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Botany
Mondays & Wednesdays
Lecture: 8:30-10:00 AM
Quezon Hall Room 211
Lab: 10:00 AM-1:00 PM
Rizal Hall Room 106

By: Carielle Nicole C. Montilla
Teacher: Sir Ryan Odio
 Botany
BOTANY so they prefer to grow in dark or shady
 Botany is the scientific study of places
plants. This definition requires an  If exposed to the sun they will
understanding of the concepts “ plants” desiccate (it means to remove
and “ scientific study.” moisture, or become completely dry)
 Botany starts when the human and eventually die because to
being starts to establish & appreciate reproduce they need water or moisture
the role of plants in our lives.  Only needs small amounts of light
TWO TYPES OF PLANTS for photosynthesis
(1) Vascular Plants  Since body is small less sugar is
(2) Nonvascular Plants needed
VASCULAR PLANTS USES OF PLANTS
 These are higher form of plants (1) Source of medicine
 Plants have vascular tissues – (2) Source of food
xylem and phloem which are a (3) Source of clothing
complex system of transport vessels SOURCE OF MEDICINE
 Almost all plants are vascular. One  Herbal medicine
type of plant that is vascular is
flowering plants.
NONVASCULAR PLANTS
 Nonvascular plants are also known
as Bryophytes, and one prime example
is moss.
 These plants from the name has no
vascular tissues, meaning there is no
xylem & phloem
 One good example are Upas trees
 Small (usually only 5-8 cm tall), (Antiaris toxicaria), which are relatives
non-vascular, non-woody of the common fig tree, flourish in the
 It is small because it has no vascular jungles of Java and some of some
tissues to transport nutrients around. neighboring islands
 Gametophyte dominates life cycle  It is poisonous from the name itself,
has leaf-like, stem-like, & root-like “ toxicara”. This was used by natives
parts for poison arrows.
 Lacks essential/vegetative organ of  Later on the tree was found to
the plants actually treat cancer
 Usually in wet habitats because
It has a flagellated sperm that require
water to reach eggs
Made up of simple cells & tissues &
no organ
 It has no cuticle to protect themself
from UV rays (will cause loss of water)
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 In the picture are immature poppy
capsules that were gashed with a razor  Marijuana in some countries as well
blade. is illegal however countries in some
 Opium poppy is a drug that was states in the US, Netherlands it is legal
banned because of its addictive while others allow for medical
nature. purposes only
 However, it actually has medicinal The plant itself is not in the wrong,
value but the abusive use of it the human itself is in the wrong
(addiction) is prohibited by the because they are the ones abusing
government. these plants.
 Some countries allow the use of
opium as long as it is for medicinal
purposes while others don’t at all

 California coastal redwoods
 Tobacco Cigarettes are still legal in (Sequoia sempervirens). Coastal
the country despite their addictive redwoods may grow for thousands of
nature. This is due to the vast years and some may reach heights of
medicinal applications tobacco has nearly 100 meters (330 feet).
and the economic impact it will bring.  Red wood tree peculiar because it
 Since fully illegalizing tobacco will reaches at least 100m in height.
lead to a downturn in the economy, the  So how can water from the ground
country decided to go with the scare be transported to the tip of the tree
campaign instead. which is at least 100m tall?

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SOURCE OF FOOD  When we look at the inner part it is
 Caffeine in coffee is one good more complex than the outer parts
example however it is addictive when because it is older than the outer parts
you over use it like nicotine  As the plants grow older they
SOURCE OF CLOTHING become more complex
 Cotton for example is very rampant  After cells are produced by
in the textile industry meristems, the cells assume various
PLANT TISSUES shapes and sizes related to their
 Tissues are a group of cells of similar functions as they develop and mature.
structure and perform the same  Some tissues consist of only one kind
function. of cell, while others may have two to
(1) Meristematic Tissues several kinds of cells
(2) Simple Tissues (1) Apical Meristems
MERISTEMATIC TISSUES (2) Lateral Meristems
(3) Intercalary Meristems
APICAL MERISTEMS
 Apical meristems are meristematic
tissues found at, or near, the tips of
roots and shoots, which increase in
length as the apical meristems
produce new cells
The increase in length is called
Primary growth
 Three primary meristems, as well as
embryo leaves and buds, develop from
apical meristems.
 The three primary meristems that
give rise to primary tissues are:
(1) Protoderm
(2) Ground meristems
(3) Procambium
 Unlike animals, plants have PROTODERM
permanent regions of growth called  Give rise to the primary tissue called
meristems, or meristematic tissues, the epidermis of the plant
where cells actively divide GROUND MERISTEM
 Parts of the plant that are very  Gives rise to two primary tissues --
active in cell division due to the the pith & cortex in roots
addition of next set of cells to promote PROCAMBIUM
growth and development  Produces the primary xylem &
 Along the diff stages or points in a phloem, & the vascular cambium
planT body LATERAL MERISTEMS

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 Grasses and related plants have
neither a vascular cambium nor a cork
cambium.
 Instead, they have apical
meristems, and, in the vicinity of nodes
(leaf attachment areas), they have
other meristematic tissues called
 The vascular cambium and cork intercalary
cambium, are lateral meristems, which  Present in the base of leaves or
produce tissues that increase the girth internodes to increase the size of
of roots and stems. leaves
 Such growth is termed secondary  If you trim grass today it will grow
growth. back tomorrow unlike normal leaves
 Responsible for the increase in like gumamela which will retain how
diameter / girth of the stem or the you cut it the next day
sideways growth of the stem  The three primary meristems
 Reason for the difference in girth or produced are like that of apical
width of the tree of an acacia, which meristems
has lateral meristems that can  Tissue Differentiation
increase the diameter of the stem, and
Meristem Tissues produced
a coconut tree which has no lateral
 Protoderm Epidermis
meristems thus their stem cannot
Ground
increase its width only relies on cell  Ground tissues
Meristems
growth.
Primary
VASCULAR CAMBIUM  Procambium
vascular tissue
 Often referred as the cambium
 The vascular cambium also has SIMPLE TISUES
meristematic capabilities and it acts as (1) Parenchyma
secondary meristems to give rise to (2) Collenchyma
secondary tissues that primarily (3) Sclerenchyma
function in support and conduction. PARENCHYMA
 It gives rise to secondary xylem and  Parenchyma tissue is made of
phloem. parenchyma cells
CORK CAMBIUM Thin walled, pliable walls, irregular in
 Epidermis is replaced when the shape & flattened in cells
plant is older by the cork beneath it to They are more or less spherical in
prevent water from escaping from the shape when they are first produced,
body but when all the parenchyma cells
 Part of the Periderm or the armour push up against one another, their thin,
protecting the plant (outer covering) pliable walls are flattened at the points
of contact.
INTERCALARY MERISTEMS  Very simple & allow passage of
water & minerals
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 They mediate short distance
transport of materials through a large
extensive plasma membrane that
could hold numerous molecular pumps
COLLENCHYMA

