Videos

Navigating Biochemical Pathways for Cell Polarization and Motility (A Personal Journey)

Presenter
January 11, 2017
MBI
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Abstract
Many cell types, including cells of the immune system, are able to polarize and crawl in response to chemical or mechanical stimuli. In this way, they can perform vital functions such as immune surveillance, wound healing, and tissue development. I will describe our efforts to understand the underlying biochemistry governing the initial direction sensing, polarization, cell shape change, and motility. While much of the biology is undergoing rapid discovery, we have found that mathematical ideas supply additional tools. Such tools help to decipher underlying mechanism, to weed between competing hypotheses, and to suggest new experimental tests. On the same journey, we also encountered some new and interesting mathematics.
Supplementary Materials
Timecodes
01:05
Navigating Biochemical Pathways for Cell Polarization and Motility
01:05
Navigating Biochemical Pathways for Cell Polarization and Motility
01:20
Important People
01:20
Important People
02:36
Hans Meinhardt & Lee A Segel
02:36
Hans Meinhardt & Lee A Segel
03:03
Chemotaxis
03:03
Chemotaxis
03:31
Reaction-Diffusion Equation
03:31
Reaction-Diffusion Equation
04:00
Fisher's RD Equation
04:00
Fisher's RD Equation
04:29
Bistable RD Equation
04:29
Bistable RD Equation
04:56
Traveling Wave Solution
04:56
Traveling Wave Solution
05:21
Pattern Formation (in RD Sys)
05:21
Pattern Formation (in RD Sys)
06:18
Pretty Pattern
06:18
Pretty Pattern
06:39
Simple Pattern
06:39
Simple Pattern
06:57
What is the biological problem and why it is important
06:57
What is the biological problem and why it is important
07:09
Neutrophil Chasing Bacterium
07:09
Neutrophil Chasing Bacterium
08:11
Step 1: Cell Polarization
08:11
Step 1: Cell Polarization
08:40
Cell Polarization Model (1974)
08:40
Cell Polarization Model (1974)
09:09
Step 2: Cell Motility
09:09
Step 2: Cell Motility
09:26
Cell Motility
09:26
Cell Motility
09:40
Cell Motility (cont.)
09:40
Cell Motility (cont.)
10:18
Cell Motility
10:18
Cell Motility
10:38
Actin at the Front Edge
10:38
Actin at the Front Edge
11:04
Models for Actin-Powered Cell
11:04
Models for Actin-Powered Cell
12:00
Cell Polarization Proteins
12:00
Cell Polarization Proteins
12:25
Cell Polarization Proteins
12:25
Cell Polarization Proteins
12:49
Cell Polarization
12:49
Cell Polarization
13:25
Question Break
13:25
Question Break
13:41
Question: Is actin based motility is really unique or are there other cell that can move in other ways as well?
13:41
Question: Is actin based motility is really unique or are there other cell that can move in other ways as well?
14:45
Important Pattern: Cell Polarization
14:45
Important Pattern: Cell Polarization
15:16
What properties of these Small GTPases lead to their chemical polarization?
15:16
What properties of these Small GTPases lead to their chemical polarization?
15:32
Simplified Geometry
15:32
Simplified Geometry
16:00
How can we explain GTPase pattern formation in ID (across cell diameter)?
16:00
How can we explain GTPase pattern formation in ID (across cell diameter)?
16:38
Rho GTPasses: Crosstalk
16:38
Rho GTPasses: Crosstalk
17:19
Traveling Waves, but not Robust Polarization
17:19
Traveling Waves, but not Robust Polarization
17:49
Small GTPases: Cycling
17:49
Small GTPases: Cycling
18:14
Active Forms Bind to Membrane
18:14
Active Forms Bind to Membrane
18:45
Include Inactive Forms of GTPases
18:45
Include Inactive Forms of GTPases
19:10
Wave Stalls to Form Polarized Cell
19:10
Wave Stalls to Form Polarized Cell
19:27
Initial Stimulus
19:27
Initial Stimulus
19:42
Final Robust Polarization
19:42
Final Robust Polarization
19:58
GTPases Signaling to Actin
19:58
GTPases Signaling to Actin
20:27
Cell Shape Sequence
20:27
Cell Shape Sequence
20:47
Additional Layers
20:47
Additional Layers
21:06
Rac and Rho
21:06
Rac and Rho
21:31
What makes this happen?
