Proteins membrane-attachment, cytoskeletal

Bundles of parallel actin filaments with uniform polarity. The microvilli of intestinal epithelial cells (enterocytes) are packed with actin filaments that are attached to the overlying plasma membrane through a complex composed of a 110-kD protein and calmodulin. The actin filaments are attached to each other through fimbrin (68 kD) and villin (95 kD). The actin bundles that emerge out of the roots of microvilli disperse horizontally to form a filamentous complex, the terminal web, in which several cytoskeletal proteins, spectrin (fodrin), myosin, actinin, and tropomyosin are present. Actin in the terminal web also forms a peripheral ring, which is associated with the plasma membrane on the lateral surfaces of the enterocyte (see Figure 5, p. 24). 

The red blood cell must be able to squeeze through some tight spots in the microcirculation during its numerous passages around the body the sinusoids of the spleen are of special importance in this regard. For the red cell to be easily and reversibly deformable, its membrane must be both fluid and flexible it should also preserve its biconcave shape, since this facilitates gas exchange. Membrane lipids help determine membrane fluidity. Attached to the inner aspect of the membrane of the red blood cell are a number of peripheral cytoskeletal proteins (Table 52-6) that play important roles in respect to preserving shape and flexibility these will now be described. 

EPEC causes a degeneration of the microvillus brush border, with cupping and pedestal formation of the plasma membrane at the sites of bacterial attachment and reorganization of cytoskeletal proteins [43, 44], Invasion has been observed in some clinical specimens, but the mechanism of how this bacteria produces diarrhea is not fully understood. Some possibilities include an increase in permeability and loss in microvilli leading to malabsorption. 

This process is an early morphological change in cells often seen in isolated cells in vitro but also known to occur in vivo. The blebs, which appear before membrane permeability alters, are initially reversible. However, if the toxic insult is sufficiently severe and the cellular changes become irreversible, the blebs may rupture. If this occurs, vital cellular components may be lost and cell death follows. The occurrence of blebs may be due to damage to the cytoskeleton, which is attached to the plasma membrane as described above. The cause may be an increase in cytosolic Ca2+, interaction with cytoskeletal proteins, or modification of thiol groups (see below). 

The contacts between two adjoining cell membranes are stabilized by specific cell adhesion molecules (CAMs), which include the Ca+2-dependent cadherins. These molecules appear to lead the way for cell-cell communications and are involved in mechanochemical transduction via cell-cell interactions. In some cell types, cadherins are concentrated within adherens junctions that are stretch-sensitive and their extracellular domains interact with cadherins on adjacent cells whereas their cytoplasmic domains provide attachment to the actin cytoskeleton via catenins and other cytoskeletal proteins. The Rho family is required for the establishment and maintenance of cadherin-based adherens junctions. The type of cadherin expressed in a cell can affect the specificity and the physiological properties of cell-cell interactions. 

Ankyrin is a 200 kDa protein that links cytoskeletal protdns to membrane proteins. It is bound tightly to the cytoplasmic surface of the erythrocyte plasma membrane to which it attaches the cytoskeletal protein spectrin. 

In recent years the biological importance of the cytoskeletal structures—microtubules, intermediate filaments, and microfilaments (actin)—has attracted the attention of many cell biologists. In striated muscle, myosin and actin filaments together with Z lines are the main cytoskeletal structures to form sarcomeres of the myofibril. However, myosin and actin are contractile proteins, and some of the proteins constituting the Z line are classified as actin-associated proteins. Therefore, cell membrane attachment proteins, intermediate filaments, and some other structural proteins are described in this section. There has not been any report on muscle microtubules, although their presence is shown in some electron micrographs of sectioned samples. 

Figure 5. Schematic diagram of synaptic multiprotem complexes. Post-synaptic complexes of proteins associated with the NMDA receptor and PSD-95, found at excitatory mammalian synapses, are shown. Individual proteins are illustrated with arbitrary shapes and known interactions indicated. Proteins shown in colour are those found in a proteomic screen, whereas those shown in grey are inferred from bioinformatic studies. The specific protein-protein interactions are predicted, based on published reports from yeast two-hybrid studies. Membrane proteins (such as receptors, channels and adhesion molecules) are attached to a network of intracellular scaffold, signaling and cytoskeletal proteins, as indicated.

In this review by Franks et al. solid-state NMR shows its uses and applications in structural biology.Further developments promise great potential for investigations on functional biological systems such as membrane-integrated receptors and channels, and macromolecular complexes attached to cytoskeletal proteins. 