 Irregularly shaped, the white part
due to the storage of carbohydrates
 In root crops like potatoes radishes,
carrots. The roots contain a lot of these
types of cells and they perform by Black part is the uneven cell wall
storing a lot of starch  Collenchyma cells like parenchyma
 Promote repair of damaged tissues cells, have living cytoplasm and may
(Capable of regeneration) remain alive a long time.
 Promotes photosynthesis because  Their walls generally are thicker and
may contain chloroplast more uneven in thickness than those of
 Can contain chemicals and crystals parenchyma cells
that could protect them for herbivores  Collenchyma cells often occur just
 Two examples of parenchyma beneath the epidermis
tissues:  Typically, they are longer than they
(1) Aerenchyma are wide, and their walls are strong.
(2) Chlorenchyma  Found in areas with minimal support
(3) Glandular Cells Thicker the cell wall the better it is for
(4) Transfer Cells support. Thus collenchyma cells are
AERENCHYMA better for support compared to
 Parenchymal tissue contains gas parenchyma cells
 Allows aquatic plants to float on  Found in parts of the plant that need
water minimal support: like nodes where
 The type of parenchyma tissue with leaves flowers and roots attach
extensive connected air spaces  The thin part of the cell wall allows
CHLORENCHYMA transport of materials while the thick
 Parenchyma cells that contain don’t but provide structural support
numerous chloroplasts (as found in instead
leaves) SCLERENCHYMA
GLANDULAR CELLS  Has thick tough secondary walls that
 Secrete nectar, fragrances, is normally impregnated with lignin
mucilage, resins, and oils.  Walls are thick enough to not allow
 These cells have greater amounts of passage of materials so most
dictyosomes and endoplasmic sclerenchyma cells are dead at
reticulum with lesser chloroplasts. maturity and function only for support
TRANSFER CELLS

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 Two forms of sclerenchyma occur:  The transportation of organic
(1) Mechanical Sclerenchyma material, water, and minerals up and
(2) Conducting Sclerenchyma down the plants is done by the
MECHANICAL SCLERENCHYMA complex tissues. Therefore, they are
(1) Sclereids also known as the Conducting and
(2) Fibers Vascular tissues.
SCLEREIDS  Two of the most common example
of complex tissues are xylem and
phloem tissue
EPIDERMIS
 Epidermis is a protective layer
covering plant organs
 Consists primarily of parenchyma or
Sclereids in the cross-section of a pear
parenchyma-like cell
 Also called stone cells  It also often includes specialized
 Short & isodiametric; typically dead cells involved in the movement of
at maturity water and gases in and out of plants,
 When u eat pears the sand-like or secretory glands, various hairs
gritty texture are due to sclereids, (trychome), cells in which crystals are
avocados on the other hand do not isolated, and others that greatly
have sclereids so they are smooth to increase absorptive parts of roots.
eat  Since made up of multiple types of
FIBERS cells it is complex
 Long; most of its types are dead and PERIDERM
the others that remain alive are  Bark of woody plants
involved in storage.  Mostly cork cells but some may
 For strength to support the tree and have parenchyma cells to repair
flexibility to allow it to sway in the wind damage
without breaking XYLEM
 Examples of plants with fibers are  A type of vascular tissue found in
Cotton, Abacca, Pineapple, Banana, plants that transport water and
etc. dissolved minerals from the roots to
CONDUCTING SCLERENCHYMA the rest of the plant while also
 These are sclerenchyma cells that providing physical support.
have tracheary elements,  Is made up of tracheary
 These include tracheids and vessel components, which are specialised
elements which can be found in the water-conducting cells.
xylem.  Xylem tissue is an important
COMPLEX TISSUES component of the "plumbing" and
 Consists of more than one type of storage systems of a plant and is the
cell which works together as a unit. chief conducting tissue throughout all

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organs for water and minerals overlapping with those of other
absorbed by the roots tracheids.
 Combination of parenchymal cells, PHLOEM
fiber (structural support to vessels),  Conduct dissolved floor materials
vessels, tracheids (main transport primarily sugar & other dissolved
element together w/ vessels) and ray solutes like the xylem but food
cells materials instead
 is made up of living tissue that
actively transports sugars to plant
organs such as fruits, flowers, buds,
and roots by using turgor pressure and
energy in the form of ATP
 Phloem tissue conducts dissolved
food materials (primarily sugars)
produced by photosynthesis
throughout the plant
 At the right are vessels (bigger)
 It is composed mostly of two types
while the left shows tracheid
of cells without secondary walls.
(narrower)
SIEVE TUBE
 Most plants have vessels because of
 The relatively large, more or less
their bigger size thus they are able to
cylindrical sieve tube members have
pump more water
narrower. more tapered companion
VESSELS
cells closely associated with them.
 Vessels have vessel elements as its
 Made up of sieve tube members
main unit
and together they form association w/
 Long tubes made up of individual
companion cells that are there to
cells called vessel elements that are
provide support
open at each end, with bar like strips of
 Like vessels are vessel elements
wall material extending across the
sieve tube has sieve tube members
open areas in some instances.
TRACHEID
 Spiral thickening
on the inside wall of a
tracheid
 Slender compared
to vessels
 Like vessel
elements, are dead at
maturity and have
relatively thick secondary cell walls,  The picture shows the longnitudinal
are tapered at each end, the ends view of part of the phloem of a black
locust tree (Robinia pseudoacacia)

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 The blue things in the picture are
sieve tube members that come
together to form a tube like structure
called the sieve tube
 Surrounding this tube is a bright
yellow colored companion cell. The
materials that the sieve tube cannot
produce is done by companion cells
instead
VASCULAR BUNDLES

 Are both your xylem and phloem GAMETOPHYTE
tissues and other smaller stuff like  This is the more dominant stage in
vessels, and parenchymal cells mosses because it is the visible stage of
 Tracheids since smaller are not plants and the sporophyte is simply
common in plants. attached to the gametophytes making
ALTERNATION OF GENERATIONS them dependent on this stage for
(1) Bryophytes nutrients
(2) Angiosperms  This starts from the protonema or
BRYOPHYTES protonemata (earliest form of a
 AKA Non-vascular plants or mosses gametophyte; thread-like chain of
 Made up of parenchyma cells only cells)
 They have no true stem, roots, and  The gametes (sex cells) of plants;
leaves however they still undergo thus, it is haploid (n)
photosynthesis The antheridium
Male
 Thus, they are considered as lower (1) pouch contains
gametophyte
forms of plants the sperm cells
 There are two generations: The single egg
Female
(1) Gametophyte (2) cell is in the
gametophyte
(2) Sporophyte archegonium
 Formed using meiosis so genes are
mixed together.
 When the egg is fertilized, it
becomes a zygote

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ANGIOSPERM BOTANY AS A SCIENCE
 The study of plants, called botany—
from three Greek words botanikos
(botanical), botane (plant or herb), and
boskein (to feed) and the French word
botanique (botanical)—appears to have
had its origins with Stone Age peoples
who tried to modify their surroundings
and feed themselves.

PLANT CELL

GAMETOPHYTE

FIBROUS ROOT TAPROOT

SIEVE TUBE MEMBERS AND
COMPANION CELLS

 Some plants have roots that, as well
as anchoring and absorbing, store
water or food, or perform other
specialized functions.

