Marek L F, Kelley R O, Perdue B D
Cell Motil. 1982;2(2):115-30. doi: 10.1002/cm.970020204.
The relationship between the cytoskeleton, stress fiber formation, and cell shape has been difficult to determine in fibroblasts grown in tissue culture. Vagaries in cell shape are complicated, as well, by stochastic cell movements. We dictated the attachment sites and shape of fibroblasts by growing them on square adhesive substrates surrounded by nonadhesive substrates. Cytoskeletal models were made by treating the cells with buffered Triton X-100 and glycerol. The residues were then examined by scanning electron microscopy followed by light microscopy of the same cells. The cytoskeletons of randomly moving cells were examined with whole mount transmission microscopy to confirm images seen with scanning microscopy. The cells thus examined demonstrated definite relationships between ruffling activity and stress fiber terminations, which were limited to the more adhesive, palladium substrate. No stress fibers were seen to end on the lesser adhesive substrate, agarose, and ruffling did not occur across the agarose. Cells too small to fill an entire square tended to extend across one diagonal of the square, and the stress fibers ran parallel to the longest axis of these cells. Larger cells were able to completely fill their squares. The cytoskeletons of these cells were organized in a spatial relation to the square shape of the cells. The cortical meshwork was aligned circularly and diagonally within the cells. Stress fibers appeared to form from the microfilaments of the meshwork and were aligned diagonally across the cells. We conclude that the diagonal arrangement of the stress fibers and cortical meshwork is caused by the same mechanism by which smaller cells spread over the longest axis of a square. Regions of cells where the meshwork was absent or where stress fibers were tightly bundled were occupied by more randomly arranged cytoskeletal components. Regions of tightly bundled stress fibers did not seem to coincide with regions of cortical meshwork as seen by either whole mount transmission or scanning electron microscopy. Stress fibers were revealed in the light microscope to course beneath more randomly oriented cytoskeletal elements. These "lacework-like" elements were found frequently in square cells. Conspicuous structures in this random lacework were focal points of radially arranged filaments. Our observations suggest a continuity between stress fibers and the cortical microfilaments. The orientation of fibers and filaments was, in turn, dependent on cell shape for organization within the cell.
在组织培养中生长的成纤维细胞中,细胞骨架、应力纤维形成和细胞形状之间的关系一直难以确定。细胞形状的变化无常也因细胞的随机运动而变得复杂。我们通过将成纤维细胞培养在被非粘性底物包围的方形粘性底物上来控制其附着位点和形状。通过用缓冲的Triton X-100和甘油处理细胞来制作细胞骨架模型。然后通过扫描电子显微镜检查残留物,随后对相同的细胞进行光学显微镜检查。用整装透射显微镜检查随机移动细胞的细胞骨架,以确认扫描显微镜下看到的图像。如此检查的细胞显示出褶皱活动与应力纤维终止之间存在明确的关系,这些关系仅限于粘性更强的钯底物。在粘性较小的底物琼脂糖上未观察到应力纤维终止,并且在琼脂糖上也未发生褶皱。太小而无法填满整个方形的细胞倾向于沿着方形的一条对角线延伸,并且应力纤维与这些细胞的最长轴平行排列。较大的细胞能够完全填满它们的方形区域。这些细胞的细胞骨架与细胞的方形形状在空间上相关联。皮质网络在细胞内呈圆形和对角线排列。应力纤维似乎由网络的微丝形成,并在细胞内呈对角线排列。我们得出结论,应力纤维和皮质网络的对角线排列是由较小的细胞沿着方形最长轴扩散的相同机制引起的。网络缺失或应力纤维紧密束集的细胞区域被更随机排列的细胞骨架成分占据。无论是通过整装透射显微镜还是扫描电子显微镜观察,紧密束集的应力纤维区域似乎都与皮质网络区域不一致。在光学显微镜下可以看到应力纤维在更随机取向的细胞骨架元件下方穿过。这些“花边状”元件在方形细胞中经常发现。这种随机花边结构中的明显结构是径向排列的细丝的焦点。我们的观察结果表明应力纤维和皮质微丝之间存在连续性。反过来,纤维和细丝的取向取决于细胞形状,以便在细胞内进行组织。
