Cell Signaling Lecture Notes PDF

Summary

These lecture notes provide an overview of cell signaling, covering various aspects of the topic, including signaling molecules, receptors' modes of action, and different signaling pathways. They also discuss specific examples, such as hormones and growth factors.

Full Transcript

16
Cell Signaling
16 Cell Signaling

Signaling Molecules and Their Receptors
G Proteins and Cyclic AMP Signaling
Tyrosine Kinases and Signaling by MAP
Kinase, PI 3-Kinase, and Phospholipase
C/Calcium Pathways
Receptors Coupled to Transcription Factors
Signaling Dynamics and Networks
Introduction

All cells receive and respond to signals
from their environment.
Bacteria and unicellular eukaryotes
respond to environmental signals and to
signaling molecules secreted by other
cells for mating and other
communication.
Introduction

In multicellular organisms, cell–cell
communication is highly sophisticated.
Each cell must be carefully regulated to
meet the needs of the whole organism.
A variety of signaling molecules are
secreted or expressed on the surface of
one cell, and bind to receptors
expressed by other cells.
Introduction

Binding of signal molecules to receptors
initiates a series of reactions that
regulate all aspects of cell behavior.
Many cancers arise from problems in
signaling pathways that control normal
cell proliferation.
Much of our understanding of cell
signaling has come from the study of
cancer cells.
Signaling Molecules and Their Receptors

Signaling molecules range in complexity
from simple gases to proteins.
Some carry signals over long distances;
others act locally.
They also differ in modes of action:
Some cross the plasma membrane and
bind to intracellular receptors; others
bind to receptors on the cell surface.
Signaling Molecules and Their Receptors

Modes of cell signaling include:
Direct cell–cell signaling—direct
interaction of a cell with its neighbor,
(e.g., via integrins and cadherins).
Signaling by secreted molecules—
three categories are based on the
distance over which signals are
transmitted.
Figure 16.1 Modes of cell–cell signaling (Part 1)
Signaling Molecules and Their Receptors

Endocrine signaling
Signaling molecules (hormones) are
secreted by specialized endocrine cells
and carried through the circulation to
target cells at distant body sites.
Example: estrogen
Figure 16.1 Modes of cell–cell signaling (Part 2)
Signaling Molecules and Their Receptors

Paracrine signaling
Molecules released by one cell act on
neighboring target cells.
Example: neurotransmitters
Figure 16.1 Modes of cell–cell signaling (Part 3)
Signaling Molecules and Their Receptors

Autocrine signaling
Cells respond to signaling molecules
that they themselves produce.
Example: T lymphocytes respond to
antigens by making a growth factor that
drives their own proliferation, thereby
amplifying the immune response.
Figure 16.1 Modes of cell–cell signaling (Part 4)
Signaling Molecules and Their Receptors

Abnormal autocrine signaling often
contributes to cancer.
A cancer cell produces a growth factor to
which it also responds, thereby
continuously driving its own
unregulated proliferation.
Signaling Molecules and Their Receptors

Receptors may be located on the cell
surface or inside the cell.
Intracellular receptors respond to small
hydrophobic molecules that can diffuse
across the plasma membrane.
Examples: Steroid hormones, thyroid
hormone, vitamin D3, and retinoic acid.
Signaling Molecules and Their Receptors

Steroid hormones are synthesized from
cholesterol:
Testosterone, estrogen, and
progesterone are the sex steroids,
produced by the gonads.
Figure 16.2 Structure of steroid hormones, thyroid hormone, vitamin D 3, and retinoic acid
Signaling Molecules and Their Receptors

Corticosteroids from the adrenal gland:
Glucocorticoids—stimulate
production of glucose.
Mineralocorticoids—act on the
kidneys to regulate salt and water
balance.
Signaling Molecules and Their Receptors

Ecdysone is an insect hormone that
triggers metamorphosis of larvae to
adults.
Brassinosteroids are plant steroid
hormones that control several
processes, including cell growth and
differentiation.
Signaling Molecules and Their Receptors

