02-Topic 2 Biological Membranes PDF

Summary

These notes cover biological membranes, including their components, structure, and function. They also discuss membrane transport, different types of cell signalling, and cell recognition. The notes include diagrams and figures for better understanding.

Full Transcript

TOPIC 2
BIOLOGICAL MEMBRANES

SEM image shows a WBC (dyed red) in the act of destroying TB bacteria (yellow). The
bacteria are surrounded by the cell membrane of the scavenger cell, then drawn inside and
rendered harmless. Courtesy of MPI for Infection Biology/Volker Brinkmann
 State the main components of membrane
 Identify the structural organisation of
membrane
 Relate the structure and function of membrane
 Illustrate the current model of membrane
 Define and explain the characteristics of
membrane

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 2.1 2.2 Membrane 2.4
Organisation excitation and
2.3 Membrane Cell Signalling
and fluidity of Special
Transport and Cell
membrane Membrane
components Structures Recognition

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 Lipids: phospholipids +
glycolipids

proteins

Phospholipid bilayer

Plasma membrane

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 “A microscopic membrane of lipids and
proteins that forms the external
boundary of the cytoplasm of a cell or
encloses a vacuole, and that regulates
the passage of molecules in and out of
the cytoplasm”
Merriam-Webster Dictionary

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THE PLASMA
MEMBRANE

Phospholipid
bilayer

Hydrophobic Hydrophilic
regions regions of
of protein protein
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TECHNIQUE: FREEZE FRACTURE MICROSCOPY RESULTS

Extracellular
layer

Proteins Inside of extracellular
Knife layer

Plasma membrane Cytoplasmic
layer
Inside of cytoplasmic
layer

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 The plasma membrane is the boundary that separates the
living cell from its surroundings
 The plasma membrane exhibits selective permeability,
allowing some substances to cross it more easily than
others
 Biological membranes
▪ Provide separate compartments in the cell
▪ Are dynamic and fluid structures
▪ Consist of lipids and proteins.
▪ Vary in composition according to their site.
▪ The relative amounts and chemical properties of lipid and
protein molecules affect the properties of the membrane.
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 Compartmentalization-specialized internal
activities
 Scaffold for biochemical activities-effective
interaction
 Selectively permeable barrier
 Transporting solutes
 Responding to external signals- electrical
and chemicals
 Intercellular interaction- adhesion and
communication
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 Phospholipids are the most abundant lipid in the
plasma membrane

 Phospholipids are amphipathic molecules,
containing hydrophobic and hydrophilic regions

 RECALL: The fluid mosaic model states that a
membrane is a fluid structure with a “mosaic” of
various proteins and phospholipids embedded in
it

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 Other components of cell membrane are:
▪ Lipids
▪ phospholipid bilayer/Phosphoglycerides
- Sphingolipids (amino+alcohol)
- Glycolipids (CHO+lipids)
- Cholesterols

▪ Carbohydrates

▪ Proteins
Transmembrane proteins
Interior protein network
Peripheral protein
Glycoproteins

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 Plasma membrane is composed of both lipids and globular
proteins.
▪ Membrane proteins are not very soluble in water.

Molecules of cholesterol embedded in the membrane functions in
breaking up the Van der Waals interactions and close packing of
the phospholipid tails.
This disruption makes the membrane more fluid. Therefore, one
way for a cell to control the fluidity of its membrane is by
regulating its level of cholesterol in the cell membrane.
Q- What is the significance of a membrane which is
fluid?

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 Fluid Viscous

Unsaturated hydrocarbon Saturated hydro-
tails with kinks carbon tails

(b) Membrane fluidity

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▪ Types of membrane LIPIDS
▪ phospholipid bilayer/Phosphoglycerides
▪ Sphingolipids (amino+alcohol)
▪ Glycolipids (CHO+lipids)
▪ Cholesterols

▪ Phospholipids form the backbone of biological membranes
▪ The amount of lipid varies from 20% to 78% according to the site
of the membrane.

▪ Phospholipid molecules can organize themselves to form stable
membranes

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▪ Function of lipid component
▪ Physical state of a membrane
▪ Influence the activity of particular membrane proteins
▪ Precursors for highly active chemical messenger
▪ Continuous interconnection, unbroken structures
▪ Facilitate the regulated fusion or budding of membranes
▪ Maintaining the proper internal composition of a cell-
separating the electrical charges across PM
▪ Able to self assemble-eg liposomes

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 Phospholipid has two fatty-acid chains
attached to its backbone.
▪ One end is strongly nonpolar while the other end
is strongly polar.
▪ POLAR HEAD oriented toward water (hydrophilic)
and NONPOLAR TAILS oriented away from water
(hydrophobic)-amphipathic lipids
▪ bilayer is stable because water’s affinity for
hydrogen bonding never stops

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 Alberts et al., 2002. Molecular Biology of the Cell (4th ed). NY: Garland Science.
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  Amphipathic lipid molecule consists of

 When suspended in aqeous solution- forms
micelle structures (stable)

4-5
nm

LIPID MOLECULE MICELLE PLASMA MEMBRANE
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 Lateral movement Flip-flop
(107 times per second) ( once per month)

(a) Movement of phospholipids

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 Cholesterol

(c) Cholesterol within the animal cell membrane
HOW DOES IT EFFECT THE FLUIDITY???

