Angéline Van der Heyden

Template-assembled synthetic G-quadruplex (TASQ): a useful system for investigating the interactions of ligands with constrained quadruplex topologies.

A new biomolecular device for investigating the interactions of ligands with constrained DNA quadruplex topologies, using surface plasmon resonance (SPR), is reported. Biomolecular systems containing an intermolecular-like G-quadruplex motif 1 (parallel G-quadruplex conformation), an intramolecular G-quadruplex 2, and a duplex DNA 3 have been designed and developed. The method is based on the concept of template-assembled synthetic G-quadruplex (TASQ), whereby quadruplex DNA structures are assembled on a template that allows precise control of the parallel G-quadruplex conformation. Various known G-quadruplex ligands have been used to investigate the affinities of ligands for intermolecular 1 and intramolecular 2 DNA quadruplexes. As anticipated, ligands displaying a pi-stacking binding mode showed a higher binding affinity for intermolecular-like G-quadruplexes 1, whereas ligands with other binding modes (groove and/or loop binding) showed no significant difference in their binding affinities for the two quadruplexes 1 or 2. In addition, the present method has also provided information about the selectivity of ligands for G-quadruplex DNA over the duplex DNA. A numerical parameter, termed the G-quadruplex binding mode index (G4-BMI), has been introduced to express the difference in the affinities of ligands for intermolecular G-quadruplex 1 against intramolecular G-quadruplex 2. The G-quadruplex binding mode index (G4-BMI) of a ligand is defined as follows: G4-BMI=K(D)(intra)/K(D)(inter), where K(D)(intra) is the dissociation constant for intramolecular G-quadruplex 2 and K(D)(inter) is the dissociation constant for intermolecular G-quadruplex 1. In summary, the present work has demonstrated that the use of parallel-constrained quadruplex topology provides more precise information about the binding modes of ligands.

Multilayer films based on host–guest interactions between biocompatible polymers

Multilayer films are formed using host-guest interaction between two derivatized chitosans, one, with beta-cyclodextrin cavities and the other with adamantyl moieties.

A novel conformationally constrained parallel g quadruplex.

Guanine-rich DNA sequences are known to form highly ordered structures called G quadruplexes. These structures play an important role in many relevant biological processes, such as telomere stabilization, oncogene activation, and the regulation of the immunoglobulin switch region. The G-quadruplex motif is based on the association of planar G quartets of four guanine residues that are held together by eight Hoogsteen-type hydrogen bonds (Figure 1A). The G-quadruplex motif requires monovalent cations, such as Na and K , for stabilization. A wide variety of topologies can be adopted depending on the number of strands involved in the structure, the strand direction, as well as variations in loop size and sequence (Figure 1). The structure of parallel-stranded as well as antiparallel-stranded quadruplexes have been extensively studied by using different methods, such as NMR spectroscopy, X-ray diffraction and circular dichroism, but the exact conformation present in vivo is still under discussion. The design of small molecules that can bind to G quadruplexes has thus received attention because these nucleic acid motifs represent valuable pharmaceutical targets. For this purpose, a large number of small molecules has been evaluated for their binding with these particular DNA structures. However, as mentioned, the G quadruplex can adopt different topologies that can confuse the study of recognition phenomena. The design of a system that is able to mimic a well-defined conformation of G quadruplex is thus of great interest to precisely study the molecular interactions that can occur with small organic molecules. In 1985, Mutter proposed the TASP concept (template-assembled synthetic proteins) for the design of folded proteins. These pioneering works described the use of a cyclodecapeptide that allows the preparation of artificial proteins with a predetermined three-dimensional structure. Despite a large number of examples that use this template, to our knowledge, it has not been applied for the design of a specific folded structure of nucleic acid. With this in mind, we investigated the use of a peptidic scaffold as a topological template that directs the intramolecular assembly of covalently attached oligonucleotides into a single characteristic folding topology of G quadruplex. We anticipated that the scaffold should permit the preorganization of the DNA strands and the stabilization of the quadruplex structure. We report herein the synthesis and characterization of the novel water-soluble peptidic scaffold–oligonucleotide conjugate 1 that mimics the parallel-stranded conformation of G quadruplex (Scheme 1). We demonstrate that the use of the scaffold allows the precise control of the conformation of the quadruplex and dramatically increases the stability of the motif—all the more so as the formation of the quadruplex motif is possible even without the addition of any monovalent cations, such as K . We also show that mimic 1 can be used for surface functionalization, and this permits the study of the molecular interaction with G-quadruplex ligands by using surface plasmon resonance (SPR). The scaffold used for the synthesis of mimic 1 is a cyclic decapeptide with two independently functionalizable faces, which are due to the orientation of the lysine side-chains. On one side, the four oligonucleotides derived from the human telomeric sequence d(TTAGGGT) were anchored by using oxime bond formation, and a biotin residue was incorporated on the other side for attachment to streptavidin-immobilized surfaces. Earlier work from our laboratory has demonstrated that the oxime coupling strategy allows the efficient preparation of peptide–oligonucleotide conjugates. Figure 1. G-quartet motif and possible folded structures of the G quadruplex. A) G quartet; B) intermolecular parallel form; C) intramolecular parallel form; D) intramolecular antiparallel form.

