1. Chapter 11
Cell Communication
Lecture adapted from:

2. Figure 11.1
Figure 11.1 How does cell signaling trigger the desperate flight of this gazelle?

3. Communication in general
Transmission, reception, and response to a signal
Stimulus
Response

4. Think of all the ways YOU communicate

5. Classifying communication routes
Direct
Local
Long distance

6. Cellular Communication
Direct contact – neighboring cells
Local – cells within the general region
“Long” distance

7. Steps of Cellular Communication
Reception: “detection” of signal by a receptor molecule on a target cell (or receptor molecule within cell, depending on type of signal)
Transduction: information changed into another form
Response: specific cellular response elicited

9. Labeling
Cell
Signaling molecule (ligand)
Receptor
Membrane Channel

10. Definitions
LIGAND: molecule that specifically binds to another molecule (usually a larger one)
Generally causes a receptor protein to undergo a change in conformation
Can come in two major types:
Water soluble/large: non-membrane permeable
Require a membrane protein receptor
Hydrophobic/small: membrane permeable
Require an intracellular receptor

11. Labeling, part two Autocrine Endocrine Juxtacrine Paracrine
Auto = self
Endocrine
Endo = within
Juxtacrine
Juxta = beside, next to, touching
Paracrine
Para = nearby

12. Cell Communication POGIL: problems 8 and 9
Read through the examples and determine what type of cell communication is featured.

13. Pathway with Friends Activity
Groups of 6: must be 6!
Each person gets a card. Read your card. Do not share what your card with others. Do not read the cards of others.
Do #1 on the card.
Proceed to #2.

16. EXTRACELLULAR FLUID CYTOPLASM Plasma membrane 1 Reception Receptor
Figure
EXTRACELLULAR FLUID
CYTOPLASM
Plasma membrane 1
Reception
Receptor
Figure 11.6 Overview of cell signaling.
Signaling molecule

17. Relay molecules in a signal transduction pathway
Figure
EXTRACELLULAR FLUID
CYTOPLASM
Plasma membrane 1
Reception 2
Transduction
Receptor
Relay molecules in a signal transduction pathway
Figure 11.6 Overview of cell signaling.
Signaling molecule

18. Relay molecules in a signal transduction pathway
Figure
EXTRACELLULAR FLUID
CYTOPLASM
Plasma membrane 1
Reception 2
Transduction 3
Response
Receptor
Activation of cellular response
Relay molecules in a signal transduction pathway
Figure 11.6 Overview of cell signaling.
Signaling molecule

19. Pathway with Friends Activity
What happened?
How did you recognize where to go?
How does this model cell communication?
What effect did joining the pathway have on you?
What problems did you encounter?
What would have happened if someone didn’t do their job (follow instructions) or weren’t there?

20. To note…
Process helps ensure that crucial activities occur in the right cells at the right time
Coordinated with other cells of organism
“Eavesdropping” rarely occurs in cells

21. Steps of Cellular Communication
Reception: “detection” of signal by a receptor molecule on a target cell (or receptor molecule within cell, depending on type of signal). PRIMARY MESSENGER. Signal does not participate in the actual pathway. In most cases, doesn’t even get into the cell!
Transduction: information changed into another form – usually involves the changing of shapes of relay molecules. SECONDARY MESSENGERS
Response: specific cellular response elicited

22. Types of Signals and their Receptors
Large, polar: non-membrane friendly. Requires a plasma membrane protein receptor.
G protein linked receptors
Receptor tyrosine kinase
Ion channel receptors
Small, nonpolar: membrane friendly. Bind with an INTRACELLULAR receptor.

23. Concept 11.2: Reception: A signaling molecule binds to a receptor protein, causing it to change shape
The binding between a signal molecule (ligand) and receptor is highly specific
A shape change in a receptor is often the initial transduction of the signal
Most signal receptors are plasma membrane proteins
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24. G protein-linked receptors (GPLRs) are the largest family of cell-surface receptors
A GPLR is a plasma membrane receptor that works with the help of a G protein
The G protein acts as an on/off switch: If GDP is bound to the G protein, the G protein is inactive. If GTP is attached = active.
© 2011 Pearson Education, Inc.

