微管可以远距离调节巨噬细胞内的假足活性。

G R Rosania, J A Swanson
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引用次数: 34

摘要

微管被认为是影响细胞形状的一个完整的细胞骨架基质的结构成分。在这里,我们表明微管可以影响巨噬细胞伪足的动力学而不被整合到巨噬细胞的结构中。降落在玻璃表面的巨噬细胞在15分钟内扩散成呈径向对称的扁平圆形细胞,微管的径向分布反映了这种对称性。用诺可达唑、秋水仙碱或长春碱解聚微管并不能抑制巨噬细胞的扩散或早期建立径向对称。然而,在扩散后不久,没有微管的巨噬细胞逐渐变得不对称,呈现不规则的叶状轮廓。不对称是由于假足突缩过大,整体呈净缩。用细胞松弛素D处理最初扩散的细胞可以抑制这种径向对称性的丧失,这表明细胞形状的改变是由肌动蛋白细胞骨架介导的。完整的微管抑制了夸张的假足运动,即使它们与细胞边缘分开了一段距离。在紫杉醇处理的细胞中,微管扩散后仍聚集在细胞中心附近,但细胞边缘伪足的动力学减弱,细胞保持圆形轮廓。同样,在低浓度诺可达唑处理的细胞中,微管细胞骨架大大减少,但仍抑制了假足动力学。我们提出,微管通过影响微丝系统结构或功能的生化中间体,在距离细胞边缘一定距离处稳定细胞形状。
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Microtubules can modulate pseudopod activity from a distance inside macrophages.

Microtubules are thought to influence cell shape as structural components of an integrated cytoskeletal matrix. Here we show that microtubules can affect the dynamics of macrophage pseudopodia without being integrated into their structure. Macrophages landing on glass surfaces spread within 15 min into flattened circular cells with radial symmetry, and the radial distribution of microtubules reflected this symmetry. Depolymerization of microtubules using nocodazole, colchicine, or vinblastine did not inhibit macrophage spreading or the early establishment of radial symmetry. Shortly after spreading, however, macrophages without microtubules gradually became asymmetric, assuming irregular, lobed profiles. The asymmetry resulted from exaggerated protrusion and retraction of pseudopodia, with net retraction overall. This loss of radial symmetry could be inhibited by treatment of initially spread cells with cytochalasin D, indicating that the change in cell shape was mediated by the actin cytoskeleton. Intact microtubules suppressed the exaggerated pseudopod movements, even when they were separated by a distance from the cell margin. In cells treated with taxol, microtubules remained clustered near the cell center after spreading, yet the dynamics of pseudopodia at the cell margin were reduced and cells maintained a circular profile. Similarly, in cells treated with low concentrations of nocodazole, a much reduced microtubule cytoskeleton nonetheless suppressed pseudopod dynamics. We propose that microtubules act to stabilize cell shape at a distance from the cell edge via a biochemical intermediate that affects the structure or function of the microfilament system.

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