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FOUR REGIONS OF THE ROOT

STORAGE ROOTS

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 The zygote, then, undergoes mitosis ROOTS
and becomes an embryo, which will
soon develop into a sporophyte
SPOROPHYTE
 The spore-bearing part of the plant
(diploid)
 Totally dependent of gametophytes
ANGIOSPERMS
 Roots anchor plants to the soil
 Holds soil and water particles
together, which is why plants are
essential to prevent soil erosion,
especially trees with larger roots
 Roots anchor trees firmly in the soil
usually through an extensive branching
network that constitutes about one-
third (⅓) of total dry weight of the plant
 Also known as the flowering plants  The roots of most plants do not
(vascular) usually extend down into the earth
 Similarly, there are two generations: more than 3-5 meters (10-16 feet)
(1) Gametophyte  Those of many herbaceous species
(2) Sporophyte are confined to the upper 0.6 to 0.9
GAMETOPHYTE meter (2-3 feet)
 Unlike mosses, the gametophytes  Besides anchoring plants, roots
are totally dependent on the absorb water and minerals in solution
sporophyte generation for nutrition and mostly through feeder roots found in
protection in flowering plants the upper meter (3.3 ft) of soil.
 The gametophytes can be seen as  Some aquatic plants (e.g.
the flowers of angiosperms duckweeds and water hyacinths)
 Similar to the Bryophytes, the normally produce roots in water
gametophyte stage contains the  Epiphytes (non-parasitic plants that
“ gametes” of the plants. Therefore, it is grow suspended without direct contact
composed of haploid cells. with the ground e.g. orchids) produce
SPOROPHYTE aerial roots
 Again, this is the diploid stage.
 In Angiosperms, the sporophyte
generation is the more dominant stage.
Since, as mentioned earlier, the
gametophyte stage is dependent on
the sporophytes.  Flooding may occur due to
VEGETATIVE ORGANS OF PLANTS deforestation and converting farms for
(1) Roots non-farm uses (residential subdivisions
(2) Stem for example)
(3) Leaves
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 Roots of plants may vary in length ROOT SYSTEMS
for denser plants to compensate for the  Two Root Systems
structure of the plant (stability to hold it (1) Fibrous
in place) (2) Taproot
 Typically, the larger the canopy of FIBROUS ROOT SYSTEM
trees, the denser roots are.  Also known as the ADVENTITIOUS
 Aside from anchoring, roots of and the DIFFUSED root system.
plants absorb water and minerals  Made up of several slender roots
 However, only young roots are that grow from the stem
capable of absorption. Old roots  No taproot or primary root or
cannot absorb, instead, they are used radicle since it disappears at maturity
for the transport of minerals or  A large number of fine roots of
conduction. similar diameter develop from the
 These young roots are very delicate adventitious roots
and fragile. Thus, they can be damaged  Adventitious roots are those that do
during uprooting. This is why some not develop from another root but
plants would die after they are develop instead from a stem, leaf, or
uprooted. other plant parts.
 Young roots are microscopic, TAPROOT SYSTEM
meaning they can only be seen under a  Also called as the PRIMARY ROOT
dissecting microscope because they system.
are small and delicate.  A taproot is a larger root where all
HOW ROOTS DEVELOP other secondary or branch roots grow
 EMBRYONIC ROOT, also called as  It is only in old age that a plant can
the RADICLE, is the first root that have both a taproot system and fibrous
emerges from the roof of the seed root system
 When a seed germinates, the tiny  Example of plant that have both root
root like radicle, a part of the embryo systems:
(immature plantlet) within it, grows out (1) Lunok - when it is young it only has
and develops into the first root. a taproot. However, as it grows
 Fate of dicot and monocot radicles older, modified adventitious roots
are different. This is because the radicle emerge from the stem.
of monocot plants disappears and (2) Kamote- like lunok it also has a
there grows the fibrous or adventitious taproot system. However, the stem
roots. Meanwhile, the radicle of dicot would develop adventitious roots
plants grows and develops to become to reach for more nutrients. These
the taproot. roots would soon develop new root
 The radicle may develop into a thick crops (kamotes).
tapered taproot, from which thinner
branch roots arise, or many
adventitious roots may arise from the
stem, which is attached to the radicle
and continues with it.

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ROOT STRUCTURE or MUCIGEN, a digestive substance
that could help roots penetrate through
hard structures like soil or rocks.
 The mucigel also provides a medium
favorable to the growth of beneficial
bacteria that add to the nitrogen
supplies available to the plants
REGION OF CELL DIVISION
 Very active during mitosis
 Where growth take place,
specifically apical meristems
 In both roots and stems, there are
 There are four regions called from
three meristematic areas
the tip:
(1) Protoderm
(1) Root Cap
(2) Ground meristems
(2) Region of Cell Division
(3) Region of Elongation (3) Procambium
(4) Region of Cell Maturation PROTODERM
ROOT CAP  Gives rise to the outer layer
 Composed of a thimble-shaped (epidermis)
mass of parenchyma cells to provide GROUND MERISTEM
covering and protection to the tip of the  Gives rise to two primary tissues --
root because it is young, fragile, and the pith & cortex in roots
easily damaged by rocks, soil acidity,  Inside of the protoderm,
and bacteria infestation parenchyma cells of the cortex
 It is quite large and obvious in some PITH
plants, while in others, it is really  Like cortex, made up of
invincible parenchyma cells
 one of its function is to protect from  Grass roots and monocot plant
damage the delicate tissues behind it roots have pith but dicot plants do not.
as the young root tip pushes through  These are parenchyma tissues that
often angular and abrasive soil are present in the stems of dicot plants
particles, and form as a part of the wood
 The root cap has no equivalent in  They work to store carbohydrates
stems and repair damaged tissues in the
 Cells contain an organelle called
roots and the stem.
dictyosome (golgi apparatus) and this
PROCAMBIUM
is abundant in the root cap.
 Produces the primary xylem &
 The dictyosomes of the root cap’s
phloem, & the vascular cambium
outer cells secrete and release a slimy
 Appears as a solid cylinder
substance that lodges in the walls and
REGION OF ELONGATION
eventually passes to the outside
 Merges with the apical meristem,
 Aside from protection they produce
usually extend about 1cm (0.4 inch or
mucilaginous lubricant called MUCIGEL
less) from the tip of the root
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 Only the root and apical meristem  Root Hairs From the epidermis
are actually pushing through the soil
since no further increase in cell since
takes place above the region of
elongation
 The region where absorption
happens sideways
 Made up of rectangular-shaped cells
 This is the region where cells
duplicate their organelles
 Cells become efficient in the
absorption of minerals before they
 The stele or the central core of the
mature
stem and root of a vascular plant is
 If a cambium is present (typically in
made up of xylem and the xylem arc
dicot plants like trees) however, there
(the red circles) and the phloem
normally is a gradual increase in girth
 Develops a casparian strip
through the addition of secondary
(typically red after staining) that is a
tissues produced by the cambium
lignin substance that makes the region
 Secondary xylem & phloem increase
of maturation water proof so water and
the girth and produces wood, for some
other nutrients don’t pass
plants without, they experience no
 However, if the root is not fully
lateral growth
mature, it will not be fully enclosed with
ZONE OF MATURATION
a casparian strip. These endodermal
 Also called as the “ root hair zone” or
cells are called as passage cells
the “ region of cell differentiation”
(encircled in red).
 The large number of hair like
 Thus, the picture above shows a
delicate protuberances that develop
young dicot root (no pith at the center).
from many of the epidermal cells give
 Suberin layer (impermeable waxy
the root hair zone its name.
substance) forms the casparian strip
 Root hairs are outgrowth in the
 Most of the cell are mature, or
epidermis
differentiate into the various distinctive
 Root hairs increase the surface area
cell types of the primary tissue in this
for absorption. However, the nutrients
region
will simply be delivered to the area of
cell division and elongation.
 The difference between secondary
roots, fibrous roots, and root hairs
grow from pericycles
Secondary
 (encircles the
roots
vascular tissue)  The picture above shows a mature
Originates from the monocot root because of the presence
Fibrous
 stem, specifically of a pith at the center (monocot) and it
roots
parenchyma tissue is fully encircled by the casparian strip.
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FOOD STORAGE ROOT