Ras is a G protein that cycle between two conformations, an activated Ras-GTP or inactivated form Ras-GDP. Ras, attached to the cell membrane by lipidation, is a key component in many signalling cascades, which couple growth factor receptors to downstream effectors that control such processes as cytoskeletal integrity, proliferation, cell adhesion, apoptosis and cell migration. Mutations and dysregulations of the Ras protein leading to increased invasion and metastasis, and decreased apoptosis are very common in cancers. 

Lipids and proteins can diffuse laterally within the plane of the membrane, but this mobility is limited by interactions of membrane proteins with internal cytoskeletal structures and interactions of lipids with lipid rafts. One class of lipid rafts consists of sphingolipids and cholesterol with a subset of membrane proteins that are GPI-linked or attached to several long-chain fatty acyl moieties. 

Phospholipid molecules in the plasma membrane diffuse rapidly enough to go from one end of an average-sized animal cell to the other in a few minutes. In a bacterial cell, such a trip would take only a few seconds. Integral membrane proteins move more slowly than phospholipids, as we expect in view of their greater mass. Diffusion of membrane proteins plays essential roles in many biochemical processes, including the cellular uptake of lipoproteins (chapter 18), responses of cells to hormones (chapter 24), immunological reactions (supplement 3), vision (supplement 2), and the transport of nutrients and ions. As we see in a later section, however, some membrane proteins cannot move about rapidly because they are attached to cytoskeletal scaffolds. 

The function of spectrin superfamily proteins is particularly evident when taken in context of their cellular localization. They often form flexible links or structures that allow interactions with the cellular cyto-skeletal architecture and the membrane. In both spectrin and dystrophin, such a function is performed, but the spectrin repeats of these molecules are also able to interact with actin and contribute to binding. A portion of the dystrophin rod domain that spans residues 11-17 contains a number of basic repeats that allow a lateral interaction with filamentous actin (Rybakova et al., 2002). The homologous utrophin can also interact laterally with actin. This interaction is distinct from that of dystrophin, as the utrophin rod domain lacks the basic repeat cluster and associates with actin via the first ten spectrin repeats (Rybakova et al., 2002). /3-Spectrin also exhibits an extended contact with actin via the first spectrin repeat. In this situation, it was found that the extended contact increased the association of the adjacent ABD with actin (Li and Bennett, 1996). In conjunction with this interaction, it has been found that the second repeat is also required for maximal interaction with adducin (Li and Bennett, 1996), a protein localized at the spectrin-actin junction that is believed to contribute to the assembly of this structure in the membrane skeletal network (Gardner and Bennett, 1987). In the erythrocyte cytoskeletal lattice, /3-spectrin interacts with ankyrin, which in turn binds to the cytoplasmic domain of the membrane-associated anion exchanger. This indirect link to the cellular membrane occurs via repeat 15 of /3-spectrin (Kennedy et al., 1991) and is largely responsible for the attachment of the spectrin-actin network to the erythrocyte membrane (reviewed in Bennett and Baines, 2001). A much larger number of direct links to transmembrane proteins have been determined for the spectrin repeats of o-actinin (reviewed in Djinovic-Carugo et al, 2002). 

The membrane skeleton acts as an elastic semisolid, allowing brief periods of deformation followed by reestablishment of the original cell shape (reviewed by Bennett and Gilligan, 1993). Erythrocytes in the human bloodstream have to squeeze repeatedly through narrow capillaries of diameters smaller than their own dimensions while resisting rupture. A functional erythrocyte membrane is pivotal to maintaining the functional properties of the erythrocyte. This importance is apparent when examination is made of many hemolytic anemias, where mutation of proteins involved in the structure of the submembranous cytoskeleton, and its attachment to the lipid bilayer, result in a malformed or altered cytoskeletal architecture and a disease phenotype. 

On such modified surfaces, some of the attached proteins are recognized by cytoskeletally associated receptors in the cell membrane. So, in the end, the extracellular substrate is mechanically connected with the intracellular cytoskele-ton, which may secrete its own adhesion proteins. Integrins, as an important class of cell receptors [63], bind to small domains on their adhesion proteins, e.g., the oligopeptide sequence arginine-glycine-aspartic acid (RGD) that is common in fibronectin [64],... 

FIGURE 3-23 Motor protein-dependent movement of cargo. The head domains of myosin, dynein, and kinesin motor proteins bind to a cytoskeletal fiber (microfilaments or microtubules), and the tail domain attaches to one of various types of cargo—in this case, a membrane-limited vesicle. Hydrolysis of ATP in the head domain causes the head domain to "walk" along the track in one direction by a repeating cycle of conformational changes. 

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