Cell Communication and Signaling Lecture Notes PDF

Summary

These lecture notes cover cell communication and signaling, including local and long-distance communication mechanisms, and signal transduction pathways. The notes also discuss the regulation of glycogen metabolism by epinephrine and the JAK-STAT pathway.

Full Transcript

Human Biology and
Physiology (BMD 211)

Lecture 4:
Cell communication
and signaling

Assistant Prof. Raghda Ramadan

1
 Midterm
evaluation
Lecture 5:
Cell signaling II
(Mechanisms of cell signaling)
 4
www.simplypsychology.org/fight-flight-freeze-fawn.html
Cell-cell communication
A) Local communication
Signals to target cells in the neighboring area

2. Synaptic 3. Autocrine and
1. Direct contact
signaling paracrine signals

Cell 1 Cell 2
 Cell-cell communication
B) Long distance communication
Signals to target cells in distant area
1. Endocrine system 2. Nervous system

Hormones Neurohormones
 B) Long distance communication

A) Local communication

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 Signal transduction pathway
❑ The process that converts a signal on a cell’s surface into a cellular response involved a series of steps
that are collectively called signal transduction pathway

1. Reception

▪ A signaling molecule binds to a receptor
protein, causing it to change shape

2. Transduction

▪ Cascades of molecular interactions relay
signals from receptors to target molecules in
the cell

3. Response

▪ Cell signaling leads to regulation of
transcription or cytoplasmic activities 8
Signal transduction pathway

In this signaling system, the hormone epinephrine (adrenaline) acts
through a G protein-coupled receptor to activate a succession of
relay molecules, including cAMP and two protein kinases (see
Figure). The final protein activated is the enzyme glycogen
phosphorylase, which uses inorganic phosphate to release glucose
monomers from glycogen in the form of glucose 1-phosphate
molecules. This pathway amplifies the hormonal signal: One receptor
protein can activate approximately 100 molecules of G protein, and
each enzyme in the pathway, once activated, can act on many
molecules of its substrate, the next molecule in the cascade.

Lecture 5:
Cell signaling II
9
(Mechanisms of cell signaling )
Lecture outline
1. Receptor major types
▪ Ligand-gated Ion channels

▪ G-protein coupled receptors

▪ Kinase-linked receptors

2. Transduction mechanisms

3. Common signaling pathways
▪ JAK-STAT signaling pathway

▪ RAS/RAF/MAPK signaling pathway

10
 Signal transduction pathway
❑ The process that converts a signal on a cell’s surface into a cellular response involved a series of steps
that are collectively called signal transduction pathway

1. Reception

▪ A signaling molecule binds to a receptor
protein, causing it to change shape

2. Transduction

▪ Cascades of molecular interactions relay
signals from receptors to target molecules in
the cell

3. Response

▪ Cell signaling leads to regulation of
transcription or cytoplasmic activities 11
 Signal transduction pathway
1. Reception

❑ Ligand-receptor interaction:

▪ Specific Ligands (key) bind to a specific receptor (lock) with a specific pose
in the active site to allow for a specific action (cell response).

Ex: In the case of the epinephrine circulating throughout the bloodstream in the fight
light response, the hormone encounters many types of cells, but only certain target cells
detect and react to the epinephrine molecule. A receptor protein on or in the target
cell allows the cell to “hear” the signal and respond to it. The signaling molecule is
complementary in shape to a specific site on the receptor and attaches there, like a
key in lock.