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 Major types of membrane proteins are:
Transmembrane proteins
Interior protein network
Peripheral protein
Glycoproteins

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 INTEGRAL/TRANSMEMBRANE PERIPHERAL PROTEINS-
PROTEINS SURFACE
 Embedded within the  Located on surface of PM
membrane  Are loosely bound and may
 May extend through the be removed with use of
membrane and project at mild detergent
both surfaces. Some only
extend through one
membrane layer and only
project on one side.

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 hydrophilic end interact with water soluble
substances
 large proteins contain interior channel –
passageway through the PM
▪ single-pass anchors
▪ multiple-pass channels and carriers
▪ pores

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 Functions:
▪ Form fibrillar networks-membrane skeleton-
attachments to cytoskeleton
▪ Provide anchor for the integral proteins
▪ Enzymes
▪ Transmit transmembrane signals
▪ Lipid anchored proteins
▪ As receptors
▪ cell adhesion proteins

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 Linked to lipids (glycolipids) or proteins
(glycoproteins-90%)

Its roles:
 Mediating interactions btwn cell & its env.
 Sorting of membrane proteins to diff cellular
compartments
 Antigenic markers – ABO blood groups

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BECKER PAGE MEMBRANE EXCITATION & SPECIAL MEMBRANE
STRUCTURES

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 2.1 2.4
Organisatio
2.2 Membrane excitation 2.3 Cell
n and
and Special Membrane Membrane Signalling
fluidity of
Structures Transport and Cell
membrane
components Recognition

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 Neurons
 Na/K pump
 Saltutory conduction
 Ion distribution across membrane
 Special membrane structures: adherent
junction, tight junction, gap junction,
plasmodesmata

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 The nervous system = CNS + PNS
 CNS- command centre
 PNS- processing centre; collects info carries out responses
 2 types of cells in nervous system
▪ Neurons – send or receive electrical impulses
▪ Glial cells – most abundant type; provides interconnection

 Neuronal highway connecting PNS to CNS PNS

▪ Interneuron –CNS
▪ Sensory neurons - PNS PNS CNS PNS

▪ Motor neurons - PNS
PNS
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 The membrane potential arises primarily
from the interaction between the membrane
and the actions of transmembrane
proteins embedded in the plasma
membrane.

 Provides the basis of electrical potential
difference across the plasma membrane.

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 CONTRIBUTORS TO MEMBRANE POTENTIAL

Na/K Pump Ion Channels
 Pumps 2K+ INTO cell for  Membrane proteins
3Na+ pumped OUT forming pores; allows
 Establishes & maintains diffusion of ions
concentration difference  More numerous & higher
▪[K+]i ; [Na+]o permeability for K+

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 ELECTRICAL POTENTIAL CHEMICAL FORCE

 Unequal DISTRIBUTION  Unequal
of charges across CONCENTRATIONS of
membrane ions across membrane

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READ ON RESTING MEMBRANE POTENTIAL
 Learning Outcomes
▪ IDENTIFY ions involved in nerve impulse
transmission and their relative concentration
inside and outside the neuron

▪ DESCRIBE the production of the resting potential

▪ EXPLAIN how the action of voltage-gated
channels produces an action potential
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 When neurons are NOT stimulated it
maintains resting potential
▪ Usually -40 to -90mV; use -70mV (-ve inside vs
outside)

 Formation of resting potential (equilibrium
between 2 forces) caused by 2 factors

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 CONTRIBUTORS TO MEMBRANE POTENTIAL

Na/K Pump Ion Channels
 Pumps 2K+ INTO cell for  Membrane proteins
3Na+ pumped OUT forming pores; allows
 Establishes & maintains diffusion of ions
concentration difference  More numerous & higher
▪ [K+]i ; [Na+]o permeability for K+

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 Arise due to action of Na+/K+ pump and
differential permeability of membrane to Na+
and K+ due to ion channels
▪ Concentration gradient created by pump
significant
▪ K+ inside higher; diffuse out thru open channels
▪ Membrane NOT permeable to –ve ions (organic
phosphates, proteins, amino acids)

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▪ so not able to counterbalance leads to build up of
+ve ions outside; -ve ions outside
▪ This electrical potential is an attractive force
pulling K+ back into cell
▪ Balance between electrical and diffusional force
leads to equilibrium potential

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▪ Nernst Equation
EK= 58 mV log ([K+]out/ [K+]in

Describe between membrane potential and ion concentration

▪ Goldman Equation

Describes combined effects of ions on membrane potential

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READBECKER PAGE 367-379
ON GRADED POTENTIALS AND ACTION POTENTIALS
 Neurons are unique as sudden temporary
disruptions to resting membrane potential
occurs in response to STIMULI

 2 types of changes can be observed:
▪ Graded potentials
▪ Action potentials

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 Graded potentials (fluctuations in potentials
able to reinforce or negate each other)

 mechanisms
▪ Ligand gated channels
▪ Depolarization & hyperpolarization

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Ligand gated channels
 Temporary binding of ligands (hormones + neurotransmitters) changes
the conformation of the membrane receptor proteins of channels

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Depolarization & Hyperpolarization
 Effect of permeability changes; measured as depolarization or
hyperpolarization

 Depolarization: Vm becomes > +ve
▪ Eg change from -70mV to -65mV

 Hyperpolarization: Vm becomes > -ve
▪ Eg change from -70mV to -75mV

 Depolarizing and hyperpolarizing
effects can combine to AMPLIFY or
REDUCE their effects

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 Classes of ion channels discussed so far
▪ Ligand-gated ion channels
▪ Voltage-gated ion channels: action potentials

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 The action potential is “all-or-none”.
 It is always the same size.
 Either it is not triggered at all - e.g. too
little depolarization/the membrane is
“refractory”; (time taken for an excitable membrane
to be ready for a second stimulus once it returns to its
resting state following an excitation)
 Or it is triggered completely.

