General Biology Reviewer PDF - G11

Summary

This document is a reviewer for General Biology, for the 1st Semester of Midterm in Grade 11 at the University of Saint Louis. It covers fundamental concepts of biology, including the branches of science as well as the characteristics of living organisms. This includes micro, macro, and environmental biology topics.

Full Transcript

University of Saint Louis
4 GENETICS- the study of how genes and how
traits are passed down from one generation to

GENERAL the next.

SOME CAREERS INVOLVING BIOLOGY

BIOLOGY FORENSIC SCIENCE- is the application of
science to answer questions related to the law.

REVIEWER NEUROBIOLOGY - is the study of the nervous
system.
1st Semester - Midterm
_________________________ PALEONTOLOGY - which uses fossils to study
life’s history.

Week 1: ZOOLOGY - which studies animals.

What is Science? BOTANY - which studies plants.
Science is the pursuit and application of
knowledge THE PROPERTIES OF LIFE
and ➔ All living organisms share several key
understanding of the natural and social characteristics or functions: order,
world following sensitivity or response to the environment,
reproduction, growth and development,
a
regulation, homeostasis, and energy
systematic processing. When viewed together, these
methodology based on evidence. eight characteristics serve to define life.

What are the branches of Science? ORDER
1. Basic Science or Pure Science Organisms are highly organized,
- It seeks to expand knowledge regardless of the coordinated structures that consist of one
short-term application of that knowledge. or more cells.

2. Applied Science SENSITIVITY OR RESPONSE TO STIMULI
- Aims to use science to solve real-world Organisms can respond to diverse stimuli.
problems such as improving crop yields, finding a Example: The leaves of the sensitive plant
cure for a particular disease, or saving animals (Mimosa pudica) will instantly droop and fold
threatened by a natural disaster. when touched. After a few minutes, the plant
returns to normal.
BRANCHES OF BIOLOGICAL STUDY REPRODUCTION
When reproduction occurs, genes
1. MICROBIOLOGY - study of microorganisms. containing DNA are passed along to an
2. PHYSIOLOGY- deals with the normal organism's offspring. These genes ensure
functions of living organisms and their parts. that the offspring will belong to the same
species and will have similar
3. ECOLOGY- study of the relationships between characteristics, such as size and shape.
living organisms, including humans, and their
physical environment.
Example: Kittens have inherited genes from both physiological; as such, adaptations
parents and share many of the same frequently involve other properties of
characteristics. organisms such as homeostasis,
reproduction, and growth and
GROWTH AND DEVELOPMENT development.
All organisms grow and develop following
specific instructions coded for by their
genes. These genes provide instructions
that will direct cellular growth and Week 2: CELL THEORY
development, ensuring that. species'
young will grow up to exhibit many of the INTRODUCTION:
same characteristics as its parents. - Aristotle proposed the idea of Spontaneous
Generation Theory which states that life may
REGULATION spontaneously arise from any inanimate matter.
Even the smallest organisms are complex - This theory persisted until 17 th century. Some
and require multiple regulatory scientists proved that life cannot come from
mechanisms to coordinate internal inanimate objects.
functions, respond to stimuli, and - They believed that life has a source. All living
Stresses. organisms are composed of at least one cell.
Today, we studied that the cell is the smallest
HOMEOSTASIS structure that can perform all activities required to
To function properly, cells need to have sustain life.
appropriate conditions such as proper
temperature, pH, and appropriate SIZE OF THE CELL
concentration of diverse chemicals. ➔ Cells are generally small. Most cells are
Homeostasis is 6 the ability of an smaller than 1mm, and some are even as
organism to maintain constant internal small as 1um.
conditions. ➔ The cell can only be viewed under the
Example: Polar bears (Ursus maritimus) and microscope to magnify its size in the field
other mammals living in ice-covered regions of view.
maintain their body temperature by generating
heat and reducing heat loss through thick fur and SURFACE AREA TO VOLUME RATION IN
a dense layer of fat under their skin. CELLS
➔ The cell itself is a system.
ENERGY PROCESSING ➔ A cell needs a surface area large enough
All organisms use a source of energy for relative to its volume to allow adequate
their metabolic activities. Some organisms nutrients to enter and sufficient waste to
capture energy from the sun and convert it be eliminated.
into chemical energy in food; others use ➔ Surface area to volume ratio is important
chemical energy in molecules they take in that it favors a smaller cell size in terms of
as food. the efficiency of the movement of
Example: The California condor (Gymnogyps molecules.
californianus) uses chemical energy derived from
food to power flight. SURFACE AREA TO VOLUME RATION IN
CELLS
EVOLUTION (ADAPTATION) ➔ The small size of the cell provides them
Adaptations help organisms survive in with a relatively higher ratio of surface
their ecological niches, and adaptive traits area to volume.
may be structural, behavioral, or
 ➔ A living entity may maintain the same total HISTORY OF THE DEVELOPMENT OF THE
volume, but having small cells will allow it CELL THEORY
to have a greater surface area available
for the movement of molecules. 1. Zacharias Janssen (1585 - 1632)
- The discovery of the cell as the basic unit of life
GENERAL FUNCTIONS OF THE CELL involves different scientists. Hans Janssen and
1. Regulation of Internal Environment his son, Zacharias Janssen, invented the first
2. Acquisition and Utilization of Energy primitive microscope which was used to view
3. Responsiveness to its Environment microscopic cells.
4. Protection and support
2. Robert Hooke (1635 - 1703)
REGULATION OF THE INTERNAL - Robert Hooke was the first to observe the cells
ENVIRONMENT by using cork from the bark of an oak tree under
➔ The small size of the cell provides them the microscope.
with a relatively higher ratio of surface
area to volume. 3. Francesco Redi (1626 - 1697)
➔ A living entity may maintain the same total - The experiment of Francesco Redi during his
volume, but having small cells will allow it time disproved the long-believed theory of
to have a greater surface area available spontaneous generation, which states that life
for the movement of molecules. comes from inanimate objects.
Example: Shivering generates metabolic heat
while perspiration serve as a cooling system to 4. Anton Van Leeuwenhoek (1632 - 1723)
remove excess heat in the body. - Anton Van Leeuwenhoek was the first to see
and describe microorganisms from a drop of
ACQUISTITION AND UTILIZATION OF water by using his self-made practical
ENERGY microscope.
➔ Energy is needed by cells to drive most of
the chemical reactions and other functions 5. Matthias Schleiden (1804 - 1881)
in the organism’s body. - Matthias Schleiden is one of the proponents of
➔ Cells acquire energy from the nutrients in cell theory who stated that plants are made up of
food that organisms consume. cells and that cell is the basic unit of life.

