Week 1 Cohort 2 - Lipids and the Cell Membrane Instructor(1) PDF

Summary

This document is a set of lecture notes on lipids and the cell membrane, covering topics such as biomacromolecules, learning objectives, and relevant readings. It includes summaries of cellular components, carbohydrate structures, and protein structures.

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10.019
Science and Technology
for Healthcare
Week 1 Cohort 2:
Lipids and the Plasma Membrane
 Lesson Outline
Four Classes of Biomacromolecules

The Plasma (Cell) Membrane

Mini-Activity: Crude extraction of DNA

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 Learning Objectives
At the end of the lesson, you will be able to:

Describe the four main classes of biomacromolecules, including the types of bonds
present, and their general roles
Describe the components of the plasma membrane and their functions
List the different types of membrane proteins and explain their roles in transport,
recognition, and communication
Explain the process of extracting DNA from cells using common household
ingredients

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 Relevant Readings
Alberts et al. Essential Cell Biology, 4th Edition, Garland Science, 2014.
Ch 2 Pg. 50 - 79.

Alberts et al. Essential Cell Biology, 4th Edition, Garland Science, 2014.
Ch 11 Pg. 359 - 389.

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 Recap: Cells and the Chemistry of Life
Each cell is a highly complex chemical system

The Chemistry of Life is:
1. based largely on carbon compounds (i.e., ‘organic’)
2. dependent on chemical reactions that take place in aqueous environments in
a narrow temperature range
3. enormously complex in its chemistry
4. dominated and coordinated by biomacromolecules (i.e., large polymers made
up of smaller linked subunits)
5. tightly regulated such that each chemical reaction occurs at the proper rate,
time, and place

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 Recap: Molecular Composition of the Cell

Lipids

Nucleic acids

Proteins

Carbohydrates

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 Recap: Four Classes of Biomacromolecules
Subunits Macromolecules

i.e., carbohydrates

Figure 3.1 Biology 2e.

Food is a rich source of nutrients,
including biological macromolecules,
necessary for life. Smaller organic
molecules are built up into the larger
macromolecules required by the cell.

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 Recap: Macromolecules are formed and broken down
via condensation and hydrolysis reactions

Subunits (monomer) are added stepwise to the end of a growing chain to obtain a
polymer

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 Video - Introduction to Biomacromolecules

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 Carbohydrates (Subunit: Simple Sugar)
Play important energy storage and structural roles in the cell
Carbohydrates include sugars and the polymers of sugars
– Simplest are monosaccharides, or single sugars
– Macromolecules are polysaccharides, composed of multiple sugar units
– Characterized by a general molecular formula of Cn(H2O)n-1

Monosaccharide Disaccharide
e.g., Glucose e.g., Sucrose =
C6H12O6 glucose + fructose
C12H22O11

Polysaccharides
(hundreds or thousands
of glucoslinked by
covalent e subunits
glycosidic bonds)

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 Proteins (Subunit: Amino Acids)
Play a diverse and important range of cellular functions, including structural support,
transport, communication, etc.
A protein is a biologically functional molecule that consists of one or more polypeptide
chains
A polypeptide is a linear polymer built from a set of 20 amino acids linked by covalent
peptide bonds

or

= one or more polypeptide chains
folded into a stable 3D conformation
Dipeptide (2 aa) (with biological function)
Oligopeptide (up to ~20aa)
Polypeptide (20 – thousands of aas)

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 Nucleic Acids (Subunit: Nucleotides)
Role in storage, transmission and use of genetic information
Nucleic acids are also called polynucleotides.
A polynucleotide is made of subunits called nucleotides linked together by covalent
phosphodiester bonds
Khan Academy

Two types of nucleic acids:

DNA = deoxyribonucleic acid
4 bases: A, C, G, T
Deoxyribose sugar
Double stranded

RNA = ribonucleic acid
4 bases: A, C, G, U
Ribose sugar
Single stranded

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 Nucleic Acids: Deoxyribose and Ribose Sugars

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 Nucleic Acids: MCQ
In terms of DNA and RNA structure, what is a nucleotide?

A. A nucleotide consists of a base

B. A nucleotide is a sugar molecule covalently bonded to a base

C. A nucleotide is a sugar molecule bonded to phosphate group and a base

D. A nucleotide is a heterocyclic base bonded to phosphate group

Answer: C

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 Nucleic Acids: DNA Structure

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 Lipids (e.g., Fats, Phospholipids, Steroids)
Plays role in insulation, energy storage, cell structure, and cell signaling
A class of large molecules comprising mostly of hydrocarbons (C, H)
– Non-polar in nature, hence insoluble with little affinity for water (hydrophobic)
Note that lipids do not form long, repeating polymers.

