BIOL111 WEEK 12 Lecture 1 signalling upload.pdf

Full Transcript

Cell Junctions

Plants

Communicating
junctions

Connecting junctions

Animals

+ tunnelling
nanotubes
3. Junctions in animal cells

Connecting
junctions

Communicating
junctions
+ tunnelling nanotubes
 3. Connecting junctions in animal cells: tight junctions

Tight junctions form a continuous
seal, to prevent movement of
liquids and material between cells

Specific proteins hold cells
together forming a “water-proof”
layer.

Alberts et al (2004) Molecular Biology of the Cell 4th ed. Figs 19.05
 Tight Junctions Function
Gut epithelium

Important in epithelial
tissues

Tight junctions
demonstrated using
tracer molecules in the
gut.

Alberts et al (2004) Molecular Biology of the Cell 4th ed. Figs 19.03
 Tight junctions also help form the blood:brain barrier

The blood:brain barrier
prevents molecules from
passing from the blood into the
central nervous system

Tight junctions help to block
passage of molecules between
cells
Tight junctions also help form the blood:brain barrier

Neisseria meningitidis

Tight junctions

Coureuil M, et al. Mechanism of meningeal invasion by Neisseria meningitidis. Virulence. 2012 Mar 1; 3(2):
164–172. doi: 10.4161/viru.18639
 Connecting junction 2: Adherens junctions
Found in most tissue types

In ~15% of breast cancer, cadherin
function is lost

Cadherins
Plasma
membranes

Actin
microfilaments
 4. Communicating junctions in animal cells

Gap junctions

Pores that connect cytoplasm of
adjacent cells

Similar in function to
plasmodesmata

Found in most animal tissues
 Structure of Gap Junctions

formed by the protein connexin

6 connexin proteins form a pore

pores from adjacent cells align
to make the gap junction.
 Function of Gap Junctions

channel is 1.4 nm in diameter

allow exchange of solutes below 1.2 kDa:
ions, sugars, amino acids, and other small
molecules

opening regulated by Ca2+ and hormones

functions in coordinating activities of cells
within a tissue eg. muscle contractions
 Where found Structure Communicating Function
or connecting

Gap Junctions Animals 1.5 nm pore Communicating Stable connections
Most tissues 6 connexin proteins lined Exchange of solutes below 1.2 kDa: ions, sugars,
up in the membrane of amino acids, and other small molecules between cells
both cells Coordinate activities of tissues eg. Muscle contractions

Tunneling
nanotubes

Plasmodesmata

Tight Junctions

Adherens
Junctions
 Cell junctions key points

Multicellular organisms use junctions between cells for communication and
connection

Plant cells communicate through plasmodesmata

Animal cells connect to each other using tight junctions and adherens junctions

Animal cells communicate through gap junctions and tunnelling nanotubes
 Biol111: Cellular Biology and Biochemistry
Lecture 33

Cell Signalling
Pathways
Today’s Outline

1. Overview of cellular signalling

2. Different types of cellular signalling

3. Different types of receptors available to a cell (reception)
Two receptors that are on the cell surface, how they respond
to signals

One receptor on the inside of the cell, and how it responds to
signals
Thursday’s Outline (ish)

4. How these signals are transferred (transduction) from the
plasma membrane to inside the cell through the use of second
messengers

5. How signals can be amplified (phosphorylation cascades)

6. How the cell reacts to these signals (response)

7. How cells are specific in what signals they respond to
 1. Introduction to signalling: Sensing

What senses do we, as humans, have?

Sight

Sound

Taste

Smell

Touch
 Sensing: detection of a signal

Can have a signal, but can you detect it?
UV light is all around us, but we don’t see it.

Must have a detection system.

humans don’t detect electrical or magnetic signals.
humans don’t detect ultrasound, UV

Must be able to process and respond to the signal.

bats can take an echo and generate spatial information.
birds can sense a magnetic signal and navigate accordingly
plants can sense gravity and grow directionally
 What can cells sense?

Multicellular organisms sense signals (light, touch, sound etc) using
specialised organs

Cells also sense signals, but using proteins called receptors
What can cells sense?

Sight Temperature

Sound

Taste

Smell

Touch
 An Overview of Cellular Signalling

Signalling allows responses to external change in:
unicellular organisms
multicellular organisms (animals, plants, fungi)
cells within multicellular organisms

Signalling enables co-ordination in multicellular organisms.

