Identification and Specificity Studies of Small-Molecule Ligands for SH3 Protein Domains

Proline-rich sequence recognition domains (PRD): ligands, function and inhibition

Low-affinity protein-protein interactions (PPI) between domains of modular proteins and short, solvent-exposed peptide sequences within their binding partners play an essential role in intracellular signaling. An important class of PPIs comprises proline-rich motifs (PRM) that are specifically recognized by PRM-binding domains (PRD). Aromatic side chains of the PRDs define the binding pockets that often recognize individual proline residues, while flanking sequences mediate specificity. Several of these PRM:PRD interactions are associated with cellular malfunction, cancer or infectious diseases. Thus, the design of PRM:PRD inhibitors by using structure-based molecular modeling as well as peptidomimetic approaches and high-throughput screening strategies is of great pharmacological interest. In this chapter we describe the molecular basis of PRM:PRD interactions, highlight their functional role in certain cellular processes and give an overview of recent strategies of inhibitor design.

The social network of a cell: recent advances in interactome mapping

Proteins very rarely act in isolation. Biomolecular interactions are central to all biological functions. In human, for example, interference with biomolecular networks often lead to disease. Protein-protein and protein-metabolite interactions have traditionally been studied one by one. Recently, significant progresses have been made in adapting suitable tools for the global analysis of biomolecular interactions. Here we review this suite of powerful technologies that enable an exponentially growing number of large-scale interaction datasets. These new technologies have already contributed to a more comprehensive cartography of several pathways relevant to human pathologies, offering a broader choice for therapeutic targets. Genome-wide scale analyses in model organisms reveal general organizational principles of eukaryotic proteomes. We also review the biochemical approaches that have been used in the past on a smaller scale for the quantification of the binding constant and the thermodynamics parameters governing biomolecular interaction. The adaptation of these technologies to the large-scale measurement of biomolecular interactions in (semi-)quantitative terms represents an important challenge.

A terphenyl scaffold for pi-stacked guanidinium recognition elements

A new synthetic model of arginine-carboxylate-aromatic triads-common motifs at sites of protein-protein interactions-is reported. Binding studies in mixed methanol/water solvent systems suggest that the carboxylate-binding ability of pi-stacked guanidinium ions is improved relative to a non-stacked control.

Synthetic ligands discovered by in vitro selection

The recognition and catalytic properties of biopolymers derive from an elegant evolutionary mechanism, whereby the genetic material encoding molecules with superior functional attributes survives a selective pressure and is propagated to subsequent generations. This process is routinely mimicked in vitro to generate nucleic-acid or peptide ligands and catalysts. Recent advances in DNA-programmed organic synthesis have raised the possibility that evolutionary strategies could also be used for small-molecule discovery, but the idea remains unproven. Here, using DNA-programmed combinatorial chemistry, a collection of 100 million distinct compounds is synthesized and subjected to selection for binding to the N-terminal SH3 domain of the proto-oncogene Crk. Over six generations, the molecular population converges to a small number of novel SH3 domain ligands. Remarkably, the hits bind with affinities similar to those of peptide SH3 ligands isolated from phage libraries of comparable complexity. The evolutionary approach has the potential to drastically simplify and accelerate small-molecule discovery.

Enteropathogenic Escherichia coli Tir is an SH2/3 ligand that recruits and activates tyrosine kinases required for pedestal formation

Enteropathogenic Escherichia coli (EPEC) cause intestinal inflammation, severe diarrhoea and mortality, particularly among children in developing nations. Upon attachment to intestinal epithelial cells, EPEC induces actin-filled membrane protrusions called 'pedestals' and disrupts microvilli to form attaching and effacing (A/E) lesions. EPEC also disrupts epithelial barrier function and causes colitis. Here we have investigated how virulence factors which orchestrate formation of actin pedestals interface with host tyrosine kinases. We show that Tec-family tyrosine kinases localize beneath EPEC and, with Abl-family kinases, comprise a set of redundant host kinases utilized by EPEC to form actin pedestals. We also show that Tir, a virulence factor required for pathogenesis, contains a polyproline region (PPR) that interacts with SH3 domains of redundant kinases, and a phosphorylation site (Y474) that interacts with kinase SH2 domains. These interactions are essential for pedestal formation, and mimic activation of kinases by cellular ligands. Our results suggest that a positive feedback loop exists in which initial phosphorylation of Tir on Y474 by tyrosine kinases causes recruitment of additional redundant kinases via PPR-SH3 interactions and PO(3)-Y474-SH2 interactions, which in turn phosphorylate other Tir molecules as well as proteins that catalyse formation of actin pedestals.