 Most roots are for carbohydrate
 The picture above on the other hand storage like ube, cassava, carrots,
shows a young monocot root. beets, sweet potatoes (ipomoea plant),
 The endodermis consists of a single and arrowroot
layered cylinder of compactly arranged  This is why arrowroots are used to
cells whose primary walls are create flour
impregnates WATER STORAGE ROOTS
 The core of tissues, referred to
collectively as the vascular cylinder lies
to the inside of the endodermis

 Some plants reserve water to use
them when needed like how succulents
store water in their leaves
 Example: Manroot (Marah), and
come members of the pumpkin family
(cucurbitaceae)
PROPAGATIVE ROOTS
 Lying directly against the inner
boundary of the endodermis is an
important layer of parenchyma tissue
known as the pericycle which give rise
to secondary roots or lateral/branch
roots.  Mother plant roots have suckers
 There is no secondary root in running near the soil surface to
monocot plants. produce new plants (asexual
SPECIALIZED ROOTS reproduction)
 Roots can either absorb nutrients or  Example: Cherries, apples, pears
anchor plants to the soil. However,
other plants may have modified roots
to suit their environment.

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PNEUMATROPHORES PROP ROOTS

 (foreground) of tropical mangroves
 Facilitate the exchange of gases in
the plant and the environment  Large adventitious roots grow from
AERIAL ROOTS the branches or the stem to absorb
more water and minerals
 Example: Abanyan ficus tree
BUTTRESS ROOTS

 Also referred as velamen roots
 They are typically green and has  Larger roots for support
presence of chlorophyll in the roots  Aerial extensions of lateral surface
 could also store water because they roots that work to stabilize the tree
have a velamen that serves as a especially in shallow saturated soils to
waterproof barrier to stop water from resist toppling or being blown over by
coming out. This velamen is composed the wind
of multiple layers of dead skin cells.  Tall and plate-like because their
 One good example are orchids, upperside grows more rapidly than
which are epiphytic because they live other parts.
attach to branches of trees.  Example: tropical fig tree
CONTRACTILE ROOTS PARASITIC ROOTS

 Dependent on other plants for
nutrients and water
 roots that dig deeper to the bottom
 Peg-like haustoria that sucks
of the soil like water lilies
nutrients out of the host plant
 The root is fixed firmly to the soil that
 Parasitic roots do not kill the host
the stem is pulled downward so that
despite taking nutrients from them
the base of the shoot is at ground level
or deeper (in bulbs).
 Ex. water lily, corm

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MYCORRHIZAE STEM

 The word myco stands for Fungus
while rrhizae means plants
 This is the association of fungi and
roots since fungi is a decomposer that
makes minerals for the roots to absorb
while the plant creates nutrients
through photosynthesis to share with
the fungi. The stem is an axis while the shoot is
 They have a mutualistic relationship the stem with leaves, buds, or flowers
because they both benefit  The area, or region (not structure),
 Essential to the normal growth and of a stem where a leaf or leaves are
development of forest trees attached is called a node,
ROOT NODULES  And a stem region between nodes is
called an internode.
 A leaf usually has a flattened blade,
and in most cases is attached to the
twig by a stalk called the petiole.
 Angle of internode and petiole is
called as the axil of the stem which is
why flowers growing there is called
 Member of legume family
axillary.
(Fabaceae)
 Axillary buds would also grow at the
 Form associations with certain soil
axil and it could develop into a branch
bacteria that result in the production of
numerous small swelling or bloom into flowers.
 This is a mutualistic relationship PHYLLOTAXY
between the roots and nitrogen-fixing  The arrangement of leaves on the
bacteria so that plants can absorb stem so that leaves do not shade each
nitrates while the bacteria is protected other
by the plant. (1) Alternate
(2) Opposite
(3) Decussate
(4) Whorled
(5) Spiral Distichous

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 Botany
ALTERNATE SPIRAL
 If the leaves are attached
to the twig alternately in two
rows (alternate distichous)
or in a spiral (alternate
spiral) around the stem, they
are said to be alternate, or
alternately arranged.
 Leaves are not aligned with their
 Only one leaf is present at each
nearest neighbor.
node,
 Leaves located slightly beside one is
OPPOSITE
immediately above or below it, forming
a spiral up to the stem
 If the leaves are attached
 Most common arrangement that
in pairs, they are said to be
could involve alternate, opposite and
opposite, or oppositely
whorled leaves
arranged
DISTICHOUS
 Two leaves per node.

WHORLED
 If they are in whorls
(groups of three or more),
their arrangement is
whorled.
 Leaves are arrange in two (di-) rows
 Three or more leaves
(-stichies) only.
per node
 Examples are leaves of corn and
DECUSSATE irises. Above are alternate distichous
and opposite distichous arrangements.
LEAF AND BUNDLE SCARS

 Leaves occur in four rows (when
looked at the top)
 This only occurs in some species  Deciduous trees and shrubs (those
with opposite leaves that lose all their leaves annually)
characteristically have dormant
axillary buds with leaf scars left below
them after the leaves fall.

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 Botany
 The remnants of this shed form leaf PROCAMBIUM
and bundle scars  A cylinder of strands constituting
 Once the leaves fall, a leaf scar is the procambium appears to the
formed. Inside, the vascular bundles interior of the protoderm.
are scarred (bundle scar) and can only  The procambium produces water-
be observed in the microscope. conducting primary xylem cells and
 Tiny bundle scars, which mark the food-conducting primary phloem cells.
location of the water conducting and GROUND MERISTEM
food-conducting tissues, are usually  The remainder of the meristematic
visible within the leaf scars. tissue, called ground meristem,
 Lenticels are openings in stems like produces two tissues composed of
the stomata in leaves which is also in parenchyma cells.
charge of the exchange of gases. (1) Pith
ORIGIN AND DEVELOPMENT OF STEMS (2) Cortex
(1) Protoderm PITH
(2) Procambium  The parenchyma tissue in the center
(3) Ground Meristem of the stem is the pith.
PROTODERM  For stems, it is present in dicot
 The outermost of the primary plants but absent in monocot plants.
meristems, the protoderm, gives rise  A complete opposite to the roots
to the epidermis. wherein monocot roots have a pith but
EPIDERMIS dicot roots do not.
CORTEX
 The other tissue produced by the
ground meristem is the cortex.
 The cortex may become more
extensive than the pith, but in woody
plants, it, too, eventually will be
crushed and replaced by new tissues
produced from within.
 Single layer of living parenchyma HERBACEOUS DICOTYLEDONOUS
cells.
 Although there are exceptions, the
epidermis is typically one cell thick and
usually becomes coated with a thin,
waxy, protective layer, the cuticle
 Cutin is the fatty substance to make Cross section of alfalfa (Medicago) stem
the wall impermeable to water. This  Herbaceous dicot stems have
builds up a pure layer called cuticle. discrete vascular bundles composed of
patches of xylem and phloem.