RESPONSIVENESS TO THEIR ENVIRONMENT 6. Theodore Schwann (1810 - 1882)
➔ The cell’s environment changes - Theodore Schwann is also a proponent of cell
constantly and rapidly. To survive, cells theory who stated that all organisms are made up
respond to various signals that indicate of cells.
any form of change in their environment.
Example: A tanned skin means more pigment is 7. Rudolf Virchow (1821 - 1902)
released in that area to impact protection to the - Rudolf Virchow another proponent of the cell
underlying cells, especially UV radiation that can theory who stated that cells come from
damage DNA. preexisting cells. Through successive cell
division, many cells can be produced from a
PROTECTION AND SUPPORT single cell.
➔ Cells protect and support their internal
environment through their cellular
membranes. Immune cells impart
protection against pathogens and other
foreign bodies that may enter the general
circulation.
PRINCIPLES OF THE CELL THEORY the fusion of egg cell and sperm cell to
form a fertilized cell call zygote.
NOTE: Reproduction, being one of the major
PRINCIPLES PROPONENT
attributes of life, is exhibited at the cellular level
1. Every living Theodore Schwann through cell division.
organisms consists of
one or more cells THE MODERN VERSION OF CELL THEORY
Energy flow occurs within the cell.
2. The cell is the Matthias Schleiden The DNA of the cell is passed from cell to
fundamental unit of cell.
life. It is the smallest All cells have similar basic cellular
structural and chemical composition.
functional unit of all
organisms. WEEK 3: MAJOR PARTS OF THE CELL

3. Cells come from Rudolf Virchow INTRODUCTION
preexisting cells. Cells - Similar to the buildings we know, our cells also
contain hereditary rely on biomolecules that provide shape and
material, which they rigidity. In addition, buildings also have
pass to their offspring structures and other security measures that
when they divide. regulate the entry and exit of people just as the
cell manages to become selective to the
molecules that will move through it.
THE CELLS AS A COMMON FEATURE
AMONG ALL ORGANISMS
- One of the principles of cell theory states that all
Unicellular organisms consist of only one
living organisms are composed of at least one
cell but are already considered living
cell. Cells are the fundamental units of structure
organisms.
and function in all living organisms.
Organisms, from unicellular forms, such
However, microscopic in size, cells are
as in paramecium (left), to multicellular
composed of structures that are complex in
forms, such as in plants (right), are made
function.
of cells.
1. PLASMA MEMBRANE
THE CELL AS THE FUNDAMENTAL UNIT OF
★ Plasma membranes mostly consist of
LIFE
phospholipids, a form of lipid molecule.
The cell is the basic level that exhibits all
Each phospholipid of the cell membrane is
the important attributes of life. It is at the
composed of two distinct regions.
level of the cell that important biochemical
★ The first part is the “head” with a
reactions take place to keep living
negatively charged phosphate group with
organisms alive.
polar covalent bonds.
NOTE: Plants cells perform various functions that
★ The second part is made up of the two
contribute to the survival of the entire plant.
nonpolar fatty acids “tails”. These
phospholipids group to form a two-layered
THE CELL AS A PRODUCT OF PREEXISTING
barrier called a phospholipid bilayer.
CELLS
★ The hydrophilic (water-loving) head region
Cells can only come from preexisting cells
of the phospholipid bilayer faces outward.
similar to how bacterial and yeast cells
This orientation exposes it to the aqueous
produce produce their daughter cells
solutions on the outside and inside of the
through binary fission. Another example is
cell.
 ★ By contrast, the hydrophobic CARRIER PROTEINS
(waterfearing) tails are oriented inward - These are involved in the transport of
and are together shielded from water. The substances across the membrane. They
middle portion of the phospholipid bilayer receive certain molecules but change their
makes the plasma membrane selectively shape to be able to move these
permeable. substances across the membrane. These
★ The CELL MEMBRANE are very specific with the molecules that
- is also composed of proteins and other they transport across the plasma
molecules that are free to drift laterally membrane.
within the bilayer. The phospholipid
bilayer is often described as a fluid mosaic
model. According to this model, proteins,
carbohydrates, and cholesterol molecules
are embedded in the membrane so that
they look like a mosaic.

ROLE OF THE LIPID BILAYER
- It serves as a primary wall or barrier of the cell
from its external environment.
- It is semipermeable in nature. It means it only
allows certain molecules to pass through. The
molecules that are free to move across the CELL RECOGNITION PROTEINS
membrane generally require no energy to pass - These proteins help recognize the
through, i.e., they can move passively. presence of pathogens so that certain
immune responses can be elicited.
ROLE OF MEMBRANE PROTEINS
RECEPTOR PROTEINS
- These proteins have a shape that allows
only specific molecules to bind to them.
When a molecule binds to a receptor
protein, the protein changes its shape,
bringing about particular cellular
responses.
Most molecules that cannot readily pass through
the lipid bilayer do so with the aid of the proteins
embedded in the membrane.

CHANNEL PROTEINS
- Channel proteins allow transport of certain
molecules through the membrane. It forms
a channel or passageway that simply
allows certain substances to move from
one side to the other.

CYTOSKELETON
- Cells are constantly exposed to various
physical forces. All eukaryotic cells have a
 system of interconnected protein filaments by special proteins. It can also facilitate
from their nucleus to the plasma cell movement. They can move the cell
membrane. This, collectively, is known as and its organelles by interacting with
the cytoskeleton which extends motor molecules such as that in muscle
throughout the cytoplasm (and outside the proteins.
cytoplasm in some cells).

INTERMEDIATE FILAMENTS
- Intermediate filaments, as the name
implies, have characteristics that lie
MICROTUBULE between those of microfilaments and
- Microtubules are straight, long, hollow microtubules. Intermediate filaments are
cylinders with globular proteins called made of a variety of proteins.
tubulin. There are two types of tubulin, - They form a ropelike assembly of fibrous
namely, the alpha-tubulin and beta-tubulin polypeptides. Some intermediate
- Alpha and beta-tubulin proteins come filaments support the nuclear envelope by
together by forming dimers. These dimers anchoring the nucleus, while others
are arranged in rows. Microtubules have support the plasma membrane.
13 rows of tubulin dimers, surrounding an - They also impart great strength to skin
empty central core. Generally, these cells because one of their components
cytoskeletal elements grow out and are includes the structural protein keratin.
organized by microtubule organizing
centers or MTOCs. The MTOCs in animal
cells are in the form of centrosomes.

