Integuments Seed Coat (Testa)
iv. Fertilized egg Embryo

*The sepals may either fall off or may remain intact in a dried
and shriveled form. Guavas show such dried sepals very
clearly. In eggplant, it remains.
 III. SENESCENCE

Senescence refers to the erosive process that accompany
ageing prior to death.

Forms of Senescence
a. Whole plant/complete senescence
It is the ageing and death of the entire plant except for
seeds.
b. Organ /Partial senescence
The deterioration and death of plant organs such as leaves,
fruits and flowers.
 SEED DORMANCY

Seed dormancy is a condition wherein the seed is viable but
fails to germinate even in the presence of favourable
environmental conditions imposed upon it.

The ability of the seeds to delay their germination until the
time and place are right is an important survival mechanism
in plants.

Seed dormancy could be due to physical causes,
physiological causes and due to double dormancy.
 Types of Seed Dormancy
1. Physiological or Internal dormancy
The failure of the seed to germinate due to inhibitors or
substances that blocks the germination process.
This can be caused by, immature embryo or presence of
chemical inhibitors such as ABA (Abscissic Acid) and
Coumarin.
2. Physical Dormancy
This is caused by hard impervious seed coats that prevents
the imbibition of water and the entrance of oxygen.
3. Double Dormancy
Both physical and physiological blocks are present in a seed
and can only be broken by exposing it to cold temperature.
 How to break physical dormancy
1. Stratification
It is the practice of exposing imbibed seeds to cool or warm
temperature conditions for a few days prior to germination in
order to break dormancy.
Types:
a. Warm Stratification
Moist seeds are stored under 15-250C.
This promotes germination as a result of microbial
decomposition of the seed covering.
b. Cold Stratification
Moist seeds are stored under 5-100C.
The stratification media are moist soil, sand and peat,
vermiculite.
…….how to break physical dormancy
2. Scarification
This refers to the alteration of seed coat to render it permeable
to gas and water exchange.

Methods:
a. Mechanical methods
It involves the use of abrasive materials to wear out the seed
coat such as sand papers, iron, etc.
b. Hot water treatment
Seeds are subjected to about 170- 212 deg. F to soften the
seed coat and renders it permeable to gas and water.
c. Chemical Scarification
It involves the use of Sulphuric acid to scarify the impervious
seed coat.
…….how to break physical dormancy

3. Dry Storage
- This is necessary for seeds that will not germinate
immediately after harvest.

4. Embryo culture
- The aseptic growth of the excised embryo in an artificial
media.
 Seed Viability
Seed viability is the measure of how many seeds in a lot are
alive and could develop into plants that will reproduce under
appropriate field conditions.
Determination of seed viability
1. Germination tests
2. Biochemical tests
- quicker but are not accurate as the germination test
 Maintaining Viability of Recalcitrant Seeds

Recalcitrant seeds are those that tolerate only slight
desiccation after harvest, if at all, and consequently are usually
sensitive to chilling temperatures as well.

a. Since recalcitrant seeds cannot withstand much drying, they
should be kept well when stored mixed with sawdust
moistened to about 10% at relative temperature (7-100C).

a. Moistened charcoal could also be used and a combination of
half-fine charcoal and sterilized sawdust is a better medium
combined with a low temperature of 7-100C.
 Maintaining Viability of Orthodox Seeds
Orthodox seeds are seeds that have the ability to endure
extreme freezing and drying conditions during ex situ
conservation.
a. Decreasing the moisture of the seed by proper drying.
b. Storing the seeds at low temperature.
c. Keeping low the oxygen in the immediate vicinity of the seeds.
d. After drying, seeds are kept in air tight containers, possibly with
desiccants – a chemical which absorbs moisture (silica gel,
calcium chloride, charcoal).
Harrington’s Thumb Rules: (1) For each 1% decrease in moisture content,
the storage life of the seed is doubled and (2) For each 10°F (5.6 °C)
decrease in storage temperature, the storage life of a seed is doubled.
 Seed Storage

✓ If seeds are to be kept in a long period, coat them with
fungicides to protect them from microorganisms.

✓ Containers for ordinary seeds range from simple polyethylene
to a more sophisticated cellophane, aluminum and vacuum
sealed cans.

✓ For home storage, cans or bottles can be used provided that
they can be tightly sealed. Sealing the lids with paraffin will
keep the bottle or cans ait-tight.
OTHER CONCEPTS RELATED TO PLANT GROWTH

