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THE NATURE AND
COMPOSITION OF
PLANTS
QUEENEEVI T. QUIJANO, R.A, MSA
-The smallest structure in the universe
capable of growth and reproduction. Plant Cell
-The basic unit of every living organism.

-An autonomousliving system capable of
independent existence and propagation.

-fundamental morphological unit of plant.
Plant cells are the building blocks of
plants. Photosynthesis is the major
function performed by plant cells.
Photosynthesis occurs in the
chloroplasts of the plant cell. It is the
process of preparing food by the
plants, by utilizing sunlight, carbon
dioxide and water.
 Plant cell has three main components:
Cell wall Cytoplasm Nucleus

The cell wall surrounds the The cytoplasm is The nucleus controls and
plasma membrane of plant responsible for holding the regulates the activities of
cells and provides tensile components of the cell and the cell (e.g., growth and
strength and protection protects them from metabolism) and carries the
against mechanical and damage. It stores the genes, structures that
osmotic stress. molecules required for contain the hereditary
cellular processes and is information.
also responsible for giving
the cell its shape.
CELL WALL CELL WALL

provide structural strength and support,
and also provide a semi-permeable
surface for molecules to pass in and out
of the cell.
 CYTOPLASM
Responsible for holding the components CYTOPLASM
of the cell and protects them from
damage. It stores the molecules required
for cellular processes and is also
responsible for giving the cell its shape.
 CYTOPLASM
PLASMALEMMA/PLASMA MEMBRANE MITOCHONDRIA

In plants, as in all organisms, the plasma a membrane-bound organelle that is the
membrane serves two main roles: (1) the site of energy production in cells.
transport of solutes, both into and out of each
cell, and (2) sensory transduction, i.e., the
PLASTID
sensing and initiation of the cellular response
to changing environmental conditions. double-membrane organelle found in the
cells of plants and are the main sites of
photosynthesis
ENDOPLASMIC RETICULUM
a network of membranes inside a cell
through which proteins and other
molecules move

GOLGI APPARATUS

responsible for transporting, modifying, and
packaging proteins and lipids into vesicles for
delivery to targeted destinations.
 CYTOPLASM
CYTOSKELETON

a structure that helps cells maintain their
VACUOLES
shape and internal organization, and it also crucial for growth and development and
provides mechanical support that enables cells
has a variety of functions, including
to carry out essential functions like division and
storage and transport, intracellular
movement.
environmental stability, and response to
injury. Depending on the cell type and
growth conditions, the size of vacuoles is
MICROBODIES highly dynamic.

It participate in numerous cell
biochemical processes. The breakdown of
lipids, amino acids, alcohol, etc. is made RIBOSOME
possible by the enzymes found in
Organelles that help in protein synthesis.
microbodies. They participate in plants'
Protein is required for many cell activities
photorespiration.
such as damage repair and other
chemical processes.
 NUCLEUS
Store DNA or hereditary information NUCLEUS
required for cell division, metabolism and
growth.
The Anatomical Regions of a Plant Body

THE PLANT BODY IS COMPOSED OF THREE
PRIMARY ORGANS:

Leaf: Primarily responsible for photosynthesis,
the process by which plants convert light energy
into chemical energy.

Stem: Provides support for the plant, facilitating
the transport of water, nutrients, and
photosynthetic products between roots and
leaves.

Root: Anchors the plant in the soil and absorbs
water and minerals necessary for growth.
Angiosperms: The Dominant Plant Group

ANGIOSPERMS (FLOWERING PLANTS)

Consist of approximately 250,000
species and dominate Earth's Fruit trees, including mango, apple,
vegetation. banana, peach, cherry, Orange, and
Pear, often show flowers before they
Seeds of angiosperms contain an bear fruits, and the pollination process is
embryo and cotyledons (seed leaves), generally carried out by agents such as
which are nourished by the endosperm bees.
and protected by a seed coat.
Grains, including rice, corn, and wheat,
are also examples of Angiosperm.
Seed Germination and Growth

Seeds germinate under favorable
conditions, including adequate
moisture, appropriate temperature,
sufficient oxygen, and sometimes light.

