Brain cytoskeleton

Methods for visualizing individual neurons and glia in vivo have depended for more than 100 years on histo-chemical reactions with cytoskeletal elements and even now these methods have not been surpassed. Because cytoskeletal structures play a particularly prominent role in the nervous system, cytoskeletal proteins represent a large fraction of total brain protein, comprising perhaps a third or more of the total. In fact, much of our knowledge about cytoskeletal biochemistry is based on studies of proteins purified from brain. The aims of this chapter are twofold first to provide an introduction to the cytoskeletal elements themselves and second to examine their role in neuronal function. Throughout, the emphasis will be on the cytoskeleton as a vital, dynamic component of the nervous system. 

In addition to its influence on protein—protein interactions, phosphorylation also affects protein structure and activity. One case involves a protein termed dematin headpiece (DHP), an actin-binding protein found in a variety of tissues including heart, brain, skeletal muscle, kidney, and lung." DHP is known to interact with Ras-guanine nucleotide exchange factor (Ras-GRF2) and this interaction can modulate MARK pathways, which can link the cytoskeleton and signaling pathways." ... 

The cytoskeleton is found near the axonal membrane and consists of microfilaments linked internally to microtubules and the plasma membrane by a network of filamentous protein that includes the brain-specific protein fodrin. This protein forms attachment sites for integral membrane proteins either by means of the neuronal cell adhesion molecule (N-CAM) or indirectly by means of a specific protein called ankyrin in the case of the sodium channels. This may provide a means whereby the sodium channels are concentrated in the region of the nodes of Ranvier. Thus the cortical cytoskeleton plays a vital role in neuronal function by acting as an attachment site for various receptors and ion channels, but also for s)maptic vesicles at nerve terminals, thereby providing a mechanism for concentrating the vesicles prior to the release of the neurotransmitter. 

Isolated microtubules always contain small amounts of larger 300-kDa microtubule-associated proteins (MAPS).330 These elongated molecules may in part lie in the grooves between the tubulin subunits and in part be extended outward to form a low-density layer around the tubule.283 309 Nerve cells that contain stable microtubules have associated stabilizing proteins.331 A family of proteins formed by differential splicing of mRNA are known as tau. The tau proteins are prominent components of the cytoskeleton of neurons. They not only interact with microtubules but also undergo reversible phosphorylation. Hyperphosphorylated tau is the primary component of the paired helical filaments found in the brains of persons with Alzheimer disease.330... 

Bennett, H., and Condeelis, J. (1988). Isolation of an immunoreactive analogue of brain fodrin that is associated with the cell cortex of Dictyostelium amoebae. Cell Motil. Cytoskeleton 11, 303—317. 

In certain types of brain injury, such as diffuse axonal injury, spectrin is irreversibly cleaved by the proteolytic enzyme calpain. This destroys the cytosketelon, causing the membrane to form blebs, irregular bulges in the plasma membrane of a cell caused by localised decoupling of the cytoskeleton from the plasma membrane, ultimately leading to degradation and usually death of the cell. 

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