Tethered bilayer lipid membranes on mixed self-assembled monolayers of a novel anchoring thiol: impact of the anchoring thiol density on bilayer formation.

Tethered bilayer lipid membranes (tBLMs) are designed on mixed self-assembled monolayers (SAMs) of a novel synthetic anchoring thiol, 2,3-di-o-palmitoylglycerol-1-tetraethylene glycol mercaptopropanoic acid ester (TEG-DP), and a new short dilution thiol molecule, tetraethylene glycol mercaptopropanoic acid ester (TEG). tBLM formation was accomplished by self-directed fusion of small unilamellar vesicles of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine. The influence of the dilution of the anchoring thiol molecule in the SAM on the vesicle fusion process and on the properties of the resulting tBLMs is studied. It is observed by quartz crystal microbalance that vesicle fusion is a one-step process for a pure TEG-DP SAM as well as for mixed SAMs containing a high concentration of the anchoring thiol. However, upon dilution of the anchoring thiol to moderate concentrations, this process is decelerated and possibly follows a pathway different from that observed on a pure TEG-DP SAM. Electrochemical impedance spectroscopy is used to qualitatively correlate the composition of the SAM to the electrical properties of the tBLM. In this paper we also delineate the necessity of a critical concentration of this anchoring TEG-DP thiol as a requisite for inducing the fusion of vesicles to form a tBLM.

Interaction of polycationic Ni(II)-salophen complexes with G-quadruplex DNA.

A series of nine Ni(II) salophen complexes involving one, two, or three alkyl-imidazolium side-chains was prepared. The lengths of the side-chains were varied from one to three carbons. The crystal structure of one complex revealed a square planar geometry of the nickel ion. Fluorescence resonance energy transfer melting of G-quadruplex structures in the presence of salophen complex were performed. The G-quadruplex DNA structures were stabilized in the presence of the complexes, but a duplex DNA was not. The binding constants of the complexes for parallel and antiparallel G-quadruplex DNA, as well as hairpin DNA, were measured by surface plasmon resonance. The compounds were selective for G-quadruplex DNA, as reflected by equilibrium dissociation constant KD values in the region 0.1-1 μM for G-quadruplexes and greater than 2 μM for duplex DNA. Complexes with more and shorter side-chains had the highest binding constants. The structural basis for the interaction of the complexes with the human telomeric G-quadruplex DNA was investigated by computational studies: the aromatic core of the complex stacked over the last tetrad of the G-quadruplex with peripherical cationic side chains inserted into opposite grooves. Biochemical studies (telomeric repeat amplification protocol assays) indicated that the complexes significantly inhibited telomerase activity with IC50 values as low as 700 nM; the complexes did not significantly inhibit polymerase activity.

The Flexible Motif V of Epstein-Barr Virus Deoxyuridine 5′-Triphosphate Pyrophosphatase Is Essential for Catalysis

Deoxyuridine 5′-triphosphate pyrophosphatases (dUTPases) are ubiquitous enzymes essential for hydrolysis of dUTP, thus preventing its incorporation into DNA. Although Epstein-Barr virus (EBV) dUTPase is monomeric, it has a high degree of similarity with the more frequent trimeric form of the enzyme. In both cases, the active site is composed of five conserved sequence motifs. Structural and functional studies of mutants based on the structure of EBV dUTPase gave new insight into the mechanism of the enzyme. A first mutant allowed us to exclude a role in enzymatic activity for the disulfide bridge involving the beginning of the disordered C terminus. Sequence alignments revealed two groups of dUTPases, based on the position in sequence of a conserved aspartic acid residue close to the active site. Single mutants of this residue in EBV dUTPase showed a highly impaired catalytic activity, which could be partially restored by a second mutation, making EBV dUTPase more similar to the second group of enzymes. Deletion of the flexible C-terminal tail carrying motif V resulted in a protein completely devoid of enzymatic activity, crystallizing with unhydrolyzed Mg2+-dUTP complex in the active site. Point mutations inside motif V highlighted the essential role of lid residue Phe273. Magnesium appears to play a role mainly in substrate binding, since in absence of Mg2+, the Km of the enzyme is reduced, whereas the kcat is less affected.