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package for msd analysis  (MathWorks Inc)


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    MathWorks Inc package for msd analysis
    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to <t>MSD</t> <t>analysis;</t> red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
    Package For Msd Analysis, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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    Images

    1) Product Images from "Actin dynamics drive microvillar motility and clustering during brush border assembly"

    Article Title: Actin dynamics drive microvillar motility and clustering during brush border assembly

    Journal: Developmental cell

    doi: 10.1016/j.devcel.2019.07.008

    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to MSD analysis; red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
    Figure Legend Snippet: (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to MSD analysis; red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.

    Techniques Used: Stable Transfection, Expressing, Standard Deviation, Diffusion-based Assay

    (A) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 20 μM Blebbistatin. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Blue arrow indicates the rate of microvillar movement after the addition of drug. (B) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 20 μM Blebbistatin. (C) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (D) MSD analysis of microvillar trajectories from B. (E) Normalized velocity autocorrelation analysis of microvillar trajectories from B; data were fit to an active movement model with D = 0.000093 μm2/s, V = 0.12 μm/min. (F) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 30 μM Cytochalasin D. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Orange arrow indicates the rate of microvillar movement after the addition of drug. (G) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 500 nM Cytochalasin B. (H) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (I) MSD analysis of microvillar trajectories from G; data could not be fit with an active movement model. The curve for mCherry-Espin with no drug treatment is plotted for comparison (grey dotted line). (J) Normalized velocity autocorrelation analysis of microvillar trajectories from G. (K-M) Average microvillar velocity, maximum microvillar length, and persistence, respectively, measured from untreated cells (from Figure 1), or cells exposed to Blebbistatin or Cytochalasin B. For Blebbistatin and Cytochalasin datasets, n = 178 and 175 microvilli, respectively, from 6-7 cells. Bars represent mean ± SD. *** p < 0.0001, n.s. = not significant.
    Figure Legend Snippet: (A) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 20 μM Blebbistatin. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Blue arrow indicates the rate of microvillar movement after the addition of drug. (B) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 20 μM Blebbistatin. (C) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (D) MSD analysis of microvillar trajectories from B. (E) Normalized velocity autocorrelation analysis of microvillar trajectories from B; data were fit to an active movement model with D = 0.000093 μm2/s, V = 0.12 μm/min. (F) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 30 μM Cytochalasin D. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Orange arrow indicates the rate of microvillar movement after the addition of drug. (G) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 500 nM Cytochalasin B. (H) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (I) MSD analysis of microvillar trajectories from G; data could not be fit with an active movement model. The curve for mCherry-Espin with no drug treatment is plotted for comparison (grey dotted line). (J) Normalized velocity autocorrelation analysis of microvillar trajectories from G. (K-M) Average microvillar velocity, maximum microvillar length, and persistence, respectively, measured from untreated cells (from Figure 1), or cells exposed to Blebbistatin or Cytochalasin B. For Blebbistatin and Cytochalasin datasets, n = 178 and 175 microvilli, respectively, from 6-7 cells. Bars represent mean ± SD. *** p < 0.0001, n.s. = not significant.

    Techniques Used: Stable Transfection, Expressing, Isolation, Comparison



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    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to <t>MSD</t> <t>analysis;</t> red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
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    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to <t>MSD</t> <t>analysis;</t> red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
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    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to <t>MSD</t> <t>analysis;</t> red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
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    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to <t>MSD</t> <t>analysis;</t> red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.
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    Image Search Results


    (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to MSD analysis; red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.

    Journal: Developmental cell

    Article Title: Actin dynamics drive microvillar motility and clustering during brush border assembly

    doi: 10.1016/j.devcel.2019.07.008

    Figure Lengend Snippet: (A) LLSM of a CL4 cell stably expressing mCherry-Espin, reconstructed then viewed as a maximum intensity z-projection. Scale bar 10 μm, blue dashed boxes corresponds to B. (B) Enlarged images from A (left) with time projections (right) showing microvillar movement over 3 minutes. (C) SDCM of the apical surface of a CL4 cell stably expressing mCherry-Espin, viewed as a maximum intensity z-projection. Scale bar 10 μm, white dashed box corresponds to D, red dashed box corresponds to E. (D) 3-dimensional (3D) depth color coded z-stack viewed en face (xy plane, upper panel) or laterally (xz plane, lower panel). Scale bars are 1 μm, z-axis depth color code (lower panel) to scale with tick marks at 1 μm intervals. Microvilli exhibit a range of orientations from parallel (represented by a single color) to perpendicular to the cell surface (spanning multiple color bands, circled—top panel, arrowheads—bottom panel). (E) Time series of microvilli translocating across the cell surface; red and orange arrows highlight the paths of two distinct protrusions. Scale bar 2 μm. (F) Rose plot of trajectories measured from the tips of microvilli (n = 101) for the cell in C. (G) Microvillar trajectories from F were subject to MSD analysis; red open circles represent the mean MSD, error bars indicate standard error of the mean (SEM), grey area marks the weighted standard deviation (SD) over all MSD curves, and the solid line indicates a fit of the data to an active movement model (diffusion coefficient, D = 0.000283 μm2/s and velocity, V = 0.21 μm/min). (H) Trajectories from F were analyzed for normalized velocity autocorrelation, solid line. Dotted line at 0 indicates the velocity autocorrelation of random diffusive movement. (I-K) Average microvillar velocity, maximum microvillar length, and persistence, respectively. (L) Microvillar lifetime frequency histogram. Error bars indicate mean ± SD, (I-L) n = 171 microvilli from 7 cells for mCherry-Espin, n = 183 microvilli from 6 cells for EGFP-Lifeact, * p < 0.05, n.s. = not significant.