▪ An agonist binds to the receptor and produces an effect within the cell.
An antagonist may bind to the same receptor, but does not produce a
response, instead it blocks that receptor to a natural agonist

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 Signal transduction pathway
1. Reception

❑ Target cell receptor location:
▪ Cell membrane:
- Outer surface receptors (most common)
- For mainly hydrophilic (water soluble) ligands that can't enter
the cells (eg: proteins, amino acids, peptides..etc)

▪ Cytosolic or Nuclear:
- In the cytosol or in the nucleus
- For hydrophobic or very small ligands that can enter the cells
(eg: steroids hormones, nitric oxide…etc)

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Signal transduction pathway
❑ Major types of receptors:
Membrane receptors Nuclear receptor

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Major types of receptors
Ligand-gated ion channels

▪ A ligand-gated ion channel is a type of membrane channel receptor
containing a region that can act as a “gate”. The channel remains closed
until a ligand binds to the receptor and the receptor changes shape.

▪ When a signaling molecule binds as a ligand to the channel receptor, the
channel opens, allowing the flow of specific ions, such as Na+ or Ca2+. This
change may directly affect the activity of the cell in some way (cellular
response).

▪ When the ligand dissociate from the receptor, the channel closes and ions
no longer enter the cell.

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Major types of receptors
Ligand-gated ion channels

▪ Ex: Neural release of acetyl choline neurotransmitters (Ligand)
acting on nicotinic receptors (ligand-gated ion channels) allowing
opening of Na+ channel and flow of Na+ into cells, which
stimulates action potential for neuron communication (response).

▪ This type of neuron communication is essential in the nervous
system function (and involved in learning and memory)

Ligand gated ion channels

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Major types of receptors
Ligand-gated ion channels

▪ Ex2: Neural release of acetyl choline neurotransmitters (Ligand)
acting on nicotinic receptors (ligand-gated ion channels)
allowing opening of Na+ channel and flow of Na+ into cells,
which stimulates Ca2+ release leading to skeletal muscles
contraction (response).

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Types of channels
Gating of channels

Ligand Voltage Mechanical
Requires binding of specific Requires a specific gradient of Requires a specific tension to open
chemical (ligand) to open electrical charge across the
Found in smooth muscle cells
membrane to open
around arteries
Ex: Acetyl choline binding to
nicotinic receptors Ex: voltage gated calcium channels
& voltage gated sodium channels

Ca+

local anesthetic drug blocking
voltage-gated sodium channels
Signal transduction pathway
❑ Major types of receptors:
Membrane receptors Nuclear receptor

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Major types of receptors
G-protein coupled receptors (GPCRs)

Several components of chocolate closely
related to neurotransmitters serotonin and
dopamine, they exert their effects by binding to
specific GPCRs in the brain, influencing mood.

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Major types of receptors
G-protein coupled receptors (GPCRs)

GPCRs are the largest and most diverse family of membrane receptors in eukaryotes, found
throughout the human body and involved in a wide range of physiological processes.

Immune system Cardiovascular system Sensory organs
Immune cells such as T & B cells, and cardiac muscle and blood vessel cells GPCRs play a key role in sensory
macrophages express various GPCRs express several GPCRs perception

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Major types of receptors
G-protein coupled receptors (GPCRs)

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Major types of receptors
G-protein coupled receptors (GPCRs)

▪ Malfunctions of GPCRs associated with many human diseases, including cancer, cardiovascular and
neurodegenerative disease (GPCRs are the target of around to 50% of all modern medicinal drugs).

Beta-Blockers (e.g., Propranolol) Histamine H1 and H2 Receptor Antagonists (e.g., Ranitidine, Telfast)

Target GPCR: Beta-adrenergic receptors (β-ARs) Target GPCR: Histamine H1 and H2 GPCRs

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 Major types of receptors
G-protein coupled receptors

G-protein coupled receptors (GPCRs)

❑Structure of GPCR
▪ The most important characteristic of GPCRs is that they have seven
transmembrane alpha helices.

▪ The extracellular domains are responsible for ligand binding, while
the intracellular domains interact with G proteins.

▪ G proteins are heterotrimeric proteins consisting of alpha, beta, and
gamma subunits.

