Cell Signaling PDF

Summary

This document provides an overview of cell signaling, including the basic components of cell signaling, various signaling pathways, and different types of signaling. It details the roles of ligands, receptors, and intracellular signaling molecules in the process of cell communication.

Full Transcript

Cell Signaling
 Contact
Karron J. James, Ph.D.
Professor, Dept. Biochemistry, Cell Biology &
Genetics
Office: GB6, Block B
Email: [email protected]
Phone 484-8900 ext 1041
Office hours (in-person or on MS Teams ): Mon-
Fri, by appointment
– Teams message @[email protected]
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 Readings
Alberts et al., Molecular Biology of the Cell, 4ed.
Ch 15:
Extracellular Signal Molecules Bind to Specific Receptors
Extracellular Signal Molecules Can Act Over Either Short or Long Distances (1st, 2nd, 3rd, 4th
paragraphs)
Autocrine Signalling Can Coordinate Decisions by Groups of Identical Cells (1st paragraph)
Different Cells Can Respond Differently to the Same Extracellular Signal Molecule
Nuclear Receptors Are Ligand-activated Gene Regulatory Proteins
The Three Largest Classes of Cell-Surface Receptor Proteins Are Ion-Channel-linked, G-Protein-linked,
and Enzyme-linked Receptors
Most Activated Cell-Surface Receptors Relay Signals Via Small Molecules and a Network of Intracellular
Signalling Proteins (1st, 2nd, 3rd paragraphs)
Cells Can Respond Abruptly to a Gradually Increasing Concentration of an Extracellular Signal (Figure
15-24)
Cells Can Adjust Their Sensitivity to a Signal
Trimeric G Proteins Disassemble to Relay Signals from G-Protein-linked Receptors (1st, 2nd paragraphs)
Some G Proteins Signal By Regulating the Production of Cyclic AMP (1st, 2nd paragraphs)
Cyclic-AMP-dependent Protein Kinase (PKA) Mediates Most of the Effects of Cyclic AMP (1st, 2nd
paragraphs)
Some G Proteins Activate the Inositol Phospholipid Signalling Pathway by Activating Phospholipase C-β
Ca2+ Functions as a Ubiquitous Intracellular Messenger (1st paragraph)
Phosphorylated Tyrosines Serve as Docking Sites For Proteins With SH2 Domains (1st, 2nd paragraphs)
PI 3-Kinase Produces Inositol Phospholipid Docking Sites in the Plasma Membrane (1st, 2nd
paragraphs)
Signal Proteins of the TGF-β Superfamily Act Through Receptor Serine/Threonine Kinases and Smads
(1st, 2nd paragraphs)
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 Signaling and basic requirements for
signal transduction
Transduction of message(s)
from one cell to another cell
resulting in altered behaviour
of target cell

Lodish, et al. ‘Molecular Cell Biology’. 6ed.
Basic requirements:
– Signaling cell
– Extracellular ligand (signaling
molecule)
– Target (responding) cell
– Receptor (plasma membrane or
intracellular)
Signal transduction

Fig 15-1. Alberts.
 Types of Signaling
Signaling by secreted molecules
1. Endocrine: signaling molecules
travel through bloodstream and
interact with distant target cells

2. Paracrine: signaling molecules
act on nearby cells

i. Juxtacrine (contact-dependent):
signaling molecules stay attached
to synthesizing cell while
interacting with target cell
ii. Synaptic: action potentials used
to transmit signals mediated by
neurotransmitters

3. Autocrine: synthesizing cell is
also target cell Fig 15-4. Alberts.

All signaling molecules only active on target cells that express an appropriate
receptor
 See Figure
legend in
textbook
Fig 15-8. Alberts.
 Individual signaling molecule can have
different effects on different target cells

Fig 15-9. Alberts.
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 Hormones
“Chemical messengers”
Hormones released mainly from
specialized cells in gonads,
thyroid, pituitary, pancreas,…
Regulate physiologic processes,
eg. reproduction, growth,
metabolism
Classified as lipophilic or
hydrophilic
 Nomenclature—FYI
Lipophilic hormones
– These are generally alcohols or ketones so many of
their names end in –ol (eg. cortisol) or –one (eg.
progesterone)

Hydrophilic hormones—include amino acid and
peptide hormones
– Many of their names end in –ine or –in, eg. insulin
– Note that there are exceptions: thyroxine (a thyroid
hormone), is lipophilic

Note: this is just for your information and is not covered by a learning objective here.
 Lipophilic Hormones or
Signaling Molecules
Include:
1. Steroid hormones

es_hormones_homeostasis/index.htm
http://www.tokresource.org/tok_classes/biobiobio/biomenu/nerv
2. Thyroid hormones
3. Retinoic acid

Small, cross plasma membrane,
and interact with receptor inside
cell

Can alter gene expression
 1. Steroid hormones
Derived from cholesterol

Synthesized and quickly
released → bloodstream,
bound by carrier proteins →
hormone, only, taken up by
target cell
Eg. Adrenal hormones (eg. cortisol), sex
hormones (testosterone, estradiol,
progesterone)
What type of carrier protein?