During germination, the root (radicle)
and shoot (plumule) emerge from the
embryo.

Seedling growth is driven by cell division Germination is specifically the process a
in meristematic tissues, which are seed goes through as it breaks
regions of active cell division. dormancy and initiates growth.

Growth is an irreversible increase in size.
Plant Development
As the seedling matures through the juvenile
stage, it eventually produces flowers and fruits
following pollination and fertilization.

Fruits develop from the fertilized flowers and
contain seeds, thereby completing the plant’s
life cycle.
 Plant Tissues
SIMPLE TISSUES COMPLEX TISSUES

The simple tissues (tissues with uniform cells) are complex tissues (tissues with more than one type
composed of the same type of cells. of cells) are composed of more than one type of
cell, these are unique to plants.
Parenchyma, Collenchyma, and Sclerenchyma are
the three types of simple permanent tissues. Xylem and Phloem are types of complex tissues.
 PLANT ORGANS

Organs: Structures composed of several
PLANT SYSTEMS
tissues that perform distinct functions.
Examples include leaves, stems, and Systems: Groups of interacting organs
roots. that work together as a functional unit in
the life of the plant. For instance, the
vascular system includes both xylem and
SIMPLE TISSUES
phloem tissues, which transport water,
This structure allows plants to efficiently nutrients, and food throughout the
perform essential functions such as plant.
photosynthesis, nutrient transport,
support, and reproduction, ensuring
their growth, survival, and propagation.
 MERISTEMATIC
TISSUES
These tissues consist of actively dividing cells that
contribute to plant growth. They are found in
regions of the plant where growth can take place.
Apical Meristems: Located at the tips of roots
and shoots, responsible for primary growth
(lengthening of the plant).
Lateral Meristems: Found in the vascular and
cork cambium, responsible for secondary
growth (increase in thickness or girth of the
plant).
Intercalary Meristems: Located at the base of
leaves or internodes, particularly in grasses, and
contribute to regrowth.
 PERMANENT
TISSUES

Group of cells that have lost the ability to
divide and have reached a stable and
mature state. These cells are specialized
for specific functions and can be further
classified into various types based on
their structure and role. Permanent
tissues are crucial for the functioning,
growth, and support of the plant.
 TYPES OF PERMANENT TISSUES

Simple Permanent Tissue: Composed of similar types of Complex Permanent Tissue: Composed of different types
cells, these tissues perform basic functions. of cells that work together to perform a specific function.

Parenchyma: These are living cells with thin cell walls Xylem: Responsible for the transport of water and
and large central vacuoles. They are involved in storage, minerals from the roots to the rest of the plant. Xylem is
photosynthesis, and wound repair. composed of tracheids, vessel elements, xylem fibers,
and xylem parenchyma.
Collenchyma: These cells have thicker cell walls and
provide flexible support to the plant. They are often found
in regions of the plant that are still growing. Phloem: Transports the products of photosynthesis, such
as sugars, from the leaves to other parts of the plant.
Sclerenchyma: These cells have thick, lignified walls and Phloem consists of sieve tube elements, companion cells,
are usually dead at maturity. They provide rigid support phloem fibers, and phloem parenchyma.
and strength to the plant. Sclerenchyma can be further
divided into fibers and sclereids.
Functions of Permanent Tissues
Parenchyma: Functions include storage of nutrients and water,
photosynthesis in chlorenchyma cells (a type of parenchyma containing
chlorophyll), and healing and repair of plant tissues.
Collenchyma: Provides flexible structural support to growing parts of the
plant such as young stems and leaves.
Sclerenchyma: Provides mechanical strength and rigidity to mature parts
of the plant, such as the bark and seed coats.
Xylem: Facilitates the upward movement of water and dissolved minerals
from the roots to the aerial parts of the plant. It also provides structural
support.
Phloem: Distributes the products of photosynthesis from the leaves to
other parts of the plant, supporting growth and development.
Plant tissue systems are organized into three major types, each
responsible for different aspects of the plant's structure and function.
These tissue systems are:
Dermal Tissue System:
Function: The dermal tissue system forms the outer protective
covering of the plant. It serves to protect the plant from mechanical
injury, pathogens, and water loss.
Components:
Epidermis: A single layer of cells covering the younger parts of the
plant, often coated with a waxy cuticle to reduce water loss.
Periderm: Found in woody plants, it replaces the epidermis in older
regions. The periderm includes the cork, cork cambium, and
phelloderm.
Specialized Structures:
Stomata: Pores flanked by guard cells that control gas exchange.
Trichomes: Hair-like structures that can reduce water loss and
provide protection against herbivores.
Ground Tissue System:
Function: The ground tissue system makes up the bulk of the plant
body and is involved in photosynthesis, storage, and support.
Components:
Parenchyma: The most common type of ground tissue, these cells
are involved in photosynthesis, storage, and tissue repair. They
have thin cell walls and large vacuoles.
Collenchyma: These cells provide flexible support for growing
parts of the plant. They have thicker cell walls compared to
parenchyma.
Sclerenchyma: These cells provide rigid support and strength to
the plant. They have thick, lignified cell walls and can be found as
fibers.
Vascular Tissue System:
Function: The vascular tissue system is responsible for the
transport of water, nutrients, and food throughout the plant.
Components:
Xylem: Transports water and dissolved minerals from the roots
to the rest of the plant. It consists of tracheids, vessel elements,
fibers, and parenchyma cells.
Phloem: Transports the products of photosynthesis (sugars)
from the leaves to other parts of the plant. It consists of sieve
tube elements, companion cells, fibers, and parenchyma cells.