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3D structure of GPCR
 Major types of receptors
G-protein coupled receptors (GPCRs)

❑How Do GPCRs work?
▪ GPCRs work with the help of a G protein

▪ In the inactive state, GDP is bound to the alpha subunit of G Li, J. et al. Nature 420, 716-717 (2002).
protein.

▪ When an agonist (ligand) binds to a GPCR, it undergoes a
conformational change that activates the G protein (GTP is The basic GPCR signaling pathway
attached). involves:

Ligand
▪ The activated G protein dissociates into alpha and beta- The GPCR
gamma subunits, which then go on to activate downstream A heterotrimeric G protein
effector proteins to stimulate a cellular response. A downstream effector
proteins
▪ Binding of signaling molecules is reversible: Like other ligands,
they bind and dissociate many times. 25
Signal transduction pathway
❑ Major types of receptors:
Membrane receptors Nuclear receptor

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 Major types of receptors
Kinase-linked receptors

❖ Receptor tyrosine kinases (RTK)

Epidermal Growth Factor Receptor (EGFR) Vascular Endothelial Growth Factor Insulin Receptor
Found on the surface of many cell types, Receptor (VEGFR) Primarily found on the surface of
including skin cells Mainly present on the surface of vascular muscle, liver, and fat cells.
Function: EGFR is involved in cell growth, endothelial cells (cells lining blood vessels). Function: They regulate glucose
proliferation, and differentiation, making it Function: critical for angiogenesis, the homeostasis
important for skin development and tissue formation of new blood vessels, and is
repair. essential for tissue growth and repair.

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Major types of receptors
Kinase-linked receptors

Examples of ligands that stimulate Receptor tyrosine kinases (RTK):

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 Major types of receptors
Kinase-linked receptors

❖ Receptor tyrosine kinases (RTK)
▪ RTKs are one of the biggest classes of Kinase-linked receptors.

▪ There are around 60 RTKs in human and they can be found throughout the human body.

▪ RTK signaling plays a pivotal role in cell proliferation, differentiation, and survival.

▪ Mutations or overexpression of RTKs can lead to uncontrolled cell growth and are often
associated with cancer.

▪ Many cancer drugs target RTKs to inhibit their signaling and slow tumor growth.

▪ EX: Breast cancer patients have a poor prognosis if their tumor cells harbor excessive
levels of a receptor tyrosine kinase called HER2. Using molecular biological techniques,
researchers have developed a protein drug called Herceptin that binds to HER2 on cells
and inhibits cell division (antagonist), thus prevents further tumor development.
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 Major types of receptors
Kinase-linked receptors

❖ Receptor tyrosine kinases (RTK)

▪ RTK is a protein kinase—an enzyme that catalyzes the transfer
of phosphate groups from ATP to another protein. The binding of a signaling molecule causes two receptor monomers to
form a complex known as a dimer
▪ Upon ligand binding, such as a growth factor, one RTK may
activate ten or more different transduction pathways and
cellular responses, helping the cell regulate and coordinate
many aspects of cell growth and cell reproduction.

▪ The ability of a single ligand-binding event to trigger so many
pathways is a key difference between RTKs and GPCRs.

Dimerization activates the tyrosine though adding a phosphate from an
ATP molecule → activates the bound relay protein → triggering a
transduction pathway, leading to a cellular response 30
Signal transduction pathway
❑ Major types of receptors:
Membrane receptors Nuclear receptor

31
 Signal transduction pathway
❑ The process that converts a signal on a cell’s surface into a cellular response involved a series of steps
that are collectively called signal transduction pathway

1. Reception

▪ A signaling molecule binds to a receptor
protein, causing it to change shape

2. Transduction

▪ Cascades of molecular interactions relay
signals from receptors to target molecules in
the cell

3. Response

▪ Cell signaling leads to regulation of
transcription or cytoplasmic activities 32
Lecture outline
1. Receptor major types
▪ Ligand-gated Ion channels

▪ G-protein coupled receptors

▪ Kinase-linked receptors

2. Transduction mechanisms

33
 Signal transduction pathway
Phosphorylation cascade
1. Protein Phosphorylation and
Dephosphorylation

▪ Many of the relay molecules in signal transduction pathways are
protein kinases, and they often act on other protein kinases in
the pathway through adding a phosphate to a target protein in
a serios of events known as phosphorylation cascade.