25. G protein-coupled receptor Plasma membrane Activated receptor
Figure 11.7b
G protein-coupled receptor
Plasma membrane
Activated receptor
Signaling molecule
Inactive enzyme
GTP
GDP
GDP
CYTOPLASM
G protein (inactive)
Enzyme
GTP 1 2
GDP
Activated enzyme
Figure 11.7 Exploring: Cell-Surface Transmembrane Receptors
GTP
GDP
P i 3
Cellular response 4

26. Reminder: polarity issues
Figure 11.7a
Signaling molecule binding site
Reminder: polarity issues
Segment that interacts with G proteins
Figure 11.7 Exploring: Cell-Surface Transmembrane Receptors
G protein-coupled receptor

27. G protein-coupled receptor Plasma membrane Activated receptor
Figure 11.7b
G protein-coupled receptor
Plasma membrane
Activated receptor
Signaling molecule
Inactive enzyme
GTP
GDP
GDP
CYTOPLASM
G protein (inactive)
Enzyme
GTP 1 2
GDP
Activated enzyme
Figure 11.7 Exploring: Cell-Surface Transmembrane Receptors
GTP
GDP
P i 3
Cellular response 4

28. G proteins… Also act as GTPase
Hydrolyzes bound GTP to GDP
G protein goes inactive
Signaling pathway shut down
Cholera, pertussis, botulism: caused by bacterial infections producing toxins that interfere with G protein activity
60% of all meds today exert effects on G protein pathways

29. Abnormal functioning of RTKs is associated with many types of cancers
Receptor tyrosine kinases (RTKs) are membrane receptors that attach phosphates to tyrosines
A receptor tyrosine kinase can trigger multiple signal transduction pathways at once
Abnormal functioning of RTKs is associated with many types of cancers
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30. Signaling molecule (ligand) Ligand-binding site
Figure 11.7c
Signaling molecule (ligand)
Ligand-binding site
 helix in the membrane
Signaling molecule
Tyrosines
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
Tyr
CYTOPLASM
Receptor tyrosine kinase proteins (inactive monomers)
Dimer 1 2
Activated relay proteins
Figure 11.7 Exploring: Cell-Surface Transmembrane Receptors
Cellular response 1
Tyr
Tyr P
Tyr
Tyr P
Tyr
Tyr P P
Tyr
Tyr P
Tyr
Tyr P
Tyr
Tyr P P
Cellular response 2
Tyr
Tyr P
Tyr
Tyr P
Tyr
Tyr P
6 ATP
6 ADP P
Activated tyrosine kinase regions (unphosphorylated dimer)
Fully activated receptor tyrosine kinase (phosphorylated dimer)
Inactive relay proteins 3 4

31. Phosphorylated tyrosines
Recognized by specific relay proteins inside the cell
Bind to a specific tyrosine, change shape, and activate
Triggers a transduction pathway

32. A ligand-gated ion channel receptor acts as a gate when the receptor changes shape
When a signal molecule binds as a ligand to the receptor, the gate allows specific ions, such as Na+ or Ca2+, through a channel in the receptor
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33. Signaling molecule (ligand)
Figure 11.7d 1 2 3
Gate closed
Ions
Gate open
Gate closed
Signaling molecule (ligand)
Plasma membrane
Ligand-gated ion channel receptor
Cellular response
Figure 11.7 Exploring: Cell-Surface Transmembrane Receptors

34. Ion flow
Rapidly changes the concentration of the particular ion inside the cell
Triggers response
When ligand dissociates, gate opens/closes and ions return to normal

35. Neurons Neurotransmitter binds as ligand Channels open
Triggers electrical signal that propagates length of receiving cell.
Some gated ion channels are controlled by electrical signals (voltage-gated ion channels)

36. Intracellular Receptors
Intracellular receptor proteins are found in the cytosol or nucleus of target cells
Small or hydrophobic chemical messengers can readily cross the membrane and activate receptors
Examples of hydrophobic messengers are the steroid and thyroid hormones of animals
An activated hormone-receptor complex can act as a transcription factor, turning on specific genes
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37. Hormone (testosterone) EXTRACELLULAR FLUID
Figure
Hormone (testosterone)
EXTRACELLULAR FLUID
Plasma membrane
Receptor protein
DNA
Figure 11.9 Steroid hormone interacting with an intracellular receptor.
NUCLEUS
CYTOPLASM

