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Summary

This document provides a detailed overview of prokaryotes and eukaryotes, along with an introduction to cell specialization. It discusses cell types (red blood cells, white blood cells, nerve cells, and muscle cells), introducing the mechanisms of bacterial and animal cell specialization.

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PROKARYOTES VS EUKARYOTES
Domains: Bacteria
Archaea
Eucarya
PROKARYOTIC EUKARYOTIC - all in domain Eukaryota /
Eucarya

Simple, unicellular organisms that do not have a Complex, cell has a nucleus enclosed by a
nucleus and membrane bound organelles membrane

Asexual reproduction; binary fission Sexual (meiosis) and asexual
(mitosis)reproduction

Movement by rigid rotating flagellum Movement by flexible (tails of) cilia or flagella
 consists of a single cylinder of protein  contain microtubules and motor proteins
subunits (flagellin) that enable complex movements.

Circle of double-stranded DNA in nucleoid Linear and organized chromosomes in nucleus

Short pieces of circular DNA that replicate NO plasmids
independently are plasmids.

70s ribosome (smaller) 80s ribosome (larger type of ribosome)

Cell wall has a rigid framework of murein, a All have cell membranes but not all eukaryotic
polysaccharide cross-linked by cells have cell walls: Animal cells don’t have.
polypeptidoglycan

 Pili - for interaction to other bacterial KINGDOM PLANTAE
cells; used in infecting cells  Plants
 Presence of Cell Wall
ARCHAEBACTERIA - all in domain Archaea  Plasmodesmata - channel for molecules
 HALOPHILES - salt concentration at from other plant cells
least five times greater than that of the  Large Vacuoles - stores wastes
ocean.
 NO lysosome - Vacuole compensates for
 PSYCHROPHILES - reproduces and this
grows best at low temperatures, VASCULAR - presence of xylem & phloem
typically in the range -10 to 20°C (14 to NON - VASCULAR - no xylem & phloem
68°F).
 THERMOPHILES - an optimum growth KINGDOM FUNGI
temperature of 50o or more, a  Heterotrophs - consumes other
maximum of up to 70oC or more organisms
 METHANOGENS - common in  Gets their nutrients from substrate
wetlands, ocean environments,
digestive tracts of animals KINGDOM ANIMALIA
 Very diverse
EUBACTERIA
 Has all the organelles except chloroplast
 Thrive at room temperature
 Examples: Propionibacterium acnes KINGDOM PROTISTA
(acne); Lactobacillus acidophilus (for
 “Garbage kingdom” - organism placed
digestion)
here if their specific kingdom is
undecided
 Ex. Amoeba, Paramecium, Euglena
Plasmodium
CELL SPECIALIZATION
 Also known as Cell Differentiation
 It is the process by which generic cells change to different types of cells to be able to perform
special or specific functions.
 From stem cells to specialized cells
RED BLOOD CELL (erythrocytes) NERVE CELL or NEURON
 It carry oxygen throughout the body  Carry nerve impulses through body
Characteristics: Characteristics:
 No nucleus - to contain more oxygen  Long, thin axon - carries signal from cell
 Biconcave shape - for better transport body to brain
 Contains hemoglobin - protein  Branching dendrites - receives outside
stimulus
WHITE BLOOD CELL (leukocytes)  Myelinated - covered by myelin sheath; for
 It play an important role in the immune faster response
system; fights diseases & pathogens
Characteristics:
 Irregular shape - different types
 Can produce antibodies and antitoxins

> Neutrophils: Kill bacteria, fungi, foreign debris
> Monocytes: Clean up damaged cells
> Eosinophils: Kill parasites, cancer cells and
involved in allergic response
> Lymphocytes: Help fight viruses & make
antibodies
> Basophils: Involved in allergic response MUSCLE CELL
SPERM CELL
 Facilitate movement
Characteristics
 Fertilize an egg cell
Characteristics:
 Elongated and elastic
 Long tail to swim for movement  Numerous mitochondria
 Numerous mitochondria - give energy to
tail for quick movement
 Head
 Contains acrosome (acrosin
enzyme) to break the egg cell
membrane and enter
 Contains nucleus for father’s
DNA

EGG CELL GUARD CELL
 Carries genetic material  Regulates rate of transpiration
 For developing embryo  Protects stomata
Characteristics Characteristics
 Large and bulky  Cell wall has varying thickness
 A chemical change in the membrane
prevents fertilization of more than one PHOTOSYNTHETIC CELLS
sperm  Produces food through the process of
photosynthesis
Characteristics
 Contains numerous of chloroplasts
PLANT TISSUES
Tissues - A group of cells that are similar in
structure and/or work together to achieve a
particular function forms a tissue.

