Transcript Ch 11 - Phillips Scientific Methods

Cell Communication
*Use THIS copy for Unit 4
CHAPTER 11
Cell Communication
Warm-Up
1. Why do you communicate?
2. How do you communicate?
3. How do you think cells communicate?
4. Do you think bacteria can communicate?
Explain.
Warm-Up
1. Compare the structure & function of these receptor
proteins: GPCR, tyrosine kinase and ligand-gated ion
channels.
2. What is a second messenger? What are some
examples of these molecules?
3. What are the possible responses to signal
transduction in a cell?
Do bacteria communicate?
Bonnie Bassler on How Bacteria “Talk”
Video Questions:
1. Why are scientists studying how bacteria (and not just
human cells) communicate?
2. What is quorum sensing?
3. Describe how Vibrio fischeri use quorum sensing in
squid.
4. According to Bonnie Bassler (Princeton University),
what are scientists hoping to use as the next class of
antibiotics?
Cell Signaling
Animal cells communicate by:
 Direct contact (gap junctions)
 Secreting local regulators
(growth factors,
neurotransmitters)
 Long distance (hormones)
Cell Signaling Examples
3 Stages of Cell Signaling:
1. Reception: Detection of a signal molecule
(ligand) coming from outside the cell
2. Transduction: Convert signal to a form that
can bring about a cellular response
3. Response: Cellular response to the signal
molecule
Video: Cell Signaling Basics (Chapman)
https://www.youtube.com/watch?v=8FJkjiNRLh8
**Note- Signal Transduction is defined as a process that
converts a signal on cell’s surface to a specific cellular
response in a series of steps
Reception
Transduction
Response
1. Reception
 Binding between signal molecule (ligand) +
receptor is highly specific.
 Types of Receptors:
a) Plasma membrane receptor
 water-soluble ligands
b) Intracellular receptors (cytoplasm, nucleus)


hydrophobic or small ligands
Eg. testosterone or nitric oxide (NO)
 Ligand binds to receptor protein  protein
changes SHAPE  initiates transduction signal
Plasma Membrane Receptors
G-Protein
Coupled
Tyrosine Kinase
Receptor (GPCR)
Ligand-Gated
Ion Channels
G-Protein-Coupled Receptor
Short video
 https://www.youtube.com/watch?v=xT0mAQ4726s
(G Protein Receptor Activation Video by Z Abrahim)
**Others on youtube: (Chapman)
https://www.youtube.com/watch?v=On8CGKDfXd8
Others on Cell Communication: Garland Science Videos;
Kahn Academy
https://www.youtube.com/watch?v=ZBSo_GFN3qI
*This one is more complex, but the explanation is very
good
G-Protein-Coupled Receptor
Plasma Membrane Receptors
G-Protein Coupled
Receptor (GPCR)
7 transmembrane
segments in
membrane
G protein + GTP
activates enzyme
 one cellular
response
Tyrosine Kinase
Ligand-Gated Ion
Channels
Receptor Tyrosine Kinase
 https://www.youtube.com/watch?v=ObrsQl-vPA4
(Receptor Tyrosine Kinase by HeyNow 1003)
**Others recommended: (Chapman)
https://www.youtube.com/watch?v=J_vdVcuzi1U
Receptor Tyrosine Kinase
Plasma Membrane Receptors
G-Protein
Coupled
Tyrosine Kinase
Receptor (GPCR)
Attaches (P) to
tyrosine
Activate multiple
cellular responses
at once
Ligand-Gated
Ion Channels
Ligand Gated Ion Channels
 Short video: Ion Channel Receptors (HeyNow1103):
 Recommended: (Chapman)
https://www.youtube.com/watch?v=USKkLQYhuyY&ind
ex=4&list=PLyV_IM5FlqWpW17e8xRPaWUQip2o-uPC
Ligand-Gated Ion Channel
Plasma Membrane Receptors
G-Protein
Coupled
Tyrosine Kinase
Receptor (GPCR)
Ligand-Gated
Ion Channels
Signal on receptor
changes shape
Regulate flow of
specific ions
(Ca2+, Na+)
Intracellular Receptors
 Molecules that are small enough or hydrophobic and
pass through the membrane - directly activate
intracellular receptors in the cytoplasm or nucleus of
target cell
Intracellular Receptors
 Quick and easy:
https://www.youtube.com/watch?v=upEV52vdhuk
 A little more detailed:
https://www.youtube.com/watch?v=Nm9u4lNCPyM
 Both are by Biology/ Medicine
 *Chapman has videos on youtube for this entire unit.
Search John Chapman Biology. Very good at
explaining the info in your book.
2. Transduction- Overview (primarily
next test)
 Cascades of molecular interactions relay
signals from receptors  target molecules
 Protein kinase: enzyme that
phosphorylates and activates proteins at
next level
 Phosphorylation cascade: enhance and
amplify signal
*See next slide for overview, which you should be able to
generally recognize on this test.
CW- Videos
 Bozeman AP Biology Video #36 (Evolution of Cell
Communication): Answer these questions in your
journal: 1- What is quorum sensing?; 2- Explain how
this process works
 Bozeman AP Video #38. Watch and complete the
review sheet
Transduction
 Specific mechanisms will be on Test #4, along
with the remainder of Ch 11, including
apoptosis
Second Messengers
 small, nonprotein molecules/ions that can relay
signal inside cell
 Eg. cyclic AMP (cAMP), calcium ions (Ca2+),
inositol triphosphate (IP3)
cAMP
 cAMP = cyclic adenosine monophosphate
 GPCR  adenylyl cyclase (convert ATP 
cAMP)  activate protein kinase A
3. Response
 Regulate protein synthesis
by turning on/off genes in
nucleus (gene expression)
 Regulate activity of proteins
in cytoplasm
An Example of Cell
Communication
http://learn.genetics.utah.edu/content/begin/cells/cellcom/
Signal Transduction Pathway
Problems/Defects:
Examples:
 Diabetes
 Cholera
 Autoimmune disease
 Cancer
 Neurotoxins, poisons, pesticides
 Drugs (anesthetics, antihistamines, blood
pressure meds)
Cholera
 Toxin modifies G-protein
 Disease acquired by
drinking contaminated
water (w/human feces)
 Bacteria (Vibrio cholerae)
colonizes lining of small
intestine and produces
toxin
involved in regulating salt &
water secretion
 G protein stuck in active
form  intestinal cells
secrete salts, water
 Infected person develops
profuse diarrhea and could
die from loss of water and
salts
Viagra
 Used as treatment for erectile dysfunction
 Inhibits hydrolysis of cGMP  GMP
 Prolongs signal to relax smooth muscle in
artery walls; increase blood flow to penis
Viagra inhibits cGMP breakdown
Apoptosis = cell suicide
 Cell is dismantled and digested
 Triggered by signals that activate cascade of
“suicide” proteins (caspase)
 Why?
 Protect neighboring cells from damage
 Animal development & maintenance
 May be involved in some diseases
(Parkinson’s, Alzheimer’s)
Apoptosis of a human white blood cell
Left: Normal WBC
Right: WBC undergoing apoptosis – shrinking and forming lobes
(“blebs”)
Effect of apoptosis during paw
development in the mouse