CMB–Lec(Lesson 1-3) PDF

Summary

This document introduces cell and molecular biology. It covers cell theory, types of cells, energy production, and cell evolution. The content focuses on eukaryotic and prokaryotic cell differences and similarities.

Full Transcript

Week 1 | Introduction to Cell and For example, In arms, the flat cells (which
should be able to protect us from
Molecular Biology environmental factors) are in the
_______________________________________ epidermis, in the dermis, there are cuboid
cells and spongy cells, and as we proceed
Cells and the structures they compromise are to musculoskeletal cells, cruciform cells
too small (they should be able to contract and relax)
A handful of pioneering scientists had used their are observed
handmade microscopes to uncover a world that Neurons – have synapses that transmit
would never have been revealed to the naked eye and receive nerve impulses for transfer of
I. Robert Hooke (1665) - looked upon slices information and locomotion.
of cork C4 Plants can compartmentalize
II. Anton van Leeuwenhoek - animalcules, oxygenation and reduction of
Theory of Pangenesis, Bovine cells are carbohydrates.
round and circular
III. Matthias Schleiden/Theodore Schwann Cells Possess a Genetic Program and the
- formulated 2 tenets of the Cell theory Means to Use It
A. All organisms are composed of Organisms are built according to
one or more cells information encoded in a
B. The cell is the structural unit of life collection of genes, which are
(the basic unit in which it was able constructed of DNA
to produce all functions of all The less tolerance of errors in the
organisms) nature and interactions of the
IV. Rudolf Virchow - third tenet of the cell parts;
theory And the more regulation or control
A. Cells can arise only by division that must be exerted to maintain
from a pre-existing cell the system

Cell is the basic unit of life Signal transduction - how the nucleus knows
Unlike the parts of a cell, which simply that it’s coming from its environment
deteriorate if isolated, whole cells can be Example: Excess/Lacking genetic
isolated from an organism and cultured in material (nullisome/trisomy), there are
a laboratory where they will grow and higher chances that they are aborted, if
reproduce for extended periods. ever born, they have a lower lifespan
Death can also be considered one of the Depending on its phenotype, they can also
most basic properties of life because only produce maintenance.
a living entity faces this prospect. Example: Lactose Operon
The first culture of human cells obtained
from a malignant tumor from Henrietta Cells Are Capable of Producing More of
Lacks was begun by George and Martha Themselves
Gey of Johns Hopkins University in 1951 Mitosis/Meiosis
To die, one must also be simple to live. Reproduce by division, a process in which
the contents of a “mother” cell are
Cells are Highly Complex and Organized distributed into two “daughter” cells that
The more complex a structure: are genetically identical to their mother
The greater the number of parts that must cells
be in their proper place; The genetic material is faithfully
There is less tolerance for errors in the duplicated, and each daughter cell
nature and interactions of the parts; receives a complete and equal share of
And the more regulation or control that genetic information
must be exerted to maintain the system
Cells Acquire and Utilize Energy
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 Light energy is converted by ○ Example: Plants do not have an
photosynthesis into chemical energy that immune system but they have
is stored in energy-rich carbohydrates, programmed cell death. If there’s a
such as sucrose or starch (for pathogen that touches the surface
maintenance and also reproduction, and of the leaf, it will try to attack the
movement of nutrients to other parts of the adjacent cells of the plant. The
cell) plant will kill the adjacent cells
For most animal cells, energy arrives found in the opposite direction of
prepackaged, often involves form of the the cell. Since the cells are dead,
sugar glucose the pathogens can no longer
Glucose is disassembled in such way that attach to the dead cells within the
its energy content can be stored in a plant.
readily available formed called ATP
Cells are Capable of Self-Regulation
Cell Carry Out a Variety of Chemical Reactions Each type of cellular activity requires a
Cells function like miniaturized chemical unique set of highly complex molecular
power plants tools and machines - the products of eons
All chemical changes that take place in of natural selection and biological
cells require enzymes - molecules that evolution
greatly increase the rate at which a They can start to evacuate when it comes
chemical reaction occurs to the presence of the pests, while doing
The sum total of the chemical reaction in a catabolism and anabolism, can do cell
cell represents that cell’s metabolism division while multiplying their protein
contents if they are expressed.
Cells Engage in Mechanical Activities The most fit mutation becomes the norm,
Cells are sites of bustling activity for example in photosynthesis, it makes
Materials are transported from place to you more compatible in your environment
place, structures are assembled and then that is receiving sunlight - Natural
rapidly disassembled, and, in any case, Selection.
the entire cell moves itself from one site to
another
Initiated by changes in the shape of
“motor” proteins
○ E.g.Cilia for amoeba
Cells never stop producing materials.
Golgi Apparatus becomes the shipment
for the desired products Cells Evolve
Changes in cell metabolism that are led by It is presumed that cells evolved from
motor proteins. some type of precellular life forms from
non-living organic materials that were
Cells Are Able to Respond to Stimuli present in the primordial seas.
A single celled protist moves away from According to one of the tenets of modern
object in its path or moves toward a biology, all living organisms have evolved
source of nutrients from a single, common ancestral cell that
Most cells are covered with receptors that lived more than three billion years ago
interact with substances in the
environment in highly specific ways
Cells may respond to specific stimuli by
altering their metabolic activities, moving
from one place to another, or even
committing suicide

