HSS2305A - 2024 - Lecture 16 PDF

Summary

Lecture notes on signal transduction, focusing on G protein-coupled receptors and their roles in cellular processes. Includes diagrams and mentions of related diseases.

Full Transcript

HSS2305: Molecular
Mechanisms of Disease

Lecture 16 – Signal Transduction: IP3, DAG and PKC
Section A00
Spring 2022
Prof. Keir Menzies
Today’s Outline
Announcements
Signal Transduction: IP3, DAG
and PKC
Cell Signalling
Overview
Cell Signalling
signal transduction

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
G Protein-Coupled
Receptors

https://www.youtube.com/watch?v=jmYn1jJZ9BE
G Protein-Coupled
Receptors
G Protein-Coupled
Receptors
Effectors
2nd
Effector messenger

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

Gq → + PLCβ →  IP3 + DAG
(PLC:phospholipase C)

G12/13 → + small G proteins
* excessive cell proliferation and
malignancies

https://www.youtube.com/watch?v=3
qR9B2JCT_s
Watch until 14min mark for an
overview of Gs, Gi and Gq
 G Protein-Coupled Receptors
Effectors and 2nd messengers - cAMP

Protein
Kinase A
G Protein-Coupled
Receptors
Effectors and 2nd messengers - cAMP
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
Effectors and 2nd messengers - cAMP

CREB = cAMP response
element-binding protein
Transcription factor
Binds to CRE – response element
(TGACGTCA)

Fraction of PKA translocate to
nucleus→ can phosphorylate
CREB → p-CREB

Increase transcription of cAMP
sensitive genes
i.e. gluconeogenesis
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
Effectors and 2nd messengers - cAMP

The response by a liver cell to glucagon or
epinephrine.

CREB: cAMP response
element binding protein
G Protein-Coupled
Receptors
Light triggered cell signalling
 G Protein-Coupled Receptors
Light triggered cell signalling

Plasma
membrane
of Rods
G Protein-Coupled Receptors
Effectors and 2nd messengers - cGMP

Gαt (‘transducin’)
Receptor:
– Rhodopsin (light-sensitive receptor protein found in the rod cells of the retina )

Effector enzyme = cGMP phosphodiesterase
(PDE)
Second messengers:
– Reduction of cGMP
 G Protein-Coupled Receptors
Effectors and 2nd messengers - cGMP
During the dark cGMP-dependent
Na+ and Ca2+ ion channels are
open
Then when the lights come on:
photon light activates GPCR
“rhodopsin”
Activates G-protein –”transducin”
Gαt triggers activation of cGMP
phosphodiesterase
(effector/enzyme)
cGMP→ GMP
 cytosolic cGMP closes cGMP-
dependent Na+ and Ca2+ ion https://youtu.be/JIPE3in2EcQ
channels
Membrane hyperpolarization https://youtu.be/AuLR0kzfwBU
(membrane becomes more Optional video to watch
negative) – signal to visual center
G Protein-Coupled Receptors
Effectors and 2nd messengers - cGMP

Bradyopsia (slow vision) → mutations in genes encoding RGS9
RGS9 normally inactivates transducin during light termination
allowing cGMP to increase
The result is slower  cGMP → Na+ and Ca2+ channels open
slower → slower membrane depolarization (more positive)

Patients have trouble
adjusting to changing light
conditions → temporary
blindness when first exposed
to bright light
G Protein-Coupled Receptors
Effectors and 2nd messengers - cGMP

AC is an effector for Gs
PDE is an effector for Gt
G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG
2nd
Effector messenger

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

Gq → + PLCβ →  IP3 + DAG

G12/13 → + small G proteins
* excessive cell proliferation and
malignancies
G Protein-Coupled
Receptors
2nd messengers derived from cell membrane

Phospholipids in cell membrane can be targeted for modification and or
cleavage by a variety of enzymes
Phospholipid kinases - phosphorylation
Phospholipid phosphatases – dephosphorylation
Phospholipases - cleavage
G Protein-Coupled
Receptors
2nd messengers derived from cell membrane
inositol C5
C4
P

2

Phosphatidylinositol Phosphatidylinositol
(PI) 4,5-di-phosphate
[PIP2]
G Protein-Coupled
Receptors
2nd messengers derived from cell membrane

Phospholipids in cell membrane can be targeted for cleavage by
phospholipase enzymes → cleave at specific sites
By-products of cleavage can act as second messengers within the cytoplasm
 G Protein-Coupled
Receptors
2nd messengers derived from cell membrane

Phosphatidylinositol (PI) represents the whole molecule below:

PI (Phosphatidylinositol)
Inositol phosphate
(IP)
Diacylglycerol
(DAG)
 G Protein-Coupled
Receptors
2nd messengers derived from cell membrane
PIP2
Inositol phosphate
3 (IP3)
Diacylglycerol
**IP3 → 3 P
phosphate P (DAG)
groups
attached to P
ring

Phospholipase C (PLC): cleaves phosphatidylinositol di-phosphate (PIP2) → IP3
and DAG
IP3 and DAG can act as second messengers within the cytoplasm
G Protein-Coupled Receptors
2nd messengers – IP3 & DAG

Gαq → Effector enzyme = phospholipase C (PLC)
which cleaves PIP2
Second messengers:
– inositol trisphosphate (IP3)
– diacylglycerol (DAG)

Receptors:
– Alpha 1 adrenergic receptors (P.S. Alpha 2 adrenergic receptors are the
type from the last lecture that induce Gi to reduce cAMP and therefore
smooth muscle contraction)
– Serotonin receptor (5-HT receptor type 2)
– Muscarinic receptors 1, 3, 5
– Histamine receptor type 1
– Calcitonin receptor
G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG

