HSS2305A - 2024 - Lecture 15 PDF

Summary

This lecture provides an overview of cell signaling, including details on various types of signaling and signal transduction pathways. It covers topics such as receptors, ligands, and second messengers. The content is suitable for a university-level biology course.

Full Transcript

HSS2305: Molecular
Mechanisms of Disease

Lecture 15 – Cell Signalling and G-Coupled Receptors
Prof. Keir Menzies
Cell Signalling
Overview- with an old school video! lol

http://www.dnalc.org/resources/3d/cellsignals.html

http://www.dnalc.org/resources/3d/cellsignals.html
Cell Signalling
Overview

Cells must respond adequately to external stimuli to survive
Cells respond to stimuli via cell signaling
Some signal molecules (or ligands) enter cells; others bind to cell-surface
receptors
Receptors respond to ligands to initiate intracellular action
Message relayed inside cell via a cascade of downstream protein conformational
changes → action
Cell Signalling
Overview

Extracellular messenger molecules: transmit messages between cells
autocrine signalling → cell has receptors on its surface that respond to the
messenger (a)
Cells induce or supress themselves – send and respond to same message
paracrine signalling → messenger molecules travel short distances through
extracellular space (b)
Adjacent cells, regulate each other
endocrine signalling → messenger molecules (hormones) reach their target
cells through the bloodstream (c)
Messenger travels far from site of secretion to reach target tissues/organs/cells
Cell Signalling
how is a signal transduced: signal transduction

Ligand
Extracellular messages / signal molecule
Ex. steroids, neurotransmitters, glucagon,
insulin, growth factors
Receptors
Proteins on target cells that receive
messages
Conformational change in receptor
relays message into cytoplasmic domain
2 major routes of message transmission
1. Generation of an intracellular second
messenger via an effector enzyme
Second messengers
activate/inactivate target proteins
2. Recruit signaling proteins to their
intracellular domains to initiate a
protein activated cascade
Cell Signalling
signal transduction

Signalling pathways or signalling
cascades
each protein alters conformation of
the next protein
protein conformation usually
altered by phosphorylation
Kinases (+ Pi; ~500)
Phosphatases (- Pi; ~150)
Amino acids Serine, threonine,
tyrosine*
Activate/inactivate an enzyme
Target proteins ultimately receive a
message to alter cell activities
such as:
Leading to phosphorylation of a TF→
gene transcription
Activity of metabolic enzymes
Cell mobility
DNA synthesis → replication
Cell death
Cell Signalling
signal transduction

Protein phosphorylation can
change protein behavior of
cells in different ways
activate/inactivate an
enzyme
Increase/decrease protein-
protein interactions
change subcellular location
of a protein
trigger protein degradation
Phospho patterns can differ
between cell types
(e.g. 2 types of breast
cancer cells, which could
lead to treatment decisions) Comparison in frequency of tyrosine
phosphorylation (red intensity) in 2 types
of breast cancer cells.
mail

Phosphorylation Is a Central
Mechanism for Circadian
Control of Metabolism and
Physiology
Maria S. Robles1, Sean J.
Humphrey1, Matthias
Mann1, 2, ,

Cell Metabolism 2016
Cell Signalling
Receptors
Cell Signalling
Receptors

Receptor types include: a)
a) G-protein coupled
receptors (GPCRs)
b) Receptor protein-tyrosine
kinases (RTKs)
c) Ligand gated channels b) d)
allow or conduct passage
of ion
d) Steroid hormone receptors
nuclear receptors c)
e) Specialized receptors
i.e. B-and T-cell receptors
- immune response to
generate diversity in
immune response
G Protein-Coupled
Receptors