Thyroid hormone: synthesized from
tyrosine in the thyroid gland; important
in development and metabolism.
Vitamin D3 regulates Ca2+ metabolism
and bone growth.
Retinoic acid and retinoids:
synthesized from vitamin A; important
in vertebrate development.
Signaling Molecules and Their Receptors

Receptors for these molecules are
members of the nuclear receptor
superfamily.
They are transcription factors that have
domains for ligand binding, DNA binding,
and transcriptional activation.
The steroid hormones and related
molecules directly regulate gene
expression.
Signaling Molecules and Their Receptors

Ligand binding has different effects on
different receptors.
Some nuclear receptors are inactive in the
absence of hormone:
Glucocorticoid receptor is bound to
Hsp90 chaperones in the absence of
hormone.
Glucocorticoid binding displaces Hsp90
and leads to binding of regulatory DNA
sequences.
Figure 16.3 Glucocorticoid action
Signaling Molecules and Their Receptors

Hormone binding can alter the activity of
a receptor:
In the absence of hormone, thyroid
hormone receptor is associated with
a corepressor complex and
represses transcription of target
genes.
Hormone binding results in activation
of transcription.
Figure 16.4 Gene regulation by the thyroid hormone receptor
Signaling Molecules and Their Receptors

Lecture Recap:

Cell Signaling and its Importance
Modes of Signaling
Types of Signaling Molecules –
Hydrophilic and Hydrophobic
Hydrophobic Molecules– Steroid
hormones and related molecules
directly regulate gene expression via
signaling pathway
Signaling Molecules and Their Receptors

Lecture Outline:
Hydrophobic signaling molecules and
mechanism of action of Nitric oxide
(NO) and Carbon monoxide
Hydrophilic signaling molecules
Neurotransmitters
Peptide hormones
Neuropeptides
Polypeptide growth factors
G protein-coupled receptors and cAMP
signaling
Signaling Molecules and Their Receptors

Nitric oxide (NO) is a gas, It can cross
the plasma membrane and alter the
activity of enzymes.
Nitric oxide (NO) is a paracrine signaling
molecule in the nervous, immune, and
circulatory systems.
Its action is local, because it is extremely
unstable, with a half-life of only a few
seconds.
Figure 16.5 Synthesis of nitric oxide
Figure 16.5 Synthesis of nitric oxide
Signaling Molecules and Their Receptors

The main target of NO is guanylyl cyclase.
NO binding stimulates synthesis of cyclic
GMP (a second messenger).
A second messenger is a molecule that
relays a signal from a receptor to a target
inside the cell.
Signaling Molecules and Their Receptors

NO can signal dilation of blood vessels.
NO diffuses to smooth muscle cells and
stimulates cGMP production. cGMP
induces muscle cell relaxation and blood
vessel dilation.
Signaling Molecules and Their Receptors

Carbon monoxide (CO), also functions
as a signaling molecule in the nervous
system.
It is related to NO and acts similarly as a
neurotransmitter and mediator of blood
vessel dilation.
Figure 16.6 Structure of representative neurotransmitters
Signaling Molecules and Their Receptors

Neurotransmitters carry signals
between neurons or from neurons to
other cells.
They are released when an action
potential arrives at the end of a neuron.
The neurotransmitters then diffuse
across the synaptic cleft and bind to
receptors on the target cell surface.
Signaling Molecules and Their Receptors

Because neurotransmitters are
hydrophilic; they can’t cross plasma
membranes and must bind to cell
surface receptors.
Many neurotransmitter receptors are
ligand-gated ion channels.
Neurotransmitter binding opens the
channels.
Signaling Molecules and Their Receptors

Neurotransmitter receptors are:
Ligand –gated ion channels--binding
opens the channels.
Enzyme-coupled receptors – binding
of neurotransmitters to extracellular
domain activates cytosolic domains
Coupled to G proteins—a major group
of signaling molecules that link cell
surface receptors to intracellular
responses.
Signaling Molecules and Their Receptors