Shoot System: flower, leaves, stem
Root System: taproot, lateral roots

Meristematic – Meristos meaning “dividing”
cells; found in the growing areas of plants.
Permanent – “non-dividing cells”; composed
of matured meristematic tissue

MERISTEMATIC TISSUES
Apical Meristem Wood - densely packed in heartwood
 Apical meristems are responsible for Bark > Living phloem: provides nutrients
the primary growth (height) of plants. > Periderm > Cork cambium
 Mitosis phases are seen at root tips > Cork
 Give rise to permanent tissues which > Cork: Cork cells for protection against
will differentiate into specialized cells injuries and microorganisms
with certain functions.
PERMANENT TISSUES

Derivatives of apical meristem (byproducts)
 Procambium: gives way to primary
Simple Permanent Tissues
xylem and phloem
 Composed of one kind of cell
 Ground meristem: food; storage,
photosynthesis
Ground tissue
 Protoderm: protection
o Parenchyma cells - Mostly responsible
for photosynthesis and storage of
Lateral Meristem
food. Thin and flexible cell wall.
 Lateral meristems are responsible for
o Collenchyma cells - Provides a
the secondary growth (girth or
furnishing flexible support to immature
diameter) of plants. Ex. stems
parts of plants. Thin & Thick cell wall.
o Sclerenchyma cell – Thick cell walls
Vascular cambium  Sclereids strengthen seed
o Gives rise to secondary xylem and
coats and are responsible for
phloem. Secondary xylem gives rise
gritty-textured flesh of some
to wood.
fruits
Cork cambium  Fibers are used commercially
o Gives rise to cork cells which replaces
as components of making
epidermis of plants once they
rope and flax fibers.
mature.
o Cork cambium, cork, and phloem
make up the bark.

Parenchyma Collenchyma Schlerenchyma
Dermal Tissue (Epidermis) Phloem
o It covers the whole body of non
woody and young woody plants
o The lower and upper parts of leaves
are protected by this

Parts:
 Cuticle prevents water loss and
invasion of disease-causing
microorganisms.
 Root hairs help in increasing the
absorption capacity of roots.
 Trichomes are hair-like epidermal
outgrowths in leaves and stems that  Phloem is composed of sieve-tube
prevent water loss and reflect excess elements that help in the transport of
light. nutrients throughout the plant’s body.
 Guard cells are specialized structures  Companion cells aid in transportation
at the lower epidermis that regulate of nutrients
the opening and closing of stomata.  Two-way transport of food and
 Stomata are slit-like structures on the nutrients; (1) photosynthesis to roots
lower epidermis of leaves which aid in and (2) soil to leaves
the exchange of gases between
plants and the environment.

 Mesophyll region (Photosynthetic cells)
Palisade mesophyll - photosynthesis
layer
Spongy mesophyll - facilitates the
exchange of gases through air
spaces

Complex Permanent tissues
 Vascular tissues are the only complex
permanent tissues in plants.

Xylem

 Tracheids are thin and elongated
cells where water passes through.
 Vessel Elements have perforated
plates that allow the transport of
water through the vessels.
 One way transport of water
ANIMAL TISSUES
In complex multicellular organisms like animals, cells
come in different structures and functions.
There are different levels of biochemical
organization, and these include the following (lowest
to highest): chemical, organelle, cell, tissue, organ,
organ system, organism, population, community,
ecosystem, and biosphere.
Tissues refer to groups of cells that are similar in
structure and function. The four types of tissues in
animals vary significantly in structure and function
EPITHELIAL TISSUES
 Epithelial tissue or epithelium is a type of animal tissue that forms the inner and outer lining
of organs, the covering in surfaces, and the primary glandular tissue of the body.