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Action potentials
 Exists when depolarization reaches and
exceeds threshold
 Caused by
▪ voltage gated channels: either Na+ or K+ voltage-
gated channels
▪ Used to establish action potential in neurons

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 4 phases
▪ Resting phase
▪ Rising phase
▪ Top of curve
▪ Falling phase

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 4 phases: Resting phase

▪ Voltage-gated ion channels are closed; partial
diffusion of K+
▪ +stimulus: depolarize until reach threshold; action
potential produced

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 4 phases: Rising phase
▪ Voltage-gated Na+ channel OPEN; influx of Na+
into axon
▪ Rapid depolarization (spike)

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 4 phases: Top of curve
▪ Voltage-gated Na+ channel CLOSES; no more
Na+ enters axon
▪ Voltage-gated K+ channel OPENS

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 4 phases: Falling phase
▪ Repolarization occurs; K+ diffuses OUT from axon
▪ Hyperpolarization occurs before original resting
potential is restored

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 We have discussed how action potentials are
ESTABLISHED.

 Now, how are they PROPAGATED????

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 Factors affecting impulse transmission

▪ more or less nerve being stimulated
▪ type of nerve: High or low threshold nerve
▪ Different speed depending on: diameter of
axon/strength of stimulus
▪ Achieved through SALTATORY CONDUCTION
(120m/sec)

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 Think of propagation of ACTION
POTENTIALS as DOMINOS

 Myelinated axon provides the dominos effect
making SALTATORY
CONDUCTION possible

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 “rapid transmission of a nerve impulse along
an axon, resulting from the action potential
jumping from one node of ranvier to another,
skipping the myelin-sheathed regions of
membrane.”

 Saltatory conduction animation

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 Most mammalian axons are myelinated.

 The myelin sheath is provided by
oligodendrocytes and Schwann cells.

 Myelin is insulating, preventing passage of
ions over the membrane. (80% lipid and
about 20% protein)

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Source: https://www.inkling.com/read/medical-physiology-boron-boulpaep-2nd/chapter-7/propagation-of-action-potentials 68
 Myelinated regions of axon are electrically
insulated.
 Action potentials occur only at unmyelinated
regions: nodes of Ranvier.

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 Communication
between neurons
achieved through
transmission of
signals using
neurotransmitters.

 Gap junction
forms the synapse
between 2 neurons

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 SYNAPTIC CLEFT- the void

 SYNAPTIC VESICLES- the vehicle

 NEUROTRANSMITTERS- Ach, amino acids,
epinephrine, norepinephrine, dopamine,
serotonin

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 Depolarization opens Ca+ channel; Ca+ influx
into the terminal knob-neural transmitter
(NT) vesicle fuses with PM
 NT is then released into the synapse- bind to
post synaptic receptors and triggers AP (influx
of Na+) or inhibit AP (influx of Cl-) of the
adjacent neuron.
e.g Ach inhibits heart contraction but
stimulate skeletal muscle contraction.
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 LECTURE PLAN

2.2 SPECIAL MEMBRANE 2.4 CELL SIGNALLING & CELL
STRUCTURES 2.3 MEMBRANE TRANSPORT RECOGNITION

-DIFFUSION -PARACRINE
-ADHERENS JUNCTION
-FACILITATED DIFFUSION -ENDOCRINE
-TIGHT JUNCTION
-OSMOSIS -RECEPTORS (G-PROTEIN
-GAP JUNCTION COUPLED; TYROSINE KINASE;
-BULK TRANSPORT
-PLASMODESMATA CYTOPLASMIC
-ACTIVE TRANSPORT (1 @ 2) INTRACELLULAR)
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 Adherens
tight junction
junction

Gap junction plasmodesmata

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Junction between cells function:
Hold cells together
Form a barrier
Prevent materials from moving between cells
Cell to cell communication
to integrate the life and growth of higher
organisms
77
 An anchoring junction that connects the actin
filaments of one cell with those of adjacent
cells or with the extracellular matrix

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 Region of actual fusion of plasma membranes
between two adjacent animal cells that
prevent materials from leaking through the
tissue

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 barrier to water and solutes from ECM to cell
maintain cell polarity by blocking the
diffusion of integral proteins
prevents water loss from skin (dehydration)
blood-brain barrier (protect brain from
unwanted solutes)

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 Junction between adjacent animal cells that
allows the passage of materials between the
cells.

 eg SA nodes impulses in heart, peristaltic
waves of esophagus

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 Cytoplasmic connections between adjacent
plant cells

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 2.1
Organisatio 2.4
2.2 Membrane
n and Cell
excitation and 2.3 Membrane
fluidity of Signalling
Special Membrane Transport
membrane and Cell
Structures
component Recognition
s

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 Identify, explain, provide examples & state
the importance of the different types of
membrane transport
 Distinguish passive from active transport
 Explain the mechanism involved in the
different types of active transport
 Relate membrane components with transport
types across membrane

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 SELECTIVE PERMEABILITY OF PM
▪ Cells require high concentrations of the right chemicals in order to
carry out the processes of life

▪ Cells need to be able to get rid of waste products that interfere with
the processes of life

▪ small molecules (O2, CO2, ethanol, etc) can diffuse across the
membrane but at differing rates

▪ depending upon their ability to enter the hydrophobic interior of the
membrane bilayer.