Signalling at a cellular level involves 3 processes:
1 signal reception
2 signal transduction
3 signal response

Signal reception - Signal transduction - Signal response
 Cellular signalling
Sometimes the cell that detects the signal is the same as the one that responds

1. Signal: a nutrient 1. Signal: a toxin is
is detected by a detected by a
receptor receptor

2. Signal is relayed 2. Signal is relayed
(transduced) (transduced)
through the through the
cytoplasm to the cytoplasm to the
flagella motor flagella motor

3. Response:
3. Response:
keep swimming
stop swimming
in that direction
in that direction
 Cellular signalling

Sometimes the cell that detects the signal is a long way away from the ones
that respond

Signal (heat) is Signal is relayed
detected by (transduced) as
thermoreceptors an electrical
in the skin signal through the
spine

Muscles
respond
mechanically to
the signal by
contracting
 2. Kinds of cellular signalling

1. Direct cell-to-cell signalling

1A. Cell junctions 1B. Cell-cell recognition
 2. Kinds of signalling

2. Local signalling

2A. Paracrine signalling 2B. Synaptic signalling
 2. Kinds of signalling

3. Long-distance signalling
Called endocrine signalling
Mediated by hormones
 2. Kinds of signalling

3. Long-distance signalling
Called endocrine signalling
Mediated by hormones
 2. Kinds of signalling

Signalling molecules can be
Gaseous, water-soluble, lipid-soluble
Small molecules or proteins

Ethylene, gas Estrogen, lipid-soluble Insulin, a protein
Reception - Transduction - Response

* signal reception
* signal transduction
* signal response = change in protein activity or expression.

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.06
 3. Reception of signals

A signalling molecule binds to a receptor and it changes shape.

Receptors are specific for certain signals
So that only the correct cells respond “lock and key”
So that the cells don’t respond to the wrong signals

A ligand is the specific signalling molecule that binds to a
specific receptor

receptor ligand

Signal reception - Signal transduction - Signal response
 3. Reception of signals

Receptors:
Cell-surface receptors:
i. Ligand-gated ion channel receptors.
ii. G protein-coupled receptors.
iii. Enzyme-coupled receptors

Cytoplasmic receptors:
iv. Steroid receptors

30% of human
proteins are cell
surface receptors!

Signal reception - Signal transduction - Signal response
Ligand-Gated Ion Channel Receptors
System involves:
* signal molecule (wide range possible).
* gated ion channel.

When the signalling molecule binds to the
channel, it opens and allows the flow of
specific ions.

It is critical that the gate returns to the
closed position at the end of the signal.

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
Ligand-Gated Ion Channel Receptors

Example: chemical synapses

Ligand: neurotransmitter eg. Dopamine,
acetyl choline

Receptor: Transmitter-gated ion channel

Effect: activation of the next nerve cell by
ions entering the cell

Alberts et al. (2014) Molecular Biology of the Cell, Fig. 11.36
 II. G Protein-Coupled Receptors (GPCRs)

G protein receptors are
signal receptors found
associated with the plasma
membrane.

Found in all eukaryotes.

800 different GPCRs in
humans

60% of drugs target GPCR
pathways

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 G Protein-Coupled Receptors

System involves:
signal molecule (ligand)
G protein-coupled receptor
G protein
enzyme.

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 II. G Protein-Coupled Receptors (GPCRs)
G proteins are GTP-binding proteins

Inactive G-protein

 ATP

 GTP

Active G-protein
 GDP

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 G Protein-Coupled Receptors

System involves: The signal molecule binds to the
signal molecule (ligand) receptor.
G protein-coupled receptor Receptor shape changes to allow
G protein G-protein to bind
enzyme. G protein is activated by
switching GDP for GTP

1. Resting state 2. GPCR activates G-protein

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 G Protein-Coupled Receptors

Activated G-protein then G protein deactivated by
activates an enzyme that hydrolysis of GTP to GDP.
triggers a cellular response Signalling system turned off and
reset.

3. G-protein activates enzyme 4. System returns to resting state

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 G Protein-Coupled Receptors
Examples:

Adrenaline receptor Rhodopsin: photoreceptor

Reece et al. (2011) Campbell Biology, 9th ed, Fig. 11.07
 Today’s Key Messages

Cells can detect and respond to a wide variety of signals, most of
which are chemical signals

Signalling can be direct, local, or long-distance

Signalling molecules are diverse in structure and solubility

Signalling consists of three steps
Signal reception
Signal transduction
Signal response

Ligand-ion channels and GPCRs are examples of membrane-
bound receptors