Epithelial Tissue No. of layers and Examples Functions
cell shape

Simple Squamous - one layer air sacs or alveoli, site of diffusion or
- flat, scale-like capillary walls – for exchange of
gas exchange substances;
secretion
Simple Cuboidal - one layer glands and their absorption and
- cube shaped ducts, ovaries, and secretion
lining of kidney
tubules
Simple Columnar - one layer walls of the absorption and
- elongated or gastrointestinal tract secretion; contains
column-shaped and body cavities goblet cells that
secrete mucus

Pseudostratified columnar - one layer the lining of the absorption and
- elongated or respiratory tract secretion; usually
column-shaped ciliated; cells have
unequal length and
position of nucleus
forming a false
layering of cells
Stratified Squamous - more than one the epidermis, lining protection against
layer of mouth, abrasion or constant
- flat, scale-like esophagus, and exposure to friction
- “fake” “layer” vagina

Stratified Cuboidal - more than one sweat glands, protection and
layer salivary glands, and secretion
- cube-shaped mammary glands

Stratified Columnar - more than one male urethra and protection and
layer ducts of some secretion
- elongated or glands
column-shaped
CONNECTIVE TISSUES Loose connective tissue
 The basic components of connective  Matrix contains more cells and lesser
tissues vary according to their type fibers than dense connective tissue so
(left, extracellular matrix; right, fibers). it is softer.
 The different connective tissues vary  Adipose tissue or fat tissue (ex.
with the composition of their stomach, mammary gland, skin)
extracellular matrices and the types  insulation, storage (of energy since it
of cells they consist of. is taken from fats)
 All tissues give protection and support
Blood
 Plasma
 Cellular components consist of blood
cells.
 With fibers that are only visible during
clotting because they are made up
of soluble proteins
 Erythrocytes, Leukocytes,
Thrombocytes
 transport of substance, immune
response, and blood clotting

MUSCULAR TISSUE
 The types of muscle tissues differ in
their general structure but more or
less perform the same function, to
elicit movement.

Bone or osseous tissue
 layers of a very hard matrix with
calcium salts and collagen fibers
 strengthen skin and joints
 skull and ribs

Cartilage
 more flexible matrix than bone; to
reduce friction in joints
Skeletal muscle
 cartilage cells called chondrocytes
 Attached to the skeleton or bones
 hyaline cartilage: ribs, nose, trachea
 Long, cylindrical, striated (with visible
 fibro cartilage: spinal cord, knee
stripes), and multinucleated (with
 elastic cartilage: ear, larynx
more than one nucleus)
 voluntary
Dense connective or dense fibrous tissue
 Matrix is predominantly made up of Smooth muscle
collagen fibers and has lesser cells.  Found in the walls of hollow organs
 This is a fibroblast or a fiber-forming such as intestines, stomach, bladder,
cell. blood vessels, and uterus
 Tendon and ligament  Made up of nonstriated,
uninucleated, and spindle shaped
(have pointed ends) cells.
 Involuntary
Cardiac muscle
 Found in the heart
 Uninucleated and striated
 Has intercalated disks - junctions
between muscle fibers that allow for
rapid electric transmission
 Involuntary
NERVOUS TISSUE
 Neuron, the basic unit of the
nervous system, consists of
supporting cells (glial cells) that
support, protect, and insulate
neurons and conduct
electrochemical signals as a form of
information.

Astrocytes
 Located in CNS
 Star-shaped cells that support and
control the chemical environment
around the neurons. These are the
most abundant glial cell in the CNS.

Microglial cells
 Located in CNS
 Ovoid cells in the CNS that can
transform into a phagocytic
macrophage to clean neuronal
debris and wastes.

Ependymal cells
 Located in CNS
 Ciliated cells that line the central
cavities of the brain and the spinal
cord and form a fairly permeable
membrane between the cavities
with cerebrospinal fluid and the
tissues of CNS.

Oligodendrocytes
 Located in CNS
 Responsible for the production of
the myelin sheath which is needed
for faster conduction of signals

Schwann cells
 Located in PNS
 They surround all the nerve fibers
and produce myelin sheath similar
to the oligodendrocytes.
CELL MODIFICATION
General Biology | Quarter 1 STEREOCILIA
- Non-motile modified microvilli
Adaptation or changes acquired by the cell - Actin-based protrusions on auditory and
after the cell division that aids the cell in various vestibular sensory cells for hearing and
beneficial ways. balance. Convert stimuli to electrical signals
- Ex. ears (cochlea), male reproductive part
CILIA
(vas deferens and epididymis)
- Hair-like structures extending from the cell
surface.
- Locomotion and mechanoreception.
- Organisms that possess cilia are known as
ciliates. Use cilia for feeding & movement.