Vitamin D3—synthesized in skin
 2. Thyroid hormones

daltonsurgical.com
Precursor = Thyroglobulin (Tg)
large glycoprotein

Thyroid hormones (T3, T4) made
by and secreted from thyroid
gland

Bound by carrier proteins for
transport through circulation
 3. Retinoic acid

Retinoic acid—synthesized from retinol, not
cholesterol

Retinol transported into cytosol and is
converted to retinoic acid
– Tc factor, important for embryonic development
 Lipophilic hormones bind
nuclear receptor superfamily

Located primarily in
cytosol*, nucleus (T3, RA)

Ligand binding → binding
of DNA regulatory
sequence by receptor →
activation of
transcription studyblue.com
Pause for
Retrieval
Practice
https://www.bookw
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horm
 Hydrophilic Hormones
Amino acids, peptides, proteins

Synthesized and secreted by cells of
hypothalamus, pituitary, pancreas, …

Inactive precursor stored in
secretory vesicles, released through
exocytosis

Bind plasma membrane receptors
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 Three major classes of
cell surface receptors
R1.

R2.

R3.

Fig 15-15. Alberts.
 R1. Ligand-gated Ion Channel
Ionotropic receptor

Membrane protein
complex that includes
ligand binding sites
forms a pore

https://www.nature.com/scitable/topicpage/ion-channel-14047658
 Ligand-gated ion channel

The neurotransmitter
is the ligand.

Examples:
Nicotinic
acetylcholine
receptor
GABA receptor

Fig. 2. Diagram for ligand-gated ion channels Siegelbaum et al (2000).
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 R2. G-protein-coupled Receptor

A.k.a. seven-transmembrane
receptor

Gs, Gi, Gq proteins
– αβγ subunits

Relies on second messengers
to relay intracellular signals https://www.nature.com/scitable/topicpage/gpcr-14047471
 G-proteins
a. Gs
Activates adenylyl cyclase

b. Gi
Inhibits adenylyl cyclase

c. Gq
Activates phospholipase C
 R2a. GPCR—Gs signalling

What is the role of
phosphodiesterase? PKA

From: 1 Cell and Membrane Physiology
Lippincott® Illustrated Reviews: Physiology, 2e, 2019
R2a. GPCR—Gs signalling
Pause for
Retrieval
Practice
https://www.bookw
idgets.com/play/FP
B5jK2C-
iQAEtO3EOgAAA/TE
83ET8/gs
R2b. GPCR—Gi signalling

X
Adapted from: Wettschureck, N. and Offermanns, S. Mammalian G
Proteins and Their Cell Type Specific Functions. Physiology Reviews, 85, 4,
2005, 1159-1204.
R2c. GPCR—Gq signalling

From: 1 Cell and Membrane Physiology
Lippincott® Illustrated Reviews: Physiology, 2e, 2019
R2c. GPCR—Gq signalling
Pause for
Retrieval
Practice
https://www.bookwidgets.co
m/play/OQu8uXIZ-iQAFC5o-
2gAAA/BE87XBK/gq-
signaling?teacher_id=48370122
12285440
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
R3. Some cell surface receptors have enzymatic
activity—Enzyme-coupled Receptors

A. Receptor tyrosine kinase

B. Receptor serine-threonine kinase
 R3. Enzyme-linked Receptors

A. Receptor tyrosine kinase

B. Class I cytokine receptor

C. Receptor serine-threonine kinase
R3A. Receptor Tyrosine Kinase–
Activation Overview

Change in protein activity or
change in gene expression

See Fig 15-52. Alberts.
 RTK Signaling can occur via 3
pathways

Signal transduction pathways:
1. PI3-K
2. Ras/MAPK
3. PLC

Signaling molecules include insulin, some growth
factors

Some signaling molecules bind >1 member of the
RTK family
 A 44-year-old female performs a finger-stick
test to check her blood glucose 2 hours after
eating a meal and sees a reading of 140 mg/dL
(normal: 70-100 mg.dL). Three hours later, she
does another test and the result is 99mg/dL.
 A1. PI3-K Pathway
Ligand binding→ receptor
dimerization→ RTKs activate
kinase activity in each other
Activated RTKs recruit
intracellular signal transducers
near membrane. Eg. IRS1
– Phosphorylate Y’s→formation of
binding sites for substrates w/ SH2
domains, eg. PI3K
Activated PI3-K: PIP2→ PIP3
PIP3→→ phosphorylates,
activates Akt (PKB) →
phosphorylation cascade
downstream→→→
→GLUT4 translocates to https://employees.csbsju.edu/hjakubowski/classes/ch331/signaltrans/ST_9
C9_Insulin_Sig_PI3K_Ak.html
membrane
 A2. RAS/MAPK Pathway
Examples: insulin, EGF
Activated RTKs recruit
intracellular signal transducers Insulin
near membrane.
– Phosphorylate Y’s→formation of (Insulin receptor)