▪ Phosphate group is removed by protein phosphatases from a
target protein (mostly to turn it off). The process is known as
dephosphorylation. Thus, turning off the signal transduction
pathway

In a phosphorylation cascade, a series of different proteins in a
pathway are phosphorylated in turn, each protein adding a
phosphate group to the next one in line. Here, phosphorylation
activates each protein, and dephosphorylation returns it to its
inactive form.
 Signal transduction pathway
2. Small Molecules and Ions as The GPCR adenylyl cyclase cascade
Second Messengers

Second Messenger (cAMP):

▪ cAMP (cyclic Adenosine Mono-Phosphate) is produced
by the enzyme adenylyl cyclase in response to the
binding of extracellular signaling molecules to cell
surface GPCRs. cAMP then activates a variety of
downstream effector proteins, as in the adenylyl
cyclase cascade (amplify signals)

Calcium Ions and Inositol Trisphosphate (IP3 )
▪ Calcium ions (Ca2+) and inositol trisphosphate (IP3) also
function as second messengers in many signal
transduction pathways.
One signal molecule can activate amplified signal molecules

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Signal transduction pathway
2. Small Molecules and Ions as
Second Messengers

Exanple: Regulation of glycogen metabolism by epinephrine in
fight/flight response

GPCR stimulation by epinephrine (ligand) leads to G protein
activation → adenylyl cyclase activation (amplifier enzyme) →
cAMP, (second messenger), activates protein kinase A →
activation of phosphorylase kinase → activation of glycogen
phosphorylase, which catalyzes the breakdown of glycogen to
glucose1phosphate (response).

36
 Signal transduction pathway
❑ The process that converts a signal on a cell’s surface into a cellular response involved a series of steps
that are collectively called signal transduction pathway

1. Reception

▪ A signaling molecule binds to a receptor
protein, causing it to change shape

2. Transduction

▪ Cascades of molecular interactions relay
signals from receptors to target molecules in
the cell

3. Response

▪ Cell signaling leads to regulation of
transcription or cytoplasmic activities 37
Signal transduction pathway
3. Response

❑ Ultimately, a signal transduction pathway leads to the regulation of one or more cellular activities. The
response at the end of the pathway may occur in the nucleus of the cell or in the cytoplasm.

❑ Why different cells when they are exposed to the same signaling molecule, they have different responses?
Ex: Epinephrine stimulates the liver cell to break down glycogen, but the main response of the heart cell to epinephrine is
contraction, leading to a more rapid heartbeat. How do we account for this difference?

The reason for signal specificity is that each cell type has
different receptors, relay molecules, and effector proteins 38
Signal transduction pathway
Signal Termination

❑ The cell has to stop responding to a particular signal in order to be able to respond to other
signals.

❑ For this reason, the changes across the signal transduction pathway must all be reversible.
▪ Reception: the binding of a ligand to a receptor is reversible. To terminate the signal,
the ligand dissociates from the receptor.

▪ Transduction: To terminate the signal, phosphorylated (active) kinases are
dephosphorylated.

▪ Response: the effector proteins are dephosphorylated or degraded

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Lecture outline
1. Receptor major types
▪ Ligand-gated Ion channels

▪ G-protein coupled receptors

▪ Kinase-linked receptors

2. Transduction mechanisms

3. Common signaling pathways
▪ JAK-STAT signaling pathway

▪ RAS/RAF/MAPK signaling pathway

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 Common signaling pathways
❖The JAK-STAT pathway
▪ The Janus kinase (JAK) - Signal Transducer and Activator of Transcription
(STAT) pathway is a crucial signaling cascade in cell communication, mainly
involved in transmitting signals from the cell surface to the nucleus in
response to various extracellular signals, including cytokines and growth
factors that activate Tyrosine kinase receptors (RTK).

