Ultrahigh Precision Optics Technology Team, RIKEN Center for Advanced Photonics, Saitama, Japan.
Biochem Biophys Res Commun. 2013 Sep 6;438(4):594-9. doi: 10.1016/j.bbrc.2013.08.010. Epub 2013 Aug 11.
Leukocytes can rapidly migrate virtually within any substrate found in the body at speeds up to 100 times faster than mesenchymal cells that remain firmly attached to a substrate even when migrating. To understand the flexible migration strategy utilized by leukocytes, we experimentally investigated the three-dimensional modulation of cortical plasticity during the formation of pseudopodial protrusions by mouse leukocytes isolated from blood. The surfaces of viable leukocytes were discretely labeled with fluorescent beads that were covalently conjugated with concanavalin A receptors. The movements of these fluorescent beads were different at the rear, central, and front surfaces. The beads initially present on the rear and central dorsal surfaces of the cell body flowed linearly toward the rear peripheral surface concomitant with a significant collapse of the cell body in the dorsal-ventral direction. In contrast, those beads initially on the front surface moved into a newly formed pseudopodium and exhibited rapid, random movements within this pseudopodium. Bead movements at the front surface were hypothesized to have resulted from rupture of the actin cytoskeleton and detachment of the plasma membrane from the actin cytoskeletal cortex, which allowed leukocytes to migrate while being minimally constrained by a substrate.
白细胞可以在体内任何基质中快速迁移,速度比间质细胞快 100 倍以上,间质细胞即使在迁移时也牢牢附着在基质上。为了了解白细胞所利用的灵活迁移策略,我们从血液中分离出的小鼠白细胞,实验性地研究了在伪足突起形成过程中皮质可塑性的三维调节。活白细胞的表面用荧光珠进行离散标记,这些荧光珠通过与伴刀豆球蛋白 A 受体的共价结合而被标记。这些荧光珠在细胞体的后、中、前表面的运动方式不同。最初位于细胞体后、中背表面的珠子沿后外周表面线性流动,同时细胞体在背腹方向显著塌陷。相比之下,最初位于前表面的珠子移动到一个新形成的伪足中,并在这个伪足中表现出快速、随机的运动。假设前表面的珠子运动是由于肌动蛋白细胞骨架的破裂以及质膜与肌动蛋白细胞骨架皮质的分离,这使得白细胞在迁移时受到最小的基质限制。