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 Last universal common ancestor (LUCA) - ○ Such as the production of ATP,
term used in… NADPH, and NADH
Similar mechanism of photosynthesis
○ Prokaryotes may lack chlorophyll,
they harness light energy
Similar mechanisms for synthesizing and
inserting membrane proteins
Proteasomes of similar constructions

Differences of Two Cell Types
Eukaryotic cell Prokaryotic cell

Division of cells into Nucleoid
nucleus and
cytoplasm

Complex Ribosomes
Cells are able to evolve if we look at membranous
cytoplasmic
housekeeping genes, e.g, enzymes
organelles
needed from glycolysis, all those enzymes
are found in all organisms both Specialized No specialized
prokarytic/eukaryotic. Looking at those cytoplasmic organelles for
sequencing, there are more things organelles photosynthesis
common between all living organisms. mitochondria and
photosynthesis
Meaning we can trace it back in evolution
through LUCA. LUCA is a term used in Cytoskeletal system Simple compositions
Phylogenetics in which we can trace the (may move through of locomotory
branch points of one organism to another. flagella/cilia) organelles - flagellin

Complex flagella and Peptidoglycan cell
Two Kinds of a Cell
cilia wall (Rigid Cell Wall)
1. Eukaryotic Cell
2. Prokaryotic Cell Phagocytosis Asexual reproduction

Similarities of the two Cellulose cell walls
Plasma membrane of similar construction
Sexual reproduction
Genetic information encoded in DNA using
identical genetic code
○ Same codon preference - codons Type of Prokaryotic Cells
found in prokaryotes that may code 1. Domain Archaea
different amino acids that might be a. Species that live in extremely
different of those found in inhospitable environments
eukaryotic b. They are often referred to as
Similar mechanisms for transcription and “Extremophiles”
translation of genetic information c. Methanogens - prokaryotes
○ They both have ribosomes, they capable of converting CO2 and H2
both have transcription gases into methane (CH4) gas
machineries d. Archaic - lives in extreme
Shared metabolic pathways conditions, such as halophiles,
○ Both do respiration, the only thermophiles, cryophiles, and often
difference is energy source referred to as extremophiles, such
Similar apparatus for conservation of as methanogens that can
chemical energy as ATP synthesize methane gas from

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 carbon dioxide and H2 gases. on a small number of “representative
Depending on the organisms models.”
involved, they can be used in
carbon production and absorption
in the environment.
2. Domain Bacteria
a. Includes the smallest known cells
in the world - mycoplasma
b. Lack cell walls (A) Arabidopsis thaliana - apatella for the
c. A genome with fewer than 500 production of petals
genes (B) Yeasts - easily reproduced due to its size
d. Present in every conceivable (C) C. elegans
habitat on Earth. Even in the (D) Drosophila - their eyes can be found at the
respiratory tract, gastrointestinal, back, if the disks are swapped.
and skin. (E) Mice and Rabbits (Mammals) - for testing
we usually use Sprague rats
Type of Eukaryotic Cells (F) Danio rerio (zebra fish) - can be used for
In many regards, the most complex research
eukaryotic cells are not found inside of
plants or animals, but rather among the How smol is small?
unicellular protists
An alternate pathway has led to the
evolution of multicellular organisms in
which different activities are conducted by
different types of specialized cells
As a result of differentiation, different
types of cells acquire a distinctive
appearance and contain unique materials.
○ E.g. bones - bones are made up
of calcium, and it allows the
reproduction of red blood cells and
the rigidity of the bones.