binding sites for substrates w/ SH2
domains
Ras converted of from inactive
to active (GTP-bound) form
Ras-GTP interacts with and
stimulates downstream
effectors, leading to activation
of the MAP kinases ERK1 and 2
ERK enters nucleus,
phosphorylates and activates Tc
factors for growth, proliferation;
affects differentiation of genes
 A3. PLC Pathway
Example: EGF
Activated RTKs recruit
intracellular signal
transducers near membrane
– Bind and phosphorylate
substrates w/ SH2 domains, eg.
PLCγ→ stimulation of
phospholipase activity

PLC: PIP2→ IP3, DAG

IP3→ Ca2+ release from ER
http://publication.letstalkacademy.com/ip3-dag-pathway-of-receptor-tyrosine-
Ca2+, DAG activate kinase-in-cell-signalling

PKC→→→ activate Tc of
genes involved in
proliferation, survival, etc.
Pause for
Retrieval
Practice
https://www.bookw
idgets.com/play/zBr
dMYRn-
iQAFUTH82gAAA/U
E9CEUU
 R3B. Class I Cytokine Receptors

No intrinsic TK activity

Associate with ‘non-
receptor tyrosine kinase’—
Jak (in cytosol)

Jak/STAT pathway

STAT regulates transcription Fig 1-6
 R3B. Receptor Serine Threonine Kinases

Cell surface receptors that
are activated to
phosphorylate S or T on
substrate proteins
Bind TGF-β family of
signalling molecules
– TGF-β involved in
proliferation of various cell
types, cell differentiation
Activated receptor complex
binds Smad proteins— Fig. 15-65. Alberts.
transcription regulators
Smads enter nucleus to
regulate transcription of
target genes
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
 Positive feedback amplifies a
response
Output stimulates its continued production
May be stopped by a definitive event
Example?

Fig 15-17. Alberts.
Describe the occurrence of
positive feedback in generation of
an action potential
See Fig 15-24.
 Negative feedback can terminate
signaling event
Output inhibits its continued production or activation
Limits cellular response to maintain stability
Example?

Fig 15-17. Alberts. 6ed.
Feed-forward

Fig 7-40. Alberts. 6ed.
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.
Ligand binding can serve to activate the
receptor
 Response to ligand-binding is
regulated
Receptors may be up-regulated
– May be in response to activation of receptor
– May be in response to reduced level of ligand
– Increase transcription, translation
– Decrease degradation of receptors

Receptors may be down-regulated
– Reduce transcription, translation
– Increase degradation of receptors
 “Opioids are the most potent drugs used for
pain relief. However, their therapeutic potential
could be limited as a protracted use will lead to
tolerance to analgesic effects requiring
escalating doses that is associated with side
effects such as respiratory depression.”
– Allouche, S., Noble, F., and Marie, N. (2014). Opioid receptor
desensitization: mechanisms and its link to tolerance. Frontiers in
Pharmacology, 5(280), 1-20. doi: 10.3389/fphar.2014.00280.
 Cell can become de-sensitized to
ligand
Desensitization (adaptation) can
occur after prolonged exposure
of receptor to ligand

Reduced response to future
stimulation by same ligand or
same concentration of ligand
– Over time, no response to same
ligand concentration
– Need greater ligand concentration
to produce response
Fig 15-48. Alberts.
Can occur by receptor
endocytosis, receptor down-
regulation, receptor inactivation
(eg. by phosphorylation)
Can lead to cessation of signaling
Regulation mechanisms:

See Fig 15-25. Alberts.
A bit more about cell signaling…

A ligand can activate more than one signaling
pathway

Note that there are other signaling routes that do
not involve GPCR, receptor enzymes, ion channels

– Many target gene expression

– Regulate variety of cell functions
Use a medical dictionary to define
these two terms:

Agonist

Antagonist
 Goal MCB.12. Understand the general principles
of cell signaling and its clinical significance
Learning Objectives
Given a clinical or research vignette, scenario, table, graph, or diagram,
students should be able to:
MCB.12.1. Distinguish the basic components of a reaction: releasing cell,
signaling molecule (ligand), target cell, receptor.
MCB.12.2. Classify signaling molecules as lipophilic and peptide ligands.
MCB.12.3. Distinguish membrane-bound and intracellular receptors based
on their location, structure, and function.
MCB.12.4. Contrast the pathways involved in use of G protein-coupled
receptors, enzyme-linked receptors, and ligand-gated ion channels.
MCB.12.5. Recognize negative and positive feedback and their downstream
effects.
MCB.12.6. Recognize activation, deactivation, up-regulation, down-
regulation, sensitization, and de-sensitization of receptors.