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 Botany
 The vascular bundles are arranged
in a cylinder that separates the cortex
from the pith,
 although in a few plants (e.g.,
foxgloves), the xylem and the phloem
are produced as continuous
rings(cylinders) instead of in separate
bundles
 The procambium produces only This tree was 24 years old when it was cut
primary xylem and phloem,  Over a period of years, the result of
 But later, a vascular cambium this type of switch between the early
arises between these two primary spring and the summer growth is a
tissues and adds secondary xylem and series of alternating concentric rings of
phloem to the vascular bundles. light and dark cells (Annual Ring).
WOODY DICOTYLEDONOUS  However annual rings cannot
accurately predict the age of the tree
since it would vary depending on the
climate of the place.

Cross section of young linden (Tilia) stem
 In woody plants, however, obvious
differences begin to appear as soon as
 This older, darker wood at the
the vascular cambium and the cork
center is called heartwood,
cambium develop.
 The lighter, still-functioning xylem
 The most conspicuous differences
closest to the cambium is called
involve the secondary xylem, or wood,
sapwood.
as it is best known.
 Except for giving strength and
 The xylem that is produced after the
support, the heartwood is not of much
spring wood, and which has smaller or
use to the tree since it can no longer
fewer vessel elements and larger
conduct materials.
numbers of tracheids, is referred to as
summer wood.

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 Botany
thus produce no secondary vascular
tissues or cork.

 This is why this coastal redwood is
thriving despite the removal of its  In a typical monocot such as corn, a
lower heartwood and a little of its bundle's xylem usually contains two
large vessels with several small vessels
sapwood.
 Sapwood forms at roughly the same between them.
rate as heartwood develops, so there is  The phloem consists entirely of sieve
always enough "plumbing" for the vital tubes and companion cells, and the
entire bundle is surrounded by a
conducting functions.
sheath of thicker-walled sclerenchyma
 While the vascular cambium is
producing secondary xylem to the cells.
inside, it is also producing secondary
phloem to the outside.

SPECIALIZED STEM
 Stems have nodes, internodes, and
axillary buds; these features distinguish
them from roots and leaves, which do
not have them.
(1) Rhizomes
 The term bark is usually applied to (2) Runners
all the tissues outside the cambium, (3) Stolons
including the phloem. (4) Tubers
MONOCOT ROOT (5) Bulbs
 Most monocots (e.g., grasses, lilies) (6) Corms
are herbaceous plants that do not (7) Cladophylls
attain great size. (8) Thorn
 The stems have neither a vascular (9) Spines
cambium nor a cork cambium and (10) Prickles
(11) Tendrils
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 Botany
RHIZOMES

 Rhizomes are horizontal stems that
grow below ground, often near the
surface of the soil.
 They superficially resemble roots,
but close examination will reveal scale  In Irish potato plants, tubers are
like leaves and axillary buds at each produced at the tips of stolons.
node, at least during some stage of TUBER
development, with short to long  For storage (carbohydrates);
internodes in between. horizontal like rhizomes
 Ex. Ginger  The "eyes" of the potato are actually
 In monocot stem the nodes are nodes formed in a spiral around the
arranged along the stem it can be seen modified stem.
in the ginger thus it is not considered a
root.
RUNNERS & STOLON
 Both are propagative stems

 Each eye consists of an axillary bud
in the axil of a scale-like leaf, although
this leaf is visible only in very young
 RUNNERS are horizontal stems that tubers; the small ridges seen on
differ from rhizomes in that they grow mature tubers are leaf scars.
above ground, generally along the BULB
surface; they also have long
internodes.
 STOLONS are similar to runners but
are produced beneath the surface of
the ground and tend to grow in
different directions but usually not
horizontally.
*In the book, stolons are simply another
 Bulb are short shoots with thick
term for runners
leaves (onion, daffodils, garlic).

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 Botany
 Bulbs are actually large buds
surrounded by numerous fleshy leaves,
with a small stem at the lower end.
 Adventitious roots grow from the
bottom of the stem, but the fleshy
leaves comprise the bulk of the bulb
tissue, which stores food. Example: Gabi
 In onions, the fleshy leaves usually CLADOPHYLLS
are surrounded by the scale-like leaf
bases of long green, aboveground
leaves.
 Other plants producing bulbs
include lilies, hyacinths, and tulips.
CORMS

 The stems of butcher's broom plants
are flattened and appear leaf like.
 Such flattened stems are called
cladophylls (or cladodes or
phylloclades).
 There is a node bearing very small,
Gladioluses have corms with fleshy stems and papery leaf
scalelike leaves with axillary buds in
 Corms resemble bulbs but differ
the center of each butcher's broom
from them in being composed almost
cladophyll.
entirely of stem tissue, except for the
few papery scale like leaves sparsely
covering the outside.
 Adventitious roots are produced at
the base, and corms, like bulbs, store
food.  The feathery appearance of
 The crocus and the gladiolus are asparagus is due to numerous small
examples of plants that produce cladophylls.
corms-like bulb but is more of a
storage stem
 short, stout, solid, and more or less
rounded in shape. It is filled with stored
food and grows in a vertical direction

 Stems of cacti are also cladophylls.

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 Botany
 Since they have no leaves, they have PRICKLES
leaf-like stems instead that flattens
and increases areas for photosynthesis  Like in roses,
so that lesser water is lost. they have
broader bases
and is shorter
and pointed
 a sharp
outgrowth from
the epidermis or
bark

TENDRILS
Bali-bali stems are also cladophylls
THORNS

 Extension of the stem to support
 Smaller base, longer compared to vines as it climbs
spine  Plants like kalabasa (squash) and
 a stiff, woody, modified stem with a marguso (bitter gourd) has this type of
sharp point modified stem
SPINE

 Firm, slender, sharp-pointed
structure, representing a modified leaf
or stipule

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 Botany
LEAVES  Leaves are also responsible for the
(1) Function release of O2 in the atmosphere for
(2) External Anatomy humans and animals to breathe.
(3) Internal Anatomy  In some plants, leaves have become
(4) Specialized Leaves adapted for specialized functions.
FUNCTION EXTERNAL ANATOMY