TYPES OF CILIA
Non-motile or Primary cilia (sensory)
- Sensory cellular antenna that coordinates
cellular signaling pathways.
- Ex. photoreceptors of retina, for urine flow
of tubular epithelial kidney cells
Motile (movement)
- Clearing the mucus and dust out of the
lungs
- Ex. Upper respiratory tract, Bronchi,
Oviducts (fallopian tube), Inner ear

Epididymis - Stores sperm and facilitates their maturation,
enabling motility and fertilizing capability before ejaculation.
Vas Deferens - Transports mature sperm from the epididymis
to the urethra during ejaculation

PSEUDOPODS
- ”False feet”
- Temporary extension of the cytoplasm
- For movement and ingestion of particles
during phagocytosis
- Allow cells like amoebas and white blood
FLAGELLA
cells to move and capture food
- Long whip-like structures for locomotion
- Allows cell to swim from one location to
another by rotating a rigid filament
- Ex. Spermatozoa or Sperm

VILLI or MICROVILLI
- Small, slender,
finger-like
projections
- Increases
surface area to
increase
absorption of
nutrients
- Ex. lumen of
small intestine - absorbs nutrients and minerals from
digested food and completes most digestion
CELL CYCLE AND CELL DIVISIONS

Any sexually reproducing multicellular Introduction to Cell Cycle
organism begins as a single -celled entity.  Cell cycle describes how cells grow,
It then relies on cellular events to produce develop, and reproduce.
more cells, the early stage of which is shown  Involves different phases that constitute
in the blastula. a series of preparations for a cell to
divide to produce new cells.
THE GENETIC MATERIAL OF CELLS
DNA Molecule THREE STAGES OF CELL CYCLE
 Almost every cell in our bodies has
genetic material in the form of
deoxyribonucleic acid (DNA)
 The primary genetic material of living
organisms, stores genetic info in the
sequences of its nucleotides
 Most biological traits are coded for by
the DNA.

INTERPHASE
Histones Gap 1
 Positively charged histone proteins aid  Growth of cytoplasm and doubling of
in DNA packaging. organelles
z  Produce proteins, enzymes, nutrients,
Chromatin and energy
 Interphase DNA is found in the form of  Highest rate of protein synthesis
chromatin, a complex of DNA and  Movement of centrioles of the
proteins. centrosomes away to await and assist
 Dispersed inside the intact cell nucleus the events of mitosis
during interphase. S Phase
Chromosomes  This stage is named so because it is
 DNA in interphase in form of chromatin when the cell synthesizes a copy of its
condenses during mitosis DNA in a very notable process called
 Each chromosome is made up of two DNA replication.
sister chromatids
 Humans have 46 individual (or 23 pairs
of) chromosomes
Gap 2 CELL CYCLE CONTROL SYSTEM
 Continued growth, further maturation To ensure that they replicate all their DNA and
and the production of materials that organelles, and divide in an orderly manner,
are necessary for cell division eukaryotic cells possess a complex network of
 Protein synthesis but not at the rate regulatory proteins
similar to that of the G1 phase
Cyclins
MITOSIS OR MEIOSIS  Regulatory proteins whose
 The M phase in eukaryotic organisms concentrations rise and fall at specific
involves either one of two processes times during the eukaryotic cell cycle
 Division of nucleus and genetic material
o Sex cells or gametes undergo meiosis
and produce varied cells
o Somatic cells or non-sex cells undergo
mitosis and produce identical cells

CYTOKINESIS
 marked by the formation of a cleavage
furrow in animal cells; cell plate in plants
 Division of cytoplasm Kinase
 Can only occur once the genetic  Enzymes that catalyze the
material is properly distributed to the phosphorylation of a protein resulting
daughter cells in a change affecting that protein’s
function
o Phosphorylation = turning ON
o Dephosphorylation = turning OFF

Cyclin-dependent kinase (CDK)
o Cdk1
o Cdk2
o Cdk4
o Cdk6

CELL CYCLE CHECKPOINTS
G1-to-S Checkpoint (Restriction point) Cyclin-Cdk Complexes
 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 the DNA properly replicated?
 Is there a presence of DNA damage?

M (metaphase) Checkpoint
 Are the spindles properly attached?
 All the sister
chromatids
correctly
attached to
the spindle
microtubule?
MITOSIS

Mitosis refers to how a cell divides to produce PHASES OF MITOSIS
new cells. Only somatic cells (also known as
body cells) undergo mitosis.