https://www.youtube.com/watch?v=Glu_T6DQuLU
G Protein-Coupled
Receptors
G protein-coupled receptors (GPCRs)
Largest family of membrane proteins by size and diversity
7 transmembrane helical domain receptor Thousands of different GPCRs
Coupled to cytoplasmic G protein
3 subunits (α, ß, γ)
Uses GTP to activate “effector” protein and trigger second messengers
G Protein-Coupled
Receptors
Small molecules such as amino acids and their derivatives
(e.g. acetylcholine, epinephrine, dopamine).
Gases such as NO and CO
Steroids (regulate sexual differentiation, pregnancy,
carbohydrate metabolism)
Eicosanoids, which are lipids derived from fatty acids.
Various peptides and proteins
G Protein-Coupled
Receptors
G Protein-Coupled
Receptors
G Protein-Coupled
Receptors

Heterotrimeric G
protein
G Protein-Coupled
Receptors
signal transduction
1. Ligand binding to the extracellular
domain alters receptor conformation
 affinity and binding of G protein to receptor
2. Upon binding, Gα conformational
change
GDP is exchanged for GTP = G protein
activation
A number of G proteins can become
activated
3. GTP-Gα dissociates from Gßγ and
binds effector
has low affinity for Gßγ subunits
4. GTP-Gα can activate/inhibit an effector
protein
Adenylyl cyclase → convert ATP to
cAMP (2nd messenger)
Phospholipase C
cGMP phosphodiesterase
G Protein-Coupled
Receptors
signal transduction
1. Ligand binding to the extracellular
domain alters receptor conformation
 affinity and binding of G protein to receptor
2. Upon binding, Gα conformational
change
GDP is exchanged for GTP = G protein
activation
A number of G proteins can become
activated
3. GTP-Gα dissociates from Gßγ and
binds effector
has low affinity for Gßγ subunits
4. GTP-Gα can activate/inhibit an effector
protein
Adenylyl cyclase → convert ATP to
cAMP (2nd messenger)
Phospholipase C
cGMP phosphodiesterase
G Protein-Coupled
Receptors
signal transduction
1. Ligand binding to the extracellular
domain alters receptor conformation
 affinity and binding of G protein to
receptor
2. Upon binding, Gα conformational
change
GDP is exchanged for GTP = G
protein activation
A number of G proteins can become
activated
3. GTP-Gα dissociates from Gßγ and
binds effector
has low affinity for Gßγ subunits
4. GTP-Gα can activate/inhibit an effector
protein
Adenylyl cyclase → convert ATP to
cAMP (2nd messenger)
Phospholipase C
cGMP phosphodiesterase
G Protein-Coupled
Receptors
signal transduction
1. Ligand binding to the extracellular
domain alters receptor conformation
 affinity and binding of G protein to receptor
2. Upon binding, Gα conformational
change
GDP is exchanged for GTP = G protein
activation
A number of G proteins can become
activated
3. GTP-Gα dissociates from Gßγ and
binds effector
has low affinity for Gßγ subunits
4. GTP-Gα can activate/inhibit an effector
protein
Adenylyl cyclase → convert ATP to
cAMP (2nd messenger)
Phospholipase C
cGMP phosphodiesterase
G Protein-Coupled
Receptors
signal transduction
5. Gα subunit can turn itself “off” via
hydrolysis of GTP → GDP + Pi
6. Conformational change of Gα
decreases affinity for effector
protein and increases affinity for
Gßγ subunits
7. Can be Desensitized: receptor is
phosphorylated by G protein-
coupled receptor kinase (GRK)
8. Desensitization step 2: Arrestin
protein binds to receptor and
inhibits binding of G protein
Promote internalization of GPCRs
Internal signalling
Degradation
Dephosphorylated and returned
to cell membrane (re-
sensitized)
G Protein-Coupled
Receptors
signal transduction
5. Gα subunit can turn itself “off” via
hydrolysis of GTP → GDP + Pi
6. Conformational change of Gα
decreases affinity for effector
protein and increases affinity for
Gßγ subunits
7. Can be Desensitized: receptor is
phosphorylated by G protein-
coupled receptor kinase (GRK)
8. Desensitization step 2: Arrestin
protein binds to receptor and
inhibits binding of G protein
Promote internalization of GPCRs
Internal signalling
Degradation
Dephosphorylated and returned
to cell membrane (re-
sensitized)
G Protein-Coupled
Receptors
signal transduction
5. Gα subunit can turn itself “off” via
hydrolysis of GTP → GDP + Pi
6. Conformational change of Gα
decreases affinity for effector
protein and increases affinity for
Gßγ subunits
7. Can be Desensitized: receptor is
phosphorylated by G protein-
coupled receptor kinase (GRK)
8. Desensitization step 2: Arrestin
protein binds to receptor and
inhibits binding of G protein
Promote internalization of GPCRs
Internal signalling
Degradation
Dephosphorylated and returned
to cell membrane (re-
sensitized)
G Protein-Coupled
Receptors
signal transduction
5. Gα subunit can turn itself “off” via
hydrolysis of GTP → GDP + Pi
6. Conformational change of Gα
decreases affinity for effector
protein and increases affinity for
Gßγ subunits
7. Can be Desensitized: receptor is
phosphorylated by G protein-
coupled receptor kinase (GRK)
8. Desensitization step 2: Arrestin
protein binds to receptor and
inhibits binding of G protein
Promote internalization of GPCRs
Internal signalling
Degradation
Dephosphorylated and returned
to cell membrane (re-
sensitized)
G Protein-Coupled
Receptors
signal transduction
5. Gα subunit can turn itself “off”
via hydrolysis of GTP → GDP +
Pi
6. Conformational change of Gα
decreases affinity for effector
protein and increases affinity for
Gßγ subunits
7. Can be Desensitized: receptor
is phosphorylated by G protein-
coupled receptor kinase (GRK)
8. Desensitization step 2: Arrestin
protein binds to receptor and
inhibits binding of G protein
Promote internalization of GPCRs
Internal signalling
Degradation
Dephosphorylated and returned to cell
membrane (re-sensitized)
G Protein-Coupled
Receptors
signal transduction