Peptide signaling molecules are peptide
hormones, neuropeptides, and growth
factors. These molecules can’t cross
the plasma membranes of target cells,
so they act by binding to cell surface
receptors.
Abnormalities in growth factor signaling
are the basis for many diseases,
including many cancers.
Signaling Molecules and Their Receptors

Peptide signaling molecules include
peptide hormones, neuropeptides, and
polypeptide growth factors.
Peptide hormones include insulin,
glucagon, and pituitary gland hormones
(e.g., growth hormone, follicle-
stimulating hormone, prolactin).
Signaling Molecules and Their Receptors

Neuropeptides are secreted by some
neurons.
Enkephalins and endorphins act as
neurotransmitters and as
neurohormones—natural analgesics
that decrease pain responses; they bind
to the same receptors on brain cells as
morphine does.
Signaling Molecules and Their Receptors

Nerve growth factor (NGF) is a
member of the neurotrophin family
that regulates development and
survival of neurons.
Epidermal growth factor (EGF)
stimulates cell proliferation. It is the
prototype for the study of growth
factors.
Figure 16.7 Structure of epidermal growth factor (EGF)
Signaling Molecules and Their Receptors

Platelet-derived growth factor (PDGF)
is stored in blood platelets and released
during blood clotting at the site of a
wound.
It stimulates proliferation of fibroblasts,
contributing to regrowth of the
damaged tissue.
Signaling Molecules and Their Receptors

Cytokines regulate development and
differentiation of blood cells and
activities of lymphocytes during the
immune response.
Membrane-anchored growth factors
remain with the plasma membrane and
function as signaling molecules in
direct cell–cell interactions.
Table 16.1 Representative Peptide Hormones, Neuropeptides, and Polypeptide Growth Factors
Signaling Molecules and Their Receptors

Plant hormones:
Gibberellins—stem elongation
Auxins—cell elongation
Ethylene—fruit ripening
Cytokinins—cell division
Abscisic acid—onset of dormancy
Figure 16.9 Plant hormones
G Proteins and Cyclic AMP Signaling

Most ligands responsible for cell–cell
signaling bind to surface receptors on
target cells.
Intracellular signal transduction: The
surface receptors regulate intracellular
enzymes, which then transmit signals
from the receptor to a series of
additional intracellular targets.
G Proteins and Cyclic AMP Signaling

The targets of signaling pathways
frequently include transcription factors.
Ligand binding to a receptor initiates a
chain of intracellular reactions,
ultimately reaching the nucleus and
altering gene expression.
G Proteins and Cyclic AMP Signaling

G protein-coupled receptors are the
largest family of cell surface receptors.

Signals are transmitted via guanine
nucleotide-binding proteins (G proteins).
G Proteins and Cyclic AMP Signaling

G proteins have three subunits
designated α, β, and γ.
They are called heterotrimeric G
proteins to distinguish them from other
guanine nucleotide-binding proteins,
such as the Ras proteins.
The receptors have seven membrane-
spanning α helices.
Figure 16.11 Structure of a G protein-coupled receptor
Figure 16.12 Hormonal activation of adenylyl cyclase
G Proteins and Cyclic AMP Signaling

Binding of a ligand induces a
conformational change that allows the
cytosolic domain to activate a G protein
on the inner face of the plasma
membrane.
The activated G protein then dissociates
from the receptor and carries the signal
to an intracellular target.
G Proteins and Cyclic AMP Signaling

G proteins were discovered during
studies of cyclic AMP (cAMP), a
second messenger that mediates
responses to many hormones.
A G protein is an intermediary in
adenylyl cyclase activation, which
synthesizes cAMP.
G Proteins and Cyclic AMP Signaling

The α subunit binds guanine, which
regulates G protein activity.
In the inactive state, α is bound to GDP
in a complex with β and γ.
Homone binding to the receptor causes
exchange of GTP for GDP. The α and
βγ complex then dissociate from the
receptor and interact with their targets.
Figure 16.13 Regulation of G proteins
Signaling Molecules and Their Receptors

