Actin-containing microfilaments control cell shape, adhesion, and contraction. In striated muscle, ␣-actinin and other Z-disk proteins coordinate the organization and functions of actin filaments. In smooth muscle and nonmuscle cells, periodic structures termed dense bodies and dense regions, respectively, are thought to serve functions analogous to Z-discs. We describe here identification and characterization of human palladin, a protein expressed mainly in smooth muscle and nonmuscle and distributed along microfilaments in a periodic manner consistent with dense regions/bodies. Palladin contains three Ig-domains most homologous to the sarcomeric Z-disk protein myotilin. The N terminus includes an FPPPP motif recognized by the Ena-Vasp homology domain 1 domain in Ena/vasodilatator-stimulated phosphoprotein (VASP)/WiscottAldrich syndrome protein (WASP) protein family. Cytoskeletal proteins with FPPPP motif target Ena/VASP/WASP proteins to sites of actin modulation. We identified palladin in a yeast two-hybrid search as an ezrin-associated protein. An interaction between palladin and ezrin was further verified by affinity precipitation and blot overlay assays. The interaction was mediated by the ␣-helical domain of ezrin and by Ig-domains 2-3 of palladin. Ezrin is typically a component of the cortical cytoskeleton, but in smooth muscle cells it is localized along microfilaments. These cells express palladin abundantly and thus palladin may be involved in the microfilament localization of ezrin. Palladin expression was up-regulated in differentiating dendritic cells (DCs), coinciding with major cytoskeletal and morphological alterations. In immature DCs, palladin localized in actin-containing podosomes and in mature DCs along actin filaments. The regulated expression and localization suggest a role for palladin in the assembly of DC cytoskeleton.
INTRODUCTIONActin-containing microfilaments play an essential role in determining cell shape, and in cell locomotion and contractility. Filamentous actin and actin-associated proteins can assemble into higher order structures, such as filopodia, microspikes, lamellipodia, and stress fibers. In various cell types, microfilaments (termed thin filaments in skeletal muscle) interact with myosin and with other proteins to provide machinery for coordinated contraction.In the contractile unit of the skeletal muscle, i.e., the sarcomere, the thin filaments are interconnected and aligned at specialized structures, the Z-discs (Fü rst and Gautel, 1995;Young et al., 1998). In smooth muscle, actin filaments emerge obliquely from structural elements termed dense bodies (reviewed by Small and Gimona, 1998;Stromer 1998). Thus, in smooth muscle, the dense bodies serve a function analogous to the Z-discs. Stress fibers are bundles of actin microfilaments linked to the cell membrane in specific cell attachment sites, focal adhesions. Stress fibers are present in most adherent cell types. They are also organized in a periodical manner and contain structural elements called dense regions (Ka...