Three biologically important lipids:

Credit: BioNinja
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 Video – A closer look at lipids

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 Dehydration reaction to form covalent ester bond
Triglycerides (Fats) are constructed from two types of smaller molecules: glycerol
and fatty acids
– Glycerol is a three-carbon alcohol with a hydroxyl group on each carbon
– A fatty acid consists of a carboxyl group attached to a long carbon tail
– Linked together via a dehydration reaction to form a covalent ester bond

Fig. 5.10 Cambell Biology

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 Saturated vs. Unsaturated Fats
Fatty acids can vary in length (number of carbons) and in the number and locations of
double bonds
– Saturated fatty acids have the maximum number of hydrogen atoms possible and no double bonds
– Unsaturated fatty acids have one or more double bonds

Saturated fats are associated with
elevated cholesterol levels and higher
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 Summary: Four Classes of Biomacromolecules
Cells are highly complex
chemical systems with shared
fundamental characteristics

Biomacromolecules are
important cellular components
and perform a wide range of
necessary functions.

Cells are mainly composed of
four classes of biological
macromolecules –
carbohydrates, proteins,
nucleic acids, and lipids

Macromolecules are formed
and broken down via
dehydration and hydrolysis The complex cellular landscape
reactions, respectively Credit: cellsignal.com

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 Lesson Outline
Four Classes of Biomacromolecules

The Plasma (Cell) Membrane

Mini-Activity: Crude extraction of DNA

Questions on the
material so far?

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 The Plasma (Cell) Membrane
The plasma membrane is the boundary of the cell
Acts as a selective barrier that separates the internal components
from the outside environment
Comprises a phospholipid bilayer with embedded proteins
– Lipid bilayer serves as a permeability barrier to polar molecules and ions
– Proteins carry our other important membrane functions (e.g., sensing, transport)
The plasma membrane is involved in cell communication,
import/export of molecules, and cell growth and motility

Fig 11.1 and 11.2, Essential Cell Bio
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 The Lipid Bilayer is a Flexible 2D Fluid
(Fluid Mosaic Model)

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 The Phospholipid Bilayer
Fig 11.4 and 11.5, Essential Cell Bio
Transmission electron micrograph
(TEM) view 3D view

2D view

Membrane phospholipids are
amphipathic, i.e., they have both
hydrophilic and hydrophobic parts

Membrane phospholipids arrange into
two closely apposed sheets, i.e., lipid
bilayer, in water

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 Membrane lipids are amphipathic
Phosphatidylcholine is the Other types of membrane lipids. Each of
most common phospholipid the three types shown here has a
found in cell membranes hydrophilic head and hydrophobic tails

Fig 11.6 and 11.7, Essential Cell Bio

What happens to amphipathic molecules in water?
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 Amphipathic molecules self-assemble in water
Fig 11.11 and 11.13, Essential Cell Bio
Lipid bilayer (double sheet)
Hydrophilic heads orient towards the aqueous
environment on both surfaces of the bilayer
Hydrophobic tails orient towards each other in the interior
of the bilayer and are shielded from water
Spontaneously assembles into sealed compartments to
avoid free edges (energetically unfavorable)

Fig 5.4 Biology 2e.
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 Selective Permeability of the Lipid Bilayer
The lipid bilayer serves as a
permeability barrier and
“gatekeeper” to regulate the
entry/exit of molecules

Which of the following molecules
will be able to diffuse across the
lipid bilayer? Which will not?
– Oxygen
– Carbon dioxide
– Water
– Ions (e.g., H+, Na+)
– Glucose

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 Selective Permeability of the Lipid Bilayer
The lipid bilayer serves as a
permeability barrier and
“gatekeeper” to regulate the
entry/exit of molecules

Selective Permeability:
Small non-polar molecules (e.g., O2)
diffuse across readily
Smallest uncharged polar molecules
(e.g., H2O) can diffuse across
Larger polar molecules (e.g., glucose)
hardly diffuse across
Impermeable to all ions (e.g., Cl-)
regardless of size So how do solutes
enter/exit the cell?

