Tropomodulin (E-Tmod) is an actin filament pointed end capping protein that maintains the length of the sarcomeric actin filaments in striated muscle. Here, we describe the identification and characterization of a novel tropomodulin isoform, skeletal tropomodulin (SkTmod) from chickens. Sk-Tmod is 62% identical in amino acid sequence to the previously described chicken ETmod and is the product of a different gene. Sk-Tmod isoform sequences are highly conserved across vertebrates and constitute an independent group in the tropomodulin family. In vitro, chicken Sk-Tmod caps actin and tropomyosin-actin filament pointed ends to the same extent as does chicken E-Tmod. However, E-and Sk-Tmods differ in their tissue distribution; Sk-Tmod predominates in fast skeletal muscle fibers, lens, and erythrocytes, while E-Tmod is found in heart and slow skeletal muscle fibers. Additionally, their expression is developmentally regulated during chicken breast muscle differentiation with Sk-Tmod replacing E-Tmod after hatching. Finally, in skeletal muscle fibers that coexpress both Sk-and E-Tmod, they are recruited to different actin filament-containing cytoskeletal structures within the cell: myofibrils and costameres, respectively. All together, these observations support the hypothesis that vertebrates have acquired different tropomodulin isoforms that play distinct roles in vivo.
Terminal differentiation of lens fiber cells resembles the apoptotic process in that organelles are lost, DNA is fragmented, and changes in membrane morphology occur. However, unlike classically apoptotic cells, which are disintegrated by membrane blebbing and vesiculation, aging lens fiber cells are compressed into the center of the lens, where they undergo cell-cell fusion and the formation of specialized membrane interdigitations. In classically apoptotic cells, caspase cleavage of the cytoskeletal protein ␣-spectrin to ϳ150-kDa fragments is believed to be important for membrane blebbing. We report that caspase(s) cleave ␣-spectrin to ϳ150-kDa fragments and -spectrin to ϳ120-and ϳ80-kDa fragments during late embryonic chick lens development. These fragments continue to accumulate with age so that in the oldest fiber cells of the adult lens, most, if not all, of the spectrin is cleaved to discrete fragments. Thus, unlike classical apoptosis, where caspase-cleaved spectrin is short lived, lens fiber cells contain spectrin fragments that appear to be stable for the lifetime of the organism. Moreover, fragmentation of spectrin results in reduced membrane association and thus may lead to permanent remodeling of the membrane skeleton. Partial and specific proteolysis of membrane skeleton components by caspases may be important for age-related membrane changes in the lens.The spectrin-actin membrane skeleton underlies the plasma membranes of all cells and is important for cellular shape, membrane stability and deformability, as well as the formation of membrane subdomains (1). The major component of the membrane skeleton, spectrin, is composed of an ␣/ heterodimer that self-associates head-to-head to form a 200-nm extended tetramer filament. Spectrin cross-links actin filaments into an isotropic meshwork. This spectrin-actin meshwork is attached to the membrane by direct interactions of -spectrin with membrane proteins and indirect interactions of -spectrin with membrane attachment proteins such as ankyrin (2).Proteolysis of ␣-spectrin (␣II-spectrin, non-erythroid spectrin, or fodrin) to discrete fragments is implicated in changes in cell shape and membrane morphology which occur in many cell types. During platelet activation, which includes a cell shape transformation from discs into irregular spheres, spectrin is cleaved to ϳ150-kDa fragments by the calcium-dependent protease, calpain (3). ␣-Spectrin cleavage by calpain has also been implicated in cellular hypoxia (4), neuronal injury and degeneration (5), and neuronal growth cone formation (6). However, in apoptotic cells, ␣-spectrin proteolysis to ϳ150-kDa fragments is mediated by caspases; in these cells, spectrin proteolysis is thought to be important for the disintegration of the plasma membranes via formation of vesicular "apoptotic bodies" (7-12). Although calpain cleavage of spectrin is known to affect its ability to bind membranes or actin filaments (13, 14), the detailed consequences of caspase cleavage of spectrin have not been studied.The terminal ...
Actin filaments are integral components of the plasma membrane-associated cytoskeleton (membrane skeleton) and are believed to play important roles in the determination of cell polarity, shape, and membrane mechanical properties, however the roles of actin regulatory proteins in controlling the assembly, stability, and organization of actin filaments in the membrane skeleton are not well understood. Tropomodulin is a tropomyosin and actin-binding protein that stabilizes tropomyosin-actin filaments by capping their pointed ends and is associated with the spectrin-actin membrane skeleton in erythrocytes, skeletal muscle cells, and lens fiber cells, a specialized epithelial cell type. In this study, we have investigated the role of tropomodulin and other membrane skeleton components in lens fiber cell differentiation and maturation. Our results demonstrate that tropomodulin is expressed concomitantly with lens fiber cell differentiation and assembles onto the plasma membrane only after fiber cells have begun to elongate and form apical-apical contacts with the undifferentiated epithelium. In contrast, other membrane skeleton components, spectrin, actin, and tropomyosin, are constitutively expressed and assembled on the plasma membranes of both undifferentiated and differentiated fiber cells. Tropomodulin, but not other membrane skeleton components, is also enriched at a novel structure at the apical and basal ends of newly elongated fiber cells at the fiber cell-epithelium and fiber cell-capsule interface, respectively. Once assembled, tropomodulin and its binding partners, tropomyosin and actin, remain membrane-associated and are not proteolyzed during fiber cell maturation and aging, despite proteolysis of alpha-spectrin and other cytoskeletal filament systems such as microtubules and intermediate filaments. We propose that actin filament stabilization by tropomodulin, coupled with partial proteolysis of other cytoskeletal components, represents a programmed remodeling of the lens membrane skeleton that may be essential to maintain plasma membrane integrity and transparency of the extremely elongated, long-lived cells of the lens. The unique localization of tropomodulin at fiber cell tips further suggests a new role for tropomodulin at cell-cell and cell-substratum contacts; this may be important for cell migration and/or adhesion during differentiation and morphogenesis.
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