LIEBIG’S LAW OF MINIMUM

THE LAW OF LIMITING FACTORS

THE LAW OF DIMINISHING RETURNS
 LIEBIG’S LAW OF MINIMUM
“If one of the essential plant nutrients is deficient, plant growth will
be poor even when all other essential nutrients are abundant”.
Formulated by the German scientist Justus von Liebig in the 19th
century.
Example: When fertilizer prices — especially of
nitrogen (N) and phosphate (P2O5) products —
are high, some growers reduce or even eliminate
applications of micronutrient or secondary
nutrient fertilizers that provide balanced
potassium (K), magnesium (Mg) and sulfur (S).
But von Liebig’s Law tells us that if a soil is
deficient in, say, Magnesium, yields will be
depressed regardless of how much N-P-K
product you apply.
 THE LAW OF LIMITING FACTORS
“The rate of a physiological process will be limited by the factor
which is in shortest supply. Any changes in the level of
the limiting factor will affect the rate of reaction”.
Example: Photosynthesis requires basic components like water, sunlight in proper
intensity, chloroplast, temperature, carbon dioxide and chlorophyll present in certain
required amount. Any of these factors if present in scarcity will affect the rate of
photosynthesis.
 THE LAW OF DIMINISHING RETURNS
“If one input in the production of a commodity is increased while
all other inputs are held fixed, a point will eventually be reached
at which additions of the input yield progressively smaller, or
diminishing, increases in output”
It is also called principle of diminishing marginal productivity.
 PLANT MOVEMENTS
TROPISM
It is a biological phenomenon, indicating growth or turning
movement of a biological organism, usually a plant, in
response to an environmental stimulus.

NASTIC MOVEMENTS
Nastic movements are plant movements that occur in
response to environmental stimuli but unlike tropic
movements, the direction of the response is not dependent
on the direction of the stimulus.
 Tropic Movements

1. Phototropism
It is the movement of plant
organs in response to light.
Auxins are responsible for
phototropism.
It could be positively phototropic
(stems generally show a
curvature toward the source of
light) or negatively phototropic
(roots which grow away from the A stem manifesting
source of light). positive phototropism as it
bend towards the source
of light (window).
………….. tropic movements

2. Geotropism or Gravitropism
It is the unidirectional response of plants to
gravitational pull.

a. Positive geotropism
The organ grows downward toward the direction
of the pull of gravity (center of the earth). e.g.
The primary root
b. Negative geotropism
The organ moves upward in opposite direction to
the pull of gravity. e.g. The shoots
c. Diagravitropic
The organ, grows perpendicular to the pull of
gravity.
e.g. Stolons and rhizomes
………….. tropic movements

3. Chemotropism
This is the plant movement in
response to a chemical substance.
Example: Plant roots elongate
towards a supply of essential mineral
nutrients.

4. Hydrotropism
The growth of the plant parts (i.e. the
roots) in response to moisture or water.
The root exhibits positive hydrotropic
response by moving towards the water
source.
Note: Hydrotropism in roots is stronger than
root gravitropism
………….. tropic movements

5. Heliotropism
This is also called “solar tracking”.
It is a plant movement in which the organs of plants track the
sun across the sky.
The responding organ may be oriented perpendicular, parallel,
or obliquely to the sun’s rays.

Compass plant
(Silphium laciniatum)
Sunflower
(Helianthus annuus)
………….. tropic movements

6. Thigmotropism
It results to the curvature and the coiling of tendrils or entire
stems on supports. It also occurs in other plant organs such as
leaves, petioles, and roots.
The curvature is due to differential growth, that is, more cell
division and elongation at the outer than at the inner side in
contact with the support.

Examples: The tendrils of
Momordica charantia (Ampalaya),
Phaseolus vulgaris (Beans),
Sechium edule (Chayote)
 Nastic Movements

1. Epinasty
It is the bending of an organ,
such as petioles, leaves, and
peduncles, toward the ground
not due to gravity.
The bending response is due
to higher rate of longitudinal
growth at the upper than at
the lower side of the organ.
……nastic movements
2. Nyctinasty
The sleep movement (opening and closing) of plant organs,
such as leaves and flowers, due to day and night periods of
daily rhythm and change in temperature.
Photonastic (caused by change in light intensity) and
thermonasty (caused by change in temperature)

Photonastic movement in Night Jasmine Thermonastic movement in
plants as in closes its flower by night and Rhododendrons as it closes its leaves at
opens it by day. low temp and opens at high temperature.
……nastic movements

3.Seismonasty
This is the movement in plants in response to touch as well
as other forms of physical contact or mechanical disturbance
such as shaking, wounding, wind, raindrops, and intense heat
or burning.
In the case of the sensitive plant (Mimosa pudica), a leaflet,
leaf, or group of leaves rapidly folds and bends in response to
the external stimulus.
 ……nastic movements

4. Thigmonasty or haptonasty
These movements are exemplified by
the closing of the insect-eating plant
venus flytrap (Dionaea muscipula) and
the bending of the glandular hairs of
sundew (Drosera sp.) as a result of
contact with an insect.

The leaves of a sundew are covered with
long, nectar-tipped tentacles which traps
the insect that stops for a sip. The
struggles of an insect causes the leaf to
slowly curl around its trapped prey. They
Sundew also cue the leaf to produce digestive
You can't fool a sundew. Non-nutritious matter that enzymes that dissolve the captured insect,
falls onto it may cause a leaf to begin to curl, but it and the plant absorbs the liquid, nutrient-
soon rejects and releases the offending annoyance. rich soup.