Lecture 21-24: Cell Signaling PDF

Summary

These lecture notes cover different aspects of cell signaling, including the response of cells to external stimuli, various signaling pathways, and modes of cell communication. Examples of hormones and processes are described, relevant diagrams included.

Full Transcript

Introduction- Cell Signaling. Ch 16

Cells must respond adequately to external stimuli to survive.

Cells respond to stimuli via cell signaling.

Cell signaling is involved in the regulation of cell growth and division.

Cell signaling affects virtually every aspect of cell structure and
function.

Some signal molecules enter cells; others bind to cell-surface
receptors.
Introduction
Each Cell Is Programmed to Respond to Specific Combinations of Extracellular Signals

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Figure 16.1 Modes of cell–cell signaling

(A) direct cell–cell contacts

(B) the action of secreted signaling molecules.

Endocrine: hormones are carried through the
circulatory system to act on distant target cells.

Paracrine: a molecule released from one cell
acts locally to affect nearby target cells.

Autocrine: a cell produces a signaling molecule
to which it also responds.
Extracellular Signals Can Act Over Short or Long Distances

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Extracellular Signal Molecules Bind to Specific Receptors
 In general, cells can only respond to a
signal if they possess the correct receptor
Types of Receptors

Receptor types include:
– Steroid hormone receptors (nuclear receptor
superfamily)
– G-protein coupled receptors (GPCRs)
– Receptor protein-tyrosine kinases (RTKs)
– Non-Receptor protein-tyrosine kinases
– Ligand gated channels
– Specific receptors such as B-and T-cell receptors
Figure 16.2 Structure of steroid hormones, thyroid hormone, vitamin D3, and retinoic acid

Cross the PM. Can you tell from the structure?
Bind to members of the nuclear receptor superfamily.
nuclear receptor superfamily members are transcription factors with domains for ligand
binding, DNA binding, transcriptional activation
Figure 16.3 Glucocorticoid action (ex cortisol)

Glucocorticoids diffuse across the PM.

Binds to the glucocorticoid receptor,
displaces Hsp90.

Receptor dimers form

Receptors translocate to the nucleus,
bind DNA, and associate with
coactivators with histone
acetyltransferase (HAT) activity

Transcription of target genes occurs
Figure 16.4 Gene regulation by the thyroid hormone receptor

Thyroid hormone receptor
binds DNA in the presence or
absence of hormone.

In the absence of hormone,
the receptor associates with
corepressors with histone
deacetylase (HDAC) activity.
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In the presence of hormone,
the receptor associates with
coactivators with histone
acetyltransferase (HAT)
activity.
Figure 16.5 Other signaling molecules

Small signaling molecules

Peptides (EGF, insulin,
endorphins, growth factors,
others )

EGF
Most signals bind to cell-surface receptors
 2 Types of signaling pathways: General properties

Most signaling pathways
Are not linear,
but branched and
interconnected

Produce second Cytoplasmic
messengers domain converted
to recruiting
station for
Small molecules that signaling proteins
Activate or inactivate
specific proteins
Common Elements of Cell Signaling Systems:
kinase cascades are common to signal transduction

Signaling pathways consist of a
series of proteins.
– Each protein in a pathway alters
the conformation of the next
protein.
– Protein conformation is commonly
altered by phosphorylation.
– Kinases add phosphate groups
while phosphatases remove them.
– Target proteins ultimately receive a
message to alter cell activity.
– This overall process is called
signal transduction.
Common Elements of Cell Signaling Systems:
What does phosphorylation do?

Protein phosphorylation can change protein
behavior in different ways.
– It can activate or inactivate an enzyme.
– It can increase or decrease protein-protein
interactions.
– It can change the subcellular location of the
protein.
– It can trigger protein degradation.
– Phosphorylation patterns differ between cell types
Besides kinases/phosphatases, GTP-binding proteins are also common to
signaling pathways
Note check

1. Proteins in the nuclear receptor superfamily are transcription factors that
contain domains for ligand binding, DNA binding, and transcriptional
activation. Sketch a figure that shows how the glucocorticoid receptor
regulates gene expression, indicating those domains.