THE ROLE OF MITOSIS IN THE CELL CYCLE
 It allows the cell to divide and produce
new cells.

A cell will only begin mitosis if the conditions PROPHASE
are correct and favorable for cell division.  The nucleolus
- Cell cycle checkpoints check for errors. disintegrates.
- The synthesis phase involves the  The chromatin
duplication of the cell’s DNA. condenses into
chromosomes.
 The mitotic
spindle starts to
form.

METAPHASE
Prometaphase
 Nuclear membrane dissolve
 Proteins (cohesin) attach to the
centromeres creating the kinetochores.
 Microtubules attach at the
kinetochores and the chromosomes
Haploid and Diploid cells begin moving
 The human genome has 23 pairs of
chromosomes for a total of 46
chromosomes in each cell.
 23 is the haploid number whereas 46 is
the diploid number.
 Haploid is n while diploid is 2n.
 The number of sets of chromosomes
that a cell or an organism has is known
as ploidy.
 All human body cells are diploid except
gametes which are haploid. Metaphase
 Microtubules of the mitotic spindle
attach and interact with the
kinetochores of the chromosomes.
 The chromosomes align at the center of
the cell, in the metaphase plate.
ANAPHASE
Early Anaphase
 The mitotic spindle pulls and separates
the sister chromatids apart.
 The chromatids, now called daughter
chromatids, are then pulled toward the
opposite poles.

Late Anaphase
 Chromosomes have almost reached
their respective poles
 Cell membrane begins to pinch at the
center.

TELOPHASE and CYTOKINESIS
 Daughter chromatids decondense.
o In animals, the boundary of the new
cells is known as the cleavage furrow.
o In plants, it is known as the cell plate.

Cytokinesis
After telophase, cytokinesis will divide the cell
into two.
 Cytokinesis is not a phase of mitosis but
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.

TIPS
 In Prophase, the cell’s genetic material
resembles Polka dots or strings.
 In Metaphase, the chromosomes
Migrate to the Middle of the cell.
 In Anaphase, the chromosomes move
Away from each other.
 In Telophase, the parent cell starts to
form Two new cells.
MEIOSIS
General Biology | Quarter 1 Week 7

Like mitosis, meiosis also refers to how cells
divide to produce new cells.
Sex cells or gametes are produced from meiotic
division.
Very closely tied with the process of sexual
reproduction.
Meiosis is the M phase that leads to the
production of either sperm cells or egg cells.
PROMETAPHASE I
MEIOTIC DIVISION - further chromosomal condensation
- further disintegration of nuclear envelope
- meiotic spindle formation

METAPHASE I
- Alignment of the homologous
chromosomes at metaphase plate
- Facilitates reduction in chromosome
number

- Production of functional sex cells or ANAPHASE I
gametes - Separation of homologous pairs
- Reduction in the chromosome number
- Two rounds: meiosis I and meiosis II. Meiosis II TELOPHASE I and CYTOKINESIS
immediately takes place after meiosis I, so - Chromosomes reach opposite poles.
only the latter is preceded by the - Cytoplasm divides
duplication of genetic material
- Allows restoration of original chromosome MEIOSIS II
number during fertilization - EQUATIONAL division because there is no
- Involves two rounds of cytokinesis which will further reduction of the chromosome
ultimately produce four daughter cells with number in daughter cells
a reduced chromosome number.

PROPHASE II
- Preceded by an interkinesis, chromosomes
decondense
- A new spindle forms around chromosomes
MEIOSIS I
- REDUCTIONAL division because it reduces PROMETAPHASE II
the number of sets of chromosomes from - Disintegration of nuclear envelope
two to one
METAPHASE II
- Alignment of the duplicated metaphase II
chromosomes at the metaphase plate

ANAPHASE II
- Centromeres divide
- Separation of sister chromatids
PROPHASE I
- Chromosome condensation, synapsis,
TELOPHASE II
crossing over
- Formation of daughter cells
- Nuclear envelope breaks down
- A nuclear envelope forms around each set
of chromosomes
- Cytoplasm divides
-
MITOSIS AND MEIOSIS DIFFERENCE CHANGES IN # OF CHROMOSOME

Syndromes
Nondisjunction - uneven distribution of chromo.