Two units of linear measure are most
commonly used to describe structures
within a cell: the micrometer (μm) and
nanometer (nm). One μm is equal to
10^-6 meters, and one nm is equal to
10^-9 meters. The angstrom (Å), which is
equal to one-tenth of a nm, is commonly
employed by molecular biologists for
atomic dimensions. One angstrom is
roughly equivalent to the diameter of a
hydrogen atom.
Model Organisms
Cell and molecular biologists have Special Topics: Viruses, Stem Cells and
focused considerable research activities Endosymbiosis

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Viruses
Responsible for dozens of human Viroids
diseases, including AIDS, polio, An infectious agent consisting of a small
influenza, cold sores, measles, and a circular RNA molecular that totally lacks a
few types of cancer. protein coat.
○ HIV is the virus of AIDS. T.O. Diener coined the term viroid.
Occur in a wide variety of very different The RNAs of viroids range in size from
shapes, sizes, and constructions, but all of about 240 to 600 nucleotides, one tenth
them share certain common properties. the size of the smaller viruses.
All viruses are obligate intracellular Viroids - Obligatory Parasites; Small RNA
parasites; that is, they cannot reproduce virus, smaller than Viruses. They are
unless present within a host cell. already RNA, they can easily infect one
Virus is a genetic material coated with cell to another since they are ready for
protein, this genetic material might be translation. Viroids can slip through
RNA or DNA. As they enter the host, they connecting appendages of the cell.
are able to release the genetic material
into the cytoplasm of the host to translate. Stem Cells
These proteins may be able to replicate Hematopoietic stem cells in the bone
and be coated inside the cytoplasm. They marrow are an example of an adult stem
explode inside and infect other cells. cell
Obligatory parasites - they need a host Stem cells are defined as
to thrive undifferentiated cells that
○ Are capable of self-renewal, that is,
production of more cells like
themselves, and
○ Are multipotent, that is, are
capable of differentiating into two
or more mature cell types
Inside the bone marrow, we have
Hematopoietic Stem Cells or Adult Stem
Cells, they do not differentiate because it
Depending on the specificity of the virus, is essential to constantly replenish the
the host may be a plant, animal, or amount of RBCs in our bodies. They
bacterial cell. produce nucleated RBCs, once done, they
Outside of a living cell, the virus exists as are out o the Hematopoietic Stem Cells
a particle, or virion, which is little more Once the RBCs are found in the
than a macromolecular package bloodstream, they are slowly being
Sometimes, we have viruses that can endonucleated.
affect multiple targets. Outside of a living
cell, it can only exist as a virion. This virion
can be destroyed by a lot of objects or
dehydration that can be associated with
sanitization.

Embryonic Stem Cells

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 Embryonic stem (ES) cells, which are a Endosymbiont Theory
type of stem cell isolated from very young Ancestral eukaryotes came from large
mammalian embryos prokaryotes that ingested aerobic
The egg would be allowed to develop to prokaryotes.
an early embryonic stage, and the ES Mitochondria - The prokaryotes are able
cells would be removed, cultured, and to create energy without energy that
induced to differentiate into the type of becomes mitochondria. The heterotrophic
cells needed by the patient prokaryote digested food that gives food
Ethical considerations to the mitochondria.
Chloroplast - Photosynthetic
cyanobacteria entered the macrophage

Induced Pluripotent Stem Cells
The cells are not initially totipotent but
pluripotent, plural, it can differentiate into
multiple functions.
Unlike ES cells, the generation of iPS
cells does not require the use of an
embryo. Week 2 | The Cellular Basis of
This feature removes all of the ethical Life
reservations that accompany work with ES
Microscopes
cells and also make it much easier to
developed for clearer view of cells and
generate these cells in the lab.
cellular structure
Undifferentiated iPS cells may give rise to
The first microscopes were Light
teratomas.
Microscopes (LM), visible light passes
The usage of chemicals may activate
through a specimen, then through glass
cancer genes is the sought problem
lenses, and finally is projected into the
viewer's eye
Light microscopes can magnify
effectively to about 1,000 times the
actual size of the specimen

Parameters in Microscopy
1. Magnification - is the ratio of an object’s
image size to its real size (increase in an object's
image view compared with its actual size.
2. Resolution - is a measure of the clarity of the
image; it is the minimum distance two points can
Endosymbiont Theory
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be separated and still be distinguished as
separate points.

