L11 Cell Signaling (1) PDF

Summary

This document provides a lecture on cell signaling, covering topics like required reading, objectives, interactive activity details. It introduces concepts of intracellular receptors, signaling molecules. A summary of cell surface receptors and G-protein coupled receptors is also included.

Full Transcript

Lecture 11
Cell Signaling
Required Reading:
Morris text: Chapter 9
Section 9.1 Principles of Cell Signaling
Section 9.2 Distance Between Cells

Objectives:
Signaling Receptors
G Protein-coupled Receptors
Receptor Kinases
Textbook reference sections/pages:
Morris text – Chapter 9 (pp. 179-194)
Section 9.3 Signaling Receptors (pp. 185-188)
Section 9.4 G Protein Coupled Receptors (pp. 188-191)
Section 9.5 Receptor Kinases (pp. 191-194)

BIOL1010 and BIOL1011
 Interactive Activity
Using your laptop or phone or tablet…
Go to: https://b.socrative.com/login/student/
Or search Socrative Student
Enter Room Name: BIOLOGYANA and enter
your first and last name
You may discuss the answers with others in
the class before answering

BIOL1010 and BIOL1011 Slide 2
 How Do Cells Communicate?
All cells process information from the environment
Communication required for coordination of activities
Communication most often via chemical signals that bind
to specific receptors
– Hormones, neurotransmitters, CO2, H+
Signals can come from outside the organism, or from
neighboring cells; short distances or long
Examples of molecules that act a signals:

Plants: Animals:
– Ethylene – Epinephrine

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Receptor Activation and Receptor Types
Receptor: protein that receives and
interprets information carried by signaling
molecule (ligand)
Ligand binds to ligand-binding site on
receptor 🠦 conformational shape change in
the entire receptor
Shape change activates receptor
Receptors can be found on:
– inside the cell = intracellular receptors
– cell surface = cell surface receptors
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 Intracellular Receptors
– Found inside the cell
– Receptor + ligand (if steroid) =
steroid–receptor complex
Either in cytoplasm or nucleus

– Use non-polar signaling molecules:
Small and pass freely through plasma membrane
Can be a steroid
Steroids are hydrophobic; pass through plasma membrane
Active steroid-receptor complexes act as transcriptional
regulators and control gene expression

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 Cell Surface Receptors
General structure:
1. Ligand-binding site
2. Extracellular domain
3. Transmembrane domain
4. Cytoplasmic domain
1
2

3

4

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 Cell Surface Receptors (2)
Use polar signaling molecules
– Small polar proteins, cannot cross
plasma membrane

Types of cell-surface
receptors:
– There are thousands of different receptor proteins on
the surface of any given cell.
– Most can be placed into one of three groups,
according to the way they are activated.
G protein-coupled receptors
Receptor kinases
Ion channels

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 Cell Surface Receptors (3)
Cell Surface Receptors Act Like Molecular
Switches
– Many receptors exist in two alternative states – on or off
– Signaling molecule bound to receptor 🠦 receptor activated
(i.e. on)
– Signaling molecule not bound to receptor 🠦 receptor
inactive (i.e. off)

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 Signal Transduction, Response and
Termination

Signal transduction (and sometimes amplification),
response and termination are the steps that occur
after a signaling molecule binds to receptor
– Although the ligands are different, the subsequent steps
are similar

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 G Protein-Coupled Receptors
Transmembrane proteins with this general structure:
i. Ligand binding site – extracellular
ii. Transmembrane region - 7 alpha helices
iii. G-protein binding site – cytoplasmic
Types of signal molecules used
by G-protein-coupled receptors:
Small molecules
Many hormones
Neurotransmitters
G-protein-coupled receptors
are responsible for senses of
sight, smell, taste

BIOL1010 and BIOL1011 Slide 10
 G Protein-Coupled Receptors
When ligand binds to G protein-coupled receptor, it is
activated
When active, it binds to a G protein (cytoplasm)
G proteins can be bound to either GDP or GTP
(guanine nucleotides)
G protein + GTP = active
G protein + GDP = inactive

Ligand binds 🠦 receptor then binds to G protein 🠦
GDP replaced with GTP and G protein activated 🠦
signal transmitted
– Active G protein then activates other proteins as part of
signaling pathway

