We herewith present a novel and universal method to convert protein-ligand coordinates into a simple fingerprint of 210 integers registering the corresponding molecular interaction pattern. Each interaction (hydrophobic, aromatic, hydrogen bond, ionic bond, metal complexation) is detected on the fly and physically described by a pseudoatom centered either on the interacting ligand atom, the interacting protein atom, or the geometric center of both interacting atoms. Counting all possible triplets of interaction pseudoatoms within six distance ranges, and pruning the full integer vector to keep the most frequent triplets enables the definition of a simple (210 integers) and coordinate frame-invariant interaction pattern descriptor (TIFP) that can be applied to compare any pair of protein-ligand complexes. TIFP fingerprints have been calculated for ca. 10,000 druggable protein-ligand complexes therefore enabling a wide comparison of relationships between interaction pattern similarity and ligand or binding site pairwise similarity. We notably show that interaction pattern similarity strongly depends on binding site similarity. In addition to the TIFP fingerprint which registers intermolecular interactions between a ligand and its target protein, we developed two tools (Ishape, Grim) to align protein-ligand complexes from their interaction patterns. Ishape is based on the overlap of interaction pseudoatoms using a smooth Gaussian function, whereas Grim utilizes a standard clique detection algorithm to match interaction pattern graphs. Both tools are complementary and enable protein-ligand complex alignments capitalizing on both global and local pattern similarities. The new fingerprint and companion alignment tools have been successfully used in three scenarios: (i) interaction-biased alignment of protein-ligand complexes, (ii) postprocessing docking poses according to known interaction patterns for a particular target, and (iii) virtual screening for bioisosteric scaffolds sharing similar interaction patterns.
A new series of imidazolyl nitrones spin traps has been synthesized and evaluated pharmacologically. The salient structural feature of these molecules is the presence of an imidazole moiety substituted by aromatic or heteroaromatic cycles. This connectivity imparts to the nitrone superior neuroprotective properties in vivo and in parallel reduced side effects and toxicity. Thus compound 6a (a 2-phenylimidazolyl nitrone) administered intraperitoneally protects (80%) mice from lethality induced by an intracerebroventricular administration of tert-butyl hydroperoxide (t-BHP) an oxidant capable of inducing neurodegenerative processes. Administration of the archetypal nitrone phenyl-tert-butyl nitrone (PBN) at an equimolar dose also affords some protection (60%) in this test. However, this activity is accompanied by hypothermia, whereas no such effect is apparent for 6a. Moreover, previously prepared nonsubstituted or alkyl-substituted imidazolyl nitrones were shown to be extremely toxic to rats in contrast to the compounds prepared in this study. The observed activities in vivo correlate well with the calculated partition coefficients (ClogP) and HOMO energy level.
Three-dimensional models of ligand-receptor complexes based on site-directed mutagenesis experiments of the monoamine G protein-coupled receptors reveal the existence of three distinct drug binding sites inside the receptors. Here, we develop this``three-site'' hypothesis and outline its implications for the modular design of ligands for monoamine GPCRs. Molecular models of receptor-ligand complexes are built for the 5-HT 1A receptor where mutagenesis studies map three spatially distinct binding regions which correspond to the binding sites of thè`s mall, one site-®lling'' ligands 5-HT, propranolol and 8-OH-DPAT, respectively. The models of the 5-HT 1A ligandreceptor complexes provide a frame for the discussion of other ligand-receptor interactions, including a 1 and b 2 adrenoceptors, D 1 and D 2 dopamine, and 5-HT 1D and 5-HT 2A receptors, where mutagenesis and modelling studies also showed occupation of the corresponding three binding locations. All three binding sites are located within the highly conserved seven helix transmembrane domain of the receptor and overlap partially at the prominent Asp residue in TM3 which constitutes the benchmark anchor site for monoamine ligands. The analysis of the sequence similarity, for each binding site, among the monoamine GPCR superfamily shows that the three loci display different degrees of evolutionary conservation. This result suggests different roles for each of the binding sites in intrinsic receptor functions and provides additional insights for the design of ligand functionality and selectivity. The existence of three distinct binding sites is also re¯ected by the architecture of known high af®nity ligands which crosslink two or three``one site-®lling'' fragments around a basic amino group. Typical ligands reported in the CipslineyMDDR portfolio illustrate this point despite the occasional dif®culty of attributing the individual ligand fragments to a speci®c receptor site. The database exploration illustrates the binding site promiscuity of some fragments which is particularly evident for symmetrical ligands and which has implications for 3D QSAR methods dependent on alignments. We propose to generate by deconvolution of known ligands three distinct databases of site-speci®c bioisosters which should provide keystones for the design of novel recomposed monoamine GPCR ligands. The systematic exploration of the``three site'' hypothesis should open novel perspectives for the understanding of ligand recognition for this class of therapeutically important receptors.
We report here on the synthesis and pharmacological properties of a new series of small linear and cyclic peptides derived from the five C-terminal amino acid residues of second-generation bradykinin receptor antagonists. Variations of the two first residues of the pentapeptide (Thi-Ser-D-Tic-Oic-Arg) were shown to modulate the biological activities of the analogs on bradykinin-induced smooth muscle contractions in rabbit jugular vein (RJV), a tissue preparation specific of the B2 bradykinin receptor. Several analogs showed pA2 values around 7 on this tissue preparation, and one cyclic compound, c[-Gly-Thi-D-Tic-Oic-Arg-], 24, in which Thi-Ser was replaced by Gly-Thi, displayed a pA2 of 7.4 on RJV. On the basis of these results, three cyclic molecules and their linear counterparts (compounds 22-24 and 4-6, respectively) were tested on human umbilical vein, a tissue specific of the human B2 receptor. The pKB values obtained for these compounds on these tissue preparations were equivalent to those obtained for the decapeptide NPC 567 (4.8 < pA2 < 5.1). NMR and molecular modeling studies performed on compound 24 clearly demonstrated a type II' beta-turn structure. This analog may serve as a new lead for the design of nonpeptide ligands of the bradykinin B2 receptor subtype.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.