THE GENERAL ROLE OF THE
CYTOSKELETON
If compared to a factory building, the
cytoskeleton serves as the foundation and
beams that support the whole structure of
the factory. The cytoskeleton also
Microtubules are also helpful during cell division. supports the structure of the cell itself and
They assemble into structures called spindle provides anchorage and reinforcement for
fibers that separate the duplicated chromosomes many organelles.
then disassemble afterward. - It also serves as both the skeleton and the
“muscles” of the cell, which provides support and
MICROFILAMENTS movement. Furthermore, it maintains cell shape
- Microfilaments are long and flexible fibers and it allows the cell and its organelles to move.
composed of the protein actin which is the
thinnest component of the cytoskeleton. THE CYTOPLASM
- It provides structural support as a dense, The entire region of the cell between the
complex web, to which they are anchored nucleus and the plasma membrane is the
 cytoplasm. In eukaryotic cells, it is in the A cell wall is permeable to water which is
cytoplasm that all the various subcellular why it is easier for dissolved substances
structures are suspended. to cross it to the plasma membrane.
The plasma membrane encloses it together with Although permeable to water, the cell wall
all other cellular contents. The cytoplasm is maintains cell shape, and it keeps cells
composed of the cytosol, a semifluid solution from absorbing too much water so that
that consists of water and inorganic and organic they will not burst especially in plant cells.
molecules.
MAJOR PARTS OF THE CELL
THE ROLE OF CYTOPLASM 1. PLASMA MEMBRANE
If the factory building has a floor where all 2. CYTOPLASM
raw materials, machines, other 3. CYTOSKELETON
equipment, and employees work and 4. CELL WALL
manufacture products, the cell has its
cytoplasm to serve as a vessel for various COMPONENTS OF THE CELL:
functions to take place. The role of the SUBCELLULAR ORGANELLES
cytoplasm is simply to put all organelles
and other cellular contents in place. It is
where all other molecules inside the cell
are suspended, most of which are
substrates for enzymatic reactions to take
place.

THE STRUCTURE OF THE CELL WALL Some scientists believed that the nucleus
evolved as a result of invagination. Much
scientific evidence also shows that
mitochondria and chloroplasts arose when
a large eukaryotic cell engulfed
independent prokaryotes.
This relationship is later on referred to as
the endosymbiotic theory. This theory is
the explanation for the double membrane
of mitochondria and chloroplasts and also
the reason for having their own genetic
material aside from the one found in the
The cell wall is a rigid structure that surrounds nucleus.
most prokaryotic cells, including archaea and
bacteria. GENETIC CONTROL OF THE CELL
A cell must maintain its structures and
Peptidoglycan – the cell wall of bacteria also process energy to support its cellular
Cellulose - the cell wall of plants activities. But which of the organelles
Chitin – the cell wall of fungi. controls the orders, masters the plan,
commands the responses to its
environment? Just like a factory building,
ROLE OF CELL WALL the cell needs a “command center” that
It is a rigid structure that provides would direct and give instructions on what
protection and structural support to cells. processes or activities will take place.
NUCLEUS

The three types of RNA produced in the nucleus:
ribosomal RNA (rRNA), messenger RNA (mRNA)
and transfer RNA (tRNA).

★ THE COMMAND CENTER OF THE CELL
★ The importance of the nucleus in the cell
is that it is the one that specifies the code
for protein synthesis.
NUCLEOLUS
CHROMATIN
★ The nucleolus, which is a dark region of
★ The nucleus contains chromatin and a
chromatin, produces the ribosomal RNA.
semifluid matrix called the nucleoplasm.
This is where the rRNA joins with proteins
Chromatin is a network of strands that
to form the subunits of ribosomes.
condenses and undergoes coiling into
rod-like structures called chromosomes.

NUCLEAR ENVELOPE
CHROMOSOMES
★ The nuclear envelope is a double
membrane that is similar to the plasma
★ The chromosomes are carriers of genetic
membrane of the cell. It physically
information and that the nucleus is the
separates the nucleus from the cytoplasm
command center of the cell. The number
but is still able to communicate with the
of chromosomes in a cell depends on the
cytoplasm through the nuclear pores
species; for example, each cell of the
human body contains 46 chromosomes,
NUCLEAR PORES
rice cells have 24 and dog cells have 78.
★ The nuclear pores permit the passage of
ribosomal subunits and mRNA out of the
The chromatin and the chromosomes contain
nucleus into the cytoplasm. It also
DNA and some RNA. Genes, are composed of
facilitates the passage of proteins from the
DNA which are units of heredity located on the
cytoplasm into the nucleus.
chromosome.
★ The nuclear pore complexes act like
gatekeepers to regulate what comes in
and out of the nucleus.
RIBOSOMES ROUGH ENDOPLASMIC RETICULUM
- There are attached ribosomes in the RER.
These ribosomes produce proteins that will be
inserted into the growing endoplasmic reticulum
membrane, transported to other organelles and
eventually exported.
- Some products manufactured by rough
endoplasmic reticulum are dispatched to other
★ Ribosomes are the organelles that use locations in the cell by means of transport
instructions from the nucleus, written in vesicles which are sacs made of the membrane
mRNA, to build proteins. Ribosomes are that bud off from the rough endoplasmic
composed of small and large subunits. reticulum.
★ These can be found in the cytosol, which
are called free ribosomes. They can also SMOOTH ENDOPLASMIC RETICULUM
be attached to the outside of the - Just like the rough endoplasmic reticulum, it
endoplasmic reticulum or nuclear also forms vesicles that transport molecules to
envelope, as bound ribosomes. other parts of the cell.
- Enzymes of the smooth endoplasmic reticulum
The DNA programs protein production in the are important in the synthesis of lipids, including
cytoplasm by transferring its coded information to oils, phospholipids, and steroids.
a molecule called messenger RNA. The mRNA - Another function of smooth endoplasmic
molecule then carries the order to build a certain reticulum is the storage of ions. It also houses
type of protein from the nucleus to the cytoplasm. enzymes that detoxify drugs and poisons.

The mRNA exits through pores in the nuclear COLGI BODIES
envelope and travels to the cytoplasm, where it ★ An organelle named for its discoverer, an
then binds to ribosomes. The ribosome moves Italian scientist named Camillo Golgi, the
along the mRNA, translating the genetic Golgi apparatus or Golgi bodies work in
message into a protein with a specific amino acid close partnership with the endoplasmic
sequence. reticulum. It serves as a warehouse and
processing station for products
ENDOMEMBRANE SYSTEM manufactured by the endoplasmic
- The endomembrane system consists of the reticulum.
endoplasmic reticulum, the Golgi bodies, and
many vesicles. The vesicles transport molecules LYSOSOMES
from one part of the system to another. It is a
series of interacting organelles between the
nucleus and the plasma membrane. Many of
these organelles interact in the synthesis,
distribution, storage, and export of molecules.

ENDOPLASMIC RETICULUM
- The endoplasmic reticulum is one of the main
manufacturing facilities within the cell. It consists
of a system of membranous channels and
saccules that is physically continuous with the
nuclear envelope.
 It takes up to 90% of the cell’s volume
which is filled with fluid called cell sap that
gives added support to the cell.