Microscopes have limitations
human eye and microscope have limits of
resolution–the ability to distinguish
between small structures
Therefore, the LM cannot provide the
details of a small cell structure.
Depth of field - can be increased to
improve focus

In 1950s,
scientists started using the electron
microscope (EM) to view the
ultrastructure of cells
Instead of light, EM uses a beam of
electrons
EM can:
○ resolve biological structures as
small as 2 nm
○ can magnify up to 100,000 times

Types of Electron Microscope
1. Scanning Electron Microscope -
detailed architecture of cell surfaces
2. Transmission Electron Microscope -
details of internal cell structure

Differential interference (LM) amplifies differences
in density so that structures in living cells appear
three-dimensional.

Using LM, scientists studied:
microorganisms
animal and plant cells
some structures within cells

In 1800s, studies lead to cell theory which
states that
all living organisms are composed of cells
these cells arise from pre-existing cells

Small size of cells relates to the need to
exchange materials across the plasma
membrane.
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Cell size must
be large enough to house DNA, proteins,
and structures needed to survive and
reproduce but
remain small enough for an efficient
Surface-Volume (SV) ratio.

Parts of a Prokaryotic Cell

Plasma membrane

Functional Compartments of Eukaryotic Cells
1. The nucleus and ribosomes are
responsible for genetic control.
2. The endoplasmic reticulum, lysosome,
vacuoles, and peroxisomes are
responsible for the manufacture,
Parts of a Eukaryotic Cell (Animal and Plant) distribution, and breakdown of
molecules.
3. Mitochondria in all cells and chloroplasts
in plant cells are involved in energy
processing.
4. Structural support, movement, and
communication between cells are
functions of the cytoskeleton, plasma
membrane, and cell wall.

Nucleus
most noticeable organelle in a cell
separated by a nuclear envelope
DNA is separated into chromatin fibers
with histone proteins (octamer for
supercoiling of DNA)

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 studded with of nuclear pores for transfer ER, Golgi, Lysosomes function in the distribution
of DNA of materials.
○ Retroviruses can surpass…
○ can be managed through CRISPR
(gene-editing) and stem cell Endoplasmic Reticulum
Largest component of ES
Ribosomes Extensive network of flattened sacs and
involved in cell protein synthesis tubules
responsible in creating the polypeptide Smooth ER: no ribosomes
used for translation to proteins Rough ER: w/ ribosomes
cells that make a lot of proteins have a ○ Growing polypeptides grow here.
large number of ribosomes (e.g., Protists Glycoprotein binds folding.
undergo polycistronic transcription: mRNA
codes for more than one protein ) The ER is a biosynthetic workshop
In eukaryotes, they are monocistronic SER: lipids store Calcium ions
because the mRNA codes for only one RER: marks additional membrane &
protein. secretory proteins
some are free (in the cytosol), some are
bound to the endoplasmic reticulum or
nuclear envelope

Endomembrane System
Cytoplasm - region between the plasma
membrane and the nucleus
ES components are suspended in the
cytosol
Region where cell metabolic processes
occur
Some are physically converted ….