Synapsis involves the pairing of the members of
homologous chromosomes so as to allow them
to undergo crossing over and to segregate
them.
Crossing over refers to the exchange of
segments between non-sister chromatids of
homologous chromosomes. Ultimately, this
enhances the genetic diversity of species.
Importance:
- facilitates genetic recombination Down Syndrome or Trisomy 21
- enhances genetic variation - Extra chromosome 21
- increases chances of survival - Some physical
characteristics of the down
Number of chromosomes of daughter cells syndrome include the following: protruding
tongue, small stature, and a short neck,
eyes that slant upward.

Klinefelter Syndrome
- Extra X chromosome
- Typically have small testes
- May have low muscle tone
and problems with
coordination
- Wide hips, breast development, narrow
shoulders, poor hair growth

Cri du chat syndrome
- Chromosome 5 is missing
- Mitosis maintains an identical set of genetic - High-pitched cry sounds like cat
material in the daughter cells whereas - Small head size, low birth
meiosis reduces this amount and introduces weight, and weak muscle tone
new combinations. These have different - Widely set eyes, low-set ears, a small jaw,
consequences and applications as a result. and a rounded face.
MEIOSIS I and MEIOSIS II DIFFERENCE Turner’s syndrome
- Synapsis occurs only in meiosis I. - All X chromosomes is missing
- Crossing over occurs only in meiosis I. - Below average in height and they
- Tetrads line up and separate into individual experience early loss of ovarian function
homologous chromosomes in meiosis I.
- Sister chromatids line up and separate into
individual chromosomes in meiosis II.
- Meiosis I and II are also different in terms of
the segregating elements. Meiosis I entails
the separation of the members of the
homologous chromosomes, whereas
meiosis II involves the separation of the
sister chromatids
DEFINITION OF TERMS:

Centrosome
Kinetochore
- The structure that organizes microtubules in
- A protein complex located at the
animal cells, consisting of two centrioles. It
centromere
serves as the main microtubule-organizing
- Where microtubular spindle fibers attach to
center (MTOC) and plays a critical role in
pull the chromatids apart during cell
the formation of the spindle apparatus
division.
during cell division.
Centromere
Centriole
- The region of a chromosome where two
- A cylindrical structure made of nine
sister chromatids are held together, and
microtubules arranged in a circle and
where the spindle fibers attach during
found in animal cells
mitosis and meiosis.
- Important for the formation of spindle fibers
Chromatid
during cell division.
- One of the two identical halves of a
Spindle/ mitotic fibre
duplicated chromosome, connected by
- Microtubule fibers that form during cell
the centromere. Sister chromatids separate
division and attach to the chromosomes
during mitosis or meiosis.
- Responsible for separating the
Telomere
chromosomes by pulling sister chromatids to
- The protective, repetitive DNA sequences
opposite poles of the cell.
found at the ends of chromosomes
They prevent chromosomes from deteriorating
or fusing with neighboring chromosomes and
are involved in the aging process.
CELL MEMBRANE - The presence of double bonds in fatty
General Biology | Quarter 1 Week 8 acids helps maintain membrane fluidity.
Present in all cells (animal, plant, bacterial)
with the primary function of protection.
- With no membrane, organelles become
exposed to the outside environment that may
be toxic; cell therefore becomes non-functional
and life ceases to exist

Cholesterol
- Only present in animal cells; may be good
or bad
- Affects and regulates membrane
compaction and expansion at different
temperatures
- Warm temp: Restrains movement of
phospholipids. Since heat expands the
spaces between phospholipids
Fluid Mosaic Model - Cool temp: Maintains the fluidity by
- Static in structure but neither rigid nor static preventing tight packing that may break
in structure but is highly flexible and can down the lipids
change its shape and composition
through time. Phytosterol
- Structure is composed of diverse protein - Only synthesized in plants
molecules embedded in a mosaic-like - Helps plants maintain temperature In harsh
fashion in the fluid phospholipid bilayer. environments
- Lowers bad cholesterol- Used in plant
Components of the cell membrane based oils which are healthier but more
Phospholipid pricey due to it being harder to extract
- Made of two layers of lipids with
hydrophilic head and hydrophobic tail Functions of cell membrane
- Most abundant lipids in membranes, an 1. Define the boundaries and act as
amphipathic molecule permeability barriers
- As barrier: To keep desirable substances in
the cell and keep undesirable substances
out.