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 Structure of the Plasma Membrane

Fig 4.9 Biology 2e

Component Location
Phospholipid Main membrane fabric
Cholesterol Between phospholipids and between the two phospholipid layers
Embedded within the phospholipid bilayer; may or may not penetrate
Integral membrane proteins
through both layers
On the phospholipid bilayer’s inner or outer surface; not embedded within
Peripheral membrane proteins
the phospholipids
Carbohydrates (components of
Generally attached to proteins on the outside membrane layer
glycoproteins and glycolipids)

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 Types of Membrane Proteins
Membrane transport proteins

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 Solutes can cross the plasma membrane via
membrane transport proteins
Fig 12.3 and 12.8 Essential Cell Bio

Each membrane has its own
characteristic set of membrane
transport proteins

Solutes ( e.g., inorganic ions and
small, polar organic molecules) can
cross the plasma membrane
through these channels

Some transport proteins
discriminate solutes based on
size and charge (less specific)

Others allow only specific
molecules or ions that fit into
Solutes may cross the membrane by either passive (i.e., down a
binding sites to cross
concentration gradient) or active (i.e., energy-dependent) transport

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Example: Aquaporin – Water Channel Protein

Aquaporin channels allow for water
transport in & out of the cell; play an
important role in water reabsorption
in kidneys and other cells

Yellow sphere = one H2O molecule

Extremely narrow central channel
allows passage of water molecules in
single-file

Top-down view:
 Larger molecules and particles enter the cell via bulk transport
Wikipedia

Larger molecules,
such as proteins and
polysaccharides
generally cross the
membrane in bulk,
packaged in vesicles

Fig 7.19 Campbell Biology

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 Types of Membrane Proteins

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 Cell-Identity Markers (i.e., Cell Surface Markers)
Membrane glycoproteins, receptors, and other molecules act as markers (“ID tags”) of
specific cell types
Immune system can distinguish own body’s cells (‘self’) vs. foreign materials (‘non-self’);
important for body’s defenses
White blood cell surface markers (FYI)

CUSABIO

Antibodies can be used to probe for specific cell-surface antigens
(markers that trigger an immune response)
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 Example: Human ABO Blood Groups
“ABO” blood groups are distinguished by the carbohydrate tails of glycoproteins on
the red blood cell (RBC) membrane
Summary of ABO Blood Groups

Different sugars on
RBC surface

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 Types of Membrane Proteins

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 Example: Sars-CoV2 entry and infection
The Sars-CoV2 virus attaches to the
host cell by way of its spike protein,
which binds to a specific receptor
protein (hACE2) on the host cell’s
surface.

The spike protein also contains parts
that facilitate the fusion of the viral
membrane with the host cell
membrane to deliver the viral
genome inside the cell.

Understanding of the coronavirus
SARS-CoV-2 spike binds to membrane fusion mechanism offers
the human ACE2 (hACE2)
cell-surface receptor
a potential target for anti-viral
development.

Animation link:
Cornell News 7 Apr 2020 https://www.cornell.edu/video/corona
virus-membrane-fusion

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 Summary: The Plasma Membrane
The principal components of the plasma membrane are lipids (phospholipids and
cholesterol), proteins, and carbohydrates (in the form of glycoproteins/glycolipids).
The lipid bilayer serves as a permeability barrier to polar molecules and ions, while
proteins carry out other important membrane functions (e.g., sensing, transport, etc.)
The plasma membrane protects intracellular components from the extracellular
environment and mediates cellular processes by regulating the materials that enter
and exit the cell.
The plasma membrane is also involved in cell communication, import/export of
molecules, and cell growth and motility

Questions on the
material so far?
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 Lesson Outline
Four Classes of Biomacromolecules

The Plasma (Cell) Membrane

Mini-Activity: Crude extraction of DNA
– Refer to Week 1 Cohort 2 In-class Worksheet

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 Lab Activity: Crude Extraction of DNA
DNA extraction is a basic procedure in laboratories and is important to the study of genetics. Extracted DNA can
be used in genetic profiling (or ‘DNA fingerprinting’) to help diagnose genetic diseases, establish paternity and aid
in forensics analysis. Scientists can even manipulate the DNA of organisms for biomedical purposes.

backbone

sugar
phosphate
sugar

phosphate

Where is the DNA and sugar
how do we get it out? phosphate

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 Very Simple Schematic of a Cell
Plasma membrane Plasma membrane and
2. What is it made of? nuclear envelope are made up
of phospholipid bilayers.

