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Vav Deficient Macrophages: The Roles of Rac and Rho in Cell Migration

Vav Deficient Macrophages: The Roles of Rac and Rho in Cell Migration. Vav-Vav-voom, let’s Rac ’n’ Rho! Julia Sero Ty Thomson 12/10/2002. Models of Macrophage Migration. Hematopoietic cells migrate during development and immune response Macrophage migration mechanism is not well understood

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Vav Deficient Macrophages: The Roles of Rac and Rho in Cell Migration

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  1. Vav Deficient Macrophages: The Roles of Rac and Rho in Cell Migration Vav-Vav-voom, let’s Rac ’n’ Rho! Julia Sero Ty Thomson 12/10/2002

  2. Models of Macrophage Migration • Hematopoietic cells migrate during development and immune response • Macrophage migration mechanism is not well understood • Genetic knockout is a molecular biological tool to investigate gene product functions • Modeling is an engineering tool to help direct research and verify hypotheses

  3. Vav- Cell Phenotype • Vav: guanine nucleotide exchange factor and adaptor protein (3 isoforms) • Vav1>Vav3>>Vav2 • Activates Rho GTPases (Rac, Rho, Cdc42) • Involved in signal transduction from integrins and other receptors via multiple pathways • Vav-deficient macrophages show migration defect • Vav1-/-;Vav3-/- extend multiple lamellipodia but do not migrate in wound healing assay • Short, narrow lamellipodia • Fail to translocate nuclei or retract tails

  4. Movies: Wild type: Double knock out:

  5. Vav pathways Integrin Src Syk Active Vav F-actin Rac Rho F-actin MAPK/ERK pathway ROK Calpain Activation Myosin Phosphorylation

  6. Hypothesis • Local signals mediated by Vav complexes crucial for downstream effects • Rac versus Rho type adhesions: • Dynamic and propulsive (calpain) • Stable and anchoring (myosin contraction) • Balance of signal outputs is necessary for efficient migration • DKO cells have an imbalance between focal adhesion turnover and intracellular contraction due to loss of Vav

  7. MAPK Pathway (Modified from Bhalla et al., 2002)

  8. Myosin Activation Pathway Active Vav GDP-Rho GTP-Rho GTP-Rho/ ROK ROK MLC MLC* GTP-Rho/ MBS MBS

  9. Major Model Assumptions • Vav1, Vav2 and Vav3 all have the same activity • Localized signaling can studied, and the effects summed to account for overall behavior

  10. Nuclear MAPK * Concentration Profile

  11. Normalized Active Calpain Levels

  12. Normalized Activated Myosin Light Chain Concentration

  13. Differential of Contraction and Focal Adhesion Turnover

  14. Differential of Contraction and Focal Adhesion Turnover Physiological Range? Pathological Range?

  15. Summary of Observations • Calpain production and activation only significant for active Vav concentrations of greater than ~1nM • Myosin activation significant for Vav concentrations of greater than ~0.1nM • Postulated wild type active Vav concentration at about 10-100nM • If [Vav2]/[Vav1+Vav3] = (1/10 to 1/100), then DKO could fall in region of myosin activation but low calpain activation

  16. Model Predictions • Normal active Vav concentrations in the range of 10-100nM, while active Vav2 in DKO concentration about 0.4-4nM • Vav DKO macrophage phenotype may be as result of imbalance between focal adhesion turnover and myosin mediated contraction

  17. Other Considerations • Vav also interacts with Cdc42, which is thought to be important for cell polarity • Rac and Rho are also involved in F-actin polymerization • Time delay observed between Rac and Rho activation and maturation of focal contacts • Signaling upstream of Vav has been ignored • Other pathways downstream of Vav affected • Concentrations of Rac, Rho, ROK, MLC, MBS all assumed to be 0.2uM

  18. Proposed Experiments • Observe DKO phenotype on other substrates in response to different signals • Measure biochemical interactions between species (kinetics) in vitro • Assay for myosin phosphorylation and active calpain • Tension force assay to determine if DKOs lack propulsive traction forces at leading edge • Measure half life of focal adhesions (GFP-tagged proteins, confocal microscopy)

  19. Thank you! • Joan Brugge, Amy Hall, and the Brugge lab (Dept. of Cell Biology, Harvard Medical School) • Reshma Shetty • Ali Khademhosseini • Doug Lauffenburger

  20. References • Abe K., et al. Vav2 is an activator of Cdc42, Rac1, and RhoA. J. Biol. Chem. 257(14):10141-10149. 2000. • Amano, M., et al. Phosphorylation and activation of myosin by Rho-associated kinase. J. Biol. Chem. 271(34):20246-20249. 1996. • Astagarthi A.R., Nelson C.M., Horwitz A.F., Lauffenburger D.A. Quantitative relationship among integrin-ligand binding, adhesion, and signaling via focal adhesion kinase and extracellular signal-regulated kinase 2. J. Biol. Chem. 274(38):27119-27127. 1999. • Ballestrem C., Hinz B., Imhof B.A., Wehrle-Haller B. Marching at the front and dragging behind: differential V3-integrin turnover regulates focal adhesion behavior. J. Cell Biol. 155(7):1319-1332. 2001. • Beningo K.A., Dembo M., Kaverina I., Small V.J., Wang Y. Nascent focal adhesions for the generation of strong propulsive forces in migrating fibroblasts. J. Cell Biol. 153(4):881-887. 2001. • Bhalla U.S. , Ram P.T., Iyengar R. 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