Ang SF , Zhao ZS , Lim L , Manser E .

	Figure 1. DAAM1 is localized to different regions in the cells.(A) Western analysis of DAAM1 expression in different cell lines. Total protein lysate (30 µg) were loaded per lane. (B) Domain organization of DAAM1. (C) Left: confocal images of COS-7 cell taken at different planes. Right: co-localization of DAAM1 with centrosomes in prophase (after centrosome duplication) marked by anti-γ-tubulin. White arrowheads indicate centrosomes. (D) Confocal images of U2OS and DAAM1-null H460 cells, as well as COS-7 and COS-7 cells with DAAM1 knockdown by siRNA (COS-7 + siDAAM1). Endogenous DAAM1 was detected by indirect immuno-fluorescence with anti-DAAM1 under identical conditions. (E) Full-length Flag-DAAM1 or Flag-hDia1 (in green) was expressed in COS-7 cells and co-stained for actin (red). Bars  = 10 µm.
	Figure 2. N-terminal regions of DAAM1 are involved with actin stress fibers and centrosome targeting.(A) GFP-Flag-DAAM1 (1–440) was expressed in HeLa and analyzed by confocal imaging. DAAM1 was immuno-localized with anti-GFP (in green). Cells were counter-stained with TRITC-phalloidin, anti-myosin IIA or anti-myosin IIB (red). (B) Table summarizing the localization of various DAAM1 constructs tested in this study. (C) COS-7 cells expressing DAAM1(100–350) form large filaments enriched for myosin IIB that do not colocalize with F-actin. Treatment with various acto-myosin disrupting drugs with the indicated concentration for 45 min do not abolish the presence of these fibrils. Bars  = 10 µm.
	Figure 3. Interaction of DAAM1 with Rho GTPases.(A) The design of putative Rho binding defective mutants was based on sequences in mDia1: RhoA complex [6]. An in-vitro pulldown assay was performed in which equal amounts of DAAM1-N wildtype (WT) or the GBD mutants were added to Sepharose beads loaded with GST or GST-RhoAV14. The proteins were transferred to PVDF and stained as shown. The membrane was subsequently probed as indicated (B) GFP-DAAM1-N WT or the GBD mutants were expressed in COS-7 cells and immuno-localized with anti-GFP and F-actin (TRITC-phalloidin); all three constructs show typical DAAM1 filamentous staining. Bars  = 10 µm.
	Figure 4. DAAM1 knockdown affects directed cell migration.(A) Efficacy of two different siRNA against DAAM1 in COS-7 cells by Western analysis at 24 hours and 48 hours post-transfection. (B) COS-7 cells transfected with control (Ctr) or human DAAM1 siRNA (si2318) for 48 hours were scratched and observed using time-lapse imaging for 12 hours. Tracks of individual cells are shown as colored lines. Bar  = 40 µm. (C) Wound-edge COS-7 cells subjected to GSK inhibitor (SB216763, 20 µM) and PKC inhibitor (RO-320432, 20 µM), or si2318 (40 pmol) were stained with anti-α-tubulin to visualize the microtubule network. Loss of DAAM1 was associated with random protrusions versus the more organized broad extensions in controls. Wound-edge U2OS cells subjected to siRNA treatment are shown in the bottom panel. Bar  = 10 µm. (D) Forward Golgi orientation of COS-7 cells transfected with control (Ctr) or DAAM1 siRNA (si2318 or si2832, 40 pmol) at 0 and 1 hour post-wounding. Cells were scored for Golgi re-orientation using a 120° sector centered on the nucleus as shown on the right. (E) Right: Western analysis of DAAM1 knockdown in U2OS cells. Left: Golgi re-orientation in COS-7 and U2OS cells treated with various inhibitors 1 hour before wounding. PKC inhibitor (PKCi) and GSK inhibitors (GSKi) were used as in (c). In these analyses, cells were scored for Golgi re-orientation in three separate experiments. Error bars indicate standard deviation from the mean.
	Figure 5. Stable expression of DAAM1 in U2OS cells.(A) Levels of mCherry-DAAM1 and endogenous DAAM1 in the five stable U2OS lines as determined by western analysis with anti-DAAM1. (B) Typical myosin IIB staining of the ventral membrane region for the control and mCherry-DAAM1 expressing cells. Bars  = 10 µm.
	Figure 6. Effects of stable DAAM1 expression in U2OS cells.(A) Cells stably expressing mCherry alone or mCherry-DAAM1 as shown in Fig. 5 were subjected to wound healing assays and stained with Alexa Fluor 633-phalloidin to visualize the actin fibers. Red arrows indicate the different arrangement of actin fibers at the leading edges of vector control and DAAM1-expressing cells. Red arrows indicate the lamella region largely devoid of stress fibers in controls (top panel red arrows), and the presence of prominent actin fibers instead for the DAAM1-expressing cells (lower panel). (B) Cell lines stably expressing the mCherry vector or mCherry-DAAM1 were subjected to scratch wounding (wound indicated by dotted lines) and images were acquired at 2 hour intervals over 6 hours using an Olympus IX71 microscope equipped with a 10x/0.25 Plan-APOCHROMAT lens. Images at 0 and 4 hour time points are shown here for control and the DAAM1 cell-line 3. (C) Line graph showing the reduction in wound gap over the entire course of 6 hours for the control line and DAAM1-expressing line 3. (D) Percentage of wound gap covered 2 hours after scratch is plotted for control versus three of the lines. Error bars indicate standard error of the mean (SEM) from 3 independent experiments. Asterisks indicate that difference in the measurement between the control and each DAAM1 expressing line is statistically significant with a p-value less than 0.05 (t-test). Bars  = 10 µm (unless specified).
	Figure 7. A model of DAAM1 involvement in directed cell migration.Through its effects on F-actin assembly and the propensity to associate with myosin IIB, DAAM1 can directly affect the regulation of the acto-myosin network. Its upstream activator, Disheveled, is involved with activation of other polarity proteins through Cdc42 [30]. Cdc42 and MRCK are implicated in nuclear movement via effects on the sub-nuclear acto-myosin network [28], [34]. PAR3/PAR6/aPKC and dynein maintain the centrosome in the cell centroid via their effects on microtubule organization [29]. The ability of DAAM1 to interact with RhoA and Cdc42 could be a focus of cooperativity between the two GTPases in the polarity pathway. Full arrows indicate direct interaction, dashed arrows indicate indirect interaction, and dotted arrows indicate interaction yet to be established in this pathway.

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