▪ ions (Na+, Mg2+) have to be transported across the PM

▪ AMPHIPATHIC: having both hydrophobic and hydrophilic regions
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 Lipid bilayer impermeable to:
▪ ions such as
▪ K+, Na+, Ca2+ (called cations because when subjected to
an electric field they migrate toward the cathode [the
negatively-charged electrode])
▪ Cl-, HCO3- (called anions because they migrate toward
the anode [the positively-charged electrode])

small hydrophilic molecules like glucose
macromolecules like proteins and RNA
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 Permeability of a molecule through a membrane depends on the
interaction of that molecule with the HYDROPHOBIC CORE of the
membrane.

 Hydrophobic molecules, like hydrocarbons, CO2 and O2 can dissolve in
the lipid bilayer and cross easily.

 Ions and polar molecules pass through with difficulty.
▪ Includes small molecules (water) and larger critical molecules
(glucose and other sugars).
▪ Ions, whether atoms or molecules, and their surrounding shell of
water also have difficulties penetrating the hydrophobic core.

 Proteins can assist and regulate the transport
of ions and polar molecules
→ membrane transport proteins
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 Facilitated
Diffusion Osmosis
Diffusion

Active
Bulk
Transport (1°
Transport
and 2°)

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1) Uniport- (system in which one solute transported)

2) Passive Transport
a) Simple Diffusion- (no assistance)
b) Facilitated Diffusion- rate enhanced by carrier or channel,
generally an integral membrane protein (transporter or
permease)
▪ rapid diffusion "down" a concentration gradient
▪ saturable (reaches a maximum velocity that depends on
transporter concentration
▪ specific (depends on interaction of solute with transporter)
c) Gated Ion Channels

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3) Active Transport
a) Primary active transporters
i. Ion transporters: Na+/K+ ATPase, Plasma membrane
Ca2+ ATPase, H+ pump
b) Secondary active transporters
i. Cotransport (system in which transport of one
solute is coupled to transport of another)
▪ Symport- (different solutes transported in same direction)
▪ Antiport-(different solutes transported
in opposite directions)

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 PASSIVE TRANSPORT
▪ Translocation of molecules down their
concentration gradient
▪ eg osmosis, diffusion & facilitated diffusion

 ACTIVE TRANSPORT
▪ requires an investment of energy to move
molecules against their concentration gradient.

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  Defined as:
 Movement of solutes down its concentration
gradient (as potential energy)
 From an area of higher concentration to an
area of lower concentration
 passive transport because it requires no
energy from the cell

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 a permeable membrane Molecules of dye Membrane
separating a solution with dye
molecules from pure water, dye
molecules will cross the barrier
randomly.
 The dye will cross the
membrane until both solutions
have equal concentrations of
the dye.
 At this dynamic equilibrium as
many molecules pass one way
across the other direction.
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 However, membranes are selectively
permeable and the interactions of the
molecules with the membrane play a role in
the diffusion RATE.

 Diffusion of molecules with limited
permeability through the lipid bilayer may be
assisted by transport proteins.

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 Transports ions and other solutes across the
plasma membrane.

 Facilitate movement by physically binding
molecules on one side of the membrane, and
releasing them on the other.

 essential characteristics
▪ specific
▪ passive
▪ Saturates- as limitting factor to rate

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 Characteristics
▪ Movement is still passive (like diffusion), from high
concentration to low.
▪ Saturates when substance reaches high concentrations
due to lack of available protein
▪ Related substances can compete for the same carrier or
pore.
▪ Maximum rate of transport (fully saturated) is called Tm,
the transport maximum

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 Transmembrane proteins create a
water-filled pore through which ions
and some small hydrophilic molecules
can pass by diffusion.

 The channels can be opened (or
closed) according to the needs of the
cell.

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  Many transport proteins simply
provide corridors allowing a
specific molecule or ion to cross
the membrane.
▪ These channel proteins allow fast
transport.
Channel Protein ▪ For example, water channel
proteins and aquaporins,
facilitate massive amounts of
diffusion.

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  The plasma membrane of
human red blood cells contain
transmembrane proteins that
permit the diffusion of glucose
from the blood into the cell.
 The channels are selective;
that is, the structure of the
protein admits only certain
types of molecules through.
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  So, after all that.....

What is the
DIFFERENCE between
DIFFUSION
and OSMOSIS?

Clue: solutes vs solvent

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 Integral proteins function as gated ion channels
 NOTE: transmembrane channels that
permit facilitated diffusion can be opened
or closed. They are said to be "gated".
 types of gated ion channels:
▪ ligand-gated
▪ mechanically-gated
▪ voltage-gated
▪ light-gated

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 Some channel proteins, ‘gated channels’, open or close depending
on the presence or absence of a physical or chemical stimulus.

