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Identification of talin as a major cytoplasmic protein implicated in platelet activation

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Abstract

During platelet activation there is a major reorganization in the platelet cytoskeleton that accompanies a rapid change in platelet shape1,2. Many of the events associated with activation are attributed to a rise in calcium concentration within the platelet cytoplasm3,4. One direct consequence of the elevated calcium is the activation of a calcium-dependent protease that cleaves a major platelet protein of relative molecular mass (Mr) ∼235,000 (235K) to 200K (refs 5, 6). This protein, P235, has been purified6 and reported to interact with actin7, but the significance of the proteolytic cleavage is unknown. Talin, a cytoskeletal protein in smooth muscle and fibroblasts8,9, binds vinculin10 and, together with vinculin8,9,11,12, is localized in fibroblasts at sites of actin–membrane attachment. Talin and P235 have similar purification procedures, sedimentation coefficients and Stokes' radii (ref. 6 and Molony et al., unpublished observations). Of particular significance, talin is readily cleaved by proteases from ∼215K to a fragment of ∼190K27. Given these similarities we have investigated the possible relationship between these proteins. Here we demonstrate that platelet P235 is recognized by anti-talin antibody and that it binds vinculin. Both proteins are cleaved in vitro by the calcium-activated protease to yield similar fragments. We conclude that P235 corresponds to the platelet form of talin.

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Authors and Affiliations

  1. Department of Anatomy, Laboratories for Cell Biology, University of North Carolina School of Medicine, Chapel Hill, North Carolina, 27514, USA

    Theresa O'Halloran, Mary C. Beckerle & Keith Burridge

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  1. Theresa O'Halloran
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  2. Mary C. Beckerle
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  3. Keith Burridge
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O'Halloran, T., Beckerle, M. & Burridge, K. Identification of talin as a major cytoplasmic protein implicated in platelet activation. Nature 317, 449–451 (1985). https://doi.org/10.1038/317449a0

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