The position of the microtubule-organizing center in directionally migrating fibroblasts depends on the nature of the substratum.

Schütze, Karin; Maniotis, Andrew J.; Schliwa, Manfred

doi:10.1073/pnas.88.19.8367

Cited by 43 publications

(27 citation statements)

References 21 publications

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“…However, mixed front-back positions have been observed in CHO cells during wound healing (Yvon et al, 2002), in endothelial cells under shear stress (Coan et al, 1993) and in fibroblasts grown on grooved substrates or grown in collagen gels (Schütze et al, 1991). These results challenge the view that the Golgi complex -similar to the centrosome -is always at the leading edge of a migratory cell.…”

Section: Introductioncontrasting

confidence: 55%

In migrating cells, the Golgi complex and the position of the centrosome depend on geometrical constraints of the substratum

Pouthas

Girard

Lecaudey

et al. 2008

Journal of Cell Science

152

141

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Although cells migrate in a constrained 3D environment in vivo, in-vitro studies have mainly focused on the analysis of cells moving on 2D substrates. Under such conditions, the Golgi complex is always located towards the leading edge of the cell, suggesting that it is involved in the directional movement. However, several lines of evidence indicate that this location can vary depending on the cell type, the environment or the developmental processes. We have used micro contact printing (μCP) to study the migration of cells that have a geometrically constrained shape within a polarized phenotype. Cells migrating on micropatterned lines of fibronectin are polarized and migrate in the same direction. Under such conditions, the Golgi complex and the centrosome are located behind the nucleus. In addition, the Golgi complex is often displaced several micrometres away from the nucleus. Finally, we used the zebrafish lateral line primordium as an in-vivo model of cells migrating in a constrained environment and observe a similar localization of both the Golgi and the centrosome in the leading cells. We propose that the positioning of the Golgi complex and the centrosome depends on the geometrical constraints applied to the cell rather than on a precise migratory function in the leading region.

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Section: Introductioncontrasting

confidence: 55%

In migrating cells, the Golgi complex and the position of the centrosome depend on geometrical constraints of the substratum

Pouthas

Girard

Lecaudey

et al. 2008

Journal of Cell Science

152

141

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“…Our experiments tested the hypothesis that directional migration requires that fibroblasts reorient in the direction of movement, as they do during spontaneous or wound-healing migration (Palazzo et al, 2001b;Ueda et al, 1997). MTOC reorientation does not occur in fibroblasts migrating within three-dimensionally oriented collagen gels (Schutze et al, 1991) or in wound-healing Journal of Cell Science 117 (8) (b) show that most PAK4 transfectants were flatter and more bipolar than controls, in which 20-25% of cells appear spherical before EF application. Primary fibroblasts from mouse embryos whose PAK4 expression was knocked out by homologous recombination (PAK4 -/-; c) and PAK4-expressing heterozygotes (PAK4 +/-; d) were morphologically indistinguishable.…”

Section: Discussionmentioning

confidence: 99%

“…For example, MTs are unnecessary for fibroblast locomotion in an oriented, three-dimensional extracellular matrix (ECM) (Schutze et al, 1991) or for rapid migration of tiny fish keratocytes (Euteneuer and Schliwa, 1984), or keratocyte fragments (Verkhovsky et al, 1999). Fibroblasts, however, require MTs (Gail and Boone, 1971;Vasiliev et al, 1970), specifically dynamic MTs (Liao et al, 1995), for spontaneous and wound-healing migration.…”

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confidence: 99%

Roles of microtubules, cell polarity and adhesion in electric-field-mediated motility of 3T3 fibroblasts

