Further characterization of the alpha-actinin-actin interface and comparison with filamin-binding sites on actin.
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The interaction between alpha-actinin and actin was further characterized using natural and synthetic peptides of actin together with anti-actin antibodies of known specificity. We demonstrated that two alpha-actinin binding sequences on actin are located within residues 112-125 and 360-372. Each peptide was shown to directly bind alpha-actinin and was able to dissociate the alpha-actinin-actin complex using solid phase binding assays and cosedimentation experiments. Taking into account the three-dimensional structure of actin (Kabsch, W., Mannherz, H. G., Suck, D., Pai, E. F., and Holmes, K. C. (1990) Nature 347, 37-44), we postulate that these two segments, proximal in the actin structure, are part of the same site. In addition, we compared these two segments with those recently found for filamin (Mejean, C., Lebart, M. C., Boyer, M., Roustan, C., and Benyamin, Y. (1992) Eur. J. Biochem. 209, 555-562), Egan, S., Stewart, M., Stossel, T. P., Kwiatkowski, D. J., and Hartwig, J. H. (1990) J. Cell Biol. 111, 1089-1105), and concluded that the two actin-binding proteins interact with closely spaced or overlapping but not identical sequences of actin subdomain 1.Keywords:
Actin-binding protein
Actinin
Actina
Actin remodeling
Characterization
We previously showed that R ab13 and its effector protein, junctional R ab13‐binding protein ( JRAB )/molecules interacting with C as L ‐like 2 ( MICAL ‐L2), regulate junctional development by modulating cell adhesion molecule transport and actin cytoskeletal reorganization in epithelial cells. Here, we investigated how JRAB regulates reorganization of the actin cytoskeleton in NIH 3T3 fibroblasts, in an attempt to obtain novel insights into the mechanism of JRAB action. To this end, we expressed mutant proteins that adopt a constitutively open or closed state and then examined effect on cellular morphology of the resulting actin cytoskeletal reorganization. Expression of the JRAB Δ CT mutant (constitutively ‘closed’ state) induced stress fibers, whereas expression of the JRAB Δ CC mutant (constitutively ‘open’ state) caused cell spreading with membrane ruffles. Next, we identified the proteins involved in JRAB ‐induced rearrangement of actin cytoskeleton leading to morphological changes. In NIH 3T3 cells expressing HA ‐ JRAB Δ CC , filamin, an actin cross‐linking protein, coimmunoprecipitated with HA ‐ JRAB Δ CC . Expression of ASB 2 induced degradation of all three filamin isoforms and inhibited the JRAB Δ CC ‐induced cell spreading. Consistent with our previous results, actinin‐1/‐4 were also immunoprecipitated with HA ‐ JRAB Δ CC . However, actinin‐1/‐4 have no effect on the cell spreading regulated by JRAB Δ CC . These data suggest that JRAB contributes to the rearrangement of the actin cytoskeleton during cell spreading via filamins.
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Actin interaction with L-plastin, a plastin/fimbrins isoform of the α-actinin family of molecules, is poorly characterized, from the biochemical point of view. Besides, molecular modeling of the T-isoform has recently provided a complete model of interaction with filamentous actin [Volkmann, N., DeRosier, D., Matsudaira, P., and Hanein, D. (2001) J. Cell Biol. 153, 947−956]. In this study, we report that recombinant L-plastin binds actin in a manner that strongly resembles that of the α-actinin−actin interface. The similitudes concern the absence of specificity toward the actin isoform and the inhibition of the binding by phosphoinositides. Furthermore, the participation of actin peptides 112−125 and 360−372 in the interface together with an inhibition of the rate of pyrenyl F-actin depolymerization is in favor of a lateral binding of the plastin isoform along the filament axis and strenghtens the similitudes in the way L-plastin and α-actinin bind to actin. We have also investigated the functional aspect and the putative equivalence of the two actin-binding domains of L-plastin toward actin binding. We demonstrate for the first time that the two recombinant fragments, expressed as single domains, have different affinities for actin. We further analyzed the difference using chemical cross-linking and F-actin depolymerization experiments assayed by fluorescence and high-speed centrifugation. The results clearly demonstrate that the two actin-binding domains of plastin display different modes of interaction with the actin filament. We discuss these results in light of the model of actin interaction proposed for T-plastin.