ENERGY HOUSES
★ The cell needs energy houses that can
manage the production of ATP. The cell
requires a continuous supply of energy to
perform the work of life. Energy is very
important in every cellular process
★ A lysosome is a membrane-enclosed sac because it powers each process to make
of digestive enzymes that is absent in it possible for the cell to survive.
plant cells. It is developed from vesicles MITOCHONDRIA
that bud off from the Golgi bodies. It has a ★ Mitochondria are often called the
very low pH and stores powerful powerhouse of the cell because it
hydrolytic-enzymes in an inactive state. converts the chemical energy of foods that
★ Lysosomes destroy nonfunctional produce most of the cell’s ATP in the
organelles and portions of cytoplasm, process of cellular respiration, wherein the
breakdown wastes, ingests cells, and oxygen is used and the carbon dioxide is
cellular debris delivered by other vesicles. given off.
★ It provides an acidic environment for its
enzymes without affecting other CHLOROPLAST
organelles of the cell. This organelle also ★ Chloroplasts are unique to plant and algal
serves as recycling centers. cells which perform photosynthesis.

PEROXISOMES
★ All peroxisomes contain enzymes that MITOCHONDRIA VS. CHLOROPLAST
result in the creation of hydrogen peroxide
(H2O2 ) which is a toxic molecule that is
immediately broken down to water (H2O)
and oxygen (O2 ) by another peroxisomal
enzyme called catalase.
★ Peroxisomes perform metabolic
assistance to organelles. They have
varied functions but they specialize in
synthesizing and breaking down lipids.
They also break down fatty acids, amino Mitochondria are present in all eukaryotic cells
acids, and toxins such as alcohol. including plant and algal cells. Even though
mitochondria are smaller than chloroplasts, they
VACUOLES can usually be seen using a light microscope.
★ The large sacs of membrane or vesicles The number of mitochondria can vary depending
that bud from the endoplasmic reticulum, on the metabolic activities and energy needed
Golgi bodies, or plasma membrane are within a cell.
called vacuoles.
★ The central vacuole of a plant cell is a On the other hand, chloroplasts are only
versatile compartment that stores organic present in plant cells and some algal cells have
nutrients, such as proteins and poisons, one chloroplast only. It can be quite large, twice
that protect against plant-eating animals. as wide and as much as five times the length of
the mitochondria. Chloroplasts have a
three-membrane system. The grana are the solar This is comparable to a mansion that has
power packs of the chloroplasts which trap light several rooms or compartments.
energy and convert it into chemical energy. Domain Eukarya which includes protists,
fungi, plants, and animals are examples of
eukaryotes. Eukaryotes are organisms
that consist of eukaryotic cells.

PRESENCE OF A NUCLEUS
In a prokaryotic cell, the genetic materials
(DNA) are concentrated in a region of the
cytoplasm called the nucleoid. The term
prokaryotic comes from the Greek terms
prowhich means before and karyon or
kernel that refers to the nucleus.On the other hand, the term eukaryotic
comes from the Greek terms eu meaning
true and karyon or kernel.

CELL WALL AND CELL MEMBRANE
The cell wall is present in almost all
prokaryotic cells, but not in most
eukaryotic cells (these are not found in
WEEK 4:
animals and most protists]. Structurally,
the cell wall of prokaryotes is made up of
PROKARYOTIC CELLS
peptidoglycan - a complex sugar
A prokaryotic cell is a type of cell that
(polysaccharide] and a few amino acids.
does not have a nucleus and
eukaryotes, it is either made up of
membrane-bound organelles within its
cellulose as in plants and chitin in fungi.
cytoplasm.
Prokaryotes do not have sterols in the cell
Prokaryotes are small, single-celled
membrane but have a sterol-like lipid
organisms that have prokaryotic cells.
component called hopanoid.
These organisms are metabolically
In eukaryotic cells, the sterols that are
diverse because they can utilize different
present in the cell membrane are
nutrients and energy sources and they
cholesterol (animals], phytosterol (plants],
can inhabit all types of environments on
and ergosterol (fungi)
Earth. All bacteria that include the
organisms of domains Archaea and
ENDOMEMBRANE SYSTEM AND OTHER
Bacteria are considered prokaryotes.
ORGANELLES
The endomembrane system is bresent
EUKARYOTIC CELLS
in eukaryotic cells, but not in prokaryoti
The other type of cell that is characterized
cells. Other organelles like mitochondria
by the presence of a nucleus and
and chloroplast are also present in
membrane-bound organelles within its
eukaryotic cells, but not in prokaryotic
cytoplasm is called a eukaryotic cell.
cells.
Membrane-bound organelles of eukaryotic
The presence of organelles in eukaryotic
cells provide compartmentalization in the
cells provides compartmentalization. It
cell.
increases the surface area-volume ratio of
 the cells, allows the occurrence of
simultaneous cell activities without MODE OF REPRODUCTION
interference from each other, and allows Most prokaryotic cells reproduce through
the separation of DNA the nucleus, binary fission and some reproduce
mitochondria, and chloroplast. through spores.
Binary fission is a process of reproduction
RIBOSOMES wherein one cell is divided into two new
Ribosomes are present in both prokaryotic cells.
and eukaryotic cells. These have the In eukaryotic cells, individual cells
same function in both, which is protein reproduce through mitosis and meiosis.
synthesis. Mitosis (somatic or body cell division] and.
In a prokaryotic cell, all ribosomes are meiosis (sex cell division! are types of cell
found in the cytoplasm. In eukaryotic cells, division, in eukaryotic cells.
they can be found in the cytoplasm, outer
nuclear membrane, rough endoplasmic DNA REPLICATION
reticulum, mitochondrion, and chloroplast. DNA replication in eukaryotes takes a
longer time than in prokaryotes because
SHAPE OF DNA AND NUMBER OF eukaryotes have more DNA than
CHROMOSOMES prokaryotes. In prokaryotic cells, DNA
DNA is the genetic material in replication occurs in two opposing
chromosome) prokaryotic and eukaryotic directions at the same time in the
cells. It codes for protein and RNA. In cytoplasm.
prokaryotic cells, DNA is found in the On the other hand, eukaryotic cells have
nucleoid region of the cytoplasm. multiple points of origin and use
Prokaryotes, as well as the mitochondrion unidirectional replication within the
and the chloroplast, have covalent, nucleus.
closed, circular DNA that is not coiled in
protein "spools" called histones. Most TRANSCRIPTION AND TRANSLATION
prokaryotes have only one chromosome In prokaryotic cells, transcription and
and an extrachromosomal DNA called a translation can be done at the same time
plasmid. in the cytoplasm.
In eukaryotic cells, the linear DNA is Aside from that, there is no
coiled in histones and is found inside the post-transcriptional processing because
nucleus. the DNA of prokaryotes does not have a
Eukaryotes have more than one non-coding part called introns.
chromosome so histones are essential in In eukaryotic cells, the transcription occurs
packaging DNA into nucleosomes and in the nucleus and the translation occurs in
helping it to the cytoplasm.
Condense into chromatin. Through this, Eukaryotic DNA contains exons (coding
several chromatins can fit into the nucleus part] and introns (non-coding part).
without the high risk of mechanical Post-transcriptional processing is done in
damage. eukaryotes to remove introns and come up
with the final RNA
CELL SIZE
Prokaryotic cells are smaller compared to STRUCTURES AND FUNCTIONS OF ANIMAL
eukaryotic cells. Typical, prokaryotic cells CELLS
can range from 0.1 to 5um in. diameter
while eukaryotie cells are typically 10 to - Tissues are groups of cells that are similar in
100um in diameter. structure and function. In animals, there are four
main types of tissue—epithelial, connective, and multinucleated (with more than one
muscle, and nervous tissues. nucleus). -They pull the bone and skin
when they contract to cause movement.

