Beáta Flachner

Correlation between conformational stability of the ternary enzyme–substrate complex and domain closure of 3‐phosphoglycerate kinase

3‐Phosphoglycerate kinase (PGK) is a typical two‐domain hinge‐bending enzyme with a well‐structured interdomain region. The mechanism of domain–domain interaction and its regulation by substrate binding is not yet fully understood. Here the existence of strong cooperativity between the two domains was demonstrated by following heat transitions of pig muscle and yeast PGKs using differential scanning microcalorimetry and fluorimetry. Two mutants of yeast PGK containing a single tryptophan fluorophore either in the N‐ or in the C‐terminal domain were also studied. The coincidence of the calorimetric and fluorimetric heat transitions in all cases indicated simultaneous, highly cooperative unfolding of the two domains. This cooperativity is preserved in the presence of substrates: 3‐phosphoglycerate bound to the N domain or the nucleotide (MgADP, MgATP) bound to the C domain increased the structural stability of the whole molecule. A structural explanation of domain–domain interaction is suggested by analysis of the atomic contacts in 12 different PGK crystal structures. Well‐defined backbone and side‐chain H bonds, and hydrophobic and electrostatic interactions between side chains of conserved residues are proposed to be responsible for domain–domain communication. Upon binding of each substrate newly formed molecular contacts are identified that firstly explain the order of the increased heat stability in the various binary complexes, and secondly describe the possible route of transmission of the substrate‐induced conformational effects from one domain to the other. The largest stability is characteristic of the native ternary complex and is abolished in the case of a chemically modified inactive form of PGK, the domain closure of which was previously shown to be prevented [Sinev MA, Razgulyaev OI, Vas M, Timchenko AA & Ptitsyn OB (1989) Eur J Biochem180, 61–66]. Thus, conformational stability correlates with domain closure that requires simultaneous binding of both substrates.

Substrate-induced double sided H-bond network as a means of domain closure in 3-phosphoglycerate kinase

Closure of the two domains of 3‐phosphoglycerate kinase, upon substrate binding, is essential for the enzyme function. The available crystal structures cannot provide sufficient information about the mechanism of substrate assisted domain closure and about the requirement of only one or both substrates, since lattice forces may hinder the large scale domain movements. In this study the known X‐ray data, obtained for the open and closed conformations, were probed by solution small‐angle X‐ray scattering experiments. The results prove that binding of both substrates is essential for domain closure. Molecular graphical analysis, indeed, reveals formation of a double‐sided H‐bond network, which affects substantially the shape of the main molecular hinge at β‐strand L, under the concerted action of both substrates.

Communication between the nucleotide site and the main molecular hinge of 3-phosphoglycerate kinase

3-Phosphoglycerate kinase is a hinge-bending enzyme with substrate-assisted domain closure. However, the closure mechanism has not been described in terms of structural details. Here we present experimental evidence of the participation of individual substrate binding side chains in the operation of the main hinge which is distant from the substrate binding sites. The combined mutational, kinetic, and structural (DSC and SAXS) data for human 3-phosphoglycerate kinase have shown that catalytic residue R38, which also binds the substrate 3-phosphoglycerate, is essential in inducing domain closure. Similarly, residues K219, N336, and E343 which interact with the nucleotide substrates are involved in the process of domain closure. The other catalytic residue, K215, covers a large distance during catalysis but has no direct role in domain closure. The transmission path of the nucleotide effect toward the main hinge of PGK is described for the first time at the level of interactions existing in the tertiary structure.

Structure-Based Consensus Scoring Scheme for Selecting Class A Aminergic GPCR Fragments

Aminergic G-protein coupled receptors (GPRCs) represent well-known targets of central nervous-system related diseases. In this study a structure-based consensus virtual screening scheme was developed for designing targeted fragment libraries against class A aminergic GPCRs. Nine representative aminergic GPCR structures were selected by first clustering available X-ray structures and then choosing the one in each cluster that performs best in self-docking calculations. A consensus scoring protocol was developed using known promiscuous aminergic ligands and decoys as a training set. The consensus score (FrACS-fragment aminergic consensus score) calculated for the optimized protein ensemble showed improved enrichments in most cases as compared to stand-alone structures. Retrospective validation was carried out on public screening data for aminergic targets (5-HT1 serotonin receptor, TA1 trace-amine receptor) showing 8-17-fold enrichments using an ensemble of aminergic receptor structures. The performance of the structure based FrACS in combination with our ligand-based prefilter (FrAGS) was investigated both in a retrospective validation on the ChEMBL database and in a prospective validation on an in-house fragment library. In prospective validation virtual fragment hits were tested on 5-HT6 serotonin receptors not involved in the development of FrACS. Six out of the 36 experimentally tested fragments exhibited remarkable antagonist efficacies, and 4 showed IC50 values in the low micromolar or submicromolar range in a cell-based assay. Both retrospective and prospective validations revealed that the methodology is suitable for designing focused class A GPCR fragment libraries from large screening decks, commercial compound collections, or virtual databases.

