1. Cytoskeleton

 

Our appreciation and understanding of living processes have been considerably enhanced by the development of probes and instrumentation that allow the localisation of proteins in living cells. Perhaps the most dramatic general finding that has emerged from the use of current imaging technology is the dynamism of structural assemblies in cells. Cell shape is formed by three primary polymer systems that make up the “cytoskeleton” : the actin filaments, intermediate filaments and microtubules.

 

 

 

 

Far from being static, as the name would suggest, these polymer systems undergo continual turnover and rearrangement. This continual reorganisation is the essence of life itself as it underlies the changes in cell morphology and migration that shape the organism. 

 

Figure 1-3. The three cytoskeleton filaments in the electron microscope. The  cytoskeleton can be visualised in the electron microscope after extracting cells with detergents to remove membranes, organelles and soluble components of the cytoplasm. In the examples shown here the cytoskeleton filaments have been contrasted by the negative staining method. Negative staining entails the drying of the preparation in a heavy metal salt (typically of tungsten or uranium) from an aqueous solution. The cell structures then appear light against the surrounding electron dense stain. A, Electron micrograph of the peripheral region of the cytoskeleton of a B16 melanoma cell showing microtubules (25nm diameter) in a loose network of actin filaments (8nm diameter). The cell was extracted in a mixture of glutaraldehyde and detergent and negatively stained (see Small, 1988, Small and Celis, 1978a). B, Electron micrograph of intermediate filaments (10nm diameter) in an epithelial cell. To reveal the intermediate filaments the cell was first extracted with detergent and then in a concentrated salt solution to remove actin filaments and microtubules (Small and Celis, 1978b).

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