EPITHELIAL TISSUE 2. SMOOTH MUSCLE
➔ Epithelial tissue or epithelium is a type of - Smooth muscle or visceral muscle is a
animal tissue that forms the inner and type of muscle tissue commonly found in
outerlining of organs, the covering in the walls of hollow organs such as
surfaces, and the primary glandular tissue intestines, stomach, bladder, blood
of the body. In terms of structure, vessels, and uterus.
epithelial cells are closely packed to form
continuous sheets. This kind of structure - It involuntarily contracts slower than the
allows epithelium to form linings and other two types of muscle tissue. Smooth
impart protection to bodily structures muscles are nonstriated, uninucleated,
and spindle-shaped (have pointed ends)
Cell junctions like desmosomes and tight cells.
junctions permit the cells of epithelial tissue to
absorb and filter different substances
CARDIAC MUSCLE
CONNECTIVE TISSUE - Cardiac muscle is a muscle tissue found
➔ Connective tissue is the most abundant in the heart. Unlike a skeletal muscle, it is
tissue in the body that connects body uninucleated (one nucleus) and it moves
parts. Unlike the avascularized epithelial involuntarily (cannot be controlled
tissues, most connective tissues are consciously). However, it has striations
vascularized (with constant lood supply like skeletal muscle.
from blood vessels) except tendons and
ligaments. - Cardiac muscle cells are branching
together and fit tightly together at
If epithelial tissues have a basement membrane, junctions called intercalated disks. These
connective tissues have an extracellular matrix. disks contain gap junctions that facilitate
the rapid conduction of electrical impulses
MUSCULAR TISSUE across the heart
➔ Muscular tissue, or simply muscle, is
made up of specialized cells that can NERVOUS TISSUES
shorten or contract to produce ➔ Nervous tissue makes up the central
movements. Muscle tissues consist of nervous system and peripheral nervous
long and extensive muscle fibers. Three system. It is composed of neurons and
types of muscle tissues differ in structure neuroglia or supporting cells.
and function. ➔ A neuron is made up of the cell body or
soma, dendrite, and axon.

TYPES OF MUSCLE TISSUES The dendrite is the receiver of electrochemical
signals from external stimuli or adjacent neurons.
1. SKELETAL MUSCLE It transmits incoming signals towards the cell
- Skeletal muscle is a muscle tissue body.
attached to the skeleton or bones. These
muscles can be controlled consciously or The cell body or soma contains the nucleus and
voluntarily. Skeletal muscle cells are long, specialized organelles that produce molecules
cylindrical, striated (with visible stripes), needed by the neuron. Electrochemical signals
will be transmitted away from the cell body by Rudolph Virchow. Cells, in a particular part of
through the axon a body, have specific functions.
- When a group of cells is performing the same
➔ The cell body or soma contains the function, they are considered as tissues. There
nucleus and specialized organelles that are different types of cells found in an organism’s
produce molecules needed by the neuron. body.
➔ Electrochemical signals will be - In plants, tissues can be classified as
transmitted away from the cell body meristematic and permanent tissues. These
through the axon. tissues are generally responsible for growth,
support, and transport.
The axon is surrounded by an insulating layer
called the myelin sheath that allows impulses to MERISTEMATIC TISSUES
transmit quickly and efficiently along the neuron. ★ Meristematic tissues are composed of
The periodic gaps between myelin sheaths on an cells that give rise to another set of cells.
axon are called Nodes of Ranvier. ★ The cells produced from meristematic
tissues can either stay as meristematic
Between two neurons, or a neuron and a muscle cells to continually produce more cells or
or gland, there is a neural junction or synapse transform into specialized cells which will
where the transmission of electrochemical become parts of some tissues and organs
signals occurs. of a growing plant.
★ Meristematic tissues are mainly
THREE TYPES OF NEURONS responsible for the growth of a plant. They
1. SENSORY NEURON also give rise to essential parts of a
- Sensory neurons are usually unipolar or growing plant. Apical and lateral
pseudounipolar with an axon that meristems are the major meristematic
branches into two extensions. The first tissues found in plants.
one is connected to the dendrite that
receives sensory input, and the other one APICAL TISSUES
transmits the information to the central ★ The height of plants is attributed to the
nervous system. work of apical meristems. These
meristems are located on the shoots and
2. INTERNEURON roots of the plant. As apical meristems
- Interneurons are bipolar or multipolar divide to produce new cells, they are also
neurons with one axon and multiple elongating the root and shoot systems by
dendrites. It connects the sensory neuron producing the primary plants’ body which
to the motor neuron. includes the dermal, vascular, and ground
3. MOTOR NEURON tissues.
- Motor neurons are multipolar neurons ★ Elongation of the root and shoot systems
that carry electrochemical signals from the is referred to as primary growth in plants.
CNS to the muscles or glands. Apical meristems, located at the root tips
and terminal buds in a plant’s shoots, are
continuously dividing to produce primary
meristems.
STRUCTURES AND FUNCTIONS OF PLANT ★ Primary meristems are derivatives of
CELLS apical meristems consisting of protoderm,
procambium, and ground meristem which
PLANT TISSUES will, later on, give rise to the plants’ three
- All organisms are made of cells,” is one of the tissue systems-- epidermis, stele (xylem
statements in cell theory which was formulated
 and phloem), and ground tissues, ★ In leaves and in stems, the epidermis has
respectively. tiny outgrowths called trichomes. These
hairlike outgrowths prevent water loss and
LATERAL MERISTEMS reflect excess light. When young woody
★ A plant does not only increase in height plants mature, the epidermis is replaced
but also increases in diameter. In most by periderm which is produced by cork
plants, growth in diameter and girth is an cambium.
essential factor for survival because it The lower and upper parts of leaves are
increases the plants’ rigidity and protected by the epidermis. The lower epidermis
sturdiness. of a leaf has guard cells.
★ A growth in diameter and girth is called
secondary growth which results from the
continuous division of lateral meristems. Guard cells are specialized structures that
★ Vascular cambium and cork cambium are regulate the opening and closing of stomata.
the lateral meristems found along the Stomata are slit-like structures on the lower
length of the plant which causes the epidermis of leaves which aids in the exchange
increase in diameter and girth of plants. of gases between plants and the environment.