 The chemical stimulus is usually different from the transported
molecule.

 For example, when neurotransmitters bind to specific gated
channels on the receiving neuron, these channels open.
▪ This allows sodium ions into a nerve cell.
▪ When the neurotransmitters are not present, the channels are
closed.

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Importance of Gated Ion Channels
 Formation and propagation of impulses
 Secretions of substances into extracellular
space
 Muscle contraction
 Regulation of cell volume
 The opening of stomatal pores in plant leaves
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 Ligand is defined as a small signalling molecule which causes a
response upon binding

 conformational state depends on the binding of a specific
molecule (the ligand)

 Some ion channels are gated by extracellular ligands; some by
intracellular ligands. In both cases, the ligand is not the substance
that is transported when the channel opens.

▪ External ligands: bind to a site on the extracellular side of the
channel.
▪ Internal Ligands: bind to a site on the cytosolic side of the
membrane
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Internal Ligands
 bind to a site on the channel protein exposed to the cytosol.
 Examples:
▪ "Second messengers", like cyclic AMP (cAMP) and cyclic GMP (cGMP),
regulate channels involved in the initiation of impulses in neurons responding
to odors and light respectively.

 ATP is needed to open the channel that allows chloride (Cl-) and
bicarbonate (HCO3-) ions out of the cell.
 This channel is defective in patients with cystic fibrosis. Although the
energy liberated by the hydrolysis of ATP is needed to open the channel,
this is not an example of active transport; the ions diffuse through the
open channel following their concentration gradient.

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Examples of Ligand gated ion channel:

 Acetylcholin (ACh)
▪ The binding of the neurotransmitter acetylcholine at
certain synapses opens channels that admit Na+ and
initiate a nerve impulse or muscle contraction

 Gamma amino butyric acid (GABA)
▪ Binding of GABA at certain synapses — in the central
nervous system admits Cl- ions into the cell and
inhibits the creation of a nerve impulse
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 open by transmitting physical forces of stretch
or pressure to the channels, causing them to
undergo a conformational change to allow ions
to pass through.
 Opening the channels allows ions to permeate
and flow down their concentration gradient;
causing a change in membrane potential.

 Example:
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 conformational state depends on the difference in
ionic charge of both sides of the membrane
 In "excitable" cells like neurons and muscle cells, some
channels open or close in response to changes in the
charge (measured in volts) across the plasma
membrane.
 Example: As an impulse passes down a neuron, the
reduction in the voltage opens sodium channels in the
adjacent portion of the membrane. This allows the
influx of Na+ into the neuron and thus the
continuation of the nerve impulse.
nhi/bio411_Topic2/2012 113
 Definition:
▪ Group of transmembrane proteins forming pores

 Pores responds to light stimuli by opening or
closing

 Eg of naturally occurring
Light- gated ion channel
is the Channelrhodopsin
nhi/bio411_Topic2/2012 114
 Active transport involves the expenditure of energy
(ATP) to move substance against their
concentration gradient.

 involves highly selective protein carriers
within the membrane, eg:
▪ sodium-potassium pump
▪ coupled transport - using energy stored in a
gradient of a different molecule

nhi/bio411_Topic2/2012 115
nhi/bio411_Topic2/2012 116
 Proteins in the membrane act as pumps.
 Move ions or small molecules from low
concentration to high concentration (i.e. up
their gradients).
 Require cellular energy, usually as ATP
 Saturates when substance reaches high
concentrations due to lack of available protein
 Example: Na-K ATPase - Present in nearly
every cell in the body, Pumps 3 Na ions out in
exchange for 2 K ions pumped in (cost=1 ATP)
 Other pumps include the Ca-ATPase, and the
H-ATPase.

nhi/bio411_Topic2/2012 117
Ratio of
Transport
3 Na: 2 K
nhi/bio411_Topic2/2012 118
 establishes a net charge across the plasma membrane
with the interior of the cell being negatively charged with
respect to the exterior.
This resting potential prepares nerve and muscle cells for
the propagation of action potentials leading to nerve
impulses and muscle contraction.
The accumulation of sodium ions outside of the cell draws
water out of the cell and thus enables it to maintain
osmotic balance (otherwise it would swell and burst from
the inward diffusion of water).
The gradient of sodium ions is harnessed to provide the
energy to run several types of indirect pumps.

nhi/bio411_Topic2/2012 119
 The sodium-potassium pump actively
maintains the gradient of sodium (Na+) and
potassium ions (K+) across the membrane.
▪ Typically, an animal cell has higher concentrations
of K+ and lower concentrations of Na+ inside the
cell.
▪ The sodium-potassium pump uses the energy of
one ATP to pump three Na+ ions out and two K+
ions in.

nhi/bio411_Topic2/2012 120
 PRIMARY AT SECONDARY AT

 energy is derived directly  energy is derived secondarily
from energy that has been
from the breakdown of ATP stored in the form of ionic
concentration differences
 utilizes energy in form of ATP between the two sides of a
membrane
to transport molecules across
a membrane against their  energy comes from the
electrochemical gradient
concentration gradient created by pumping ions out of
the cell
 Pumps possess one or more
 Co-Transport
ATP binding sites present on ▪ symport
cytosolic face of membrane ▪ antiport

nhi/bio411_Topic2/2013 121
 TWO TYPES OF CA 2+ ATPase PUMP

Plasma Sarcoplasmic
Membrane Reticulum
Ca 2+ ATPase Ca 2+ ATPase

nhi/bio411_Topic2/2012 122
 resides in the sarcoplasmic
reticulum (SR) within muscle cells. It is a
Ca2+ ATPase that transfers Ca2+ from
the cytosol of the cell to the lumen of
the SR at the expense of ATP
hydrolysis during muscle relaxation.