38. Hormone (testosterone) EXTRACELLULAR FLUID
Figure
Hormone (testosterone)
EXTRACELLULAR FLUID
Plasma membrane
Receptor protein
Hormone- receptor complex
DNA
Figure 11.9 Steroid hormone interacting with an intracellular receptor.
NUCLEUS
CYTOPLASM

39. Hormone (testosterone) EXTRACELLULAR FLUID
Figure
Hormone (testosterone)
EXTRACELLULAR FLUID
Plasma membrane
Receptor protein
Hormone- receptor complex
DNA
Figure 11.9 Steroid hormone interacting with an intracellular receptor.
NUCLEUS
CYTOPLASM

40. Hormone (testosterone) EXTRACELLULAR FLUID
Figure
Hormone (testosterone)
EXTRACELLULAR FLUID
Plasma membrane
Receptor protein
Hormone- receptor complex
DNA
Figure 11.9 Steroid hormone interacting with an intracellular receptor.
mRNA
NUCLEUS
CYTOPLASM

41. Hormone (testosterone) EXTRACELLULAR FLUID
Figure
Hormone (testosterone)
EXTRACELLULAR FLUID
Plasma membrane
Receptor protein
Hormone- receptor complex
DNA
Figure 11.9 Steroid hormone interacting with an intracellular receptor.
mRNA
NUCLEUS
New protein
CYTOPLASM

42. End show here for today

43. Transduction: Bellringer
POGIL, #5-7
Trans- : prefix, across, through, beyond, changing thoroughly

44. Concept 11.3: Transduction: Cascades of molecular interactions relay signals from receptors to target molecules in the cell
usually involves multiple steps
Benefits:
amplify a signal: A few molecules can produce a large cellular response
more opportunities for coordination and regulation of the cellular response
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45. Like falling dominoes, the receptor activates another protein, which activates another, and so on, until the protein producing the response is activated
At each step, the signal is transduced into a different form, usually a shape change in a protein

46. Relay Molecules
The molecules that relay a signal from receptor to response are mostly proteins
Can also be small, nonprotein water soluble molecules (like cyclic AMP) or ions (like Ca 2+) = SECOND MESSENGERS. More on this later
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47. Protein Phosphorylation and Dephosphorylation
In many pathways, the signal is transmitted by a cascade of protein phosphorylations
Protein kinases transfer phosphates from ATP to protein (phosphorylation)
Phosphate groups are negatively charged = causes a slight change in protein shape as R-groups interact with the phosphate group.
Change in shape = activates or deactivates
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48. Protein phosphatases remove the phosphates from proteins, a process called dephosphorylation
This phosphorylation and dephosphorylation system acts as a molecular switch, turning activities on and off or up or down, as required
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49. Activated relay molecule
Figure 11.10
Signaling molecule
Receptor
Activated relay molecule
Inactive protein kinase 1
Active protein kinase 1
Inactive protein kinase 2
ATP
Phosphorylation cascade
ADP
Active protein kinase 2 P PP
P i
Inactive protein kinase 3
Figure A phosphorylation cascade.
ATP
ADP P
Active protein kinase 3 PP
P i
Inactive protein
ATP
ADP P
Active protein
Cellular response PP
P i

50. Activated relay molecule
Figure 11.10a
Activated relay molecule
Inactive protein kinase 1
Active protein kinase 1
Inactive protein kinase 2
ATP
Phosphorylation cascade
ADP
Active protein kinase 2 P PP
P i
Inactive protein kinase 3
ATP
Figure A phosphorylation cascade.
ADP
Active protein kinase 3 P PP
P i
Inactive protein
ATP
ADP P
Active protein PP
P i

51. Small Molecules and Ions as Second Messengers
Signal = pathway’s “first messenger”
Second messengers are small, nonprotein, water-soluble molecules or ions that spread throughout a cell by diffusion
Second messengers participate in pathways initiated by GPLRs and RTKs
Cyclic AMP and calcium ions are common second messengers
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52. Cyclic AMP
Cyclic AMP (cAMP) is one of the most widely used second messengers
Adenylyl cyclase, an enzyme in the plasma membrane, converts ATP to cAMP in response to an extracellular signal
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53. Figure 11.11 Adenylyl cyclase Phosphodiesterase Pyrophosphate AMP
P i
ATP
cAMP
AMP
Figure Cyclic AMP.

