Adhesive signaling near the leading edge of MII-depleted cells. MIIA- or MIIB-depleted or control cells were plated on fibronectin and then fixed and stained for phosphotyrosine (A), phosphoTyr397-FAK (B), and phosphoTyr31-paxillin (C). Bar, 10 μm.

Contractility-deficient mutants of MIIA and MIIB exhibit differential rescue of actin bundling, protrusion, and adhesion dynamics in MIIA- and MIIB-deficient cells. Inhibited FRAP of GFP-MIIA N93K (A) and GFP-MIIB R709C (B) in actin bundles. Data are the mean ± the SD of >20 individual measurements from four independent experiments. (C) Differential FRAP of GFP-MIIA-WT and GFP-MIIB-WT in actin bundles. (D) A MIIB-depleted cell cotransfected with paxillin-GFP and mChe-MIIB R709C (not depicted). (E) Localization of GFP-MIIB and GFP-MIIB R709C. Arrows show the direction of migration. (F) Polarity index of migrating CHO.K1 cells. Data are the mean ± the SD of >100 cells analyzed/condition. (G) Time-lapse series of a MIIA-depleted cell expressing paxillin-GFP and mChe-MIIA (not depicted). Bars: (D) 3 μm; (G) 15 μm.

MIIA and IIB regulate protrusion and differentially control adhesion turnover. (A; top) Kymographs from control (pSUPER), MIIA-depleted (pSUP-IIA), and MIIB-depleted (pSUP-IIB) cells. (bottom) Overlay of periodicity and slope from the kymographs. (B) Protrusion rates from A. At least 12 cells (3–5 protrusions/cell) from four independent experiments were analyzed. Data is presented as the mean ± the SEM. (C) Image sequence of control (top; Video 7) and MIIA- (middle; Video 6) and MIIB-depleted cells (bottom; Video 8) cotransfected with paxillin-GFP. (D) Color-inverted image sequence of MIIA-depleted cell expressing paxillin-GFP (Video 9). Time is shown in seconds. (E) Image sequence of paxillin-GFP–expressing, MIIA- (top) or MIIB-depleted (bottom) cells cotransfected with mChe-MIIA or mChe-MIIB, respectively (not depicted). (F) Image sequence of paxillin-GFP–expressing, MIIA-depleted cell. Arrowheads point to central adhesions; arrows point to impaired disassembly at the trailing edge (Video 10). (G) Image sequence of paxillin-GFP in a MIIB-depleted cell (left) expressing mChe-IIA (not depicted) and a MIIA-depleted cell (right) expressing mChe-IIB (not depicted). Bars: (C) 5 μm; (D) 3 μm; (E) 5 μm; (F) 20 μm; (G) 5 μm. Videos 6–10 are available at http://www.jcb.org/cgi/content/full/jcb.200612043/DC1.

Knockdown of MIIA or MIIB differentially alters cell polarity. (A) CHO.K1 cells were transfected with pSUPER-GFP vector or pSUPER-GFP-RNAi against MIIA or MIIB, and blotted for MIIA or MIIB. GIT1 is a loading control. (B) Representative images of MIIA- (top) and MIIB-depleted cells (bottom) stained for MIIA or MIIB, respectively. Arrows point to transfected cells. (C–E) Time-lapse series of MIIA-depleted (C; Video 1), MIIB-depleted (D; Video 2), or control cells (E; Video 3). In C, arrowheads point to the defect in tail retraction. (D) Arrows point to transfected, unpolarized cells. Videos are representative of >25 cells in 6 independent experiments. (F) Fluorescence images depicting the enlargement of MIIB-deficient cells. Images are representative of >300 cells. (G; top) Effect of MIIB knockdown on cell area. Data are the mean ± the SD of 4 independent experiments comprising >300 cells/experiment. (bottom) Cell areas in control and MIIB-depleted cells. (H) MIIB-deficient cell showing clockwise rotation of the nucleus. Arrowhead points to nucleolus; top-right indicator, clockwise angular displacement (Video 4). (I) Depolarization of the Golgi is observed in MIIB-deficient cells (arrows) and not in nontransfected cells (arrowheads). Bars: (C) 40 μm; (D–F and H) 50 μm. Videos 1–4 are available at http://www.jcb.org/cgi/content/full/jcb.200612043/DC1.