Cell Communication II PDF

Summary

This document discusses the stages of cell signaling, including reception, transduction, and response. It also details signal transduction pathways, kinases, and phosphatases in the context of cellular functions and processes related to cell biology.

Full Transcript

Session Learning Outcomes
(SLOs)

SLO# 3: Describe the stages and events of
cell signaling.

SLO# 1 : Define kinases and phosphatases and
their role in signal transduction.
 The Three Stages of Cell Signaling

Cells receiving signals went through three processes
receive the
signal
– Reception targetcell will conformation
receptor andcausechange
by
– Transduction
movement megration celldevision
– Response
behavior
expression
gene

Called Signal transduction pathway

Signal transduction: ability of cell to translate receptor-
ligand interaction into a change in behavior or gene
expression
 Signal Transduction Pathway
function: convert extracellular information into an
appropriate cellular response
composed of:
– signals
intracellular
– receptors al
extracellula

– signaling proteins
– second messenger
molecules sina.imssinge

i ii

initiation

if
EXTRACELLULAR CYTOPLASM
FLUID
Plasma membrane

1 Reception 2 Transduction 3 Response
Receptor
Activation
of cellular
response
Relay molecules in a signal transduction pathway

Signaling
molecule
 The Three Stages of Cell Signaling
ñ
1) Reception: The target cell's detection of a signaling molecule
coming from outside the cell. This occurs when a chemical signal
is sensed due to the binding of a signaling molecule to a receptor
protein, causing it to change shape.
EXTRACELLULAR CYTOPLASM
FLUID
Plasma membrane

1 Reception
Receptor
The receptor and signaling molecules
fit together (lock and key model,
induced fit model, just like enzymes)

Signaling
molecule
 The Three Stages of Cell Signaling
2) Transduction:
Transmission of the signal to effector molecules and down a signaling
pathway where every protein typically changes the conformation of the
next down the path, most commonly by phosphorylation (by kinases) or
dephosphorylation (by phosphatases)
EXTRACELLULAR CYTOPLASM
FLUID
Plasma membrane

1 Reception 2 Transduction
Receptor
2nd
Messenger!
Relay molecules in a signal transduction pathway

Signaling
molecule

The signal is converted into a form that can produce a cellular response.
2. Transduction

Transduction: Cascades of molecular
interactions relay signals from receptors to target
molecules in the cell
Multistep pathways
– Can amplify a signal (Amplifies the signal by activating
multiple copies of the next component in the pathway)
– Provide more opportunities for coordination and
regulation Integration ofthepathway togive
suitable response
 Intracellular signaling proteins propagate signals
within a cell
Key Concepts:
– Signaling proteins rapidly transmit and amplify signal
information.
– As information passes through a signal transduction
pathway, it often changes physical form. change conformation

– Signaling proteins are grouped into six classes based
on their structure, location, and mechanism of signal
transmission. into totein near to thereceptor
tothenucleus
phosphorylation
dephosphorylation

near

– Second messengers are non-protein molecules that
link signaling proteins together in signal transduction
pathways.
In 3Amin
Acids Protein Phosphorylation and
Dephosphorylation

Many signal pathways
– Include phosphorylation cascades
– In this process, a series of protein kinases add
a phosphate to the next one in line, activating
it
– Phosphatase enzymes then remove the
phosphates for Homeostasis
 hydrolysis
of
ATP

serine
Threonine

Thyronine
 Protein Phosphorylation and
Dephosphorylation
Signal molecule

conformation
change

Receptor Activated relay 1 A relay molecule
molecule
activates protein kinase 1.
Inactive
protein kinase 2 Active protein kinase 1
1 Active transfers a phosphate from ATP
protein
kinase
to an inactive molecule of
1 phosphorylated protein kinase 2, thus activating
Inactive
activated this second kinase.
protein kinase ATP
2 ADP Active P 3 Active protein kinase 2
protein then catalyzes the phos-
PP kinase
Pi 2 phorylation (and activation) of
protein kinase 3.
Inactive
protein kinase ATP
ADP P Finally, active protein
3 Active 4
protein
5 Enzymes called protein kinase
kinase 3 phosphorylates a
PP
phosphatases (PP) Pi 3 protein that brings about the
catalyze the removal of cell’s response to the signal.
Inactive
the phosphate groups
from the proteins, in protein ATP
ADP
Active
P
Cellular
making them inactive PP
protein response
and available for reuse. P i
 Many G-proteins trigger the formation of cAMP, which
then acts as a second messenger in cellular pathways.
First messenger
(signal molecule
such as epinephrine)

Adenylyl
G protein cyclase

Enzyme
GTP
e willactivate
6Proteinafter G protein-coupled
sidingofligand receptor
ATP
Second
cAMP messenger
Eyelic
Protein
Transduction in a G-
medengers
kinase A activate
protein pathway kinases

Cellular responses
 Small Molecules and Ions as Second
Messengers
Secondary messengers Ca
– Are small, nonprotein, water-soluble molecules or ions that
act as secondary messengers. when we have
more thanone
secondmessenger

Activate

charnel
smooth
 The Three Stages of Cell Signaling
3) Response: The transduced signal triggers a specific cellular
response.