Strength and duration of signal are
determined by rate of GTP
hydrolysis by Gα subunit
Gα subunit possess weak
GTPase activity → slowly
hydrolyzes GTP and inactivates
themselves
Termination of response can
be accelerated by
Regulators of G protein
Signaling (RGSs; not seen
in diagram here)
Increases rate of GTP
hydrolysis
G Protein-Coupled
Receptors
 G Protein-Coupled
Receptors
Effectors
2nd
Effector messenger

Gs → + Adenylyl Cyclase → cAMP
Gs Gi
Gi → inhibit Adenylyl Cyclase →  cAMP

https://www.youtube.com/watch?v=
qOVkedxDqQo
G Protein-Coupled
Receptors
Effectors
2nd
Effector messenger

Gs → + Adenylyl Cyclase → cAMP
Gi → inhibit Adenylyl Cyclase →  cAMP

Gq → + PLCβ →  IP3 + DAG
(PLC:phospholipase C)
G Protein-Coupled
Receptors
Effectors
2nd
Effector messenger

Gs → + Adenylyl Cyclase → cAMP
Gi → inhibit Adenylyl Cyclase →  cAMP

Gq → + PLCβ →  IP3 + DAG

G12/13 → + small G proteins
* excessive activation leads to cell
proliferation and malignancies
G Protein-Coupled
Receptors
Effectors
G Protein-Coupled Receptors
second messengers

Second messengers → released into
the cytoplasm after binding of a
ligand
Many can be created by one effector
enzyme in order to amplify the
response to a single extracellular
ligand