 Leaves possess a blade or lamina,
an edge called the margin of the leaf,
the veins (vascular bundles), a petiole,
and two appendages at the base of the
petiole called the stipules (small leaf-
lie structure at the base of the petiole).
 Leaves are the solar energy and
CO2 collectors of plants.
 Aborbing CO2 is important because
this greenhouse gas traps heat in out
atmosphere causing global warming
 Leaves are involved in
photosynthesis
 Leaves produce carbohydrates
which is why when it is eaten by  Plants with stipule are called as
animals they gain carbohydrates like stipulate and plants without stipules
when we eat bread or rice. are called exstipulate

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 Botany

 The midrib is the main vein.
The petiole connects the leaf to the
stem and is also known as the stalk

 Plants with petioles are called Poplar’ s Single leaf
petiolate while those without are called COMPOUND
sessile  Blade divided into leaflets, leaflets
 The base is the portion of the leaf lack an axillary bud but each
where the petiole attaches (like how compound leaf has a single bud at the
nodes is where the petiole attach in the base of its petiole
stem)  leaflets are the division of the blade
 The tip or the apex of the leaf is its  There are two types of compound
top most part leaves:
 The margin is the sides of the leaf (1) Pinnately Compound
(1) Leaf Types (2) Palmately Compound
(2) Venation PINNATELY COMPOUND
LEAF TYPES
(1) Simple
(2) Compound
(3) Peltate
(4) Perfoliate
SIMPLE
 Undivided blade with a single  Leaflets in pairs and attached along
axillary bud at the base of its petiole. a central rachis (central vein where
leaflets attach)
 Examples: ash, walnut, pecan, and
rose

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 Botany
 Examples: buckeye, horse
chestnut, hemp or marijuana, and
shamrock.
PELTATE

 Two types:  Petioles that are attached to the
(1) ODD  The middle of the blade. We call this
top/terminal leaflet terminal attachment because it is at
is only one the top of the petiole
 The picture  A simple leaf since there are no
above is an leaflets as it is not completely divided
example  Examples include Mayapple
(2) EVEN  It has two PERFOLIATE
terminal leaflets
PALMATELY COMPOUND

 Sessile leaves that surround and are
pierced by stems
 Examples include yellow-wort and
thoroughwort
VENATION
 Arrangement of veins in a leaf
(1) Netted-venation
(2) Parallel venation
(3) Dichotomous venation
 Leaflets attached at the same NETTED-VENATION
point at the end of the petiole  Also known as Reticulate Venation
 Same attachment of leaflets  One or a few prominent midveins
 The central point is called the from which smaller minor veins branch
into a meshed network
central rachis
 Common to dicots and some
nonflowering plants.
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 Botany
 Two types: DICHOTOMOUS VENATION
(1) Pinnately-veined leaves
(2) Palmately-veined leaves
PINNATELY-VEINED LEAVES

 No midrib or large veins
 A combination of netted and parallel
venation
 Rather individual veins have a
 A single main vein called midrib tendency to fork evenly from the base
with secondary veins branching from it of the blade to the opposite margin,
 Example: elm creating a fan-shaped leaf (e.g.,
PALMATELY-VEINED LEAVES Gingko).
INTERNAL ANATOMY

 In the upper epidermis, there is
 Veins radiate out of base of blade lesser stomata because it is mostly for
 There is multiple main veins collecting light energy from the sun
 Example: maple  Palisade parenchyma is filled with
PARALLEL VENATION photosynthetic cells (chlorophyll)
 Spongy parenchyma is where gaps
in between cells are present for the
exchange of gases

 Characteristics of many monocots
like grasses, cereal grains
 Veins are parallel to one another
 There are several veins of the same
size
 No midrib or main veins
 The midrip and veins are actually
the vascular bundle where xylem and
phloem tissues are found. Surrounding
the midrib is the bundle sheath cells

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 Botany
 Longitudinal section through a leaf
axil, showing the abscission zone in the
petiole and the axillary bud just above
 The xylem and phloem are not
interrupted until the leaf actually falls
away
 At the leaf base, usually in the
petiole, is an abscission zone oriented
perpendicular to the petiole
 Its cells are involved in cutting off
the leaf when its useful life is over
 Adjacent undamaged cells swell and
become corky, forming protective scar
 The trichomes prevent water loss by tissue, the leaf scar, across the wound.
increasing leaf-air boundary  Without an abscission zone, dead
resistance. Water loss through the leaves might tear off irregularly,
epidermis is called transpiration leaving an open wound vulnerable to
pathogens.
SPECIALIZED LEAF
(1) Bulb
(2) Leaf Tendril
(3) Leaf Spine
(4) Leaf scales
(5) Leaflet hook
(6) Cotyledons
(7) Needle
(8) Bracts
(9) Carnivorous Leaves
BULB

 Storage leaves that do not undergo
photosynthesis
 Example: Onion

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 Botany
LEAF TENDRIL

 Unlike photosynthetic leaves,
tendrils grow
indefinitely and contain cells that
are capable of sensing contact with
an object.
 When the tendril touches
something, the side facing the
object stops growing but  Above are different climbing
the other side continues to structures, the terminal tendrils are
elongate, causing the tendril to coil leaf tendrils while those growing
around the object from the axil is the stem tendril
and use it for support. LEAF SPINE
 Lamina would be detrimental,
and none forms. Whereas many
foliage leaves sense the direction of
sunlight and reorient the lamina for
maximum photosynthesis, tendrils
respond by sensing solid objects
and growing  Cactus spines are modified leaves of
around them. axillary buds.
 The succulent, moist cactus body
 no leaf blade, and whereas
would be an excellent source of water
foliage leaves stop growing after for animals were it not for the
they reach a specific size, this protective spines. Their needle shape
tendril continues to grow protects the plant from herbivores.

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 Botany
LEAF SCALES  During germination, the cotyledon
acts as digestive or absorptive tissue.
NEEDLE

 Small, flat, scale-like leaves form a
shield-like covering on stems of
junipers, cypresses (Cupressus),
arborvitae (Thuja), and others.
 This allows the bud to lessen water  Needles, either short or long, occur
loss. in all pines, firs, and spruces
LEAFLET HOOK  It reduces water loss however, it also
has lesser surface area for
photosynthesis
BRACTS

 Similar to tendrils in the stem but
they grow from the compound leaves  Certain plants produce clusters of
COTYLEDONS tiny flowers and rather than making
sepals for each flower, they just make
one set of large bracts that protects the
entire cluster; these flowers lack sepals
 Bracts are colored leaves that looks
like a petal for apetalous flowers to
attract pollinators
 Examples are poinsettia and
bougainvillea

 Cotyledons are embryonic leaves
that store starch and protein.
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 Botany
CARNIVOROUS LEAVES

 The ability to trap and digest insects
has evolved in several families.
 Insectivory has evolved in plants
that grow in habitats poor in nitrates
and ammonia; by digesting insects,
plants obtain the nitrogen they need
for their amino acids and nucleotides
PITCHER PLANT
 secretes chemicals to attract
insects and they would die once they
reach the water