1. Nuclear envelope : synthesis
2. ER, Golgi apparatus, lysosomes:
distribution Golgi Apparatus
3. Vacuoles : storage Molecular warehouse & processing station
4. Plasma membrane: export of molecules for products manufactured by ER
Ships in the forms of vesicles; has
Many organelles are connected in the receiving and shipping side
Endomembrane System (ES)
Many membranes are part of the ES
Some membranes are physically
connected, or pinch off as vesicles

The ES includes
Nuclear envelope - synthesis
ER
Golgi apparatus - detects where material
will go; sorting center
Lysosome - vesicle containing enzymes
that degrade food
Vacuoles - storage
Plasma membrane - export of molecules

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 mRNA → nuclear pore → translated by
ribosomes in the RER → polypeptide chain/

protein is synthesized in the RER → Golgi
Apparatus identifies the tag and sorts → secretes
as a vesicle
Lysosome
Membrane-enclosed sac of digestive Mitochondria
enzymes made by RER and processed Carry out cellular respiration in all
in the Golgi Apparatus eukaryotes
Fuse w food vacuoles & digested food Cristae enhances surface area which
Destroy bacteria engulfed by WBCs increases ATP production
Fusse w/ other vesicle containing Cellular respiration converts chemical
damaged organelles for recycling energy in the form of ATP

Chloroplasts
Convert light energy to chemical energy
of sugar molecules
Photosynthesizing organelles of plants &
algae
Vacuoles
Large storage spaces
Some protists have contractile vacuoles,
which eliminate water from the protists

The Endomembrane System

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Mitochondria & chloroplasts have own DNA
Microtubules
(Endosymbiont Theory)
Shape & support
*anaerobic* bacteria & *anaerobic*
Tracks along which organelles quipped
photosynthetic eukaryote
with motor
proteins move
Grow out from
centrosomes,
which contain a pair
of centrioles
25 nm in length

Intermediate Filament
Reinforce cell shape, anchor some
organelles
Often more permanent fixtures in cell
Does not undergo repair once broken but
instead is replaced in sets
10 nm

Microfilaments
Support cell shape
Motility
7 nm in diameter

The Cell’s Internal Skeleton Cilia & Flagella
Cytoskeleton - network of protein fibers, Cilia - propel protists
organizes structures ○ Other protists may move using
Microtubules - made of tubulin flagella; longer than cilia and
Intermediate filaments - fibrous protein limited to 1 or a few
Microfilaments - actin filaments Both are composed of microtubules
wrapped in an extension of the plasma
membrane
9+2 pattern: a ring of microtubule
doublets surround a pair of central
microtubules

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 Scaffolding For Biochemical Activities
There are some proteins embedded on the
membrane that act as chaperones for proper
folding of the mechanisms and amino acids.
o E.g., Pieces of amino acid and
polypeptide chain sent by Golgi
apparatus can form one functional
protein in a form of subunit
▪ Subunits – forms proteins
that are functional and could
send certain signal or have
Dyneins move by bending motor proteins enzymatic functions
called dynein feet Proteins found on the cell surface acts as a
scaffolding for the recruitment of other
○ These feet attach to and exert a proteins.
sliding force on an adjacent o These other proteins can recruit more
doublet proteins in a process called molecular
○ This “walking” causes the docking.
▪ Molecular docking –
microtubules to bend technique used to look into
○ Releases ATP when used protein assemblies and how
they occur real time; how to
trigger certain assemblies to
Summary
make certain reaction
Genetic control: nucleus, ribosome function/happen more inside
Manufacture & storage: ER, Golgi, the cell
Lysosomes, Peroxisomes E.g., Assemblies for
Signal
Energy Processing: mitochondria, transduction/Nerve
chloroplast Impulse – available for
scaffolding
Structural Support: cytoskeleton
Movement: cilia & flagella Selective Permeability
Protein found in cell membranes only acts in
places where only certain materials can enter
and exit the cell – specifically those materials
Week 3 | The Cell Surface needed in catabolism or anabolism.
o E.g., Carbohydrates, for Enzymatic
The Cell Surface Activities (like antibodies)
An Overview of Membrane Functions
Solute Transport in Osmosis
Studies on Plasma Membrane Structure
Go towards hypertonic environment – to
The Chemical Composition of Membranes higher solute concentration
When cell enters:
An Overview of Membrane Functions o In Hypotonic Solution – water goes
inside the cell
Compartmentalization o In Isotonic Solution – level is equal; no
One of the main functions of membrane pressure
The cell is in itself is a system, a o In Hypertonic Solution – solute is
microenvironment for the organelles, abundant in the environment, water
separated from the rest of the human body. goes out to the environment
o What happens inside one cell does not
affect the cell adjacent to it, unless Responses to External Stimuli
signaling is present. Virions and Viroid in Plants
▪ E.g., Tubers – presence of o Do apoptosis (programmed cell death)
non-photosynthetic cells in a Since plants don’t have an immune system,
plant together with a once bacteria, fungi or pathogens are present,
photosynthetic cell. They have those affected cells and the cells adjacent to it
low photosynthetic efficiency kill themselves to not spread and only localize
because of non-expressive the pathogenic effect.
chlorophyll; thus it is mainly
for storage for photosynthetic Intercellular Interaction
products. E.g., Exchange of impulses in nerves
Compartmentalization is brought about by the o Such as use of sphingolipids –
properties of cellular membranes. particular in nerve function