    Article Snippet: Data was exported and analyzed with MATLAB using a package specifically developed for MSD analysis ( Tarantino et al., 2014 ), which is publicly available at http://www.mathworks.com/matlabcentral/fileexchange/40692-mean-square-displacement-analysis-of-particles-trajectories .

    Techniques: Stable Transfection, Expressing, Standard Deviation, Diffusion-based Assay

    (A) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 20 μM Blebbistatin. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Blue arrow indicates the rate of microvillar movement after the addition of drug. (B) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 20 μM Blebbistatin. (C) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (D) MSD analysis of microvillar trajectories from B. (E) Normalized velocity autocorrelation analysis of microvillar trajectories from B; data were fit to an active movement model with D = 0.000093 μm2/s, V = 0.12 μm/min. (F) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 30 μM Cytochalasin D. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Orange arrow indicates the rate of microvillar movement after the addition of drug. (G) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 500 nM Cytochalasin B. (H) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (I) MSD analysis of microvillar trajectories from G; data could not be fit with an active movement model. The curve for mCherry-Espin with no drug treatment is plotted for comparison (grey dotted line). (J) Normalized velocity autocorrelation analysis of microvillar trajectories from G. (K-M) Average microvillar velocity, maximum microvillar length, and persistence, respectively, measured from untreated cells (from Figure 1), or cells exposed to Blebbistatin or Cytochalasin B. For Blebbistatin and Cytochalasin datasets, n = 178 and 175 microvilli, respectively, from 6-7 cells. Bars represent mean ± SD. *** p < 0.0001, n.s. = not significant.

    Journal: Developmental cell

    Article Title: Actin dynamics drive microvillar motility and clustering during brush border assembly

    doi: 10.1016/j.devcel.2019.07.008

    Figure Lengend Snippet: (A) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 20 μM Blebbistatin. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Blue arrow indicates the rate of microvillar movement after the addition of drug. (B) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 20 μM Blebbistatin. (C) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (D) MSD analysis of microvillar trajectories from B. (E) Normalized velocity autocorrelation analysis of microvillar trajectories from B; data were fit to an active movement model with D = 0.000093 μm2/s, V = 0.12 μm/min. (F) SDCM of the apical surface of CL4 cells stably expressing mCherry-Espin showing the response to 30 μM Cytochalasin D. Right, time series montage of a single protrusion highlighted with a 10% pseudo-colored overlay. Scale bars are 2 μm. Drug was added following the 5-minute time interval, yellow arrowhead. Black arrows indicate the baseline rate of microvillar movement. Orange arrow indicates the rate of microvillar movement after the addition of drug. (G) Rose plot shows the microvillar trajectories (n = 100) from a single cell treated with 500 nM Cytochalasin B. (H) 25 representative microvillar trajectories are isolated for display. Scale bar is 5 μm. (I) MSD analysis of microvillar trajectories from G; data could not be fit with an active movement model. The curve for mCherry-Espin with no drug treatment is plotted for comparison (grey dotted line). (J) Normalized velocity autocorrelation analysis of microvillar trajectories from G. (K-M) Average microvillar velocity, maximum microvillar length, and persistence, respectively, measured from untreated cells (from Figure 1), or cells exposed to Blebbistatin or Cytochalasin B. For Blebbistatin and Cytochalasin datasets, n = 178 and 175 microvilli, respectively, from 6-7 cells. Bars represent mean ± SD. *** p < 0.0001, n.s. = not significant.

    Article Snippet: Data was exported and analyzed with MATLAB using a package specifically developed for MSD analysis ( Tarantino et al., 2014 ), which is publicly available at http://www.mathworks.com/matlabcentral/fileexchange/40692-mean-square-displacement-analysis-of-particles-trajectories .

    Techniques: Stable Transfection, Expressing, Isolation, Comparison