Each of these tissue systems is integral to the plant's growth,
development, and survival, contributing to its overall function and
adaptation to its environment.
ROOTS
Regions of the Root:
Root cap – protects the tender apex (absent
in aquatic plants).
Region of cell division – 1 to few mm above
the root cap; have small cells with thin walls,
dense with protoplasm; undergo repeated cell
division (meristematic region).
Region of elongation – lies above
meristematic region; extends to 1-5 mm;
undergo rapid elongation and enlargement;
responsible for growth in length of the root.
Region of maturation – lies above the
meristematic region of elongation, this region
produces root hairs.
Types of Roots:

1. Tap root system
primary root grows vertical downward.
branches grow downward or horizontally outwards
Functions.
Functions: absorb water, mineral, salts from soil,
anchorage.

2. Adventitious root system
Roots that grow from any part of the plant body other than
radicle.

3. Fibrous root system
In monocots (with all adventitious roots).

4. Foliar root system
From leaves mainly petiole or vein (spontaneous or due to
injury).
Types of stems:
a. bulb - short, erect underground stem.
b. culm - flowering stem of grasses and sedges.
c. Offset - like runner originates from leaf axil as a short and thickened branch away
from the mother plant.
d. rhizome - horizontal underground stem.
e. runner or stolon - indeterminate aboveground stem with internodes and new
plantlet at the tip.
f. sucker - shoot arising below the ground from old stem.
g. tendril - slender coiling branch for climbing.
h. tiller - shoot produced from the base of the stem or culm.
i. tuber - thick storage underground stem.
j. corm - enlarged solid fleshy base
Leaves are indeed fascinating structures essential for the survival of
plants.

Functions of Leaves:

Food manufacture (Photosynthesis): Leaves contain chlorophyll,
which captures sunlight to convert carbon dioxide and water into
glucose, providing energy for the plant.

Exchange of gases: Leaves facilitate the exchange of oxygen and
carbon dioxide with the atmosphere, crucial for both photosynthesis and
respiration.

Evaporation of water (Transpiration): Through tiny pores called
stomata on the leaf surface, water evaporates, helping to regulate the
plant's temperature and transport nutrients.
PARTS OF A LEAF
PARTS OF A FLOWER
Complete Flower - has all four
parts of the flower (sepals, petals,
pistil and stamen).
Incomplete Flower - A flower
lacking sepals, petals, pistil or
stamen
 SEEDS a ripened ovule which when shed from the parent plant consist
of embryo and stored food supply both of which are enclosed
in a seed coat or covering.

Sexual propagation involves the union of the pollen (male) with the egg (female)
to produce a seed. The seed is made up of three parts:
the outer seed coat, which protects the seed;
the endosperm, which is a food reserve;
the embryo, which is the young plant itself.