21:31
What makes this happen?
22:00
Caricature
22:00
Caricature
22:39
Positive Feedback
22:39
Positive Feedback
23:03
100-1000 Fold Difference in Rate of Diffusion
23:03
100-1000 Fold Difference in Rate of Diffusion
23:21
Simplified Geometry
23:21
Simplified Geometry
23:55
RD Model
23:55
RD Model
24:25
Rescaled (There is a Small Parameter)
24:25
Rescaled (There is a Small Parameter)
24:53
Stimulus Initiates Wave
24:53
Stimulus Initiates Wave
25:22
Using Up Inactive Form
25:22
Using Up Inactive Form
25:24
Wave Stalls by Substrate Depletion
25:24
Wave Stalls by Substrate Depletion
25:36
Comparison
25:36
Comparison
26:04
Comparison
26:04
Comparison
26:32
Bifurcation Analysis
26:32
Bifurcation Analysis
27:32
GTPase Cycling
27:32
GTPase Cycling
28:02
Question Break
28:02
Question Break
28:10
Question: Do you need non-linear kinetics to obtain robust polarization?
28:10
Question: Do you need non-linear kinetics to obtain robust polarization?
29:05
More Recent: Shortcuts to Analysis
29:05
More Recent: Shortcuts to Analysis
30:38
Local Perturbation Analysis
30:38
Local Perturbation Analysis
31:33
Basal Activation Rate Diagram
31:33
Basal Activation Rate Diagram
31:45
Basal Activation Rate Diagram (cont.)
31:45
Basal Activation Rate Diagram (cont.)
32:17
New Regime Discovered
32:17
New Regime Discovered
33:03
Initial Conditions
33:03
Initial Conditions
33:28
Evolve Differently
33:28
Evolve Differently
33:32
Three Coexisting Spatial SS
33:32
Three Coexisting Spatial SS
33:54
Connection with Experiments
33:54
Connection with Experiments
33:59
Rae Activation Drives Cell Polarity
33:59
Rae Activation Drives Cell Polarity
34:50
Experiment and Model
34:50
Experiment and Model
35:26
Cell Response
35:26
Cell Response
35:51
Model and Experiment
35:51
Model and Experiment
36:37
Single Cell Wound Healing
36:37
Single Cell Wound Healing
37:22
Reconstruct Details of Signaling Network
37:22
Reconstruct Details of Signaling Network
37:45
Expts Model
37:45
Expts Model
38:21
Model Accounts for Expt Data
38:21
Model Accounts for Expt Data
38:50
Melanoma Cell Motility
38:50
Melanoma Cell Motility
39:52
Orientation Angle
39:52
Orientation Angle
40:09
Rac and Rho
40:09
Rac and Rho
40:44
ECM-Cell Contact and Feedback
40:44
ECM-Cell Contact and Feedback
41:50
ECM-Cell Contact and Feedback (cont.)
41:50
ECM-Cell Contact and Feedback (cont.)
42:02
Competition of Two Lamellipods
42:02
Competition of Two Lamellipods
42:10
... With Signaling in Each One
42:10
... With Signaling in Each One
42:18
... Causing Cycles of Expansion/Contraction
42:18
... Causing Cycles of Expansion/Contraction
42:28
... First in One Lamellipod then in the Other
42:28
... First in One Lamellipod then in the Other
42:37
Model Explains Cell Behaviors
42:37
Model Explains Cell Behaviors
43:01
Future Perspectives
43:01
Future Perspectives
43:31
Conclusions
43:31
Conclusions
44:08
Thanks
44:08
Thanks
44:46
Question: Would it be feasible to use Eric Betzig's super resolved fluorescent microscopy to show actual actin-myosin polarization rates to establish parameter values for this model?
44:46
Question: Would it be feasible to use Eric Betzig's super resolved fluorescent microscopy to show actual actin-myosin polarization rates to establish parameter values for this model?
46:09
Question: Is cell polarization truly unidirectional or is it possible that there are stochastic bidirectional events occurring as well?
46:09
Question: Is cell polarization truly unidirectional or is it possible that there are stochastic bidirectional events occurring as well?