Luigi Petraccone

Effect of O6-Methylguanine on the Stability of G-Quadruplex DNA

The effects of substitution of O6-methylguanine on the structure and stability of a human telomere quadruplex was studied by circular dichroism, thermal denaturation, analytical ultracentrifugation, and molecular dynamics simulations. The results show that, while quadruplex structures can form containing the modified base, they are much less stable than the normal unmodified structure. The extent of destabilization is critically dependent on the exact position of the modified base within the quadruplex structure.

Structure-based drug design: From nucleic acid to membrane protein targets

The in silico methods for drug discovery are becoming increasingly powerful and useful. That, in combination with increasing computer processor power, in our case using a novel distributed computing grid, has enabled us to greatly enhance our virtual screening efforts. Herein we review some of these efforts using both receptor and ligand-based virtual screening, with the goal of finding new anti-cancer agents. In particular, nucleic acids are a neglected set of targets, especially the different morphologies of duplex, triplex, and quadruplex DNA, many of which have increasing biological relevance. We also review examples of molecular modeling to understand receptors and using virtual screening against G-protein coupled receptor membrane proteins.

An integrated molecular dynamics (MD) and experimental study of higher order human telomeric quadruplexes

Structural knowledge of telomeric DNA is critical for understanding telomere biology and for the utilization of telomeric DNA as a therapeutic target. Very little is known about the structure of long human DNA sequences that may form more than one quadruplex unit. Here, we report a combination of molecular dynamics simulations and experimental biophysical studies to explore the structural and dynamic properties of the human telomeric sequence (TTAGGG)(8)TT that folds into two contiguous quadruplexes. Five higher order quadruplex models were built combining known single human telomeric quadruplex structures as unique building blocks. The biophysical properties of this sequence in K(+) solution were experimentally investigated by means of analytical ultracentrifugation and UV spectroscopy. Additionally, the environments of loop adenines were probed by fluorescence studies using systematic single-substitutions of 2-aminopurine for the adenine bases. The comparison of the experimentally determined properties with the corresponding quantities predicted from the models allowed us to test the validity of each of the structural models. One model emerged whose properties are most consistent with the predictions, and which therefore is the most probable structure in solution. This structure features contiguous quadruplex units in an alternating hybrid-1-hybrid-2 conformation with a highly ordered interface composed of loop residues from both quadruplexes.

Studying the effect of crowding and dehydration on DNA G-quadruplexes

Intracellular environment is crowded with biomolecules that occupy a significant fraction (up to 40%) of the cellular volume, with a total concentration in the range 300-400mg/ml. Recently, the effect of crowding/dehydrating agents on the DNA G-quadruplexes has become a subject of an increasing interest. Crowding and/or dehydrating agents have been used to simulate how G-quadruplexes behave under cell-mimicking conditions characterized by a large excluded volume and a lower water activity. Indeed, the presence of both steric crowding and a lower water activity can affect G-quadruplex stability, their folding/unfolding kinetics, as well as their binding processes with proteins or small ligands. Many of these effects can be explored experimentally by measuring the dependence of the conformational stability, isomerisation kinetics and equilibria on the concentration of cosolutes which do not interact with the molecules (G-quadruplexes) under investigation. Spectroscopic methodologies, like circular dichroism, UV and fluorescence, have been widely employed to study G-quadruplexes in dilute solution. Here we focus on some aspects that need to be taken into account when employing such techniques in the presence of large amount of a cosolute. Additionally, we discuss possible problems/artifacts that arise in setting experiments in presence of these commonly employed cosolutes and in interpreting the results.

G-Quadruplexes from Human Telomeric DNA: How Many Conformations in PEG Containing Solutions?

G-quadruplex structures are an attractive target for the development of anticancer drugs, as their formation in human telomere induces a DNA damage response followed by apoptosis in cancer cells. However, the development of new anticancer drugs by means of structural-based drug design is hampered by a lack of accurate information on the exact G-quadruplex conformation adopted by the human telomeric DNA under physiological conditions. Several groups reported that, in a molecular crowded, cell-like environment, simulated by polyethylene glycol (PEG), the human telomeric DNA adopts the parallel G-quadruplex conformation. These studies have suggested that 40% (w/v) PEG concentration induces complete structural conversion from the other known human telomeric G-quadruplex conformations to the parallel G-quadruplex, thus simplifying the high structural polymorphism existing in the absence of PEG. In this study, we demonstrate that the structural conversion to the parallel G-quadruplex is not a complete reaction at physiological temperature. We report a complete kinetic and thermodynamic characterization of the conformational transitions involving the (TTAGGG)(4)TT and (TTAGGG)(8)TT human telomeric DNA sequences in K(+) solution containing PEG. Our data show that the hybrid-type and parallel conformations coexist at equilibrium in the presence of PEG at physiological temperature and the degree of the quadruplex interconversion depends on the PEG molecular weight. Further, we find that telomeric DNA folds in the parallel quadruplex in the seconds time scale, a much larger time scale than the one reported for the hybrid quadruplex folding (~ms). The whole of our data allow us to predict the relative amount of each G-quadruplex conformation as a function of temperature and time. The effect of other crowding agents like Ficoll 400 and glycerol on the quadruplex interconversion has been also explored.