Lecture Recap:
Hydrophobic signaling molecules and
mechanism of action of Nitric oxide
(NO) and Carbon monoxide
Hydrophilic signaling molecules
Neurotransmitters
Peptide hormones
Neuropeptides
Polypeptide growth factors
G protein-coupled receptors
Figure 16.13 Regulation of G proteins
Signaling Molecules and Their Receptors

Lecture Recap:
G protein-coupled receptors- indirectly
linked to enzymes and ion channels
Example --G protein coupled receptors
indirectly activate adneylyl cyclase
G protein coupled receptors indirectly
regulate ion channels
Example: action of the neurotransmitter
acetylcholine on heart muscle.
Figure 16.12 Hormonal activation of adenylyl cyclase
G Proteins and Cyclic AMP Signaling

A large array of G proteins connect
receptors to distinct targets.
In addition to enzyme regulation, G
proteins can also regulate ion channels.
Example: action of the
neurotransmitter acetylcholine on
heart muscle.
G Proteins and Cyclic AMP Signaling

Heart muscle cells have acetylcholine
receptors that are G protein-coupled.
The α subunit of this G protein (Gi)
inhibits adenylyl cyclase.
The Gi βγ subunits open K+ channels in
the plasma membrane, which slows
heart muscle contraction.
Signaling Molecules and Their Receptors

Lecture Outline:
Formation of cAMP
Effects of cAMP
1. Activating protein kinase A
2. Regulation of gene expression
3. Direct regulation of ion channels
Signaling by receptor tyrosine kinases
and non- receptor tyrosine kinases
G Proteins and Cyclic AMP Signaling

The role of cAMP as a second
messenger was discovered in 1958 by
Sutherland in studies of epinephrine,
which signals the breakdown of
glycogen to glucose in muscle cells.
cAMP is formed from ATP by adenylyl
cyclase and degraded to AMP by
cAMP phosphodiesterase.
Figure 16.14 Synthesis and degradation of cAMP
G Proteins and Cyclic AMP Signaling

Effects of cAMP are mediated by cAMP-
dependent protein kinase, or protein
kinase A.
Inactive form has two regulatory and two
catalytic subunits. cAMP binds to the
regulatory subunits, which dissociate.
The free catalytic subunits can then
phosphorylate serine on target proteins.
Figure 16.15 Regulation of protein kinase A
G Proteins and Cyclic AMP Signaling

In glycogen metabolism, protein kinase A
phosphorylates two enzymes:
Phosphorylase kinase is activated,
and in turn activates glycogen
phosphorylase, which catalyzes
glycogen breakdown.
Glycogen synthase is inactivated, so
glycogen synthesis is blocked.
Figure 16.16 Regulation of glycogen metabolism by epinephrine

Example of
Signal
Transduction
and Signal
Amplification
G Proteins and Cyclic AMP Signaling

Signal amplification: Binding of a
hormone molecule leads to activation of
many intracellular target enzymes.
Example: Each molecule of
epinephrine activates one receptor.
Each receptor may activate up to
100 molecules of Gs.
G Proteins and Cyclic AMP Signaling

Gs then stimulates adenylyl cyclase,
which catalyzes synthesis of many
molecules of cAMP.
Each molecule of protein kinase A
phosphorylates many molecules of
phosphorylase kinase, which
phosphorylate many molecules of
glycogen phosphorylase.
G Proteins and Cyclic AMP Signaling

In many animal cells, increases in cAMP
activate transcription of genes that have a
regulatory sequence called cAMP
response element (CRE).
Figure 16.17 Cyclic AMP-inducible gene expression

cAMP
response
element
(CRE).