3 common second messenger
systems:
cyclic nucleotides
cAMP and cGMP
Phosphatidylinositol derivatives
inositol trisphosphate (IP3) and
diacylglycerol (DAG)
calcium ions (Ca2+)
G Protein-Coupled Receptors
second messengers - cAMP

cAMP = cyclic adenosine
monophosphate
Synthesized by effector
adenylyl cyclase
ATP → cAMP
Stimulated by Gs subunit
Inhibited by Gi subunit
Capable of diffusing to other
sites within the cell
Can stimulate a variety of
cellular activities
G Protein-Coupled Receptors
second messengers - cAMP

cAMP→ Activates
protein kinases →
phosphorylation of
proteins
Cytoskeleton
Protein synthesis
Glycogen
breakdown/formation →
glucose regulation
Fatty acid formation

Activation of calcium
channels
G Protein-Coupled Receptors
second messengers - cAMP

cAMP→ Activates
protein kinases →
phosphorylation of
proteins
Cytoskeleton
Protein synthesis
Glycogen
breakdown/formation →
glucose regulation
Fatty acid formation

Activation of calcium
channels
G Protein-Coupled Receptors
second messengers - cAMP

cAMP→ Activates
protein kinases →
phosphorylation of
proteins
Cytoskeleton
Protein synthesis
Glycogen
breakdown/formation →
glucose regulation
Fatty acid formation

Activation of calcium
channels
 G Protein-Coupled Receptors
second messengers - cAMP

Protein Kinase A is activated by cAMP
“cAMP-dependent protein kinase”
Holoenzyme
a biochemically active compound formed by
the combination of an enzyme with a
coenzyme
Subunits:
regulatory subunit dimer (R)
catalytic subunit (C)
low levels of cAMP → catalytically inactive
Represents any
high levels of cAMP → cAMP binds number of
regulatory subunits, releasing the catalytic
subunits enzymes
Free catalytic subunits can phosphorylate
proteins
>100 substrates
When phosphorylated cAMP
phosphodiesterase (PDE) can break down
cAMP → feedback loop
 G Protein-Coupled Receptors
second messengers - cAMP

Protein Kinase A Anchoring Proteins (AKAPs):
Function as signalling hubs → scaffold for coordinating protein-protein
interactions by sequestering PKA to specific locations around the cell
> 50

= PKA

= AKAP
G Protein-Coupled Receptors
second messengers - cAMP
 G Protein-Coupled Receptors
adrenergic receptors

Adrenergic receptors or adrenoceptors
A class of G protein-coupled receptors
targets of catecholamines
Ex. norepinephrine (noradrenaline)
and epinephrine (adrenaline)
GPCRs for epinephrine
9 different receptors
grouped as α- and β-receptors
Responsible for fight-or-flight response
Different tissues and organs have different
adrenergic receptors
Yield different internal signaling
Ex. ß-Adrenergic receptor on cardiac muscle cell
→ Gs subunit activated
→ stimulates cAMP production Muscle Muscle
→ increased rate and force of contraction relaxation contraction
Ex. α-Adrenergic receptor on intestinal smooth
muscle cell
→ Gi subunit activated Beta blockers, also known as beta-adrenergic blocking
agents, are medications that reduce your blood pressure.
→ inhibits cAMP production Beta blockers work by blocking the effects of the hormone
→ muscle relaxation epinephrine, also known as adrenaline. Beta blockers
cause your heart to beat more slowly and with less force,
which lowers blood pressure.
 G Protein-Coupled Receptors
Regulation of Blood Glucose

Glucose Regulation
cAMP leads to glucose mobilization
1. GPCR (cAMP-mediated) responses:
Glucagon (*Endocrine Hormone)
Released from pancreas in response to low glucose
Activates Glucagon GPCR in Liver
Stimulates breakdown of glycogen and release of
glucose
Acts via GPCR (glucagon receptor)
Epinephrine (Endocrine Hormone)
Released from adrenal gland – fight or flight
Activates Adrenergic GPCR in Liver
Stimulates breakdown of glycogen and release of
glucose
Acts via GPCR (ß-Adrenergic receptor )
2. RTK (receptor protein-tyrosine kinases)
responses:
Insulin (Endocrine Hormone)
Released from pancreas in response to high glucose
Stimulates glucose uptake and storage as glycogen
* Acts via receptor protein-tyrosine kinases (RTKs) –
we’ll cover this in the upcoming lectures
*Endocrine hormones are signaling molecules that regulate the physiology and behavior of
multicellular organisms.
G Protein-Coupled Receptors
Regulation of Blood Glucose

The response by a liver cell to glucagon or
epinephrine.