54. Adenylyl cyclase Pyrophosphate P P i ATP cAMP Figure 11.11a
Figure Cyclic AMP.
ATP
cAMP

55. Phosphodiesterase AMP cAMP H2O H2O Figure 11.11b
Figure Cyclic AMP.
cAMP
AMP

56. cAMP usually activates protein kinase A, which phosphorylates various other proteins
Further regulation of cell metabolism is provided by G-protein systems that inhibit adenylyl cyclase
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57. First messenger (signaling molecule such as epinephrine)
Figure 11.12
First messenger (signaling molecule such as epinephrine)
Adenylyl cyclase
G protein
G protein-coupled receptor
GTP
ATP
Second messenger
cAMP
Figure cAMP as a second messenger in a G protein signaling pathway.
Protein kinase A
Cellular responses

58. Calcium Ions and Inositol Triphosphate (IP3)
Calcium ions (Ca2+) act as a second messenger in many pathways
Calcium is an important second messenger because cells can regulate its concentration
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59. Endoplasmic reticulum (ER)
Figure 11.13
EXTRACELLULAR FLUID
Plasma membrane
Ca2 pump
ATP
Mitochondrion
Nucleus
CYTOSOL
Ca2 pump
Figure The maintenance of calcium ion concentrations in an animal cell.
Endoplasmic reticulum (ER)
Ca2 pump
ATP
Key
High [Ca2 ]
Low [Ca2 ]

60. A signal relayed by a signal transduction pathway may trigger an increase in calcium in the cytosol
Pathways leading to the release of calcium involve inositol triphosphate (IP3) and diacylglycerol (DAG) as additional second messengers
Change in Ca2+ concentration = activation of proteins – initiates cell response (ex: muscle cell contraction, secretion, cell division)
Animation: Signal Transduction Pathways
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61. Signaling molecule (first messenger)
Figure
EXTRA- CELLULAR FLUID
Signaling molecule (first messenger)
G protein
DAG
GTP
G protein-coupled receptor
PIP2
Phospholipase C
IP3 (second messenger)
IP3-gated calcium channel
Figure Calcium and IP3 in signaling pathways.
Endoplasmic reticulum (ER)
Ca2
CYTOSOL

62. Signaling molecule (first messenger)
Figure
EXTRA- CELLULAR FLUID
Signaling molecule (first messenger)
G protein
DAG
GTP
G protein-coupled receptor
PIP2
Phospholipase C
IP3 (second messenger)
IP3-gated calcium channel
Figure Calcium and IP3 in signaling pathways.
Endoplasmic reticulum (ER)
Ca2
Ca2 (second messenger)
CYTOSOL

63. Signaling molecule (first messenger)
Figure
EXTRA- CELLULAR FLUID
Signaling molecule (first messenger)
G protein
DAG
GTP
G protein-coupled receptor
PIP2
Phospholipase C
IP3 (second messenger)
IP3-gated calcium channel
Figure Calcium and IP3 in signaling pathways.
Various proteins activated
Cellular responses
Endoplasmic reticulum (ER)
Ca2
Ca2 (second messenger)
CYTOSOL

64. Concept 11.4: Response: Cell signaling leads to regulation of transcription or cytoplasmic activities
The cell’s response to an extracellular signal is sometimes called the “output response”
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65. Nuclear and Cytoplasmic Responses
Ultimately, a signal transduction pathway leads to regulation of one or more cellular activities
The response may occur in the cytoplasm or in the nucleus
Many signaling pathways regulate the synthesis of enzymes or other proteins, usually by turning genes on or off in the nucleus
The final activated molecule in the signaling pathway may function as a transcription factor
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66. Inactive transcription factor Active transcription factor
Figure 11.15
Growth factor
Reception
Receptor
Phosphorylation cascade
Transduction
CYTOPLASM
Inactive transcription factor
Active transcription factor
Figure Nuclear responses to a signal: the activation of a specific gene by a growth factor.
Response P
DNA
Gene
NUCLEUS
mRNA