Finkelstein

Chang

Chao

et al. 2004

Journal of Cell Science

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Direct-current electric fields mediate motility (galvanotaxis) of many cell types. In 3T3 fibroblasts, electric fields increased the proportion, speed and cathodal directionality of motile cells. Analogous to fibroblasts' spontaneous migration, we initially hypothesized that reorientation of microtubule components modulates galvanotaxis. However, cells with intact microtubules did not reorient them in the field and cells without microtubules still migrated, albeit slowly, thus disproving the hypothesis. We next proposed that, in monolayers wounded and placed in an electric field, reorientation of microtubule organizing centers and stable, detyrosinated microtubules towards the wound edge is necessary and/or sufficient for migration. This hypothesis was negated because field exposure mediated migration of unoriented, cathode-facing cells and curtailed migration of oriented, anode-facing cells. This led us to propose that ablating microtubule detyrosination would not affect galvanotaxis. Surprisingly, preventing microtubule detyrosination increased motility speed, suggesting that detyrosination inhibits galvanotaxis. Microtubules might enhance adhesion/de-adhesion remodeling during galvanotaxis; thus, electric fields might more effectively mediate motility of cells poorly or dynamically attached to substrata. Consistent with this hypothesis, incompletely spread cells migrated more rapidly than fully spread cells. Also, overexpression of PAK4, a Cdc42-activated kinase that decreases adhesion, enhanced galvanotaxis speed, whereas its lack decreased speed. Thus, electric fields mediate fibroblast migration via participation of microtubules and adhesive components, but their participation differs from that during spontaneous motility.

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“…29 These studies on Dictyostelium discoideum 28 and fibroblasts 29 suggest that polarization of the centrosome is not required for directional migration in three-dimensional gels. However, large-vessel ECs differ from fibroblasts because the cells migrate on a substratum that defines a luminal and an abluminal surface of the cell, and the cells migrate only in a two-dimensional plane.…”

Section: A Centrosome-dependent Reendotheualeationmentioning

confidence: 99%

“…28 Thus, in Dictyostelium discoideum the position of the centrosome is dependent on the conditions of migration and the nature of cell-cell adhesion. 28 In a study that used chicken embryo fibroblasts, 29 it was found that the centrosomes of cells grown on glass coverslips reoriented in the direction of cell migration, whereas In vitro large-wound re-endothelialization. Inhibition of centrosome redistribution by…”

Section: Hours Later Cells Were Double Stained To Localize F-actin (mentioning

confidence: 99%

In vitro large-wound re-endothelialization. Inhibition of centrosome redistribution by transient inhibition of transcription after wounding prevents rapid repair.

Ettenson

Gotlieb

1993

Arterioscler Thromb

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Rapid, efficient re-endothelialization of large wounds is characterized by a specific sequence of cytoskeletal events that occur after wounding. Wounds 1.5 mm wide were created down the middle of confluent porcine aortic endothelial monolayers to study regulation of repair. The wounded cultures were incubated for short periods with cycloheximide or actinomycin D to test the hypothesis that transient inhibition of translation and transcription at the time of wounding disrupts rapid repair by interfering with centrosome redistribution to the front of the cell, an early event associated with cell migration. Although centrosome reorientation did not occur when protein synthesis was inhibited with 20 micrograms/mL cycloheximide for 1 hour before and for up to 4 hours after wounding, reorientation did occur by 2 hours after cycloheximide was washed out. The times taken for the wound to close for cycloheximide-treated and control cells did not differ (60 +/- 1.1 vs 60 +/- 0.8 hours). When transcription was inhibited with 0.25 micrograms/mL actinomycin D for 1 hour before and for 1 hour after wounding, re-endothelialization was dramatically reduced. The time taken for the wound to close was almost five times longer (288 +/- 5.3 hours) than for control cells. The cells moved very slowly, maintaining a flattened, spread-out shape, as opposed to being elongated. The centrosomes did not reorient to the front of the cell throughout the entire period. However, addition of actinomycin D for 2 hours when centrosomes had already moved to the front of the cells (4 hours after wounding) did not reduce subsequent wound repair (60 +/- 1.3 hours). This study supports our hypothesis that centrosome redistribution is essential for efficient wound repair and suggests that redistribution is regulated by transcription of essential gene(s) that is induced immediately after wounding by an unknown short-lived signal. Two possible signals are the loss of cell contact and/or a soluble substance released from the cells at the time of wounding. When the signal is unable to induce transcription, dysfunctional repair occurs by a very slow centrosome-independent process.

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The position of the microtubule-organizing center in directionally migrating fibroblasts depends on the nature of the substratum.

Cited by 43 publications

References 21 publications

In migrating cells, the Golgi complex and the position of the centrosome depend on geometrical constraints of the substratum

In migrating cells, the Golgi complex and the position of the centrosome depend on geometrical constraints of the substratum

Roles of microtubules, cell polarity and adhesion in electric-field-mediated motility of 3T3 fibroblasts

In vitro large-wound re-endothelialization. Inhibition of centrosome redistribution by transient inhibition of transcription after wounding prevents rapid repair.

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