Elena V. Bichenkova

Tryptophan as a molecular shovel in the glycosyl transfer activity of Trypanosoma cruzi trans-sialidase

Molecular dynamics investigations into active site plasticity of Trypanosoma cruzi trans-sialidase, a protein implicated in Chagas disease, suggest that movement of the Trp(312) loop plays an important role in the enzymes sialic acid transfer mechanism. The observed Trp(312) flexibility equates to a molecular shovel action, which leads to the expulsion of the donor aglycone leaving group from the catalytic site. These computational simulations provide detailed structural insights into sialyl transfer by the trans-sialidase and may aid the design of inhibitors effective against this neglected tropical disease.

DNA-mounted self-assembly: new approaches for genomic analysis and SNP detection.

This article presents an overview of new emerging approaches for nucleic acid detection via hybridization techniques that can potentially be applied to genomic analysis and SNP identification in clinical diagnostics. Despite the availability of a diverse variety of SNP genotyping technologies on the diagnostic market, none has truly succeeded in dominating its competitors thus far. Having been designed for specific diagnostic purposes or clinical applications, each of the existing bio-assay systems (briefly outlined here) is usually limited to a relatively narrow aspect or format of nucleic acid detection, and thus cannot entirely satisfy all the varieties of commercial requirements and clinical demands. This drives the diagnostic sector to pursue novel, cost-effective approaches to ensure rapid and reliable identification of pathogenic or hereditary human diseases. Hence, the purpose of this review is to highlight some new strategic directions in DNA detection technologies in order to inspire development of novel molecular diagnostic tools and bio-assay systems with superior reliability, reproducibility, robustness, accuracy and sensitivity at lower assay cost. One approach to improving the sensitivity of an assay to confidently discriminate between single point mutations is based on the use of target assembled, split-probe systems, which constitutes the main focus of this review.

Exciplex and excimer molecular probes: detection of conformational flip in a myo-inositol chair.

2-O-tert-Butyldimethylsilyl-4,6-bis-O-pyrenoyl-myo-inositol-1,3,5-orthoformate (6) and 2-O-tert-butyldimethylsilyl-4-O-[4-(dimethylamino)benzoyl]-6-O-pyrenoyl-myo-inositol-1,3,5-orthoacetate (10) adopt conformationally restricted unstable chairs with five axial substituents. In the symmetrical diester 6, the two pi-stacked pyrenoyl groups are electron acceptor-donor partners, giving a strong intramolecular excimer emission. In the mixed ester 10, the pyrenoyl group is the electron acceptor and the 4-(dimethylamino)benzoyl ester is the electron donor, giving a strong intramolecular exciplex emission. The conformation of the mixed ester 10 was assessed using 1H NMR spectroscopy (1H-NOESY) and computational studies. which showed the minimum inter-centroid distance between the two aromatic systems to be approximately 3.9 A. Upon addition of acid, the orthoformate/orthoacetate trigger in 6 and 10 was cleaved, which caused a switch of the conformation of the myo-inositol ring to the more stable penta-equatorial chair, leading to separation of the aromatic ester groups and loss of excimer and exciplex fluorescence, respectively. This study provides proof of principle for the development of novel fluorescent molecular probes.

Peptidyl–Oligonucleotide Conjugates Demonstrate Efficient Cleavage of RNA in a Sequence-Specific Manner

Described here is a new class of peptidyl-oligonucleotide conjugates (POCs) which show efficient cleavage of a target RNA in a sequence-specific manner. Through phosphoramidate attachment of a 17-mer TΨC-targeting oligonucleotide to amphiphilic peptide sequences containing leucine, arginine, and glycine, zero-linker conjugates are created which exhibit targeted phosphodiester cleavage under physiological conditions. tRNA(Phe) from brewers yeast was used as a model target sequence in order to probe different structural variants of POCs in terms of selective TΨC-arm directed cleavage. Almost quantitative (97-100%) sequence-specific tRNA cleavage is observed for several POCs over a 24 h period with a reaction half-life of less than 1 h. Nontargeted cleavage of tRNA(Phe) or HIV-1 RNA is absent. Structure-activity relationships reveal that removal of the peptides central glycine residue significantly decreases tRNA cleavage activity; however, this can be entirely restored through replacement of the peptides C-terminal carboxylic acid group with the carboxamide functionality. Truncation of the catalytic peptide also has a detrimental effect on POC activity. Based on the encouraging results presented, POCs could be further developed with the aim of creating useful tools for molecular biology or novel therapeutics targeting specific messenger, miRNA, and genomic viral RNA sequences.

Refined high-field NMR solution structure of a binary-addressed pyrene/perfluoro-azide complementary DNA oligonucleotide system shows extensive distortion in the central nick region