3. What is the first step to take
if we want to extract DNA?
1. What do we
Disrupt (i.e., lyse) the plasma
want in here?
Nuclear membrane and nuclear envelope
DNA
envelope
4. Which of the following should
5. How to separate the DNA from we add first?
everything else we don’t want? A. Alcohol solution
Filter. DNA is soluble in water and will B. Soap solution
remain dissolved in the filtrate. C. Salt

6. How to get DNA to precipitate out Solution B. Soap will disrupt the lipid
of solution? Adding alcohol (and salt) bilayer, releasing the DNA
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 Soap disrupts the lipid bilayer
Soap is an amphipathic molecule
– Comprise of hydrophobic tail and hydrophilic head

Soap inserts into cell membrane; captures the lipids and proteins

http://learn.genetics.utah.edu/content/labs/extraction/howto/detergent/ 43
 Anti-microbial effect of Soap
How does soap work against bacteria
and viruses (e.g., Sars-CoV2)?

Image adapted from: Jonatahan Corum
and Ferris Jabr/The New York Times

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 Video – Which is better: Soap or Hand Sanitizer? (FYI)

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 Summary: What’s happening in each step?
The extraction of DNA involves three key steps:
1. Cell Lysis
– Cell membranes, which are composed of lipids and proteins, are
disrupted or lysed using mechanical and chemical means to release the
DNA and other cellular contents.
2. Separation (filtration)
– The DNA needs to be separated from cell debris and other solids
3. Precipitation and Concentration
– DNA is soluble in water and insoluble in alcohol.
– Upon addition of cold ethanol, the DNA will form a stringy mass at the
interface of the alcohol and aqueous layers.

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 Flowchart: Crude Extraction of DNA
Mash in Add extraction buffer
Ziploc and mash some more

Observe
Work in groups of 5 to
extract strawberry DNA!
Filter slurry &
(Protocol in worksheet)
retain filtrate

DNA Add COLD ethanol to
precipitates filtrate slowly and gently
out!!
 Salt and Ethanol for precipitation of DNA

backbone
NaCl dissociates into Na+ and Cl- ions
– Na+ neutralizes the negatively charged
phosphate backbone on DNA
– The neutralized DNA aggregates more
easily (reduced repulsion)
sugar
phosphate
DNA dissolves in water but has a
sugar
lower solubility in ethanol
phosphate
– With the addition of ethanol, the aggregated
sugar
DNA precipitates more easily out of solution
phosphate

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 Worksheet Q1
Match up each step with its function:
Step Function
1) Smashing of strawberry A) To precipitate DNA from solution

2) Squeeze and mix strawberry with the B) To separate components of the cell
extraction buffer based on size

3) Filter strawberry slurry through the C)To physically break apart the cell wall
filter bag
4) Addition of cold ethanol to filtered D)To break up proteins and dissolve
extract cell membranes

Answer: 1 – C, 2 – D, 3 – B, 4 – A

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 Worksheet Q2
Where is DNA found in the cell?

A. Nucleus
B. Cell Membrane
C. Cell Wall
D. Phospholipid Micelle

Answer: A

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 Worksheet Q3
Upon adding the extraction buffer into the smashed strawberry:
A. Soap in the extraction buffer precipitates out DNA.
B. Soap in the extraction buffer neutralizes the negative charge on the sugar-
phosphate backbone of DNA.
C. Soap in the extraction buffer kills the bacteria in the strawberry slurry.
D. Soap in the extraction buffer disrupts the cell membranes and binds to the
lipids and proteins.

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 Worksheet Q3
Upon adding the extraction buffer into the smashed strawberry:
A. Soap in the extraction buffer precipitates out DNA.
B. Soap in the extraction buffer neutralizes the negative charge on the sugar-
phosphate backbone of DNA.
C. Soap in the extraction buffer kills the bacteria in the strawberry slurry.
D. Soap in the extraction buffer disrupts the cell membranes and binds to the
lipids and proteins.

Answer: D

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 Worksheet Q4
Upon adding ethanol into the strawberry slurry, DNA precipitates because:
A. DNA readily dissolves in ethanol but is insoluble in water.
B. DNA readily dissolves in water but is insoluble in ethanol.
C. DNA is insoluble in both water and ethanol.
D. DNA is readily soluble in both water and ethanol.

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 Worksheet Q4
Upon adding ethanol into the strawberry slurry, DNA precipitates because:
A. DNA readily dissolves in ethanol but is insoluble in water.
B. DNA readily dissolves in water but is insoluble in ethanol.
C. DNA is insoluble in both water and ethanol.
D. DNA is readily soluble in both water and ethanol.

Answer: B

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 END

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