 After muscle contraction, Ca 2+ is
pumped back into the sarcoplasmic
reticulum. This is done by a Ca 2+ ATPase
that uses the energy from each molecule
of ATP to pump 2 Ca 2+ ions.

 SR: The endoplasmic reticulum of a
muscle cell; it envelops the myofibrils.

nhi/bio411_Topic2/2012 123
 The plasma membrane Ca2+ ATPase (PMCA) is a transport protein in the plasma
membrane of cells that serves to remove (Ca2+) from the cell.

 It is vital for regulating the amount of Ca2+ within all eukaryotic cells

 Large transmembrane electrochemical gradient of Ca2+
▪ ~10,000-fold concentration gradient between cytosol and extracellular fluids
(ICF: ECF, 10-20 mM: 150mM)

 Ca2+ Concentration gradient drives the entry of the ion into cells

 Propagation of cell signalling achieved by maintaining low [Ca2+]: necessary for
the cell to employ ion pumps to remove the Ca2+.

 The PMCA and the sodium calcium exchanger are together the main regulators
of intracellular Ca2+ concentrations. Since it transports Ca2+ into the extracellular
space, the PMCA is also an important regulator of the calcium concentration in
the extracellular space.
nhi/bio411_Topic2/2012 124
 The parietal cells of the stomach use this pump protons
(H+) into the gastric juice (giving it a pH close to 1).
 In plants, bacteria, and fungi, a proton pump is the major
electrogenic pump, actively transporting H+ out of the cell.
 Protons pumps in the cristae of mitochondria and the
thylakoids of chloroplasts, concentrate H+ behind
membranes.
 These electrogenic
pumps store energy
that can be harnessed
for cellular work.

nhi/bio411_Topic2/2012 125
Definition:
energy from ATP hydrolysis is used to generate a
gradient of another solute, and the transport of that
solute "down" its concentration gradient is used to
drive transport of a different solute against its
concentration gradient

Cotransport is a type of 2° Active Transport.

Example:
Symport- (different solutes transported in same direction)
Antiport- (different solutes transported in opposite directions)

nhi/bio411_Topic2/2012 126
 Cotransporters restores [ion] using ATP

nhi/bio411_Topic2/2012 127
Examples of cotransport
 The human gut epithelial cells take in glucose and Na+ from the
intestines and transport them through to the blood stream using the
concerted actions of Na+-glucose symports, glucose permeases (a
glucose facilitated diffusion protein), and Na+-K+ pumps.

 Plants commonly use the gradient of hydrogen ions that is generated by
proton pumps to drive the active transport of amino acids, sugars, and
other nutrients into the cell.

 E. coli establishes a proton (H+) gradient across the cell membrane by
using energy to pump protons out of the cell. It uses this system to
transport ribose and several amino acids

nhi/bio411_Topic2/2012 128
 Osmosis is passive transport
 Differences in the relative concentration of dissolved materials
in two solutions can lead to the movement of ions from one to
the other.
▪ The solution with the higher concentration of solutes is
hypertonic.
▪ The solution with the lower concentration of solutes is
hypotonic.

These are comparative terms.
▪ Tap water is hypertonic compared to distilled water but
hypotonic when compared to sea water.

▪ Solutions with equal solute concentrations are isotonic.

nhi/bio411_Topic2/2012 129
 Osmotic concentration - concentration of all
solutes in solution
▪ Hyper-osmotic: solution with the higher solute
concentration
▪ Hypo-osmotic: solution with the lower solute
concentration
▪ Iso-osmotic: solute concentrations are equal

nhi/bio411_Topic2/2012 130
 Two solutions of differing concentration are
separated by a membrane that will allow water
through, but not solutes.

 The hypertonic solution has a lower water
concentration than the hypotonic solution.

 More of the water molecules in the hypertonic
solution are bound up in hydration shells around the
solute molecules, leaving fewer unbound water
molecules.
nhi/bio411_Topic2/2012 131
 Unbound water molecules will move from the
hypotonic solution where they are abundant to
the hypertonic solution where they are rarer.
 This diffusion of water across a selectively
permeable membrane is a special case of passive
transport called osmosis.
 Osmosis continues
until the solutions
are isotonic.

nhi/bio411_Topic2/2012 132
 Osmosis is not a problem for cells living in isotonic
environment (eg marine invertebrates).

 cells of most terrestrial animals are bathed in an
extracellular fluid that is isotonic to the cells.

 Organisms without rigid walls experience osmotic
fluctuations in either a hypertonic or hypotonic
environment and require adaptations for
osmoregulation to maintain their internal environment.

nhi/bio411_Topic2/2012 133
For example, Paramecium, a protist, is hypertonic when
compared to the pond water in which it lives.

▪ In spite of a cell membrane that is less permeable to water
than other cells, water still continually enters the
Paramecium cell.