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Actin-binding protein
Myofilament
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Nebulin
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Myofibril
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Most eukaryotic cells spend most of their life in a quiescent state, poised to respond to specific signals to proliferate. In Saccharomyces cerevisiae, entry into and exit from quiescence are dependent only on the availability of nutrients in the environment. The transition from quiescence to proliferation requires not only drastic metabolic changes but also a complete remodeling of various cellular structures. Here, we describe an actin cytoskeleton organization specific of the yeast quiescent state. When cells cease to divide, actin is reorganized into structures that we named "actin bodies." We show that actin bodies contain F-actin and several actin-binding proteins such as fimbrin and capping protein. Furthermore, by contrast to actin patches or cables, actin bodies are mostly immobile, and we could not detect any actin filament turnover. Finally, we show that upon cells refeeding, actin bodies rapidly disappear and actin cables and patches can be assembled in the absence of de novo protein synthesis. This led us to propose that actin bodies are a reserve of actin that can be immediately mobilized for actin cables and patches formation upon reentry into a proliferation cycle.
Actin remodeling
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Actin-binding protein
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Actinin
Actin-binding protein
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Actin-binding protein
Actin remodeling
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Actin-binding proteins (ABPs) regulate the assembly of actin filaments (F-actin) into networks and bundles that provide the structural integrity of the cell. Two of these ABPs, filamin and alpha-actinin, have been extensively used to model the mechanical properties of actin networks grown in vitro; however, there is a lack in the understanding of how the molecular interactions between ABPs and F-actin regulate the dynamic properties of the cytoskeleton. Here, we present a native-like assay geometry to test the rupture force of a complex formed by an ABP linking two quasiparallel actin filaments. We readily demonstrate the adaptability of this assay by testing it with two different ABPs: filamin and alpha-actinin. For filamin/actin and alpha-actinin/actin, we measured similar rupture forces of 40-80 pN for loading rates between 4 and 50 pN/s. Both ABP unfolding and conformational transition events were observed, demonstrating that both are important and may be a significant mechanism for the temporal regulation of the mechanical properties of the actin cytoskeleton. With this modular, single-molecule assay, a wide range of ABP/actin interactions can be studied to better understand cytoskeletal and cell dynamics.
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In endocrine cell, granules accumulate within an F-actin-rich region below the plasma membrane. The mechanisms involved in this process are largely unknown. Rabphilin is a cytosolic protein that is expressed in neurons and neuroendocrine cells and binds with high affinity to members of the Rab3 family of GTPases localized to synaptic vesicles and dense core granules. Rabphilin also interacts with alpha-actinin, a protein that cross-links F-actin into bundles and networks and associates with the granule membrane. Here we asked whether rabphilin, in addition to its granule localization, also interacts with the cell actin cytoskeleton. Immunofluorescence and immunoelectron microscopy show that rabphilin localizes to the sub-plasmalemmal actin cytoskeleton both in neuroendocrine and unspecialized cells. By using purified components, it is found that association of rabphilin with F-actin is dependent on added alpha-actinin. In an in vitro assay, granules, unlike endosomes or mitochondria, associate with F-actin cross-linked by alpha-actinin. Rabphilin is shown to stimulate this process. Rabphilin enhances by approximately 8-fold the granule ability to localize within regions of elevated concentration of cross-linked F-actin. These results suggest that rabphilin, by interacting with alpha-actinin, organizes the cell cytoskeleton to facilitate granule localization within F-actin-rich regions.
Actina
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Actin-binding protein
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Association (psychology)
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The interaction between alpha-actinin and actin was further characterized using natural and synthetic peptides of actin together with anti-actin antibodies of known specificity. We demonstrated that two alpha-actinin binding sequences on actin are located within residues 112-125 and 360-372. Each peptide was shown to directly bind alpha-actinin and was able to dissociate the alpha-actinin-actin complex using solid phase binding assays and cosedimentation experiments. Taking into account the three-dimensional structure of actin (Kabsch, W., Mannherz, H. G., Suck, D., Pai, E. F., and Holmes, K. C. (1990) Nature 347, 37-44), we postulate that these two segments, proximal in the actin structure, are part of the same site. In addition, we compared these two segments with those recently found for filamin (Mejean, C., Lebart, M. C., Boyer, M., Roustan, C., and Benyamin, Y. (1992) Eur. J. Biochem. 209, 555-562), Egan, S., Stewart, M., Stossel, T. P., Kwiatkowski, D. J., and Hartwig, J. H. (1990) J. Cell Biol. 111, 1089-1105), and concluded that the two actin-binding proteins interact with closely spaced or overlapping but not identical sequences of actin subdomain 1.
Actin-binding protein
Actinin
Actina
Actin remodeling
Characterization
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Citations (55)