Combination of 2D/3D Ligand-Based Similarity Search in Rapid Virtual Screening from Multimillion Compound Repositories. Selection and Biological Evaluation of Potential PDE4 and PDE5 Inhibitors

Rapid in silico selection of target focused libraries from commercial repositories is an attractive and cost effective approach. If structures of active compounds are available rapid 2D similarity search can be performed on multimillion compound databases but the generated library requires further focusing by various 2D/3D chemoinformatics tools. We report here a combination of the 2D approach with a ligand-based 3D method (Screen3D) which applies flexible matching to align reference and target compounds in a dynamic manner and thus to assess their structural and conformational similarity. In the first case study we compared the 2D and 3D similarity scores on an existing dataset derived from the biological evaluation of a PDE5 focused library. Based on the obtained similarity metrices a fusion score was proposed. The fusion score was applied to refine the 2D similarity search in a second case study where we aimed at selecting and evaluating a PDE4B focused library. The application of this fused 2D/3D similarity measure led to an increase of the hit rate from 8.5% (1st round, 47% inhibition at 10 µM) to 28.5% (2nd round at 50% inhibition at 10 µM) and the best two hits had 53 nM inhibitory activities.

Thermodynamic analysis of substrate induced domain closure of 3-phosphoglycerate kinase

The energetic changes accompanying domain closure of 3‐phosphoglycerate kinase, a typical hinge‐bending enzyme, were assessed. Calorimetric titrations of the enzyme with each substrate, both in the absence and presence of the other one, provide information not only about the energetics of substrate binding, but of the associated conformational changes, including domain closure. Our results suggest that conformational rearrangements in the hinge generated by binding of both substrates provide the main driving force for domain closure overcoming the slightly unfavourable contact interactions between the domains.

Role of side-chains in the operation of the main molecular hinge of 3-phosphoglycerate kinase

The single mutants (F165A, E192A, F196A, S392A, T393A) at and near the main hinge (β‐strand L) of human 3‐phosphoglycerate kinase (hPGK) exhibit variously reduced enzyme activity, indicating the cumulative effects of these residues in regulating domain movements. The residues F165 and E192 are also essential in maintaining the conformational integrity of the whole molecule, including the hinge‐region. Shortening of βL by deleting T393 has led to a dramatic activity loss and the concomitant absence of domain closure (as detected by small angle X‐ray scattering), demonstrating the role of βL in functioning of hPGK. The role of each residue in the conformational transmission is described.

Combination of Pharmacophore Matching, 2D Similarity Search, and In Vitro Biological Assays in the Selection of Potential 5-HT6 Antagonists from Large Commercial Repositories

Rapid in silico selection of target‐focused libraries from commercial repositories is an attractive and cost‐effective approach. If structures of active compounds are available, rapid 2D similarity search can be performed on multimillion compound databases, but the generated library requires further focusing. We report here a combination of the 2D approach with pharmacophore matching which was used for selecting 5‐HT6 antagonists. In the first screening round, 12 compounds showed >85% antagonist efficacy of the 91 screened. For the second‐round (hit validation) screening phase, pharmacophore models were built, applied, and compared with the routine 2D similarity search. Three pharmacophore models were created based on the structure of the reference compounds and the first‐round hit compounds. The pharmacophore search resulted in a high hit rate (40%) and led to novel chemotypes, while 2D similarity search had slightly better hit rate (51%), but lacking the novelty. To demonstrate the power of the virtual screening cascade, ligand efficiency indices were also calculated and their steady improvement was confirmed.

Target Identification and Polypharmacology of Nutraceuticals

Abstract Nutraceuticals are mostly multi-target agents and affect the cellular signaling systems in various stages. The multi-target feature of the herbal components allows interactions with several targets that might cooperate in a synergistic way. To elucidate the exact molecular mechanism that the nutraceuticals exhibit, identification of their beneficial effects at the direct protein target is extremely important. The completion of the human genome project has accelerated the development of the target identification methods and many of the traditional techniques were revisited and upgraded. In this chapter, the multi-target or polypharmacology aspects of the nutraceuticals are discussed, which is followed by a detailed overview of the contemporary procedures for the identification of the direct molecular targets of the most important active nutraceutical components.

Monoclonal antibody proteomics: Use of antibody mimotope displaying phages and the relevant synthetic peptides for mAb scouting

Monoclonal antibody proteomics uses nascent libraries or cloned (Plasmascan™, QuantiPlasma™) libraries of mAbs that react with individual epitopes of proteins in the human plasma. At the initial phase of library creation, cognate protein antigen and the epitope interacting with the antibodies are not known. Scouting for monoclonal antibodies (mAbs) with the best binding characteristics is of high importance for mAb based biomarker assay development. However, in the absence of the identity of the cognate antigen the task represents a challenge. We combined phage display, and surface plasmon resonance (Biacore) experiments to test whether specific phages and the respective mimotope peptides obtained from large scale studies are applicable to determine key features of antibodies for scouting. We show here that mAb captured phage-mimotope heterogeneity that is the diversity of the selected peptide sequences, is inversely correlated with an important binding descriptor; the off-rate of the antibodies and that represents clues for driving the selection of useful mAbs for biomarker assay development. Carefully chosen synthetic mimotope peptides are suitable for specificity testing in competitive assays using the target proteome, in our case the human plasma.