▪ This pathway plays a fundamental role in regulating various cellular
processes, such as cell growth, differentiation, and immune responses
(dysregulated in cancer → abnormal cell growth and differentiation).

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 Common signaling pathways
❖The JAK-STAT pathway
▪ The STAT proteins are transcription factors.

▪ In unstimulated cells, STAT proteins are inactive in the cytosol.

▪ Stimulation of cytokine ligands binding to RTK receptors leads to the
binding of STAT proteins to phospho-tyrosine binding sites on the
receptor, where they are phosphorylated by the receptor associated
JAK tyrosine kinases.

▪ The phosphorylated STAT proteins then dimerize and translocate to the
nucleus, where they activate the transcription of target genes involved
in cell growth, differentiation…etc.

How can you detect abnormal
activation of JAK-STAT pathway?
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 Common signaling pathways
How can you detect abnormal
❖The JAK-STAT pathway activation of JAK-STAT pathway?

Measuring the levels of phosphorylated JAK and STAT proteins (at the gene or the protein levels)

assess the functional consequences of JAK-STAT signaling (e.g., cell proliferation assay).

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 Common signaling pathways
❖The JAK-STAT pathway
Several drugs target the JAK-STAT pathway for various medical conditions, primarily
autoimmune diseases and certain cancers:
EX1: Tofacitinib (Xeljanz): a JAK1 and JAK3 inhibitor , primarily used for autoimmune conditions,
and has been studied in clinical trials for various cancers, including solid tumors.

EX2: Ruxolitinib (Jakafi): Ruxolitinib is a JAK1 and JAK2 inhibitor primarily used for the treatment
of myelofibrosis, a myeloproliferative neoplasm.

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 Common signaling pathways
❖The JAK-STAT pathway

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 Common signaling pathways
❖ The RAS/RAF/MAPK signalling pathway

▪ MAP kinase signaling is one of the major pathways of
signal transduction activated downstream of both
receptor and nonreceptor tyrosine kinases.

▪ The central elements in the pathway are a family of
serine/threonine kinases called the MAP kinases
(mitogen-activated protein kinases) that are
activated in response to a variety of growth factors
and other signaling molecules.

▪ This crucial pathway plays a central role in regulating
various cellular processes, including cell growth,
proliferation, differentiation, survival, and
metabolism.

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 Common signaling pathways
❖ The RAS/RAF/MAPK signalling pathway

▪ The initial step in MAP kinase signaling from growth
factor receptors is activation of the GTP binding
protein Ras protein (from rat sarcoma virus).

▪ Ras activates the Raf protein kinase, which in turn
activates MEK and ERK.

▪ Activated ERK can translocate to the nucleus and
phosphorylate transcription factors, altering gene
expression involved in growth, proliferation and
survival.

Growth, proliferation and survival

How can you detect abnormal
activation of MAPK-ERK pathway? 47
 Common signaling pathways

❖The RAS/RAF/MAPK signalling pathway

▪ Several drugs are targeting MAPK/ERK pathway for
the management of cancer

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 Common signaling pathways
The PI3K/Akt/mTOR pathway
❖The RAS/RAF/MAPK signalling pathway
Lecture 6: Cell death and
signaling

Downward et a., Nat Med. 2008 Dec;14(12):1315-6. 49
Cell communication and signaling
References

1. Campbell Biology, 11th edition, Chapter 11; Cell Communication, P. 212-233

2. Molecular Biology of the Cell, 6th edition, Chapter 15: Cell Signaling. P. 813 -888

https://www.khanacademy.org/science/ap-biology/cell-communication-and-cell-
cycle/changes-in-signal-transduction-pathways/v/example-of-signal-transduction-pathway

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