VASCULAR CAMBIUM
★ Vascular cambium gives rise to secondary GROUND TISSUES
xylem and phloem. Inward growth of ★ Cells that are neither dermal nor vascular
vascular cambium produces xylem, while are called ground tissues. They are
an outward growth produces phloem considered as fillers of plants and form the
★ As vascular cambium grows, layers of bulk of plants.
secondary xylem are added which ★ Ground tissues are usually found between
becomes wood. When wood develops, dermal and vascular tissues. The ground
plants become sturdy and rigid. tissues found on the exterior of vascular
tissues are referred to as cortex.
SIMPLE PERMANENT TISSUES
★.Simple permanent tissues are composed Meanwhile, pith is found at the center of the
of one kind of cell, while complex stem. These simple permanent tissues are
permanent tissues are composed of two generally responsible for photosynthesis,
or more kinds of cells. support, and storage. Parenchyma, collenchyma,
★ Ground and epidermal tissues are and sclerenchyma are the kinds of ground
considered as simple permanent tissues. tissues found in plants that differ in function and
On the other hand, xylem and phloem are in location.
considered as complex permanent
tissues. PARENCHYMA CELLS
★ Parenchyma cells have thin and flexible
primary walls but lack secondary walls.
EPIDERMAL TISSUES These cells are mostly responsible for the
★ Epidermis covers the whole body of synthesis and storage of plant food.
nonwoody and young woody plants and is ★ Parenchyma cells in leaves contain
protected by a waxy cuticle. The cuticle chloroplasts and perform photosynthesis.
prevents loss of water and invasion of In stems and in roots, parenchyma cells
disease-causing microorganisms. contain plastids that act as storage of
★ The epidermis in roots has tiny projections starch, which is a complex sugar found in
called root hairs which help in increasing most plants.
the absorption capacity of roots.
COLLENCHYMA CELLS ★ Sugar and other organic nutrients are
★ Unlike parenchyma, the primary walls of distributed throughout the plant’s body by
collenchyma are relatively thick although phloem. Phloem is composed of sieve
its thickness is uneven. tubes consisting of sievetube elements.
★ Collenchyma lacks secondary walls and ★ Sieve-tube elements are cells where
their primary walls do not contain lignin, nutrients, sucrose, and organic
which is a polymer providing rigidity. This compounds are transported.
thus provides a furnishing flexible
msupport to immature parts of plants.
SPECIALIZES CELL AND CELL STRUCTURES
SCLERENCHYMA
★ Sclerenchyma provides support and - Cells with these unique structures are called
rigidity to plants. It has two kinds, namely modified or specialized cells. All specialized cells
sclereids and fibers. Sclereids strengthen have undergone cell modification, a process in
seed coats and are responsible for which cells develop special structures to carry
gritty-textured flesh of some fruits. out their specific functions. Modification in cells
★ On the other hand, fibers are used includes an increase in the number of organelles
commercially as components of making like mitochondria in the muscle cells or the loss
rope and flax fibers. of organelles like the nucleus in the red blood
cells.
COMPLEX PERMANENT TISSUES
★ Plants need a constant supply of food, SPECIALIZED CELLS AND CELLS
water, and minerals for their survival. The STRUCTURE IN ANIMALS
distribution of food, water, and minerals
are acted upon by xylem and phloem. MICROVILLI
Microvilli (singular, microvillus) are
specialized structures on the surface of
epithelial cells. These cellular extensions
XYLEM are made of actin microfilaments that
★ Xylem is composed of two types of serve as their structural core.
conducting cells— tracheids and vessel A microvillus’ average diameter and length are
elements. Tracheids are thin and 0.1 and 2 micrometers, respectively. They are
elongated cells where water passes found in the small intestines, kidneys, egg cells,
through. and white blood cells.
★ Tracheids, as well as vessel elements,
have thin primary walls but thick CILIA AND STEREOCILIA
secondary walls. Their secondary walls Cilia (singular, cilium) are tiny hair-like
have pits that allow the transport of water projections on the surface of epithelial
from one cell to another. cells. Cilia in the bronchioles which are
★ The thick secondary walls of tracheids responsible for ensuring that the
serve as a rigid and strong wall against respiratory tract is free of dust, dirt, and
the tension of water transport. Moreover, pathogens.
vessel elements are thin-walled cells of Cilia are found on the respiratory tract.
xylem. Unlike tracheids, vessel elements These hairlike structures above the
have perforated plates that allow the pseudostratified epithelia of the trachea
transport of water through the vessels. prevent mucus (from goblet cells),
bacteria, and dirt from entering the lungs.
PHLOEM Stereocilia (singular, stereocilium) are
surface extensions of the epidermis which
 can be found in the epididymis of the junctions are cell junctions found in
testis and in the inner ear of humans and epithelial tissues.
animals. Tight junctions are found surrounding each cell
Stereocilia in the epididymis (which is a and serve as impermeable structures that
duct or passageway in the male prevent leakage of substances when transmitted
reproductive system through which sperm from one cell to another.
cells pass) absorb the fluid that propels Adherens junctions and desmosomes are
sperm cells from the seminiferous tubules specialized protein structures responsible
stereocilia in the inner ear serve as for connecting adjacent cells.
sensors of vibrations. Aside from sensing Adherens junctions are found below tight
vibrations, stereocilia also transform these junctions, while desmosomes are found
vibrations into neural signals that will be below adherens junctions.
interpreted by the brain. Gap junctions serve as channels of ions,
water, and other essential substances
FLAGELLA needed by cells.
The flagella (singular, flagellum) are
tail-like structures that provide motility to RED AND WHITE BLOOD CELLS
cells. Red blood cells or erythrocytes are blood
Flagella are found in sperm cells which cells that lack nuclei and mitochondria.
help them travel from the male The absence of a nucleus and
reproductive tract to the egg cell in the mitochondria in each red blood cell allows
fallopian tube. it to perform its work properly. Red blood
cells are responsible for transporting
oxygen throughout the body. The lack of
BASAL AND HEMIDESMOSOMES nucleus in red blood cells gives more
Basal infoldings and hemidesmosomes space for hemoglobin—a protein that
are both found at the basement carries oxygen; thus, more oxygen
membrane of epithelial cells. molecules can be transported.
Epithelial cells sit on a basement White blood cells, also known as
membrane that serves as their foundation. leukocytes, are specialized mcells that are
Hemidesmosomes are the ones that classified into granulocytes and
anchor epithelial cells to their basement agranulocytes. Granulocytes are white
membrane. blood cells that contain granules in their
Epithelial cells found in the salivary glands cytoplasms which are observable under a
and excretory duct contain basal light microscope. These cytoplasmic
infoldings in their basement membrane. granules are enzymes that digest
These basal infoldings increase the pathogens that can cause diseases in the
surface area of these cells. Moreover, body.
basal infoldings are responsible for ion
and fluid transport.

