Cell Membrane Structure & Composition PDF

Summary

This document provides an overview of cell membrane structure and function, including phospholipid bilayers, proteins, and carbohydrates. It discusses the fluidity and asymmetry of the membrane and the processes that regulate it, such as new membrane synthesis. The content is suitable for secondary-school level biology.

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Cell Membrane
Structure and
Composition
 Hereditary spherocytosis
Hereditary spherocytosis is
a genetic disease and a type
of hemolytic anemia.

Anemia is characterized by
symptoms such as fatigue,
dizziness, hair loss and eye
yellowing.
 In hereditary spherocytosis,
red blood cells lose their
biconcave, flexible shape
(necessary to pass through
narrow capillaries) and
become spherical.
In this disease, proteins
attaching the cell membrane to
the cytoskeleton are dysfunctional
(ex: spectrin, ankyrin)
 Red blood cell membrane: an Illustration
of cell membrane structure
Plasma membranes is Spectrin (part of
supported by a meshwork of the cell cortex in
proteins called the Cell RBCs)
Cortex (actin, myosin, and
actin-binding proteins such as
spectrin and ankyrin in red
 Plasma
blood membrane is a
cells)
thin fatty film studded
with proteins and
coated with
carbohydrates.
The carbohydrates
attached to the plasma
Ank:ankyrin
membrane proteins and Sp: Spectrin
lipids on the outside of the Act: actin
Plasma
plasma membrane form a membrane
sugar coating called Glycocalyx
glycocalyx.
 All plasma membranes are composed of
lipids and proteins

 All plasma membranes (either surrounding the cell or the organelles)
consist of lipid and proteins.
 Membrane lipids are arranged in two sheets called lipid bilayer.
 Plasma membrane lipids

 The lipids in the plasma membrane are phospholipids (major lipid
components), cholesterol and glycolipids.

All plasma membrane lipids are amphipathic (they have a hydrophilic
head and a hydrophobic tail).
 Phosphatidylcholine: an example of
phospholipid
 Phosphatidylcholine is the most
common phospholipid in biological membranes.

The hydrophilic head of phosphatidylcholine is
composed of a choline molecule and a phosphate
group.

Glycerol links the hydrophilic head to the
hydrophobic tails.
The hydrophobic tails are composed of two fatty
acids (14 and 24 carbon atoms).

 The hydrophobic tails could be saturated (no
double bonds between the carbon atoms) or
unsaturated (with double bond(s) between
the carbon atoms).
Plasma membrane phospholipids form a
lipid bilayer

The hydrophilic heads face
water on both surfaces of the
bilayer

The hydrophobic tails are all
shielded from the water and lie next
to one another in the interior (like
the filling in a sandwich).
 Phospholipid bilayers form sealed
compartments

 Phospholipid bilayers spontaneously
close in on themselves to form sealed
compartments.

 The closed structure is stable
because it avoids the exposure of
the hydrophobic hydrocarbon tails
to water.

 The layer of the lipid bilayer facing
the cytosol is called the cytosolic
monolayer (or face) and the layer
facing the exterior of the cell or the
lumen of an organelle (ex:Golgi,
ER) is called the non-cytosolic
monolayer (or face).
 The Lipid bilayer is a flexible two-
dimensional fluid

The plasma membrane is flexible and its components (lipids and
proteins) can move freely within the layer.

Phospholipids can rotate, move laterally within the same layer
and flip to the other layer (rarely, with the aid of flippase
enzymes).
 Therefore, the plasma membrane is described
as fluid.
 Several factors affect the fluidity of
the plasma membrane

The temperature
 fluidity increases as the temperature increases.
Lipid composition
 cholesterol tends to stiffen plasma
membranes.
Phospholipid tail saturation degree:
 lipid bilayers with unsaturated hydrocarbon tails
are more fluid.
Phospholipid tail length:
 lipid bilayers with shorter fatty acid chains are
 New membrane is synthesized on the
SER

Phospholipids are made and incorporated
into the cytosolic face of the smooth
endoplasmic reticulum plasma membrane.

The phospholipids are randomly
distributed to the non-cytosolic face of the
smooth endoplasmic reticulum’s
membrane.
 New membrane is then matured in the
Golgi membrane

The new plasma membrane is then
delivered to the Golgi plasma
membrane.
In the Golgi membrane, specific
phospholipids are transferred back to
the cytosolic monolayer (ex:
phosphatidylserine).
Therefore, the plasma membrane is described as
asymmetrical.