Ex. Keeps
stomach acid in
check by the
sphincter to
prevent leakage

- As permeability barrier: Hydrophobic core
prevents transport of ions and polar
molecules
- Selectively permeable - only allows
- Contains fatty acid component (carboxylic certain substances into cells while
acid); long chain of hydrocarbons keeping others out. Size and the
- Contains saturated (single bonds ONLY) chemical nature of the molecules are
fatty acid determiners of the permeability
- Unsaturated (double bonds) fatty acids
that cause bend in
hydrophobic tail
chain
- The individual lipid
molecules are able
to move in their
own monolayer.
 4. Contain the protein molecules that act as
receptors to detect extracellular signals
- Proteins in the cell membranes of neurons
contain embedded molecules that
interpret signals from neurotransmitters and
other signaling molecules.
- When these molecules bind to the
receptors, they initiate a series of
biochemical reactions inside the neuron.
- Ex. Caffeine that keeps you awake and
Adenosine that makes you sleepy

5. Membrane proteins
- Diverse proteins are associated with the
plasma membrane, and they are
functionally classified.

Molecules that are free to move across the Transport proteins
membrane (Permeable) - Classified into channel or carrier proteins
- LIPIDS, ALCOHOL
- NON-POLAR molecules - fully distributed
charge
- SMALL molecules - O2, N2, CO2, H2O
Molecules that require energy expenditure
(Impermeable)
- POLAR molecules - contain negative and
positive charges
- LARGE molecules - Glucose, amino acids,
nucleic acids, proteins

2. Site for biochemical functions
- This includes photosynthesis (both light
dependent and light independent) and
cellular respiration in mitochondria
membrane

3. Provide mechanisms for cell-to-cell
contact and communication Adhesion proteins
- Cells in multicellular organisms are in - Fasten adjacent cells together in animal
contact with other cells tissues.
- Cell junctions in skin cells that allow cells to
adhere to each other for communication Recognition proteins
- Preventing unregulated flux of fluid or - Help in recognition when the body is being
leakage of urine in urinary bladder invaded by pathogens so that the
- Plasmodesma that connects 2 plant cells necessary immune response may be
triggered eg. glycoprotein

Receptor proteins
- Have certain shapes that allow only
specific molecules to bind to them.
CELL TRANSPORT MECHANISM
General Biology | Quarter 1 Week 8 FACILITATED DIFFUSION
- Diffusion through membrane aided by
Describes the movement of molecules across transport proteins (channel and carrier
the cell membrane (ACTIVE or PASSIVE) proteins)

Protein channels
- To accommodate different molecules;
membrane becomes semi-permeable ex.
Aquaporin for water
PASSIVE TRANSPORT
- High to low concentration; along the
concentration gradient
- No energy required

SIMPLE DIFFUSION
- “Moves with the flow” since there is net
diffusion caused by uneven distribution of
molecules Protein transporters/ carriers
- Net diffusion happens to reach equilibrium - They hold onto their passengers and
where there is equal number of molecules change shape in a way that shuttles them
on each side across the membrane.
- Intrinsic energy: from internal
thermal/kinetic energy which allow
molecules to move even without ATP
- Selective permeability is still applied
Rule in DIffusion:
- In the absence of other forces, a substance
will diffuse from where it is more
concentrated to where it is less
concentrated
- Any substance will diffuse down its OSMOSIS
concentration gradient. No work must be
- Diffusion of water through the cell
done to make it happen.
membrane
Examples:
- Net movement of
- Homogeneous solution: juice powder in
water molecules to
water or blood in ocean
area with more
- Fetus and mother: nutrients, antibodies,
solute and less
vitamins of mother to fetus; CO2 of fetus to
water
mother making mother fatigued
- Lungs: Respiratory system; alveoli where gas
Cell Tonicity
exchange occurs

Each dye molecule wanders randomly , but there will
be net movement of the dye molecules across the
membrane to the side that began as pure water.
- Hypotonic for plant cells since they contain
large vacuole that can store a lot of water
Isotonic BULK TRANSPORT
- Equal solute, equal water; concentration of - For large molecules
water in the solution is the same as the
concentration of water inside the cell. Types of ENDOCYTOSIS
Hypotonic Phagocytosis
- Less solute, more water; water enters a cell - Cell engulfs large particles or even
by osmosis, causing the cell to swell and other cells, often seen in immune cells
burst (CYTOLYSIS - disruption of cell) like macrophages
Hypertonic Pinocytosis
- Less water, more solute; water leaves a cell - Involves the uptake of small particles
by osmosis, causing the cell to shrink and fluids, often referred to as "cell
(PLASMOLYSIS - shrinkage of protoplasm in drinking"
plant cell) Receptor-mediated endocytosis
- Selective form of endocytosis where
cells internalize specific molecules
based on receptor recognition,
allowing for efficient uptake of needed
substances.