When a seed is mature and put in a favorable environment, it will germinate
(begin active growth).
 SEEDS

Dicotyledon - embryo lies within an axis of two cotyledons.
Monocotyledon - consist of seed coat, endosperm and embryo.
 SEEDS

PARTS OF A SEED
 SEEDS

PARTS OF A SEED
 SEEDS

TYPES OF A SEED
Seeds can be classified based on their storage behavior into three main categories:
orthodox, intermediate, and recalcitrant seeds. Each type has specific characteristics
that affect how they are stored and their longevity.

1. Orthodox Seeds
Orthodox seeds can be dried to low moisture contents (typically around 5-7%) and
stored at low temperatures for extended periods without losing viability. These seeds
enter a state of dormancy and can withstand adverse conditions, making them suitable
for long-term storage in seed banks.
Characteristics:
Low moisture tolerance: Can be dried to low moisture levels.
Long-term viability: Remain viable for many years when stored correctly.
Storage conditions: Prefer cool and dry environments.
Examples:
Cereal grains: Wheat, rice, maize.
Legumes: Beans, peas.
Vegetables: Tomato, lettuce, cabbage.
 SEEDS

TYPES OF A SEED
2. Intermediate Seeds
Intermediate seeds fall between orthodox and recalcitrant seeds in terms of
their storage behavior. They can tolerate some drying but not to the extent
of orthodox seeds, and they are somewhat sensitive to low temperatures.
These seeds require careful handling to maintain their viability over time.
Characteristics:
Moderate moisture tolerance: Can be dried, but not to very low levels.
Shorter viability: Do not store as long as orthodox seeds.
Sensitive to low temperatures: Cannot withstand freezing conditions
well.
Examples:
Coffee
Citrus
Papaya
 SEEDS

TYPES OF A SEED
3. Recalcitrant Seeds
Recalcitrant seeds cannot withstand drying below relatively high moisture
levels and are very sensitive to low temperatures. They must be kept moist
and warm to remain viable, making them challenging to store for long
periods. These seeds often germinate quickly and have short-lived viability.
Characteristics:
High moisture requirement: Cannot be dried below certain moisture
levels.
Sensitive to drying and cold: Lose viability quickly if dried or exposed to
low temperatures.
Short viability period: Must be planted soon after harvest.
Examples:
Tropical fruits: Mango, lychee, avocado.
Some nuts: Chestnut, coconut.
Certain trees: Oak, willow.
 SEEDS

TYPES OF A SEED
Summary of Storage Recommendations:
Orthodox Seeds: Store in cool, dry conditions; ideal for seed
banks.
Intermediate Seeds: Store at moderate moisture levels and
avoid freezing; moderate storage lifespan.
Recalcitrant Seeds: Keep moist and warm; plant soon after
harvest.

Understanding the type of seed is crucial for proper storage and
ensuring their viability for future planting.
 Fruits
It is a mature, ripened ovary.
Contain the seed (ripened ovules) and pericarp (the tissue that surrounds
the seed)
Simple Fruits
Simple fruits develop from a single ovary of a single flower. They can
be either fleshy or dry.
Aggregate Fruits
Aggregate fruits develop from a single flower with multiple ovaries
(multiple carpels). Each ovary matures into a small fruitlet, and together
they form a cluster on a single receptacle. Examples include:
Raspberry
Blackberry
Strawberry (note: in strawberries, the actual fruits are the tiny seeds
on the surface, each originating from a separate ovary).
Multiple Fruits
Multiple fruits develop from an inflorescence, a group of flowers. Each
flower in the inflorescence produces a fruit, and these mature into a single
mass. Examples include:
Pineapple
Fig
Mulberry
Summary
Simple fruits: Develop from a single ovary of a single flower (e.g.,
tomatoes, peas).
Aggregate fruits: Develop from a single flower with multiple ovaries
(e.g., raspberries, blackberries).
Multiple fruits: Develop from multiple flowers in an inflorescence
(e.g., pineapples, figs).
These classifications help in understanding the development and structure
of different types of fruits.
 FLESHY FRUITS
fruits with a soft, thick pericarp (fruit wall) at maturity. They are typically
classified based on the structure and development of their pericarp.
The five main types of fleshy fruits are:

Berry: A berry is a simple, fleshy fruit in which the entire pericarp is soft
and edible. Examples include tomatoes, grapes, bananas, and
blueberries.