Messenger-2

Effector

Messenger-1

The generation of second messengers as a result of
ligand-induced breakdown of PhosphoInositides
(PIP2) in the lipid bilayer

https://youtu.be/lsYBeFqEwzk
https://youtu.be/larIxw_9ePU (@ 20 sec)
 G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG

2

Step 1 and 2 → phosphate groups are added to PI by phospholipid kinases to
generate PIP2
 G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG

Step 3 → ligand binds to receptor and activates G protein
Replacement of GDP→ GTP on Gαq
Ligands = vasopressin; thyroid-stimulating hormone (TSH); angiotensin;
neurotransmitters like GABA
Step 4 → Gαq activates phospholipase C (PLCβ)
 G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG

Step 5 → activated PLCβ cleaves PIP2 into IP3 (into cytosol) and DAG (remains
in cell membrane)
Step 6 → DAG recruits protein kinase C (PKC) to membrane and activates the
enzyme
Cellular growth and differentiation
Cellular metabolism
Cell death
 G Protein-Coupled
Receptors
2nd messengers – IP3 & DAG

Step 7 and 8 → IP3 diffuses into cytosol and
binds to receptor of Ca2+ channel on smooth
endoplasmic reticulum (SER)
Step 9 → Calcium is released into cytosol to
help recruit PKC to DAG and can also have
many other effects in the cell i.e. :
Contraction
Release of histamine
G Protein-Coupled
Receptors
PKC signalling

DAG → PKC signalling
 G Protein-Coupled
Receptors
PKC signalling

PKC = Family of serine/threonine kinases

Α,β,γ
Conventional: Require DAG + Ca2+ for activation

*
δ, ε
Novel: Require DAG but not Ca2+ activation

Atypical: Require neither DAG or Ca2+
PS: conventional or classic PKC isozymes (cPKCs; α, βI, βII, and γ), novel or nonclassic PKC isozymes (nPKCs; δ, ε, η, and θ),
and atypical PKC isozymes (aPKCs; ζ, ι, and λ).
 G Protein-Coupled
Receptors
PKC signalling

Abnormal PKC signalling in several diseases
CVD, stroke, diabetes, asthma, autoimmunity/inflammation, neurological diseases

https://youtu.be/EBRszGDkHxo

Nat Commun. 2014 Dec 8;5:5685. doi: 10.1038/ncomms6685.
G Protein-Coupled
Receptors
Ca2+ signalling

IP3 → Ca2+ signalling
G Protein-Coupled
Receptors
Ca2+ Signalling

Ca2+ probably the most widely used intracellular
messengers

Increase in intracellular Ca2+ triggers ->
muscle contraction
exocytosis, e.g., release of neurotransmitters at synapses
secretion of hormones like insulin
activation of T cells and B cells
adhesion of cells to the extracellular matrix
apoptosis
events mediated by Protein Kinase C (PKC)
 G Protein-Coupled
Receptors
Ca2+ Signalling

Cytosolic concentration of Ca2+ is maintained at an extremely
low level (about 0.1 mM)
Critical for signaling → optimize ‘signal:noise’ ratio

Two major mechanisms for
maintaining low calcium
levels:
1. active transport of Ca2+
from cytosol out of the cell

2. Sequestration of Ca2+ in
endoplasmic reticulum
 G Protein-Coupled
Receptors
Ca2+ Signalling

Cytosolic concentration of Ca2+ is maintained at an extremely
low level (about 0.1 mM)
Critical for signaling → optimize ‘signal:noise’ ratio

Increases can occur when:
Ca2+ enters the cell via
voltage-activated Ca2+
channels → depends on the
membrane potential
 G Protein-Coupled
Receptors
Ca2+ Signalling

Cytosolic concentration of Ca2+ is maintained at an extremely
low level (about 0.1 mM)
Critical for signaling → optimize ‘signal:noise’ ratio
Calcium Induced Calcium Release
(CICR)
Ryanodine calcium channels and
IP3 receptors on the SER
respond to calcium to release
more calcium (up to 1mM).
 G Protein-Coupled
Receptors
Ca2+ Signalling
Cytosolic concentration of Ca2+ is maintained at an extremely
low level (about 0.1 mM)
Critical for signaling → optimize ‘signal:noise’ ratio
IP3Rs (IP3 receptors) and ryanodine receptors:
Activation Mechanism:
RyRs: Activated by direct binding of Ca²⁺
(CICR).
IP₃Rs: Activated by IP₃ binding; Ca²⁺
modulates sensitivity.
Function:
RyRs: Facilitate rapid and substantial Ca²⁺
release, essential for processes like muscle
contraction.
IP₃Rs: Mediate Ca²⁺ release in response to
extracellular signals, influencing various
cellular functions.
G Protein-Coupled
Receptors
Ca2+ Signalling

Calcium signaling and
fertilization

40-500 million sperm in
ejaculate
200-300 make it to oviduct
20-30 make it to oocyte

What prevents more than 1
sperm from fertilizing an egg?
Polyspermy → lethal
Sperm binding receptor
activates GPCR → IP3-
mediated calcium
release (see below)–
leads to a wave of
calcium that is likely
dependent on CICR

Cortical Reaction
fusion of egg and sperm
induces a wave of Ca2+ influx
This wave of calcium
stimulates calcium granules to
release their contents outside
the egg → prevent polyspermy
by inactivating sperm-binding
receptors
G Protein-Coupled
Receptors
Ca2+ Signalling

Calcium signaling and fertilization
Next Lecture
Signal Transduction – RTKs and MAPK (Ch. 15)