67. Other pathways regulate the activity of enzymes rather than their synthesis
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68. Glucose 1-phosphate (108 molecules)
Figure 11.16
Reception
Binding of epinephrine to G protein-coupled receptor (1 molecule)
Transduction
Inactive G protein
Active G protein (102 molecules)
Inactive adenylyl cyclase
Active adenylyl cyclase (102)
ATP
Cyclic AMP (104)
Inactive protein kinase A
Active protein kinase A (104)
Figure Cytoplasmic response to a signal: the stimulation of glycogen breakdown by epinephrine.
Inactive phosphorylase kinase
Active phosphorylase kinase (105)
Inactive glycogen phosphorylase
Active glycogen phosphorylase (106)
Response
Glycogen
Glucose 1-phosphate (108 molecules)

69. Concept 11.1: External signals are converted to responses within the cell
Microbes provide a glimpse of the role of cell signaling in the evolution of life
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70. Evolution of Cell Signaling
The yeast, Saccharomyces cerevisiae, has two mating types, a and 
Cells of different mating types locate each other via secreted factors specific to each type
A signal transduction pathway is a series of steps by which a signal on a cell’s surface is converted into a specific cellular response
Signal transduction pathways convert signals on a cell’s surface into cellular responses
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71. Yeast cell, mating type a Yeast cell, mating type 
Figure 11.2
 factor
Receptor 1
Exchange of mating factors a 
a factor
Yeast cell,
mating type a
Yeast cell,
mating type  2
Mating a 
Figure 11.2 Communication between mating yeast cells. 3
New a/ cell
a/

72. Pathway similarities suggest that ancestral signaling molecules evolved in prokaryotes and were modified later in eukaryotes
The concentration of signaling molecules allows bacteria to sense local population density
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73. Individual rod-shaped cells
Figure 11.3 1
Individual rod-shaped cells 2
Aggregation in progress
0.5 mm 3
Spore-forming structure (fruiting body)
2.5 mm
Figure 11.3 Communication among bacteria.
Fruiting bodies

74. Individual rod-shaped cells
Figure 11.3a
Figure 11.3 Communication among bacteria. 1
Individual rod-shaped cells

75. Aggregation in progress
Figure 11.3b
Figure 11.3 Communication among bacteria. 2
Aggregation in progress

76. Spore-forming structure (fruiting body)
Figure 11.3c
0.5 mm
Figure 11.3 Communication among bacteria. 3
Spore-forming structure (fruiting body)

77. 2.5 mm Fruiting bodies Figure 11.3d
Figure 11.3 Communication among bacteria.

78. Local and Long-Distance Signaling
Cells in a multicellular organism communicate by chemical messengers
Animal and plant cells have cell junctions that directly connect the cytoplasm of adjacent cells
In local signaling, animal cells may communicate by direct contact, or cell-cell recognition
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79. Gap junctions between animal cells Plasmodesmata between plant cells
Figure 11.4
Plasma membranes
Gap junctions between animal cells
Plasmodesmata between plant cells
(a) Cell junctions
Figure 11.4 Communication by direct contact between cells.
(b) Cell-cell recognition

80. In many other cases, animal cells communicate using local regulators, messenger molecules that travel only short distances
In long-distance signaling, plants and animals use chemicals called hormones
The ability of a cell to respond to a signal depends on whether or not it has a receptor specific to that signal
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81. Figure 11.5
Local signaling
Long-distance signaling
Target cell
Electrical signal along nerve cell triggers release of neurotransmitter.
Endocrine cell
Blood vessel
Neurotransmitter diffuses across synapse.
Secreting cell
Secretory vesicle
Hormone travels in bloodstream.
Target cell specifically binds hormone.
Local regulator diffuses through extracellular fluid.
Target cell is stimulated.
(a) Paracrine signaling
Figure 11.5 Local and long-distance cell signaling by secreted molecules in animals.
(b) Synaptic signaling
(c) Endocrine (hormonal) signaling

82. Neurotransmitter diffuses across synapse. Secreting cell
Figure 11.5a
Local signaling
Target cell
Electrical signal along nerve cell triggers release of neurotransmitter.
Neurotransmitter diffuses across synapse.
Secreting cell
Secretory vesicle
Figure 11.5 Local and long-distance cell signaling by secreted molecules in animals.
Local regulator diffuses through extracellular fluid.
Target cell is stimulated.
(a) Paracrine signaling
(b) Synaptic signaling

83. Long-distance signaling
Figure 11.5b
Long-distance signaling
Endocrine cell
Blood vessel
Hormone travels in bloodstream.
Target cell specifically binds hormone.
Figure 11.5 Local and long-distance cell signaling by secreted molecules in animals.
(c) Endocrine (hormonal) signaling