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 Botany
REPRODUCTIVE ORGANS OF PLANTS expenditure of energy is not used to
(1) Flowers nurture the seed which is why we do
(2) Seeds not see gumamela fruits.
FLOWERS
 Also called as bloom or blossom
 Reproductive structure in flowering
plants (angiosperms or phylum
magnoliophyta) which is the most
common type of plant.
 Although flowers provide aesthetic
value to the plant, it main purpose is to
reproduce and propagate it species  Cuttings is one example of asexual
 Some flowers may not be obvious reproduction. The mother plant always
like those of gumamela, but still re have the best characteristics which is
flowering plants like crotons, grass, and why it is not typically sold.
bamboo.
 Flowers mediate the union of male
sperm with female ovum in order to
produce seeds.
 Two types of reproduction:
SEXUAL ASEXUAL
 In need of male  less  Alugbati is typically propagated
and female parts adaptation asexually because its seed are too
 more diversity as because no small but it can also be propagated
it combines the diversity; the sexually.
genes of mother & daughter plant
father but needs is exactly the
more ATP/ energy same as the
 It begins with mother plant
pollination, then  easier to
fertilization, leading propagate and
to the formation and requires less
dispersal of the energy from  Tangkong is another plant that can
seeds. the plant reproduce both sexually and asexually.
 Fun fact: Gumamelas could actually If you uproot it and throw it on soil it
reproduce sexually in other countries will grow, and if it is simply left alone, it
like Thailand and Taiwan, and will still grow because it can produce
produces an “ okra-like” fruit since it seeds.
does have an ovary. However, it has
been propagated so much in our
country that it has started to rely in
asexual reproduction. So, the
BIO 277B.
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 Botany
petals with attractive scents which is
why flowers are showy or in bright
colors.
TYPES OF FLOWERS
(1) Solitary flowers
(2) Inflorescence flowers
SOLITARY FLOWERS

 Underground orchids were found in
Australia by a farmer after digging.
 This flower produce seeds and
reproduces sexually
 The flower is intact
 Example: Gumamela
INFLORESCENCE

 The Rafflesia flower is the most foul-
smelling flower that smells rotten like a
dead rat or animal.
 The smell is to repel humans from  The flower is divided into multiple
picking its flowers while attracting florets
insects like flies for pollination  While both solitary and
inflorescence flowers have peduncles
only inflorescene has pedicels
 Example: Santan, Butterfly Orchid
COMPOSITE FLOWERS

 We mostly admire flowers for their  Species that have more than one
aesthetic value but it is for pollinators flower on an axis so-called composite
not us, humans. flowers
 Insects like bees and butterflies  Also refers to the arrangement of
typically are more attracted to colorful flowers on a stem

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 Botany
 It is basically tiny florets together  stalk of each flower (in both solitary
that look like they are one flower & inflorescence)
 For example, daisy and a sunflower  Labelled as stem in the picture
is not a flower but a flowerhead above
composed of numerous tiny flowers or PEDICEL
florets.

 Stalk of each floret in inflorescence
RECEPTACLE
 Functions for the support of the
ovary and other parts
SEPALS
PARTS OF THE FLOWER

 Typically these are green, but are
petal-like in some species
 A group of sepals or outer whorl of
(1) Non-reproductive parts sepals is called a calyx
(2) Reproductive Parts PETALS
NON-REPRODUCTIVE PARTS
(1) Peduncle
(2) Pedicel
(3) Receptacle
(4) Sepal
(5) Petal
(6) Perianth  Usually, thin, soft and colored to
PEDUNCLE attract insects that help the process of
pollination.
 A group of petals, or whorl of petals
is called the corolla

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 Botany
PERIANTH PISTIL

 Both the sepals and the petals
REPRODUCTIVE PARTS
(1) Stamen  The female part of the flower
(2) Pistil  The collective term for pistils (one or
STAMEN more pistils) is gynoecium (from Greek
gynaikos oikia: woman's house)
 Comprises the stigma, style, ovary,
and ovule.

 Male part of the flower
 It comprises the Anther and  A pistil may consist of a number of
Filament carpels merged together (3rd). Then it
 The one or two whorls of stamens is is syncarpous
androecium (from Greek andros oikia:  If there is only one pistil to each
man's house) flower, or of multiple individual carpels
ANTHER that are not conjoined like the 2nd, the
 Also called the pollen sack at it is flower is then called apocarpous.
where pollen grains are produced  If there is one carpel and one pistil, it
 Pollen grains eventually germinate is monocarpous
to become sperm  Classification of fruits may vary
 Pollen contains male gametes depending on the flower it originated
FILAMENT from
 The stalk of the anther Consists of parts
 Each filament is topped by an  CARPEL like ovary,
anther stigma, style
Consists of one
 PISTIL
or more carpels
STIGMA
 This is where pollen grains land
 Sticky part at the tip of the pistil,
where nectar is produced to facilitate

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 Botany
the pollination by insects, is the OVARY
receptor of pollen
 The chemical composition and pH
levels of nectar for every species vary
to make sure that only pollen grains of
that specific species of that plant can
germinate and become a sperm cell
 Pollen grains require a specific
nectar composition to make sure that  The ovary can either be superior or
no pollination across other species will inferior
occur  It is superior if the stamen is
 This is why if corn pollens fall on the attached at the base of the ovary (I is
stigma of the corn, it will not superior)
germinate, because of the difference of  It is inferior if the stamen is
their compatibility barriers attached at the top of the ovary (III is
 It is also possible for them to superior)
germinate to a pollen tube but once  II is half inferior ovary.
proteins on the surface of the tube OVULE
matches the incompatibility gene, the  The immature seed
stigma and style will block further  Contains the female gametes
growth. Thus, no fertilization happens. CLASSIFICATION OF PLANTS BASE ON
 Stigma is very important as it is THEIR LIFE CYCLE
responsible for germination  One life cycle is when it grows from
 Once pollen grains germinate, they a seed and can bear flowers and fruits
produce a pollen tube which travels (1) Annual
through the style, and enters the ovule (2) Biennials
to release two sperm cells which will (3) Perennials
fuse with the ovule to form a seed. ANNUAL
STYLE  The cycle is completed in a single
 Connects the stigma to the ovary season and ends with the death of the
 For fertilization to happen the pollen parent plant. (3-4 months)
grains must pass through the style  For seasonal plant like watermelon,
before going to the ovary egg plant
 The supportive stalk of the stigma BIENNIALS
which becomes the pathway for pollen  Two growing seasons to complete a
tubes to grow from pollen grains cycle
adhering to the stigma to the ovules  Can grow in summer and rainy
which carry the female reproductive season
material  Banana grows all throughout the
year, rainy season and summer

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 Botany
 Once they bear fruit, flowers bloom  Many Viola and some Salvia species
again and would bear fruit all over are known to have these types of
again. flowers.
PERENNIALS ENTOMOPHILOUS
 Take several or many growing  Attract and use insects, bats, birds
seasons to go from a germinated seed or other animals to transfer pollen
to a plant producing new seeds. from one flower to the next
 Common for fruit tress because it  Commonly have glands called
takes them several years to grow and nectaries on their various parts that
develop attract these animals.
CLASSIFICATION OF FLOWERS BASED  Flowers also attract pollinators by
ON POLLINATORS scent and color. Still other flowers use
 Each flower has a specific design fo mimicry to attract pollinators.
 Structure of the flower depends on
the pollinator it engage with
 If insects are the pollinators, then it
has to be colorful to attract insects.
These plant really need pollinators for
pollination to take place
 The design of the flower depends on
 Some species of orchids, for
the pollinator
example, produce flowers resembling
(1) Cleistogamous
female bees in color, shape, and scent.
(2) Entomophilous
 Flowers are also specialized in
(3) Anemophilous
* Entomophilous and Anemophilous are
shape and have an arrangement of the
chasmogamous plants which means that stamens that ensures that pollen
pollination happens across flowers grains are transferred to the bodies of
CLEISTOGAMOUS the pollinator when it lands in search of
its attractant (such as nectar, pollen,
or a mate).