2. Among the modes of cell-to-cell signaling, what is unique about steroid
signaling?

3. What are some categories of proteins that are common to signal transduction
pathways?
Section 16.2
G Proteins and Cyclic AMP
Types of Receptors

Receptor types include:
– Steroid hormone receptors (nuclear receptor superfamily)
– G-protein coupled receptors (GPCRs)
– Receptor protein-tyrosine kinases (RTKs)
– Non-receptor protein-tyrosine kinases
– Ligand gated channels
– Specific receptors such as B-and T-cell receptors
Figure 17.7 Structure of a G protein-coupled receptor (GPCR)

Largest family of cell-surface
receptors

The odorant receptor protein family
The amino acids that are conserved in other odorant receptor
clones are shown in white and the more variable amino acids in
black.
FIGURE 16.8 Hormonal activation of adenylyl cyclase

Binding of hormone promotes the interaction of the receptor with a G protein
(heterotrimeric).
The activated G protein α subunit dissociates from the GPCR and stimulates
adenylyl cyclase (AC).
AC catalyzes the conversion of ATP to cAMP.
Figure 16.9 Regulation of G proteins

Details of GPCR activation and deactivation
Figure 16.10 Synthesis and degradation of cAMP- a second messenger

Many GPCR’s activate AC to produce cAMP signaling

*CAMP activates protein kinase A (PKA)
FIGURE 16.11 Regulation of glycogen metabolism by epinephrine

An example of GPCR mediated signaling.
Fight or flight response: release glucose into blood stream

Epinephrine binding leads to G protein-mediated
activation of adenylyl cyclase.

cAMP activates protein kinase A, which consists of two
regulatory (R) and two catalytic (C) subunits in its
inactive form.

Binding of cAMP to the regulatory subunits leads to
dissociation of the catalytic subunits, which are then
enzymatically active.

Protein kinase A phosphorylates and activates
phosphorylase kinase

Phosphorylase kinase activates glycogen
phosphorylase, which catalyzes the breakdown of
glycogen to glucose-1-phosphate.

What is glycogen?

Signal amplification occurs during signal
transduction. Video 16.3
Figure 17.12 Cyclic AMP-inducible gene expression

Another role for PKA…

The free catalytic subunit of
protein kinase A translocates
to the nucleus

Phosphorylates the
transcription factor CREB
(CRE-binding protein)

Leads to recruitment of
coactivators and expression of
cAMP-inducible genes.
Figure 17.13 Regulation of protein phosphorylation by protein kinase A and protein phosphatase 1

Protein phosphorylation is reversed by
dephosphorylation (via phosphatases)
Note check

Explain the role of adenylate cyclase in
signaling.

Describe the steps in the activation/deactivation of
heterotrimeric G-proteins (16.9)
Types of Receptors

Receptor types include:
– Steroid hormone receptors (nuclear receptor superfamily)
– G-protein coupled receptors (GPCRs)
– Receptor protein-tyrosine kinases (RTKs)
–
–
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Non-Receptor protein-tyrosine kinases
Ligand gated channels
– Specific receptors such as B-and T-cell receptors
 2 Types of signaling pathways: General properties

Most signaling pathways
Are not linear,
but branched and
interconnected

Produce second Cytoplasmic
messengers domain converted
to recruiting
station for
Small molecules that signaling proteins
Activate or inactivate
specific proteins
16.3 Receptor Tyrosine Kinases and non-receptor tyrosine kinases
Figure 16.14 Receptor tyrosine kinase activation

The receptors for most growth factors are tyrosine kinases.

Growth factor (signal) binding induces receptor dimerization, which
results in receptor autophosphorylation as the two polypeptide chains
cross-phosphorylate one another.
Figure 16.15 Association of downstream signaling molecules with receptor tyrosine kinases

SH2 domains of signalling proteins bind to specific phosphotyrosine-containing sequences
of the activated receptors.
Figure 16.16 Activation of nonreceptor tyrosine kinases
Confusing name: these are receptors similar to RTK’s, but kinase activity is not intrinsic to the receptor, but in
an associated protein kinase.

Ligand binding induces dimerization of receptor with its associated (nonreceptor) tyrosine kinases

Dimerization leads to the activation of the associated nonreceptor tyrosine kinases via cross-phosphorylation.

The activated kinases then phosphorylate tyrosine residues of the receptor, creating phosphotyrosine-binding sites for
downstream signaling molecules.
Figure 16.17 The JAK/STAT pathway- signalling in blood cells and immune cells

An example…

The STAT proteins are transcription factors with
SH2 domains

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

Stimulation of cytokine receptors leads to the
binding of STAT proteins to phosphotyrosine-
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.
Figure 16.18 Integrin signaling via FAK – a non-receptor tyrosine kinase

Integrins link cells
to ECM.

Also serve as
receptors to
activate signaling
pathways

Can control
movement and
other aspects of
cell behaviour in
response to cell-
matrix interactions.

Binding of integrins to the extracellular matrix leads to integrin clustering and activation
of the nonreceptor tyrosine kinase FAK by autophosphorylation.

Src binds to the FAK autophosphorylation site and phosphorylates FAK on additional
tyrosine residues

Those serve as binding sites for additional downstream signaling molecules.
Note check

1. Explain this figure to your classmate.

2. Differentiate between RTK and non-RTK