84. The Three Stages of Cell Signaling: A Preview
Earl W. Sutherland discovered how the hormone epinephrine acts on cells
Sutherland suggested that cells receiving signals went through three processes
Reception
Transduction
Response
Animation: Overview of Cell Signaling
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85. 2-adrenergic receptors Molecule resembling ligand
Figure 11.8
2-adrenergic receptors
Molecule resembling ligand
Plasma membrane
Figure 11.8 Impact: Determining the Structure of a G Protein-Coupled Receptor (GPCR)
Cholesterol

86. Inactive transcription factor Active transcription factor
Figure 11.15
Growth factor
Reception
Receptor
Phosphorylation cascade
Transduction
CYTOPLASM
Inactive transcription factor
Active transcription factor
Figure Nuclear responses to a signal: the activation of a specific gene by a growth factor.
Response P
DNA
Gene
NUCLEUS
mRNA

87. Other pathways regulate the activity of enzymes rather than their synthesis
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88. Glucose 1-phosphate (108 molecules)
Figure 11.16
Reception
Binding of epinephrine to G protein-coupled receptor (1 molecule)
Transduction
Inactive G protein
Active G protein (102 molecules)
Inactive adenylyl cyclase
Active adenylyl cyclase (102)
ATP
Cyclic AMP (104)
Inactive protein kinase A
Active protein kinase A (104)
Figure Cytoplasmic response to a signal: the stimulation of glycogen breakdown by epinephrine.
Inactive phosphorylase kinase
Active phosphorylase kinase (105)
Inactive glycogen phosphorylase
Active glycogen phosphorylase (106)
Response
Glycogen
Glucose 1-phosphate (108 molecules)

89. Signaling pathways can also affect the overall behavior of a cell, for example, changes in cell shape
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90. Wild type (with shmoos) Fus3 formin CONCLUSION
Figure 11.17
RESULTS
Wild type (with shmoos)
Fus3
formin
CONCLUSION 1
Mating factor activates receptor.
Mating factor
Shmoo projection forming
G protein-coupled receptor
Formin P
Fus3
Actin subunit
GTP P
GDP 2
Phosphory- lation cascade
G protein binds GTP and becomes activated.
Formin
Formin
Figure Inquiry: How do signals induce directional cell growth during mating in yeast? P 4
Fus3 phos- phorylates formin, activating it.
Microfilament
Fus3
Fus3 P 5
Formin initiates growth of microfilaments that form the shmoo projections. 3
Phosphorylation cascade activates Fus3, which moves
to plasma membrane.

91. Wild type (with shmoos)
Figure 11.17a
Figure Inquiry: How do signals induce directional cell growth during mating in yeast?
Wild type (with shmoos)

92. Figure 11.17b
Figure Inquiry: How do signals induce directional cell growth during mating in yeast?
Fus3

93. Figure 11.17c
Figure Inquiry: How do signals induce directional cell growth during mating in yeast?
formin

94. Fine-Tuning of the Response
There are four aspects of fine-tuning to consider
Amplification of the signal (and thus the response)
Specificity of the response
Overall efficiency of response, enhanced by scaffolding proteins
Termination of the signal
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95. Signal Amplification Enzyme cascades amplify the cell’s response
At each step, the number of activated products is much greater than in the preceding step
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96. The Specificity of Cell Signaling and Coordination of the Response
Different kinds of cells have different collections of proteins
These different proteins allow cells to detect and respond to different signals
Even the same signal can have different effects in cells with different proteins and pathways
Pathway branching and “cross-talk” further help the cell coordinate incoming signals
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97. Figure 11.18
Signaling molecule
Receptor
Relay molecules
Activation or inhibition
Response 1
Response 2
Response 3
Response 4
Response 5
Figure The specificity of cell signaling.
Cell A. Pathway leads to a single response.
Cell B. Pathway branches, leading to two responses.
Cell C. Cross-talk occurs between two pathways.
Cell D. Different receptor leads to a different response.

98. Cell A. Pathway leads to a single response.
Figure 11.18a
Signaling molecule
Receptor
Relay molecules
Figure The specificity of cell signaling.
Response 1
Response 2
Response 3
Cell A. Pathway leads to a single response.
Cell B. Pathway branches, leading to two responses.

