The N-terminal domain of Homer/Vesl is a new class II EVH1 domain.

Cellular activities controlled by signal transduction processes such as cell motility and cell growth depend on the tightly regulated assembly of multiprotein complexes. Adapter proteins that specifically interact with their target proteins are key components required for the formation of these assemblies. Ena/VASP-homology 1 (EVH1) domains are small constituents of large modular proteins involved in microfilament assembly that specifically recognize proline-rich regions. EVH1 domain-containing proteins are present in neuronal cells, like the Homer/Vesl protein family that is involved in memory-generating processes. Here, we describe the crystal structure of the murine EVH1 domain of Vesl 2 at 2.2 A resolution. The small globular protein consists of a seven-stranded antiparallel beta-barrel with a C-terminal alpha-helix packing alongside the barrel. A shallow groove running parallel with beta-strand VI forms an extended peptide-binding site. Using peptide library screenings, we present data that demonstrate the high affinity of the Vesl 2 EVH1 domain towards peptide sequences containing a proline-rich core sequence (PPSPF) that requires additional charged amino acid residues on either side for specific binding. Our functional data, substantiated by structural data, demonstrate that the ligand-binding of the Vesl EVH1 domain differs from the interaction characteristics of the previously examined EVH1 domains of the Evl/Mena proteins. Analogous to the Src homology 3 (SH3) domains that bind their cognate ligands in two distinct directions, we therefore propose the existence of two distinct classes of EVH1 domains.

Affinity mass spectrometry-based approaches for the analysis of protein-protein interaction and complex mixtures of peptide-ligands.

Combined applications of affinity purification procedures and mass-spectrometric analyses (affinity mass spectrometry or affinity-directed mass spectrometry) have gained broad interest in various fields of biological sciences. We have extended these techniques to the purification and analysis of closely related peptides from complex mixtures and to the characterization of binding motifs and relative affinities in protein-protein interactions. The posttranslational modifications in the carboxy-terminal region of porcine brain tubulin are used as an example for the applicability of affinity mass spectrometry in the characterization of complex patterns of related peptides. We also show that affinity mass spectrometry allows the mapping of sequential binding motifs of two interacting proteins. Using the ActA/Mena protein-protein complex as a model system, we show that we can selectively purify Mena-binding peptides from a tryptic digest of ActA. The results from this assay are compared to data sets obtained earlier by classical methods using synthetic peptides and molecular genetic experiments. As a further expansion of affinity mass spectrometry, we have established an internally standardized system that allows comparison of the affinities of related ligands for a given protein. Here the affinities of two peptide ligands for the monoclonal tubulin-specific antibody YL1/2 are determined in terms of half-maximal competition.

Aromatic and basic residues within the EVH1 domain of VASP specify its interaction with proline-rich ligands.

Short contiguous peptides harboring proline-rich motifs are frequently involved in protein-protein interactions, such as associations with Src homology 3 (SH3) and WW domains. Although patches of aromatic residues present in either domain interact with polyprolines, their overall structures are distinct, suggesting that additional protein families exist that use stacked aromatic amino acids (AA domains) to bind polyproline motifs [1] [2] [3]. A polyproline motif (E/DFPPPPTD/E in the single-letter amino-acid code), present in the ActA protein of the intracellular bacterial pathogen Listeria monocytogenes, serves as a ligand for the Ena/VASP protein family --the vasodilator-stimulated phosphoprotein (VASP), the murine protein Mena, Drosophila Enabled (Ena) and the Ena/VASP-like protein Evl [4] [5] [6] [7]. These share a similar overall structure characterized by the two highly conserved Ena/VASP homology domains (EVH1 and EVH2) [5]. Here, using three independent assays, we have delineated the minimal EVH1 domain. Mutations of aromatic and basic residues within two conserved hydrophilic regions of the EVH1 domain abolished binding to ActA. Binding of an EVH1 mutant with reversed charges could partially be rescued by introducing complementary mutations within the ligand. Like SH3 domains, aromatic residues within the EVH1 domain interacted with polyprolines, whereas the ligand specificity of either domain was determined by reciprocally charged residues. The EVH1 domain is therefore a new addition to the AA domain superfamily, which includes SH3 and WW domains.

The sophisticated survival strategies of the pathogen Listeria monocytogenes.

The function of the ActA protein of Listeria monocytogenes has been partially elucidated. These results illustrate the sophistication with which intracellular pathogens like Listeria use the host cell to their advantage, and have provided new insights into some of the molecular mechanisms of complex cell functions such as actin-promoted cell motility. The clarification of these processes is of fundamental importance not only for understanding elementary processes such as development and growth, but also for the treatment of both diseases caused by cytopathogenic bacteria such as Listeria and pathophysiological processes arising from disorders in cell motility and cell adhesion.

A novel proline-rich motif present in ActA of Listeria monocytogenes and cytoskeletal proteins is the ligand for the EVH1 domain, a protein module present in the Ena/VASP family.

The ActA protein of the intracellular pathogen Listeria monocytogenes induces a dramatic reorganization of the actin-based cytoskeleton. Two profilin binding proteins, VASP and Mena, are the only cellular proteins known so far to bind directly to ActA. This interaction is mediated by a conserved module, the EVH1 domain. We identify E/DFPPPPXD/E, a motif repeated 4-fold within the primary sequence of ActA, as the core of the consensus ligand for EVH1 domains. This motif is also present and functional in at least two cellular proteins, zyxin and vinculin, which are in this respect major eukaryotic analogs of ActA. The functional importance of the novel protein-protein interaction was examined in the Listeria system. Removal of EVH1 binding sites on ActA reduces bacterial motility and strongly attenuates Listeria virulence. Taken together we demonstrate that ActA-EVH1 binding is a paradigm for a novel class of eukaryotic protein-protein interactions involving a proline-rich ligand that is clearly different from those described for SH3 and WW/WWP domains. This class of interactions appears to be of general importance for processes dependent on rapid actin remodeling.