CREB (CRE-
binding
protein).
G Proteins and Cyclic AMP Signaling

In many animal cells, increases in cAMP
activate transcription of genes that have a
regulatory sequence called cAMP
response element (CRE).
The free catalytic subunit of protein kinase
A goes to the nucleus and phosphorylates
transcription factor CREB (CRE-binding
protein).
G Proteins and Cyclic AMP Signaling

Phosphorylation of CREB leads to
recruitment of coactivators and
expression of cAMP-inducible genes.
Regulation of gene expression by cAMP
plays important roles in many aspects of
cell behavior such as proliferation,
survival, differentiation, learning and
memory.
Figure 16.16 Regulation of glycogen metabolism by epinephrine

Kinases are
inactivated by
phosphatases
G Proteins and Cyclic AMP Signaling

Protein kinases don’t function in isolation.
Protein phosphorylation is rapidly
reversed by protein phosphatases, which
terminate responses initiated by receptor
activation of protein kinases.
Figure 16.18 Regulation of protein phosphorylation by protein kinase A and protein phosphatase 1
G Proteins and Cyclic AMP Signaling

cAMP can also directly regulate ion
channels:
It is a second messenger in sensing
smells—odorant receptors are G protein-
coupled. They stimulate adenylyl
cyclase, leading to increased cAMP.
cAMP opens Na+ channels in the plasma
membrane, leading to initiation of a
nerve impulse.
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Other cell surface receptors are directly
linked to intracellular enzymes.
The largest family of these are the
tyrosine kinases, which phosphorylate
their substrates on tyrosine residues.
Receptor Tyrosine Kinases
Non-Receptor Tyrosine Kinases
Figure 16.20 Organization of receptor and non- receptor tyrosine
kinases
Receptor Tyrosine Kinases Non-Receptor Tyrosine Kinases
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Receptor tyrosine kinases
Includes the receptors for most
polypeptide growth factors.
The human genome encodes 58
receptor tyrosine kinases, including the
receptors for EGF, NGF, PDGF, insulin,
and many other growth factors.
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

All receptor tyrosine kinases have:
An N-terminal extracellular ligand-
binding domain
One transmembrane α helix
A cytosolic C-terminal domain with
protein-tyrosine kinase activity
Figure 16.20 Organization of receptor tyrosine kinases
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Binding of ligands (growth factors) to the
extracellular domains activates the
cytosolic kinase domains.
This results in phosphorylation of both
the receptors and intracellular target
proteins that propagate the signal.
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

The first step is ligand-induced receptor
dimerization.
This results in receptor
autophosphorylation, as the two
polypeptide chains cross-phosphorylate
each other.
Figure 16.21 Dimerization and autophosphorylation of receptor tyrosine kinases
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Autophosphorylation has two roles:
Phosphorylation of tyrosine in the
catalytic domain increases protein
kinase activity.
Phosphorylation of tyrosine outside the
catalytic domain creates binding sites
for other proteins that transmit signals
downstream from the activated
receptors.
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Downstream signaling molecules have
domains, such as SH2 (Src homology 2
), that bind to specific phosphotyrosine-
containing peptides of the activated
receptors.
SH2 domains were first recognized in
tyrosine kinases related to Src, the
oncogenic protein of Rous sarcoma
virus.
Figure 16.22 Association of downstream signaling molecules with receptor tyrosine kinases
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

Nonreceptor tyrosine kinases stimulate
intracellular tyrosine kinases with which
they are noncovalently associated.
The cytokine receptor superfamily
includes receptors for most cytokines
and some polypeptide hormones.
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

The structure of cytokine receptors is
similar to receptor tyrosine kinases, but
the cytosolic domains have no catalytic
activity.
Ligand binding induces dimerization of
receptors, and cross-phosphorylation of
associated nonreceptor tyrosine kinases.
Figure 16.24 Activation of nonreceptor tyrosine kinases (Part 1)
Figure 16.24 Activation of nonreceptor tyrosine kinases (Part 2)
Tyrosine Kinases and Signaling by MAP Kinase, PI 3-Kinase, and
Phospholipase C/Calcium Pathways

The activated kinases then
phosphorylate the receptor.
This provides phosphotyrosine-binding
sites for recruitment of downstream
signaling molecules with SH2 domains.