 Self-pollinating flowers, after which,
they may or may not open
 The perianth is closed to ensure that
pollen produced from within the flower  As you can see in the picture above
pollinates only the stigma/s of that the bee is surrounded with pollens that
flower tend to be large grained, sticky and
rich in protein (as a reward for
pollinators)
BIO 277B.
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 Botany
ANEMOPHILOUS some are separated on each plant
 Do not depend on insects for producing a male flower bearing pant
fertilization but only depend on wind to and a female flower bearing plant.
move pollen from one flower to the Similar to kalabasa.
next
 Common among the family for birch
trees, ragweed, maples, and grasses
like corn, rice, wheat, & bamboo
 They have no need to attract
pollinators and therefore tend not to be
"showy" flowers, meaning their flowers
are neither colorful nor big. They also
 In rice on the other hand, has both
produce less nectar.
female and male parts on one flower
 Pollen grains in these flowers are
or floret, but it is also an anemophilous
usually mall & light to be easily
flower.
transferred by means of wind
FERTILIZATION PROCESS
 Their pollens also have little
nutritional value because it does not
need insects
 Male and female reproductive
organs are generally found in separate
flowers, the male flowers having a
number of long filaments terminating
in exposed stamens, and the female
flowers having long, feather-like
stigmas.

 Meiosis happens since it makes sure
that every sperm cell is haploid
 Pollen then lands on the stigma & it
germinates by creating a pollen tube
as it travel down the style to connect it
to the egg to fertilize it will sperm. Once
 This is similar to corn which has its it becomes a zygote, then develops
main flower at the top (called tassel), into the seed at a proper time
and the corn fruit itself with its silks is  Double fertilization is the process
the female flower which also contains unique to angiosperms in which one
the ovary. sperm fertilizes the egg (forming a
 In papaya, some varieties can have zygote) and the other sperm fertilizes
both male and female flowers but
BIO 277B.
39
 Botany
the polar nuclei (forming the primary
endosperm nucleus).
SEED
 A seed (in some plants, referred to
as a kernel) is a small embryonic plant
enclosed in a covering called the seed
coat, usually with some stored food.
 The seed, which is an embryo with
two points of growth (one of which  The picture above shows the
forms the stems the other the roots) is
structure of the seed as it is dissected
enclosed in a seed coat with some food
reserves.
 The seed has 3 basic parts:
 It is the product of the ripened ovule
(1) Embryo
of gymnosperm and angiosperm
(2) Supply of Nutrients (for the
plants which occurs after fertilization
embryo)
and some growth within the mother
(3) Seedcoat
plant.
EMBRYO
 Seed is a mature ovule that is
 The embryo is an immature plant
developed from the fertilization of the
from which a new plant will grow under
sperm and egg cell
proper conditions.
 The formation of the seed completes
 Formed from the zygote
the process of reproduction in seed
 The embryo is further composed
plants (started with the development
into several embryonic parts:
of flowers and pollination), with the
(1) Cotyledon
embryo developed from the zygote
(2) Radicle
and the seed coat from the
(3) Plumule
integuments of the ovule.
(4) Epicotyl
 Seeds have been an important
(5) Hypocotyl
development in the reproduction and
(6) Embryonic sheath
spread of flowering plants, relative to
COTYELEDON
more primitive plants like mosses,
 The embryo has one cotyledon or
ferns and liverworts, which do not have
seed leaf in monocotyledons, two
seeds and use other means to
cotyledons in almost all dicotyledons
propagate themselves.
and two or more in gymnosperms.
THREE BASIC SEED PARTS
 The seed in the picture is therefore a
dicotyledon as it has two cotyledons.
RADICLE
 The radicle is the embryonic root,
which disappear once the plant
matures in monocots while it grows the
taproot in dicots.
PLUMULE
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 Botany
 The plumule is the embryonic shoot.  The cotyledon shrinks once the
 This contains both the cotyledon plants grows because they make use of
(embryonic leaves) and the embryonic the starch in the cotyledon. This
stems of the plant (epicotyl & happens until the plant is able to
hypocotyl) produce large enough leaves to
EPICOTYL undergo photosynthesis
 The embryonic stem above the point  Cotyledons and endosperms have
of attachment of the cotyledon(s) is the the same use in a plant.
epicotyl.  Seeds can be classified according to
 “ Epi-” means above. Thus, the name the amount of endosperms that they
itself says “ above the cotyledon” have:
HYPOCOTYL (1) Albuminous
 The embryonic stem below the point (2) Exalbuminous
of attachment is the hypocotyl. ALBUMINOUS
 “ Hypo-“ means below so it signifies  Depend greatly on the endosperm
that this stem is below the cotyledon. for nutrients so they are typically in
larger amounts.
SOURCE OF NUTRIENTS  Seeds with an endosperm at
 The ENDOSPERM is the reserve maturity are termed albuminous seeds
storage food of the seed until such time  Ex: monocots like grasses and palms
that there is no variable temperature and many dicots like. brazil nut and
and moisture for the seed to germinate castor bean
it will use the endo sperm to germinate EXALBUMIOUS
 Endosperm is triploid because  Seeds that have less or no
fertilized by a sperm and two polar endosperm at maturity; more
bodies making it triploid since all are cotyledon
haploids  Ex: bean, pea, oak, walnut, squash,
 Seeds also have limitations because sunflower, and radish
without variable temperature and SEED COAT
moisture, they will not be able to  The seed coat plays a very
germinate and will die important role that protects the
 In Ilonggo terms, it is called “ laon embryo for it to be able to germinate
nga binhi” because the embryo is dead later on; some seed coats are even
already causing the probability of resistant to fire like those of grasses
germination to be very small  The seed coat helps protect the
 COTYLEDON also serves as a embryo from mechanical injury and
source of food of the plant as it from drying out.
germinates (no photosynthesis  The seed coat is from a tissue
happens yet) derived from the maternal tissue of the
 Plants with small endosperms rely ovule.
on cotyledon.

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 Botany
SPECIALIZED SEED PARTS HILUM
 In addition to the three basic seed
parts there are additional parts which
include:
(1) Aril
(2) Hairs
(3) Hilum
(4) Funiculum
ARIL

 There may also be a scar on the
seed coat, called the HILUM
 This scar was previously where the
 Some seeds have an appendage on seed was attached to the ovary wall by
the seed coat such an ARIL (as in yew the FUNICULUS.
and nutmeg)

 Aril is the fleshy part that may
sometimes be edible like in lychees and
kamachile.  The funiculus