▪ To solve this problem,
Paramecium has a
specialized organelle
(contractile vacuole)
that functions as a
pump to force water out
of the cell.
nhi/bio411_Topic2/2012 134
nhi/bio411_Topic2/2012 135
 Endocytosis (enveloping food)
▪ Phagocytosis: material taken in is in particulate
form
▪ Pinocytosis: material taken in is in liquid form
▪ receptor-mediated endocytosis: transport of
specific molecules
 Exocytosis (discharge of material from
vesicles at the cell surface)
▪ Vesicles produced by Golgi Apparatus
nhi/bio411_Topic2/2012 136
nhi/bio411_Topic2/2012 137
nhi/bio411_Topic2/2012 138
 This process is triggered when extracellular
substances (ligands) bind to special receptors
on the membrane surface, especially near
coated pits.
 This triggers the formation of a vesicle

nhi/bio411_Topic2/2012 139
CLATHRIN

nhi/bio411_Topic2/2012 140
 Receptor-mediated endocytosis enables a cell to acquire
bulk quantities of specific materials that may be in low
concentrations in the environment.
▪ Human cells use this process to absorb cholesterol.
▪ Cholesterol travels in the blood in low-density
lipoproteins (LDL), complexes of protein and lipid.
▪ These lipoproteins bind to LDL receptors and enter
the cell by endocytosis.
▪ In familial hypercholesterolemia, an inherited disease,
the LDL receptors are defective, leading to an
accumulation of LDL and cholesterol in the blood.
▪ This contributes to early atherosclerosis.

nhi/bio411_Topic2/2012 141
nhi/bio411_Topic2/2012 142
 2.1
Organisa
2.2 Membrane
tion and 2.4
excitation and 2.3
fluidity of
Special Membrane Cell Signalling and
membran
Membrane Transport Cell Recognition
e
Structures
compone
nts

nhi/bio411_Topic2/2013 143
 Cell Communication- in multi-cell
organisms cell-to-cell contact is critical.

 CELL COMMUNICATION is most often done
by CELL SIGNAL TRANSDUCTION

 exogenous molecule is RECEIVED by a cell
& CONVERTED into a RESPONSE by the
receiving cell.

144
1. Synthesis and release of signaling molecule
2. Transport to target cells
3. Reception by target cells
4. Signal transduction
5. Response by the cell
6. Termination of signal

145
 Overall process in which information carried by extracellular
messenger molecules is translated into changes that occur
inside a cell
 Coordinating cellular activities
 Communication through extracellular messenger molecules
(ligand) and binds on receptors on target cells
 Signal received is then relayed through:
the second messenger – small substances that
activate/inactivate specific proteins
recruiting other cellular signaling proteins
 To the activated target protein that result in various cellular
activities

146
 Transcription
Survival
Protein synthesis
Movement
Cell death
Metabolic change
Two protein domains – Kinases and phosphatases (add
/remove phosphate groups)

147
148
 local regulator chemical messengers are
targeted to specific receptors

 often includes: growth factor proteins that
promote cell division & growth &
neurotransmitters that move across synapses to
other neurons

149
 target cell is close to the signal releasing cell, and the signal
chemical is broken down too quickly to be carried to other
parts of the body.

Examples of paracrine signaling include growth factor
signaling and clotting factor.
Growth factor signaling plays an important role in many
aspects of development. In mature organisms paracrine
signaling functions include responses to allergens, repairs
to damaged tissue, formation of scar tissue, and clotting.

Overproduction of some paracrine growth factors has been
linked to the development of cancer
150
 specialized cells release molecules (often
hormones) into blood vessels of circulatory
system

 hormones move to distant target cells
▪ elicits response to target cells

151
 Signaling can be more direct
with CELL-TO-CELL
CONTACT examples:

 gap junctions &
plasmodesmata results in
cytoplasmic continuity
favouring cellular
interactions.

 cell surface contacts receptor
protein specificity

 Eg: cytokines boost up
immune response
152
▪ Ion channel Receptors (ligand gated protein
channels)

 a protein PORE in a membrane opens in response to
binding a signal molecule

 ex: a neurotransmitter as acetylcholine (Ach) opens
channel and lets Na+ ions flood into cell, changing
that cell's electrical charge (potential)

153
154
 Cascade of events in a cell upon receipt of a
signal (ligand binding to receptor protein)
which produces a cellular response to a
signalling molecule.

nhi/bio411_Topic2/2013 155
 Reception - ligand molecules (usually water soluble) are
recognized by only one receptor protein bound within a cell
membrane

 Transduction -leads to a conformation change in receptor
shape; change results in receptor interacting with other intra-cellular
molecules
may result in multiple, conformational/structural changes in other
cellular proteins

▪ inactive enzymes ---> active enzymes

 Response - cellular activity, as enzyme catalysis, or the
rearrangement of cytoskeleton (movement), or specific gene
activity.
156
157
Extracellular messenger: Receptors:
 amino acids and its  G-proteins (GpCR to
derivatives – hormones GTP binding proteins)
and neurotransmitter
(Ach, Epinephrine,  Receptor Protein-
thyroid hormones) Tyrosine kinases RTKs
 Steroid hormones  Ligand-gated channel
 Eicosanoids –pain  Steroid hormone
signals receptor
 Protein and  B- and T- cells receptors
polypeptides
158
G Protein Coupled Receptor – Guanine nucleotides binding proteins

159
 has 7 transmembrane -helicies
 possess site for receptor molecule
 a specific example of G-protein cellular
responses:
Fight of Flight Response...
 1 signal molecule gives multiple-
enhanced response.