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Energy Transduction cell can interact with the
Potato – plant that is not green although all environment
cells of plants have chlorophyll E.g., exposure to heat
o Due to inactivated chlorophyll – do not induces production of
contain a lot of magnesium heat shock proteins
o However, food is stored in these types which will protect the
of plants where starch and other cell from heat
carbohydrates are produced by
photosynthesis (occurring in The Present Fluid Mosaic Models
photosynthetic materials like leaves)
o Cell in these plants are able to pass
down all of the produced starches to
the tubers.
▪ Thus, they can transform
chemical energy from leaves
to tubers to form tubers.

Studies on Plasma Membrane Functions

Ernst Overton
Pioneer of the theory of the cell membrane
Made experiments using plant roots to test Peripheral protein – found in one side of the layer
permeability. Integral protein – transcending both layers of the cell
More lipid-soluble, easy entrance to the cell Glycolipids/Glycoproteins/Oligosaccharide – these
are responsible for transferring information and acts as
Evert Gorter and Francois Grendel signaling; they are detected by the receptor of the
Used red blood cells to measure the amount adjacent cell
of surface area a lipid would cover.
o Speculated that the actual ratio was
2:1 (ratio of lipid to surface area of the Chemical Composition of Membranes
cell)
▪ Langmuir trough – a lab Chemical Composition of Membranes
apparatus where they Membranes are lipid-protein assemblies
discovered that in the moving Held together in a thin sheet by noncovalent
pan, 2/3 of the pan becomes bonds in a bilayer fashion
the cell's lipid, while 1/3 is the o Presence of two layers formed by
actual cell amount. hydrophilic head (faces inward in cell
Thus, it was deduced that the plasma environment and outward in outside of
membrane contained a bimolecular layer. cell) and hydrophobic tail (found
Hugh Davidson and James Danielli inside of lipid bilayer)
Lipid bilayer that was lined by a layer of They contain a wide diversity of lipids, all of
globular proteins which are amphipathic.
o Provide selective permeability to the Three main types of membrane lipids:
cell phosphoglycerides, sphingolipids, and
▪ Protein pores – some are cholesterol.
embedded in both layers,
some are found in an integral Phosphoglycerides
position (one side), some are Contain a phosphate group esterified to
found embedded in lipid glycerol
bilayer’s tail. o Esterified – covalent bond with C=OO
Structure:
Jonathan Singer and Garth Nicolson o Fatty acid chain esterified –
Fluid mosaic model hydrophobic tail – 16-22 carbons
o Mosaic – Due to globular proteins o Varying hydrophilic head – dictates the
span the membrane either embedded properties of the phosphoglycerides –
on one layer or two PC, PS, PE, PI
▪ Random distribution of
proteins
o Fluid – Proteins embedded in
membrane changes depending on
how it reacts in the environment
▪ Protein serves as an
interaction/signal to which the

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 Heads are sometimes sugar-coated or
alcohol