Isotonic Hypotonic Hypertonic

ACTIVE TRANSPORT
- Energy (ATP) is required
- Against the concentration gradient
(low to high concentration) EXOCYTOSIS
- Cells expel materials in vesicles that
TYPES OF TRANSPORTERS/ CARRIERS fuse with the plasma membrane,
releasing their contents outside the cell.
- Uniporters – move one molecule at a
time Ex. Sodium-Potassium pump
- Symporters – move two molecules in
the same direction Ex. Na+/glucose
- Antiporters – move two molecules in
opposite directions
ENZYMES
General Biology | Quarter 1 Week 8

Monomers
- Small, foundational units in biomolecules
that can join together to form larger
molecules known as polymers.

- Enzyme/substrate complex: transient
formation that occurs when a substrate
binds to the active site of an enzyme. It
brings the substrate into close proximity to
the enzyme, allowing for the necessary
chemical interactions to take place.
- Enzyme/product complex: forms after a
substrate is converted into products. This
temporary complex stabilizes the transition
state during the reaction, allowing the
products to be released.

Lock and key
- Model that describes enzyme specificity,
where the enzyme (the "lock") has an
active site perfectly shaped to fit a specific
substrate (the "key") allowing it to catalyze
Metabolism a reaction.
- The sum of all the chemical activities taking
place in a organism Induced fit
> Catabolism (exergonic) - Model that describes how an enzyme
- Breakdown of larger molecules into smaller changes shape upon substrate binding,
ones, releasing energy in the process. allowing for a better fit between the two.
- Enzymes facilitate these chemical
reactions, helping to convert complex Enzyme Examples:
substances into simpler forms which can
then be used for energy production. Ex.
carbohydrates to glucose
> Anabolism (endergonic)
- Build complex materials from simpler ones
- Enzymes help synthesize complex molecules
such as proteins, nucleic acids, and
polysaccharides from their monomeric units

Enzyme
- Substances (proteins) that catalyze
chemical reactions
- Act as a catalyst: speeds up chemical
reactions by decreasing the activation
energy

- Active site: A specific region on an
enzyme where substrate molecules
bind. It typically consists of a pocket or
groove formed by the arrangement of
amino acids
- Substrate: The reactant molecule that
an enzyme acts upon
FACTORS AFFECTING ENZYME ACTIVITY
General Biology | Quarter 1 Week 8 Enzyme concentration

Several factors can affect enzymatic activity
affecting its efficiency in catalyzing metabolic
processes

Temperature
- Each enzyme has its own specific optimal
temperature
- When exposed to optimal temperature, the - Enzyme concentration increases, rate of
rate of reaction is the fastest reaction also increases given there is
- Majority of human enzymes have optimal enough substrate
temperatures from 37C to 38C - More chances of enzymes colliding with
- Low temp: enzymes become inactive, substrates
unfunctional, or slow - Limiting factor - variable that slows down
- High temp: enzyme bonds breakdown or the reaction rate
denature and the active site changes
shape to the point where substrate no Inhibitors
longer fits; - Inhibitors can bind to the enzyme slowing
- At high fever, body kills pathogens and down or stopping the functionality or
denatures the enzymes present in chemical activity of the enzyme
bacterial cells - Allosteric site (regulatory site) - specific
region separate from the active site where
pH Level allosteric effectors/regulators can bind.
- Very active at optimal level of pH Binding causes a conformational change in
- If exposed beyond optimal - disruption of the enzyme's structure.
bonds that affect structure - Competitive inhibitor - Tries to compete with
- Each part of our body has different pH the substrate
levels - Non-competitive inhibitor - Molecule binds
to allosteric site and inactivates enzyme by
changing the shape of active site

Activators
- Allosteric activators - Molecules that bind at
allosteric site, causing a conformational
change that enhances the protein's
activity.
Substrate concentration

- With more substrate, there is a higher rate of
reaction until it reaches maximum point
- Higher chance of collision between enzyme
and substrate
- After reaching maximum point, enzyme
becomes saturated and rate of reaction
becomes constant