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 G Protein-Coupled Receptors
Some G proteins are composed of
three subunits:
α (alpha)
β (beta)
γ (gamma)
α (alpha) subunit binds either GDP
or GTP
α subunit + GDP 🠦 3 subunits bound =
inactive
Receptor activated 🠦 GDP on α
subunit replaced by GTP 🠦 3 subunits
separate = active
Activated α subunit binds to and
activates target protein 🠦 response

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 Example of G Protein Activation and
Amplification: Adrenaline Signaling in
Heart Muscle
Target protein = adenylyl cyclase

Activated adenylyl cyclase converts
ATP to cAMP (second messenger)
cAMP = second
messenger
cAMP binds to Protein kinase A

Activated protein kinase A
phosphorylates heart proteins
As long as adrenaline is
bound to the receptor, the
heart rate will remain high.
Heart rate increases
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 Amplification of Adrenaline Signal
A little adrenaline goes a
long way!
1 Amplification occurs at
several places (1, 2, 3)
Small amount of signal 🠦
large response

2 Key Point:
Cell response depends on cell
type and proteins in it
3 G protein-coupled receptors
typically activate downstream
enzymes or open ion channels
Effects are rapid, short-lived,
reversible
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 Termination of G protein Signal
The amount of time a signaling molecule remains bound to
its receptor depends on how tightly the receptor holds on to
it, its binding affinity for the signaling molecule.
Most ligands do not bind permanently to receptors
Signal turns off once ligand is unbound (G protein deactivates itself)
GTP to GDP

Other parts of the pathway must also turn off
Enzymes degrade cAMP to AMP

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 Termination of G protein Signal (2)

Phosphatases remove phosphate group = dephosphorylation
When a protein is dephosphorylated by a phosphatase, it
typically becomes inactive

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 Receptor Kinases
A kinase is an enzyme that adds
a phosphate group to another
molecule 🠦 phosphorylation
Phosphate group comes from
ATP
When a protein is
phosphoryl-ated by a kinase,
that protein typically becomes
active
– Shape change or
– Provides new site for other proteins
to bind
Recall: phosphatases have the
opposite effect i.e. remove
phosphate group =
dephosphorylation

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Receptor Kinase Activation/Transduction
Extracellular portion - binds signaling molecule
Intracellular portion - is the kinase
Dimerization activates cytoplasmic kinase domains causing
them to phosphorylate each other at multiple sites on their
cytoplasmic tails.
Phosphorylated areas provide sites for other proteins to bind
and become active.

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 Receptor Kinases
Where is receptor kinase signaling used?
Formation and elongation of limb buds that
become our arms and legs
Wound healing
when we cut ourselves, platelet derived growth factor
(PDGF) released from platelets in the blood signals to
cells at the wound site, triggering cell division to repair
the damage
In general, receptor kinases initiate long-term
responses
Activation of proteins involved in changes in gene
expression
Cell growth, division, differentiation, shape change
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 Receptor Kinase Example: The MAP kinase pathway
Paper cut – ouch!

Platelets release proteins
including PDGF
MAP kinase pathway:

PDGF binds to receptor
kinases on cell surface
NB:
Dimerization; receptor
Ras + GDP 🠦 inactive
activation Ras + GTP 🠦 active

Ras protein activated (in
cytoplasm); GTP bound

Kinase series triggered; kinase
enters nucleus This pathway becomes
inactive once the
GTP-bound Ras is
Transcription regulators for
cell division activated converted to GDP.

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 Receptor Kinases
A receptor kinase, Kit, responsible for the production of
pigment in skin, feathers, scales and hair
Mutations in the Kit receptor kinase causes patterns of
incomplete pigmentation (white patches)

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 Ligand-gated Ion Channels

These are receptors that alter
flow of ions across plasma
membrane (channels)
Conformational shape change
opens channel
– Allows flow of ions in and/or out
– Channel remains open as long
as the signaling molecule
remains bound

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 Integration of Signaling Pathways
Signaling pathways do not operate independently –
signaling is very complex!
– In one organism - many different signaling molecules
each with own receptors
Different signaling molecules can bind to a single cell
and activate several signaling pathways
simultaneously
– final response of a cell depends on how the pathways
intersect with one another
Also, one signal may inhibit signaling pathway
triggered by a another signal and weaken the end
response
“Molecular cross-talk”
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