160
 G-Protein Receptors are receptor proteins that bind
GTP/GDP INSTEAD OF ATP
 convert between active & inactive forms
a signal molecule binds to a receptor --> conformational
change -->
 an inactive G-(GDP)-protein now binds GTP (replacing
GDP)...
 and active G-(GTP)-protein stimulates other inactive
enzymes.
 Elicits Cellular response
161
162
G-Protein has its GTP hydrolyzed -- inactivates G-
protein

163
 second messenger are small substances that activate or inactivate
specific protein- cyclic-AMP (cAMP )

 signal molecule (hormone epinepherine) leads to activation of
membrane bound inactive enzyme Adenyl Cyclase

 ATP → active adenyl cyclase → cyclic-AMP → Cellular processes
▪ eg: Glycogen breakdown

 cAMP is inactivated by phosphodiesterase.
 Other example of second messengers: Ca 2+, Nitric Oxide , cGMP (relaxation
of muscle), phosphoinisitides

164
Epinephrine for glycogen breakdown
Glucagon & epinephrine

165
 Vibrio cholerae grow in fecal infected
waters, infect small intestine, produce
toxin, which binds to a G-protein,
prevents conversion of GTP (active) -->
GDP (Inactive)
 thus G-protein remains active, causing
cAMP to remain active....
 net result: small intestine secretes water
and salts = perfuse diarrhea = fatal.

166
 mouse embryos lacking one G-protein...
show no blood vessel development

 some human embryos w/o G-proteins...
decreased senses (esp: vision & smell)

167
 receptor proteins that have kinase activity.
 they can add a -PO4 group to tyrosine residues of inactive
proteins
 making them active → elicit cellular response
 many growth factors (stimulate cell division & growth) function
via tyr-kinases

▪ binding of growth factor (signal ligand) causes 2 single tyr-kinases to
aggregate
▪ the tyr-dimers, now each phosphorylate the others tyr residues via ATP
kinase activity
▪ the activated-phosphorylated dimer binds relay proteins, activating
them which in turn (by cascade effect) can active up to 10 others, etc.

 1 signal molecule can trigger many proteins and multiple
pathways (cascade effect)

168
Activation: Epidermal growth factor, insulin, Platelet-derived growth
factor etc.
169
 signal molecules (usually lipid soluble)
diffuse through membrane, where
binding to an intracellular receptor
protein initiates a cellular response.

 ex: steroid hormones

170
 Transcription

Translation

Protein synthesis

171
 Ca ions as second messenger cells maintain a
low (10 -7 M) cytoplasmic [Ca] by active transport
of Ca out of cytoplasm pumps keep a low
cytoplasmic [Ca], but high ER cisternae &
mitochondria [Ca] (10,000 X greater)
 Ca itself functions as a 2nd messenger, like
cAMP, as [Ca] in cytoplasm goes up, activates
Ca+ pumps (active transport), & other responses
ensue.
 Eg. muscle contractions, neurotransmitter release,
etc...
172
 Calcium channel in pm and ER membranes are kept
closed
ATP-driven ca ions transport it out of cytosol
Calcium ions as the second messenger
IP3 opens the calcium gate to release calcium into the
cytosol – muscle contraction, cell division, secretion,
fertilization, synaptic transmission, metabolism,
transcription and cell movement
Calcium-binding protein - calmodulin

173
174
175
 Eg: Guard cell of the stomata
 Opening and closing of the stomata – ionic
concentrations/turgor pressure
 Adverse conditions, stimulate the release of abscisic
acid that open calcium channel, cause Ca influx into
the cell and release calcium from internal stores.
 The K+ influx channel close but efflux open followed
by Cl- efflux
 Lead to a drop internal ion solute osmotic loss of
water

176
 most are like dominos... one activates another, then
another, then another...producing a significant
cascade multiplication effect.

 enzyme activation is by protein phosphorylation by
protein kinase enzymes, that transfer P from ATP to
another enzyme protein, thereby activating it.

177
 Signal-receptor – second messenger-
transduction
 Then the final molecules has to enter the
nucleus to activate the gene.
 The last step involves the activation or
deactivation of a process.
 For example an enzyme may be turned on or
off, a gene may be activated or not, or ions
may or may not be transported.
178
179
 plant phytochrome action via G protein &
Ca+ channels

 Function during process of greening plant
pigment in responses to light
▪ seed germination, photoperiodism, flowering, etc.

180
181
 Downregulate cell surface receptors.

 Endocytosis to reduce the number of cell surface
receptors

 Phosphorylation to inactivate cell surface receptors

 Decreased sensitivity between receptor and ligand

 separate receptor from ligand

182
 Programmed cell death is as needed for proper development as
mitosis is.
Programmed cell death is needed to destroy cells that
represent a threat to the integrity of the organism.
 What makes a cell decide to commit suicide?
the withdrawal of positive signals; that is, signals needed for
continued survival, eg. growth factors for neurons
Interleukin-2 (IL-2), an essential factor for the mitosis of
lymphocytes
the receipt of negative signals-increases levels of oxidants within
the cell
damage to DNA by these oxidants or other agents
Signals –intrinsic or extrinsic factors

183