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Signal Pathways in Cell Migration and Adhesion

Signal Pathways in Cell Migration and Adhesion. Sam Polak 28 April 2008. Cell Migration: Integrating Signals from Front to Back. Ridley A, Schwartz M, Burridge K, Firtel R, Ginsberg M, Borisy G, Parsons J, Horwitz A Science (302) 5 December 2003 1704-1709. Overview. Migration Cycle

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Signal Pathways in Cell Migration and Adhesion

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  1. Signal Pathways in Cell Migration and Adhesion Sam Polak 28 April 2008

  2. Cell Migration: Integrating Signals from Front to Back Ridley A, Schwartz M, Burridge K, Firtel R, Ginsberg M, Borisy G, Parsons J, Horwitz A Science (302) 5 December 2003 1704-1709

  3. Overview • Migration Cycle • Components of migration • Polarization • Integrins (yes, again) • Summary

  4. Migration Cycle Initial Response: Polarization Extend lamellipodia or filopodia Disassemble at back Back Front

  5. Components of Migration Lamellipodia Actin • Barbed and pointed ends • Dendritic vs Parallel • Proteins

  6. Components of Migration

  7. Components of Migration

  8. Components of Migration Filopodial Actin • Treadmilling • Ena/VASP • Fascin http://www.biol.vt.edu/faculty/kuhn/images/TIRFpoly01.gif

  9. Components of Migration Rho Family Guanosine triphosphate binding proteins • RhoG activates Rac-GEF activates Rac • Rac actives WAVE • Cdc42 activates WASP End results in activation of Arp 2/3 Positive or negative feedback to Rho-GTPases

  10. Polarization • Cdc 42 • PI3Ks and PTEN • Rac activation • Defining the tail

  11. Polarization Cdc42 • Located in front of cell • Localizes microtubule-organizing center (MTOC) and Golgi apparatus • Positive feedback loop with target PAK1

  12. Polarization PI3Ks and PTEN • Gradient amplifiers via PIP3 and PI(3,4)P2 • Off-set each other • Feedback loops between PI3K, PTEN, and Cdc42

  13. Polarization Rac Activation • Stimulate recruitment/activation of PI3Ks • Microtubules and Rac form activation/stability loop • Integrins and Rac form activation/recruitment loop

  14. Polarization Defining the Tail – Rho and Rac • Rho stabilizes microtubules • Rho and Rac mutually antagonistic • Exceptions • Rac involved in tail detachments • Rho involved in Rac activation

  15. Integrins • Integrin affinity • Formation of adhesions • Tractional forces • Adhesion disassembly in front • Adhesion disassembly in rear

  16. Integrins Integrin Affinity • Preferentially localize to leading edge • Binding of ligands leads to conformational changes • Posttranslational modification

  17. Integrins Formation of Adhesions • Migration rate influences integrin clusters • Focal complexes and focal adhesions • Rac and Cdc42 • Component kinetics

  18. Integrins Tractional Forces • Traction sites and mechanosensors • Adhesion strength determined by • Substrate ligand density • Adhesion ligand receptor density • Receptor affinity • Migrating cells vs more stationary cells • Transmitted force regulated by Myosin II

  19. Integrins Tractional Forces Phosphorlyation [Ca2+] Rho-GTP MLCK ROCK Phosphorlyation MLC Phosphorlyation MLC Phosphatase Myosin II

  20. Integrins Adhesion disassembly at the front • Disassembly vs maturation • Targeting and microtubules • Kinases and phosphatases • FAK and Src/Cas and Crk/Rac-GEFs

  21. Integrins Adhesion disassembly at the back • Tethering • Myosin II and retraction • FAK, Src, Calcium

  22. Summary

  23. Summary

  24. Summary

  25. Arf6 and microtubules in adhesion-dependent trafficking of lipid rafts Balasubramanian N, Scott D, Castle D, Casanova J, and Schwartz M Nature Cell Biology (9) 18 November 2007 1381-1390

  26. Overview • Lipid rafts and markers • Raft relationship with cytoskeletan • Raft localization after endocytosis • Arf6 and raft trafficking • Arf6 and Rac1 • Arf6 and adhesion • Microtubules and raft trafficking • Discussion/Conclusions

  27. Lipid Rafts and Markers • Modulate signalling pathways • Endocytosed via caveolae • GTPase Arf6 as a regulator • Raft marker CTxB

  28. Raft Relationship with Cytoskeletan • Addition of Latrunculin or Nocodazole • Addition of CTxB before or after detachment • Gamma-tubulin staining CTxB labeled while attached, gamma-tubulin stained CTxB labelled while attached CTxB labelled after detached

  29. Raft Localization after Endocytosis Golgi Investigation • GM130 colocalization • Befeldin A (BFA) – dispersion inducer • Protein kinase D mutant – protein movement blocker

  30. Raft Localization after Endocytosis Golgi Investigation – GM130

  31. Raft Localization after Endocytosis Golgi Investigation – Brefeldin A Localization Spreading

  32. Raft Localization after Endocytosis Golgi Investigation – Protein Kinase D Overlap of VSV and CTxB in Golgi

  33. Raft Localization after Endocytosis SER Investigation

  34. Raft Localization after Endocytosis Recycling Endosome Investigation – Rab11

  35. Raft Localization after Endocytosis Recycling Endosome Investigation – Tf

  36. Raft Localization after Endocytosis Recycling Endosome Investigation – Rab11

  37. Arf6 and Raft Trafficking • Arf6 regulates vesicle trafficking and Rac1 movement • Recycling endosomes and in lamellipodia Recycling Endosomes Lamellipodia

  38. Arf6 and Raft Trafficking • Arf6 and cell spreading • WT and caveolin -/-

  39. Arf6 and Raft Trafficking • Arf6 only involved in raft exocytosis • Cav -/- control

  40. Arf6 and Rac1 • Compare WT and Cav1 -/- • Suspension and replating

  41. Arf6 and Adhesion Adhesion regulation of Arf6

  42. Arf6 and Adhesion Arf6 recycling power

  43. Arf6 and Adhesion Arf6 recycling power

  44. Microtubules and Raft Trafficking MTs and raft components colocalize

  45. Microtubules and Raft Trafficking • WT and Cav1 -/- • Addition of nocodazole • Attached • 90 minutes in suspension • Label with CTxB • 0 minute of suspension • 90 minute of suspension

  46. Microtubules and Raft Trafficking WT Nocodazole spreading

  47. Microtubules and Raft Trafficking WT Nocodazole CTxB

  48. Microtubules and Raft Trafficking • Cav1 -/- Nocodazole

  49. Microtubules and Raft Trafficking Cav1 -/- Nocodazole CTxB

  50. Conclusions • Adhesion recycling of lipid rafts is Arp6 dependent; and Rab11, Rab22, and caveolin independent; microtubules and also involved • Arp6 gets raft to the membrane, but additional steps are needed to get the raft to the surface • Cell detachment sends rafts to recycling endosomes • Rac1 requires rafts, Arp6, and MTs for localization and activation

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