Drupe: Also known as a stone fruit, a drupe has a thin exocarp (skin), a
fleshy mesocarp, and a hard, stony endocarp (pit) that encloses a
single seed. Examples include peaches, cherries, olives, and plums.
 FLESHY FRUITS
Pome: Pomes are fruits produced by flowering plants in the
subtribe Malinae of the family Rosaceae. They have a core
containing several small seeds, surrounded by a fleshy edible
layer. Examples include apples and pears.

Hesperidium: This is a type of berry with a leathery rind and
partitions between the sections of fleshy fruit. Examples include
citrus fruits such as oranges, lemons, limes, and grapefruits.

Pepo: A pepo is a type of berry with a hard, thick rind, typically
found in the gourd family (Cucurbitaceae). Examples include
cucumbers, pumpkins, watermelons, and squashes.
 DRY FRUITS
Dehiscent Fruits
Fruits that split open at the time of maturity are referred to
as dehiscent fruits. They open naturally along their line of
weakness to shed their seeds. There are three types of
dehiscent fruits:
Follicle: A dry dehiscent fruit formed from 1 carpel that
opens only at one side. E.g, peony and milkweed
Legume: A dry dehiscent fruit formed from 1 carpel that
opens on both the sides. E.g, beans and peas
Capsule: It is a dry dehiscent fruit that is formed from
several carpels. E.g, orchid
 DRY FRUITS
Indehiscent Fruits
Fruits that do not split open to release their seeds are
referred to as indehiscent fruits. They do not have a natural
line of weakness to split apart. They are of five major types:
Achene: It is a dry indehiscent fruit that contains a
single seed. The single seed is attached only at one
point to the fruit wall. E.g, sunflower
Nut: A dry indehiscent fruit that has a thick and hard fruit
wall. E.g, hazel, walnut
 DRY FRUITS
Samara: A dry indehiscent fruit in which part of the fruit
wall grows out into a wing. It can be single or double
seeded. E.g, maple
Grain: A one seeded dry indehiscent fruit in which the
fruit wall and the seed coat are fused. E.g, corn, wheat
Schizocarp: It is a fruit that is formed from several
carpels, and at maturity each carpel separates to form a
distinct indehiscent fruit. E.g, dill
 Pericarp
Definition: The pericarp is the entire fruit wall that develops
from the ovary wall after fertilization. It surrounds the seed(s)
and is composed of three layers: the exocarp, mesocarp, and
endocarp.
Function: Protects the seed(s) and aids in their dispersal.

Exocarp
Definition: The exocarp is the outermost layer of the pericarp.
Characteristics: It forms the skin or peel of the fruit. In some
fruits, the exocarp is thin and delicate (e.g., grapes, tomatoes),
while in others, it is thick and tough (e.g., watermelon, oranges).
Function: Provides protection and may contribute to the fruit's
color and texture.
 Mesocarp
Definition: The mesocarp is the middle layer of the pericarp.
Characteristics: This layer is typically fleshy and juicy, but it can also
be fibrous or dry depending on the type of fruit. The mesocarp is often
the edible part of the fruit.
Function: Stores nutrients and water, contributing to the fruit's flavor,
texture, and overall appeal.
Endocarp
Definition: The endocarp is the innermost layer of the pericarp.
Characteristics: The endocarp can be hard and stony (as in drupes
like peaches and cherries), or it can be papery or membranous (as in
pomes like apples and pears).
Function: Encloses and protects the seed(s). In some fruits, the
endocarp helps facilitate seed dispersal.
Summary
Pericarp: The entire fruit wall, consisting of the exocarp, mesocarp, and
endocarp.
Exocarp: The outer skin or peel of the fruit.
Mesocarp: The middle, often fleshy and edible layer.
Endocarp: The inner layer that directly surrounds the seed(s).
THANK YOU
AND
GOD BLESS