Affinity chromatography for purification of the modular protein growth factor receptor-bound protein 2 and development of a screening test for growth factor receptor-bound protein 2 Src homology 3 domain inhibitor using peroxidase-linked ligand

Growth factor receptor-bound protein 2 (Grb2) is an adapter protein involved in the Ras-dependent signaling pathway that plays an important role in human cancers initiated by oncogenic receptors. Grb2 is constituted by one Src homology 2 domain surrounded by two SH3 domains, and the inhibition of the interactions produced by these domains could provide an antitumor approach. In evaluating chemical libraries, to search for potential Grb2 inhibitors, it was necessary to elaborate a rapid test for their screening. We have developed, first, a batch method based on the use of an affinity column bearing a Grb2-SH3 peptide ligand to isolate highly purified Grb2. We subsequently describe a very rapid 96-well screening of inhibitors based on a simple competition between purified Grb2 and a peroxidase-coupled proline-rich peptide.

Synthesis of N-benzylated-2-aminoquinolines as ligands for the Tec SH3 domain

In recent work, we have been developing 2-aminoquinolines as ligands for Src Homology 3 (SH3) domains, so far the only reported examples of small-molecule ligands for these domains. In this paper, we report the synthesis of a series of N-benzylated-2-aminoquinolines by reductive amination of aryl aldehydes with 2-aminoquinoline. These ligands bound the SH3 domain with ca. one and a half to twofold reduced affinity relative to 2-aminoquinoline; however, some evidence was found to suggest that the benzylic substituents made new contacts with the SH3 domain surface. These results provide useful SAR information that may assist in future ligand design.

Fragonomics: fragment-based drug discovery

The use of smaller molecules (fragments) in the drug discovery process has led to success in delivering novel leads for many different targets. This process is a highly integrated process, starting from library design to screening and medicinal chemistry. An overview of this process is presented with particular emphasis placed on the NMR aspect of screening.

Synthesis of 5-, 6- and 7-substituted-2-aminoquinolines as SH3 domain ligands

The Src homology 3 (SH3) domains are small protein-protein interaction domains that mediate a range of important biological processes and are considered valuable targets for the development of therapeutic agents. We have been developing 2-aminoquinolines as ligands for SH3 domains--so far the only reported examples of entirely small-molecule ligands for the SH3 domains. The highest affinity 2-aminoquinolines so far identified are 6-substituted compounds. In this article, the synthesis of several new 2-aminoquinolines, including 5-, 6- and 7-substituted compounds, for Tec SH3 domain ligand binding studies is presented. As a part of the synthetic investigation, the utility of different methods for the synthesis of 2-aminoquinolines was explored and potentially powerful methods were identified for the synthesis of 2-aminoquinolines with diverse functionality. Of the compounds prepared, the 5-substituted-2-aminoquinolines generally bound with similar affinities to unsubstituted 2-aminoquinoline, whilst the 7-substituted compounds generally bound with similar or lower affinity than unsubstituted 2-aminoquinoline. However, the 6-substituted-2-aminoquinolines generally bound with significantly higher affinity than unsubstituted 2-aminoquinoline. In addition, one 6-substituted-N-benzylated-2-aminoquinoline was also tested for SH3 binding and some evidence for the formation of additional contacts at other regions of the SH3 domain was found. These results provide new and useful SAR information that should greatly assist with the challenge of developing high affinity small-molecule ligands for the SH3 domains.

Trifluoroacetic acid-mediated hydroarylation: synthesis of dihydrocoumarins and dihydroquinolones

[reaction: see text] Trifluoroacetic acid mediates the hydroarylation of alkenes to afford dihydrocoumarins and dihydroquinolones in good yield. Intermolecular hydroarylation of cinnamic acids by phenols is particularly facile, which leads to the conclusion that previous reports of palladium-catalyzed hydroarylation of cinnamic acids in trifluoroacetic acid are erroneous.