The structural analysis of the photoactivated binary system of complementary-addressing nucleic acid sequences (1:2:3) by high-resolution NMR spectroscopy and restrained molecular dynamics is reported. The binary system comprised a 12 base-pair target DNA sequence, pdGTATCAGTTTCT (1), and two hexanucleotides, (dAGAAACp-L-Az (2) and Pyr-pdTGATAC (3)), complementary to neighbouring sites in the target DNA. Oligonucleotide (2) is conjugated with a p-azidotetrafludrobenzyl group (Az) via a linker group (L), and the other oligonucleotide (3) is equipped with the photosensitizing pyrenyl-1-methylamino group (Pyr). We now extend the structural analysis of 1:2:3, which was previously based on qualitative 2D 1H-NMR data and thermodynamic analysis of complex formation from UV-visible thermal denaturation experiments. In the current work structural refinement was performed by separate molecular dynamics runs for six different starting structures based on 318 proton-proton distance-range constraints, evaluated from the 1H-NOESY spectrum (tau(mix) = 200 ms, 600 MHz) using complete relaxation matrix analysis (NMR/TRIAD/MARDIGRAS). Additional Watson-Crick hydrogen bond restraints were included in the calculations based on the detected signals from the exchangeable protons, using REFOPT(NY) methods. The final averaged structure obtained from the six refined co-ordinate sets showed a considerable degree of axis bend (62.5 degrees) with the bending point in the middle of the duplex in the region of the backbone nick between the two short oligonucleotides. The complex behaves dynamically as the equivalent of two short B-DNA-like duplexes displaying a hinge-like flexing at their junction. In all final structures the Pyr function location was very restricted, the aromatic group lying in the duplex minor groove near residues 4T, 5C and 2T. In contrast, the location of the perfluoroazido group was different in all the final structures, indicating the high flexibility of this group in the duplex. The only feature common to all six final azido group orientations was the outside location on the side of the major groove. The distance between the Pyr and Az groups varied from 11 A to 24 A for the six final structures (17 A, final average structure). The dynamics of duplex denaturation for 1:2:3 was probed by monitoring the temperature-induced NMR line broadening of the imino protons in a 1D variable temperature NMR experiment. The melting of 1:2:3 starts both from the ends and from the middle part of the duplex at the backbone break between the two short oligonucleotides reflecting the destabilisation of the pyrene-arylazido nick region in the duplex.

Strong, Specific, Reversible Binding Ligands for Transfer Rna: Comparison By Fluorescence and Nmr Spectroscopies with Distamycin Binding for a New Structural Class of Ligand

Abstract Binding data are presented for the interaction with brewers yeast tRNAPhc of a new structural family of ligands, symmetrical bis-benzimidazoles. In addition specific perturbations in chemical shifts were detected by 1-dimensional NMR spectroscopy at 400 MHz for some imino and aromatic methyl protons of tRNAPhc when the tRNA was titrated with distamycin. Competitive displacement of the benzimidazole by added distamycin was followed fluorescence spectroscopy.

Molecular basis of action of HyBeacon fluorogenic probes : A spectroscopic and molecular dynamics study

Abstract HyBeacons™, novel DNA probes for ultra-rapid detection of single nucleotide polymorphisms, contain a fluorophore covalently attached via a linker group to an internal nucleotide. As the probe does not require a quencher or self-complementarity to function, this study investigates the molecular-level mechanism underlying the increase of fluorescence intensity on hybridization of HyBeacons™ with target DNA. Spectroscopic ultraviolet-visible and fluorimetrie studies, combined with molecular dynamics simulations, indicate projection of the fluorophore moiety away from the target-probe duplex into aqueous solution, although specific linker-DNA interactions are populated. Based on evidence from this study, we propose that for HyBeacons™, the mechanism of increased fluorescence on hybridization is due to disruption of quenching interactions in the single-stranded probe DNA between the fluorophore and nucleobases. Hybridization leads to an extended linker conformation, removing the fluorophore from the immediate vicinity of the DNA bases.

Molecular probes: insights into design and analysis from computational and physical chemistry

The application of new molecular diagnostics to probe cellular process in vivo is leading to a greater understanding of molecular cytology at a sub-nanoscale level and is opening the way to individualized medicines. We review here three distinct fluorescence-based molecular probes, HyBeacons, split-probe exciplexes and GFP (green fluorescent protein)-based FRET (fluorescence resonance energy transfer) systems. Through this, we highlight the insights into the mechanism and design that a combined computational and experimental approach can yield.

Binding of a porphyrin conjugate of Hoechst 33258 to DNA. I. UV-visible and melting studies detect multiple binding modes to a 12-mer nonself-complementary duplex.

Relative to ligand-free duplex DNA, the melting temperature of the 1:1 complex of the duplex d(CGAATTGTATGC):d(GCATACAATTCG) with the conjugate of Hoechst 33258 with a des-metalloporphyrin, increased from 42 to 60.5°C indicating strong ligand binding. UV–vis spectrophotometric titration detected more than one class of binding site (apparent dissociation constants ∼0.2 μ M for simple noncooperative binding and 1 μ M for the simultaneous cooperative mode with Hill coefficient ∼2).

Protein tyrosine phosphatases: Ligand interaction analysis and optimisation of virtual screening.

Docking-based virtual screening is an established component of structure-based drug discovery. Nevertheless, scoring and ranking of computationally docked ligand libraries still suffer from many false positives. Identifying optimal docking parameters for a target protein prior to virtual screening can improve experimental hit rates. Here, we examine protocols for virtual screening against the important but challenging class of drug target, protein tyrosine phosphatases. In this study, common interaction features were identified from analysis of protein-ligand binding geometries of more than 50 complexed phosphatase crystal structures. It was found that two interactions were consistently formed across all phosphatase inhibitors: (1) a polar contact with the conserved arginine residue, and (2) at least one interaction with the P-loop backbone amide. In order to investigate the significance of these features on phosphatase-ligand binding, a series of seeded virtual screening experiments were conducted on three phosphatase enzymes, PTP1B, Cdc25b and IF2. It was observed that when the conserved arginine and P-loop amide interactions were used as pharmacophoric constraints during docking, enrichment of the virtual screen significantly increased in the three studied phosphatases, by up to a factor of two in some cases. Additionally, the use of such pharmacophoric constraints considerably improved the ability of docking to predict the inhibitors bound pose, decreasing RMSD to the crystallographic geometry by 43% on average. Constrained docking improved enrichment of screens against both open and closed conformations of PTP1B. Incorporation of an ordered water molecule in PTP1B screening was also found to generally improve enrichment. The knowledge-based computational strategies explored here can potentially inform structure-based design of new phosphatase inhibitors using docking-based virtual screening.