99. Activation or inhibition
Figure 11.18b
Activation or inhibition
Figure The specificity of cell signaling.
Response 4
Response 5
Cell C. Cross-talk occurs between two pathways.
Cell D. Different receptor leads to a different response.

100. Signaling Efficiency: Scaffolding Proteins and Signaling Complexes
Scaffolding proteins are large relay proteins to which other relay proteins are attached
Scaffolding proteins can increase the signal transduction efficiency by grouping together different proteins involved in the same pathway
In some cases, scaffolding proteins may also help activate some of the relay proteins
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101. Three different protein kinases
Figure 11.19
Signaling molecule
Plasma membrane
Receptor
Three different protein kinases
Figure A scaffolding protein.
Scaffolding protein

102. Termination of the Signal
Inactivation mechanisms are an essential aspect of cell signaling
If ligand concentration falls, fewer receptors will be bound
Unbound receptors revert to an inactive state
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103. Concept 11.5: Apoptosis integrates multiple cell-signaling pathways
Apoptosis is programmed or controlled cell suicide
Components of the cell are chopped up and packaged into vesicles that are digested by scavenger cells
Apoptosis prevents enzymes from leaking out of a dying cell and damaging neighboring cells
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104. Figure 11.20
Figure Apoptosis of a human white blood cell.
2 m

105. Apoptosis in the Soil Worm Caenorhabditis elegans
Apoptosis is important in shaping an organism during embryonic development
The role of apoptosis in embryonic development was studied in Caenorhabditis elegans
In C. elegans, apoptosis results when proteins that “accelerate” apoptosis override those that “put the brakes” on apoptosis
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106. Ced-9 protein (active) inhibits Ced-4 activity
Figure 11.21
Ced-9 protein (active) inhibits Ced-4 activity
Ced-9 (inactive)
Cell forms blebs
Death- signaling molecule
Mitochondrion
Active Ced-4
Active Ced-3
Other proteases
Ced-4
Ced-3
Nucleases
Receptor for death- signaling molecule
Activation cascade
Figure Molecular basis of apoptosis in C. elegans.
Inactive proteins
(a) No death signal
(b) Death signal

107. Ced-9 protein (active) inhibits Ced-4 activity
Figure 11.21a
Ced-9 protein (active) inhibits Ced-4 activity
Mitochondrion
Figure Molecular basis of apoptosis in C. elegans.
Ced-4
Ced-3
Receptor for death- signaling molecule
Inactive proteins
(a) No death signal

108. Death- signaling molecule
Figure 11.21b
Ced-9 (inactive)
Cell forms blebs
Death- signaling molecule
Active Ced-4
Active Ced-3
Other proteases
Figure Molecular basis of apoptosis in C. elegans.
Nucleases
Activation cascade
(b) Death signal

109. Apoptotic Pathways and the Signals That Trigger Them
Caspases are the main proteases (enzymes that cut up proteins) that carry out apoptosis
Apoptosis can be triggered by
An extracellular death-signaling ligand
DNA damage in the nucleus
Protein misfolding in the endoplasmic reticulum
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110. Apoptosis evolved early in animal evolution and is essential for the development and maintenance of all animals
Apoptosis may be involved in some diseases (for example, Parkinson’s and Alzheimer’s); interference with apoptosis may contribute to some cancers
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111. Cells undergoing apoptosis
Figure 11.22
Cells undergoing apoptosis
Space between digits
1 mm
Interdigital tissue
Figure Effect of apoptosis during paw development in the mouse.

112. Interdigital tissue Figure 11.22a
Figure Effect of apoptosis during paw development in the mouse.

113. Cells undergoing apoptosis
Figure 11.22b
Cells undergoing apoptosis
Figure Effect of apoptosis during paw development in the mouse.

114. Space between digits 1 mm Figure 11.22c
Figure Effect of apoptosis during paw development in the mouse.

115. Activation of cellular response
Figure 11.UN01 1
Reception 2
Transduction 3
Response
Receptor
Activation of cellular response
Relay molecules
Signaling molecule
Figure 11.UN01 Summary figure, Concept 11.1

116. Figure 11.UN02
Figure 11.UN02 Appendix A: answer to Test Your Understanding, question 9

117. http://teachers. natickps. org/webpages/npsdhinnenkamp/resources. cfm