Only two of the hydroxyl groups of the glycerol o Sphingosine – amino alcohol along
are esterified to fatty acids; the third is with hydrocarbon chain
esterified to a hydrophilic phosphate group. o Ceramide
Possess an additional group linked to the o Sphingomyelin – long chain with
phosphate. phosphate group
Each of the additional group forms a highly The less abundant class of membrane lipids
water-soluble domain at one end of the Derivatives of sphingosine, an amino alcohol
molecule, called the head group. that contains a long hydrocarbon chain
o The properties depends on the head (Ceramide).
group. Various sphingosine-based lipids have
At physiologic pH: additional groups esterified to the terminal
o PS and PI have an overall negative alcohol of the sphingosine moiety:
charge – can interact covalently with 1. Sphingomyelin –
positively charged amino acids found phosphatidylcholine substitution.
in embedded proteins 2. Glycolipid – carbohydrate
o PC and PE are neutral substitution.
Member fatty acids may be saturated, - Cerebroside
monounsaturated, polyunsaturated. - Ganglioside
o Essential for its ability to be tightly ▪ Presence of sugars are useful
packed and loop into a spherical for transmitting information
shape. (impulses from one neuron to
▪ Saturated – saturated by another)
hydrogen atom; 4 covalent Similar to phosphoglycerides but have longer,
bonds can be attached highly saturated fatty acyl chains
▪ Monounsaturated – 1 carbon o However, high levels of sphingolipids
atom can bind due to in membrane can cause cholera
presence of double bonds infection and botulism – damaging
▪ Polyunsaturated – many for CNS
double bonds present Glycolipids play crucial roles in nervous cell
Example: function (galactocerebroside)
o EPA and DHA – Both have long Glycolipids may be a route for infection by
carbon fatty acids cholera and botulism
o However, double bonds causes
unsaturation – shortening of
distance of carbon molecules
▪ HDL – unsaturated; good
cholesterol

Cholesterol
LDL
Fifty percent of the lipid molecules in the
plasma membrane.
o Most are globular in shape – smaller
in size but interact the most with the
protein groups – fill in gaps to hold
together protein members found in
plasma membrane
Small hydrophilic hydroxyl group toward the
Sphingolipids membrane surface.

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 The hydrophobic rings of a cholesterol Integral proteins- Sometimes contain
molecule are flat and rigid, and they interfere sugar molecules to become glycoproteins.
with the movements of the fatty acid tails of
the phospholipids. The sugar molecules are responsible for
signaling, they can be perceived by a
These three lipid membranes depend on the receptor and the receptor will react with
temperature and environment and change in the sugar molecule. The receptor is a type
proportion as they react based on the environment
in which the cell is placed. of protein, in the protein, or the amino
acids will interact with the amino acid
residue found within the integral protein
Phospholipid Bilayer Membrane and as it interacts the protein will change
its conformation forming a fold of integral
protein, There will be changes if
naagkarron ng fold sa intracellular space,
magkakaroon ng active sites and doon
magkakaroon ng interaction dun sa
component found in cytoplasm.
Surface proteins- found only in
hydrophilic head and mostly hydrophilic
amino acids. Useful for quick responses to
stimuli
Globular protein- highly compact, most of
the hydrophobic materials are found inside
the globular protein and the hydrophilic
Protein component- different types of protein that head is found outside. Serves as a
are dependent on their function, type, shape, and receptor and also changes the
where it is located within the lipid bilayer components of the bilipid layer (kung
Protein channel- barrel domain (a dadagdagan ba ang cholesterol or
combination of beta and alpha helixes sphingolipids). All the components are
found within the center of cells) contains a gradually and constantly changing, it is
lot of amino acid residues that are dynamic because of the globular proteins
hydrophobic. However, on both ends of a-helix proteins (integral)- unlike
the barrel-like structure, they have peripheral proteins they maintain their
hydrophilic amino acids (they are found in tertiary structure. They are secondary or
extracellular space and intracellular space tertiary structures and also can recruit
and can interact with the hydrophilic other components later on that are found
heads of lipids). The hydrophobic barrel is in the vicinity of the cell.
found interacting with the hydrophobic
tails of the lipid bilayer. The protein Interactions of Cells with their
channel is responsible for the entrance Environment
and exit of materials within the cell and the
exchange of materials sometimes from Overview
one cell to another. The extracellular matrix
Peripheral proteins- only found in one Cell interactions with extracellular
location of the cell. They have a materials
hydrophobic tail that anchors it to the Cell-to-cell interactions
bilipid layer. Interacting with only one lipid Tight junctions, Gap junctions, and
layer or one side of the lipid bilayer. Plasmodesmata
Responsible for molecular docking, they Cell Walls
recruit other components, other proteins,
or other enzymes that can cascade The extracellular matrix
information within the cell. The Glycocalyx

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