CELL JUNCTIONS SPERM AND EGG CELLS
Cell junctions are specialized structures Gametes or sex cells are considered as
found on the lateral membrane of the structures that specialize cells because of
cells. They are responsible for adhering their distinct structures that help them
cells to other cells or to the extracellular carry out their specific functions.
matrix. Tight junctions, adherens Egg cells or ova (singular, ovum), with a
junctions, desmosomes, and gap diameter of 0.12 micrometers, are the
largest cells in humans. Egg cells have
 two outer membrane layers namely zona Root hairs are tiny hair-like structures that
pellucida and corona radiata. originated from the epidermis of plants. These
Zona pellucida is the inner layer of the egg’s specialized structures die off after 2 to 3 weeks
outer membrane. It assists the sperm cell upon but are constantly replaced by new ones to
fusion with the egg cell. maintain the efficiency of water absorption.
The outermost layer is the corona radiata
which consists of three layers of cells
derived from follicles. The two outer
membrane layers of the egg cells prevent MESOPHYLL CELLS
polyspermy—an event when an egg cell is Photosynthesis happens in the mesophyll
fertilized by more than one sperm cell. layer of the leaves located between the
Sperm cells, by contrast, are relatively lower and upper epidermis.
small compared with the egg cells. Sperm This layer is the specific site of
cells are specialized cells that have a photosynthesis as it contains a large
flagellum. The flagella in sperm cells help number of chloroplasts
them move from the reproductive tract of ★ The palisade cells are elongated and
males to that of females. The sperm cells cylindrical and form a palisade layer
have three distinct parts— head, beneath the upper epidermis of the
midpiece, and flagellum. leaves. Because of their shape, palisade
The sperm’s head contains acrosome that cells accommodate 70% of the plant’s
helps them penetrate the egg cell’s outer chloroplasts. The arrangement and
membrane, while the midpiece contains location of palisade cells allow them to
numerous mitochondria that provide obtain enough sunlight needed for
energy to the flagellum. The tail-like photosynthesis.
region in the figure is the flagellum itself ★ Spongy mesophyll cells are
which provides motility to the sperm cell. irregularly-shaped cells found beneath the
palisade layer and above the lower
epidermis of leaves, Cells in this layer are
SPECIALIZED CELLS AND CELL loosely packed and have many spaces in
STRUCTURE IN PLANTS between them. The spaces between the
❖ Trichomes are hair-like structures that cells in the spongy layer allow more
develop from the plant’s epidermis and efficient gas exchange during
are mostly found on the leaves. They may photosynthesis.
be unicellular or multicellular. Their size
and functions vary from one type of plant CELLS OF XYLEM AND PHLOEM
to another. ★ Xylem and phloem are not themselves
❖ Trichomes with glands on their tip release cells but are instead composed of
chemicals that prevent some insects from specialized cells that play a vital role in a
feeding on plants. But trichomes may also plant’s growth and development. These
produce chemicals that some useful are tube-like cells that transport water,
products are derived from, like mint nutrients, and food throughout the plant’s
fragrance. body.
★ Xylem comprises cells that are specifically
responsible for transporting water and
ROOT HAIRS nutrients obtained from the soil.
❖ Root hairs are specialized cell structures ★ Phloem comprises cells that are
that help plants to efficiently absorb water responsible for transporting food, usually
from the soil by increasing the surface the by-products of photosynthesis.
area for absorption.
 - Much like entire organisms, individual cells also
WEEK 5 : CELL CYCLE AND CELL DIVISION have their own life cycle. The life cycle of a cell is
known as the cell cycle, and this describes how
- Any sexually reproducing multicellular cells grow develop, and reproduce.
organisms begins as a single-celled entity.
- The single-celled entity then relies on The cell cycle involves different phases that
cellular events to produce more cells, the constitute a series of preparations for a cell to
early stage of which is shown in the blastula divide to produce new cells.

GENETIC MATERIAL OF THE CELL

DNA MOLECULE
➔ Almost, every cell in our bodies has
genetic material in the form of
deoxyribonucleic acid (DNA].
➔ Most biological traits such as eye color,
hair color, and height are coded for by the
DNA. STAGES OF THE CELL CYCLE
➔ DNA, the primary genetic material of living
organisms, stores genetic information in
the sequences of its nucleotides.
➔ Positively charged Histone proteins aid in
DNA packaging.

CHROMATIN
➔ Interphase DNA is found in the form of
chromatin, a complex of DNA and
proteins.
- Chromatin in dispersed inside the intact cell
nucleus during interphases
- Chromatin will sometimes need to further
condense into a highly coiled and compact
structure.
- This highly condensed form of DNA is known as
a chromosome.

NOTE: Humans have 46 individual (or 23 pairs)
of chromosomes.
Chromatin condenses into chromosomes.
Each half of the chromosome is a
chromatid.
1. INTERPHASE - GAP 1
Growth of cytoplasm and doubling of
INTRODUCTION TO CELL CYCLE
- All species of organisms have their own life cycle organelles
that shows how they are born, develop, and Produce proteins, enzymes, nutrients, and
mature. energy
Highest rate of protein synthesis
 Movement of centrioles of the
centrosomes away to await and assist the THE CELL CYCLE CHECKPOINTS
events of mitosis.

2. INTERPHASE - S
This stage is named so because it is when
the cell synthesizes a copy of its DNA in a
very notable process called DNA
replication.
- This refers to the event when an
existing DNA produces another
copy of itself. G1 TO S CHECKPOINT
- Is there any damage in the cell’s DNA?
- Is the cell large enough with all the necessary
energy reserves and doubled organelles?

G2 TO M CHECKPOINT
- Are the environmental conditions favorable for
cell division to take place? Is there a place?
- is the DNA properly replicated?
- is there a presence of DNA damage?

M CHECKPOINT
- Are there spindles properly attached?