Phosphatidylserine (light green)
Phosphatidylethanolamine (yellow)
Phosphatidylcholine (red)
Sphingomyelin (brown)
 Phospholipids and glycolipids are
distributed asymmetrically

Glycolipids are in the non-cytosolic monolayer of the lipid
bilayer and face the exterior of the cell.

phosphatidylethanolamine (yellow)
Phosphatidylcholine (red)
phosphatidylinositols (dark green)
Sphingomyelin (brown)
Glycolipids (hexagonal blue)
Phosphatidylserine (light green)
cholesterol (green)
 Plasma membrane
asymmetry is
preserved during
membrane transfer
 Plasma membrane is
transported by a process of
vesicle budding (from the Golgi
apparatus) and fusion (with the
cell membrane or the plasma
membrane of other organelles).
 Membranes retain their
orientation during transfer
between cell compartments
(lipids in the cytosolic
monolayer always face the
cytosol).
 Most plasma membrane functions are
carried out by
membrane proteins

Plasma membrane proteins have a variety of functions:
 Transporters
 Ion channels
 Anchors
 Receptor
sEnzymes
 Membrane proteins associate with the
lipid bilayer in different ways

Multipass Single pass β barrel

 There are two general types of membrane proteins:
 Integral transmembrane proteins, monolayer-associated, lip
linked (anchored)
 Peripheral proteins-attached or lipid-attached.

 The distribution of membrane proteins is also asymmetrical.
 Transmembrane
proteins usually
crosse the lipid
bilayer as an α Helix

 The backbone of a polypeptide
chain is hydrophilic.

 Single pass transmembrane proteins
have a hydrophobic alpha helix.
 Transmembrane proteins usually crosse
the lipid bilayer as an α Helix

 Multi pass transmembrane proteins have amphipathic alpha helices
(plural of helix).
 Detergents are required to solubilize
integral proteins

 Detergents (SDS and Triton) are required to solubilize
integral membrane proteins.
 Detergents are amphipathic molecules.
 Plasma
membrane
proteins can
move laterally
in the lipid
bilayer

 Staining membrane proteins allows us to
visualize membrane fluidity.
 The movement of membrane
proteins can be restricted

Cells can confine particular proteins to
localized areas:
 by binding the cell cortex.

 by binding extracellular matrix molecules.

 by binding proteins on the surface of
another cell.
 be restricted by diffusion barriers.

 Example: epithelial cells in the gut
Tight junctions prevent proteins from
the apical plasma membrane to mix
with proteins in the lateral and basal
plasma membrane
 The cell surface is coated with
carbohydrates

 All carbohydrates added to proteins and lipids face outside of the cell.

 This sugar coating is called the carbohydrate layer or glycocalyx.

 The carbohydrates of glycoproteins and proteoglycans often
function in cell recognition and adhesion.
Glycocalyx allows cell-cell adhesion
 The functions of the cell membrane

All these properties allow the cell
membrane to get involved in various
essential functions such as:

 Cell signaling
 Transport

 cell growth and motility

 Cell-cell recognition

 intercellular adhesion
 Learning outcomes

 Describe the structure, location and function of the cell cortex.
 Explain how lipid bilayer is formed and why is it considered
fluid and asymmetrical.
 List the main membrane components, explain how they move
within the lipid bilayer and how their movement (membrane
fluidity) is regulated and restricted.
 Illustrate in a diagram a cell membrane with its phospholipids
and different membrane proteins. Include examples of lipid
bilayer asymmetry.
 Predict how removal (or inhibition) of any components of the
cell membrane affects its properties and function.
 Predict the results of cell fusion experiments.
 Contrast different types of integral proteins (single pass,
multipass, β-barrel transmembrane protein, anchored protein,
etc.) and integral and peripheral proteins in terms of structure
and function.
 Learning outcomes

 Explain how the polypeptide chain of a transmembrane
protein, with its hydrophilic backbone, can span the
hydrophobic interior of the lipid bilayer.
 Explain how detergent molecules can extract proteins from
a cell membrane.
 Explain where and how new membrane is synthesized and
explain how phospholipids are asymmetrically distributed to
produce even lipid bilayers.
 Describe how membranes retain their orientation during
transfer between cell compartments.
 Describe the structure and function of the glycocalyx and
with an example explain its role in tissue formation.
 Keywords you need to know
before studying this lecture
 Amino acid

 Amino acid side chains

 Hydrophobic side chaines

 Hydrophilic side chaines

 Charged/uncharged molecules

 Hydrogen bond

 Lipid

 Polar /unpolar molecules

 Partial negative charge

 Partial positive charge

 Primary structure of a protein

 solute/solvent/solution

 Single/double covalent bond

 Secondary structure of a protein

 Protein N and C terminal