EXTRACELLULAR CYTOPLASM
FLUID
Plasma membrane

1 Reception 2 Transduction 3 Response
Receptor
Activation
of cellular
response
Relay molecules in a signal transduction pathway

Signaling
molecule

The transduced signal triggers a cellular response
3. Response
cytoplam

Geneexpression

Response- cell signaling leads to regulation of
transcription (turn genes on or off) or cytoplasmic
activities. messenger

ligands

net
of
nydropy.gs cell

Animation of how epinephrine works -
DnaTube.com - Scientific Video and Animation Site
 Growth factor

3. Response Receptor Reception

Many possible
outcomes Phosphorylation
cascade Transduction

Ex: catalysis by an
enzyme, rearrangement CYTOPLASM

of the cytoskeleton, or
activation of specific
genes. Inactive
transcription
Active
transcription
factor factor Response
P

This example shows a DNA

transcription response Gene

NUCLEUS
mRNA
Four features of signal-transducing systems.
dephosphorylation
conformation
change
i ofthecell
shutt stops ofbindingsite

Tag
fath activatethe
sameresponse
 The Specificity of Cell Signaling
 Once a signaling molecule binds to its receptor
it causes a conformational change in it that
results in a cellular response.
 The same ligand can bind to the same receptor
on different cell types causing different
responses (e.g. acetylcholine).
 On the other hand, different ligands binding to
different receptors can produce the same cellular
response (e.g. glucagon, epinephrine).
 The Specificity of Cell Signaling
Different kinds of cells have different
collections of proteins
These differences in proteins give each kind of
cell specificity in detecting and responding to
signals
The response of a cell to a signal depends on
the cell’s particular collection of proteins
Pathway branching and “cross-talk” further help
the cell coordinate incoming signalsIntegration
 Specificity of the signal
– The same signal molecule can trigger different responses
– Many responses can come from one signal!
Signaling
molecule

Receptor

The response of a
particular cell to a signal Relay
molecules
depends on the type of
proteins it contains.

Response 1 Response 2 Response 3

Cell A. Pathway leads Cell B. Pathway branches,
to a single response. leading to two responses.
 The signal can also trigger an activator or inhibitor
The signal can also trigger multiple receptors and
different responses
specifity relatedto 8
bindingsite
collectionofprotein

ofreceptor
collection

Activation
or inhibition

Response 4 Response 5

Cell C. Cross-talk occurs Cell D. Different receptor
between two pathways. leads to a different response.
 ST
for Homeostasis Termination of the Signal

Signal response is terminated quickly
w̅
– By the reversal of ligand binding conformational
change
https://youtu.be/zEZFl3MsmY0
 Types of receptors

In contrast to NO and the steroid and thyroid
hormones, the vast majority of signal molecules
are too large or too hydrophilic to cross the
plasma membrane of the target cell.

Most cell surface receptor proteins belong to on
of three large families:
1. Ion channel-linked receptors,
2. G-protein-linked receptors, or
3. enzyme-linked receptors.
Cell Surface Receptors differ in the nature of the
intracellular signal that they generate when extracellular
signal molecules binds to them.

1-ion-channel-linked receptors: the resulting
signal is a flow of ions across the membrane, which
produces electrical current.
2- G-protein-linked receptors activate a class of
membrane bound proteins.

Activate
result
eriIdeals proteinkinaseA
of
aftp
Hydrolysis

7
iii functionaldoma
toform
 3- Enzyme-linked receptors act as an enzyme or
are associated with enzymes inside the cell.

with
Associated
omflex inside
enzyme
cell
P's
in me
Act me
n
 ion-channel-linked receptors

 Of all the cell-surface types, ion channel-linked receptors
function in the simplest and direct way.
 These receptors are responsible for the rapid transmissions
of signals across synapses in the nervous system.
 They transduce a chemical signals in the form of a pulse of
neurotransmitter delivered to the outside of the target cell.
 When neurotransmitter binds, this type of receptor alters
its conformation so as to open or close channel for the flow
of specific types of ions (such as Na+, K+, Ca2)
Ion-channel-linked Receptors Convert Chemical
Signals Into Electrical Ones
Many Intracellular Signaling Proteins Act as Molecular
Switches

 Signals received via G-protein-linked or enzyme-linked
receptors are transmitted to elaborate relay systems formed
from cascades of intracellular signaling molecules.
protein
non
 Apart from a few small molecules like cyclic GMP, cyclic second massenger

AMP, and Ca2+, these intracellular molecules are proteins.

 Some serves as chemical transducer and in response to one
type of chemical signal they generate another.

 Others serve as messengers, receiving a signal in one part of
the cell and moving to another to exert an affect
 unactivated
the
because
ofGDP
binding

relased

phisphate
sina.ae
phosphorylation

activated because

thebindingofGTP
molecules

c

Many intracellular signalling proteins act as molecular switches