3. INTERPHASE - GAP 2
Continued growth and the production of
materials that are necessary for cell
division to occur.
Protein synthesis but not at the rate
similar to that of the G1 phase.

4. M- PHASE
MITOSIS AND MEIOSIS
The M phase in eukaryotic organisms
involves either one of two processes,
namely, mitosis and meiosis. STAGES OF MITOSIS
Mitosis refers to how a cell divides to
- Sex cells or gametes undergo
produce new cells.
meiosis, whereas somatic cells or
Only somatic cells (also known as body
non-sex cells) undergo mitosis.
- cells undergo mitosis.
5. CYTOKINESIS NOTE: A cell will only begin mitosis if the conditions
Cytokinesis is marked by the formation of are correct and favorable for cell division.
a cleavage furrow in animal cells.
THE ROLE OF MITOSIS IN THE CELL CYCLE

M Phase
- The cell undergoes mitosis if it is a somatic cell or
meiosis if it is a sex cell.
- It allows the cell to divide and produce new cells.

G0
Resting State
G1 CHECKPOINT
Checks for: Nutrients, Growth factors,
DNA damage
METAPHASE CHECKPOINT
Checks for: Chromosome spindle THE PHASES OF MITOSIS
attachment.
G2 CHECKPOINT 1. PROPHASE
Checks for: Cell Size, DNA replication

NOTE
The synthesis phase involves the
duplication of the cell’s DNA.
The Chromosome DNA in interphase is
found in the form of chromatin which
condenses during mitosis. ➔ The chromatin condense into
Each chromosome is made up of two chromosomes.
sister chromatids. ➔ The nucleolus disintegrates.
➔ The mitotic spindle starts to form.
Haploid and Diploid Cells
➔ The human genome has 23 pairs of
chromosomes for a total of 46
chromosomes in each cell. 1.1 PROMETAPHASE
➔ 23 is the haploid number whereas 46 is ➔ It begins after the nuclear envelope
the diploid number. ➔ breaks down.
➔ Haploid is often represented as n while ➔ The centrosomes move to opposite poles.
diploid is 2n. ➔ The kinetochores found at the
➔ The number of sets of chromosomes that centromeres become apparent.
a cell or an organism has is known as
ploidy
2. METAPHASE
 ➔ The microtubules of the mitotic spindle In Telophase, the parent cell starts to form
attach and interact with the kinetochores Two new cells.
of the chromosomes.
➔ The chromosomes align at the center of CYTOKINESIS
the cell, in the metaphase plate. ➔ After telophase, cytokinesis will divide the
cell into two.
➔ Cytokinesis is not a phase of mitosis but
3. ANAPHASE is closely related to it.
➔ Recall from the previous lesson that each
of the two daughter cells will inherit a
nucleus, similar genetic material,
organelles, and more.

➔ The mitotic spindle pulls and separates
the sister chromatids apart.
➔ The chromatids, now called daughter
chromatids, are then pulled toward the
opposite poles.

WEEK 6:
4. TELOPHASE
STAGES OF MEIOSIS
➔ Like mitosis, meiosis also refers to how
cells divide to produce new cells.
➔ Sex cells or gametes are produced from
meiotic division.

Meiosis is the M phase that leads to the
➔ Daughter chromatids decondense. production of either sperm cells or egg cells. This
➔ In animals, the boundary of the type of division is very closely tied with the
new cells is known as the cleavage process of sexual reproduction.
furrow.
➔ In plants, it is known as the cell MEIOSIS AND ITS FUNCTION
plate. Production of functional sex cells or
gametes
NOTE!: Two rounds: meiosis I and meiosis II
In Prophase, the cell’s genetic material Reduction in the chromosome number
resembles Polka dots or strings. Allows restoration of original chromosome
In Metaphase, the chromosomes Migrate number during fertilization
to the Middle of the cell.
In Anaphase, the chromosomes move
away from each other.
 ➔ Maternal and paternal chromosomes are
randomly arranged.
➔ Facilitates reduction in chromosome
number.

3. ANAPHASE 1
➔ Separation of the homologous pairs
➔ Maternal and paternal members move to
either pole

NOTE!: 4. TELOPHASE 1 AND CYTOKINESIS
Meiosis involves two rounds of cytokinesis ➔ Chromosomes reach opposite poles.
which will ultimately produce four ➔ The cytoplasm divides.
daughter cells with a reduced
chromosome number. NOTE!: Meiosis II is an EQUATIONAL division.
Meiosis I comes after the G2 phase of the
cell cycle. 1. PROPHASE II
Meiosis I is a REDUCTIONAL division. ★ A new spidle forms around the
chromosomes
1. PROPHASE 1
➔ Chromosome condensation 2. METAPHASE II
➔ Sypnasis between homologous ★ Chromosomes line up at the equator.
pairs
➔ Crossing over between 3. ANAPHASE II
homologous pairs ★ Centrosomes divide.
➔ Chromosomes after meiosis ★ Chromatids move to the opposite poles of
the cells.

4. TELOPHASE II
★ A nuclear envelope forms around each
set of chromosomes.
★ The cytoplasm divides.

DIFFERENCES BETWEEN MITOSIS AND
MEIOSIS

1.1 PROMETAPHASE 1
➔ Further chromosomal condensation
➔ Further disintegration of nuclear envelope
➔ Meiotic spindle formation

2. METAPHASE 1
➔ Alignment of the homologous
chromosomes at metaphase plate
 ❖ Sister chromatids line up and separate into
individual chromosomes in meiosis II.

IMPORTANCE OF CROSSING OVER
Facilitates genetic recombination
Enhances genetic variation
Increases chances of survival

CHANGES IN THE NUMBER OF
CHROMOSOMES

BEFORE S PHASE - Chromosomes are assumed
to be single at G1 phase (2n = 6)

AFTER S PHASE - Chromosomes are duplicated
by the end of S phase (2n = 6)

DURING MEIOSIS I - Duplicated chromosomes
enter meiosis I (2n = 6)
To help you remember:
MiSO: Mitosis for Somatic cells AFTER MEIOSIS I - Chromosome number is
MeGa: Meiosis for Gametes reduced after meiosis I (n = 3)

MEIOSIS II - Sister chromatids are separated after
meiosis II ( n= 3)

THANK YOU!! GOODLUCK SA EXAM MGA
BEBELUVS! PADAYON BESt STUDENTS!!!

Mitosis maintains an identical set of genetic
material in the daughter cells whereas
meiosis reduces this amount and introduces
new combinations.
These have different consequences and
applications as a result.

MEIOSIS I VS. MEIOSIS II
❖ Sypnasis occurs only in Meiosis I
❖ Tetrads line up and separate into individual
homologous chromosomes in meiosis I
❖ Crossing over occurs only in meiosis I