CREB: cAMP response
element binding protein
G Protein-Coupled Receptors
Regulation of Blood Glucose

The response by a liver cell to glucagon or
epinephrine.

CREB: cAMP response
element binding protein
G Protein-Coupled Receptors
Regulation of Blood Glucose

The response by a liver cell to glucagon or
Liver
epinephrine.

CREB: cAMP response
element binding protein
G Protein-Coupled Receptors
Regulation of Blood Glucose

The response by a liver cell to glucagon or
epinephrine.

CREB: cAMP response
element binding protein
G Protein-Coupled
Receptors
Regulation of Blood Glucose

2. RTK (receptor protein-tyrosine kinases)
responses:
Insulin
Released from pancreas in response to high glucose
Stimulates glucose uptake and storage as glycogen
* Acts via receptor protein-tyrosine kinases (RTKs) – we’ll cover
this in the upcoming lectures

This will be covered later…. To be continued in later
lectures
G Protein-Coupled Receptors
Human disease

Bacterial Toxins:
G proteins are so vital to normal physiology → that they are ideal targets for
pathogens
Gs→ Target of cholera toxin from the bacteria Vibrio cholerae
Modifies Gs subunit such that it cannot exert GTPase activity
prolonged Adenylyl Cyclase activation → excessive cAMP production
high levels of cAMP causes a massive loss of salts/H 20 from intestinal epithelia
profuse watery diarrhea, dehydration
The diarrhea induced by cholera toxin benefits V. cholerae by enhancing transmission of the bacteria (ie
contaminating water sources or the environment so it can find new hosts)

Diarrhea in
cholera results
from stimulation
of cAMP-
mediated
intestinal
Cl− secretion by
cholera toxin
G Protein-Coupled Receptors
Human disease
G Protein-Coupled Receptors
Human disease

Case Study:
8 Year old female
brought to ER for fractured bone
history of several bone fractures
on X-ray evidence of fibrous dysplasia
Normal bone tissue replaced by fibrous bone
tissue
onset of puberty at 7 (precocious
puberty)
breast development
menstruation at 8
developed several irregular, large
patches of dark pigmentation on skin
throughout childhood
G Protein-Coupled Receptors
Human disease

McCune-Albright Syndrome:
Abnormalities in GNAS1 gene (Chr 20)
GNAS1 encodes Gαs
Compromised GTPase activity
constitutive activation of cAMP driven pathways in the
absence of hormone stimulation
Resulting pathophysiology:
1. Fibrous dysplasia
2. Endocrine hyper-function
Precocious puberty (despite low circulating levels of hormones),
hyperthryoidism, gigantism
3. Cutaneous hyperpigmentation
 G Protein-Coupled Receptors
Human disease

McCune-Albright Syndrome:
Signalling molecules that rely on GPCRs:
MSH - melanocyte-stimulating hormones
LH – luteinizing hormone
GNRH - Gonadotropin-releasing hormone
TSH – thyroid stimulating hormone

Activating mutation of Gαs GTP
Inappropriate signalling Hydrolysis
Results in abnormally high amounts of:
Melanin - pigmentation
Estrogen (LH increases production of estrogen by ovary) – puberty
Growth Hormone - gigantism
Thyroid hormones – abnormal bone turnover and hypothyroidism
Next Lecture
Signal Transduction – IP3, DAG and PKC (Ch. 15)