Cofilin is a key player in actin dynamics during cell migration. Its activity is regulated by (de)phosphorylation, pH, and binding to phosphatidylinositol-4,5-bisphosphate [PI(4,5)P 2 ]. Here, we here use a human cofilin-1 (D122K) mutant with increased binding affinity for PI(4,5)P 2 and slower release from the plasma membrane to study the role of the PI(4,5)P 2 -cofilin interaction in migrating cells. In fibroblasts in a background of endogenous cofilin, D122K cofilin expression negatively affects cell turning frequency. In carcinoma cells with down-regulated endogenous cofilin, D122K cofilin neither rescues the drastic morphological defects nor restores the effects in cell turning capacity, unlike what has been reported for wild-type cofilin. In cofilin knockdown cells, D122K cofilin expression promotes outgrowth of an existing lamellipod in response to epidermal growth factor (EGF) but does not result in initiation of new lamellipodia. This indicates that, next to phospho-and pH regulation, the normal release kinetics of cofilin from PI(4,5)P 2 is crucial as a local activation switch for lamellipodia initiation and as a signal for migrating cells to change direction in response to external stimuli. Our results demonstrate that the PI(4,5)P 2 regulatory mechanism, that is governed by EGF-dependent phospholipase C activation, is a determinant for the spatial and temporal control of cofilin activation required for lamellipodia initiation.
We propose phage display combined with enzymelinked immunosorbent assay as a tool for the systematic analysis of protein-protein interactions by investigating the binding behavior of variants to a partner protein. Via enzyme-linked immunosorbent assay we determine both the amount of fusion protein presented at the phage surface and the amount of complex formed, the ratio of which is proportional to the affinity. Hence this method enables us to calculate the relative affinities of a large number of mutants. As model systems, we investigated actin-binding motifs conserved in a number of proteins binding monomeric or filamentous actin. The hexapeptide motifs LKKTET, present in thymosin 4, and LKKEKG, present in the villin headpiece, were mutated, and the variants were analyzed. Study of the positional tolerance allows postulating that the motifs, although similar in primary structures adopt different conformations when bound to actin. In addition, our data show that the second and the fourth amino acid of the thymosin 4 motif and the first three residues of the villin headpiece motif are most important for actin binding. The latter result challenges the charged crown hypothesis for the villin headpiece filamentous actin interaction.As a consequence of various genome-sequencing projects, novel proteins are being identified, many of which may take part in new interactions. Efforts are going on to tackle the discovery of protein-protein interactions globally (1), but there is also need for novel methods for the analysis of these interactions, preferably easy, reliable, and high through-put techniques. Several means to probe amino acids that contribute to the binding of two proteins have been developed. X-ray crystallography and NMR may yield superior information about the interface of proteins at atomic resolution (2, 3). However, both methods are intrinsically difficult (even for noncomplexed proteins) and time-consuming and require expensive and sophisticated equipment, as well as large amounts of biological material. Cross-linking of interacting proteins followed by mass spectroscopy or conventional sequence determination of covalently coupled peptide fragments has limited application (4 -6). Probing the accessible surface in protein complexes by deuterium exchange has also been employed (7). But by far the two most popular methods are the use of peptide mimetics either in solution (8) or on membranes (9, 10) and especially site-directed mutagenesis (11, 12). However, in the latter powerful technique to study functions of proteins or interactions between proteins, one often faces the difficulty of choosing the position and type of amino acid exchange to be introduced. To circumvent this, one may perform a saturation mutagenesis at several positions thought to be important for the interaction. Obviously this creates a new problem, i.e. screening a large number of mutants in a systematic way.We propose to combine saturation mutagenesis, phage display and ELISA 1 for the systematic screening and quantification of pr...
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