The triazatruxene derivative azatrux binds to the parallel form of the human telomeric G-quadruplex under molecular crowding conditions: biophysical and molecular modeling studies.

The present study has employed a combination of spectroscopic, calorimetric and computational methods to explore the binding of the three side-chained triazatruxene derivative, termed azatrux, to a human telomeric G-quadruplex sequence, under conditions of molecular crowding. The binding of azatrux to the tetramolecular parallel [d(TGGGGT)](4) quadruplex in the presence and absence of crowding conditions, was also characterized. The data indicate that azatrux binds in an end-stacking mode to the parallel G-quadruplex scaffold and highlights the key structural elements involved in the binding. The selectivity of azatrux for the human telomeric G-quadruplex relative to another biologically relevant G-quadruplex (c-Kit87up) and to duplex DNA was also investigated under molecular crowding conditions, showing that azatrux has good selectivity for the human telomeric G-quadruplex over the other investigated DNA structures.

State-of-the-art methodologies for the discovery and characterization of DNA G-quadruplex binders.

Nowadays, the molecular basis of interaction between low molecular weight compounds and biological macromolecules is the subject of numerous investigations aimed at the rational design of molecules with specific therapeutic applications. In the last decades, it has been demonstrated that DNA quadruplexes play a critical role in several biological processes both at telomeric and gene promoting levels thus providing a great stride in the discovery of ligands able to interact with such a biologically relevant DNA conformation. So far, a number of experimental and computational approaches have been successfully employed in order to identify new ligands and to characterize their binding to the DNA. The main focus of this review is the description of these methodologies, placing a particular emphasis on computational methods, isothermal titration calorimetry (ITC), mass spectrometry (MS), nuclear magnetic resonance (NMR), circular dichroism (CD) and fluorescence spectroscopies.

Differential scanning calorimetry to investigate G-quadruplexes structural stability

Differential Scanning Calorimetry (DSC) is a straightforward methodology to characterize the energetics of thermally-induced transitions of DNA and other biological macromolecules. Therefore, DSC has been used to study the thermodynamic stability of several nucleic acids structures. G-quadruplexes are among the most important non-canonical nucleic acid architectures that are receiving great consideration. This article reports examples on the contribution of DSC to the knowledge of G-quadruplex structures. The selected case studies show the potential of this method in investigating the structure stability of G-quadruplex forming nucleic acids, and in providing information on their structural complexity. Indeed, DSC can determine thermodynamic parameters of G-quadruplex folding/unfolding processes, but it can also be useful to reveal the formation of multiple conformations or the presence of intermediate states along the unfolding pathway, and to evaluate the impact of chemical modifications on their structural stability. This article aims to show that DSC is an important complementary methodology to structural techniques, such as NMR and X-ray crystallography, in the study of G-quadruplex forming nucleic acids.

The abasic site lesions in the human telomeric sequence d[TA(G3T2A)3G3]: A thermodynamic point of view

BACKGROUND The abasic sites represent one of the most frequent lesions of DNA and most of the events able to generate such modifications involve guanine bases. G-rich sequences are able to form quadruplex structures that have been proved to be involved in several important biological processes. METHODS In this paper, we report investigations, based on calorimetric, UV, CD and electrophoretic techniques, on 12 oligodeoxynucleotides analogues of the quadruplex forming human telomere sequence d[TA(G(3)T(2)A)(3)G(3)], in which each guanine has been replaced, one at a time, by an abasic site mimic. RESULTS Although all data show that the modified sequences preserve their ability to form quadruplex structures, the thermodynamic parameters clearly indicate that the presence of an abasic site decreases their thermal stability compared to the parent unmodified sequence, particularly if the replacement concerns one of the guanosines involved in the formation of the central G-tetrad. CONCLUSIONS The collected data indicate that the effects of the presence of abasic site lesions in telomeric quadruplex structures are site-specific. The most dramatic consequences come out when this lesion involves a guanosine in the centre of a G-run. GENERAL SIGNIFICANCE Abasic sites, by facilitating the G-quadruplex disruption, could favour the formation of the telomerase primer. Furthermore they could have implications in the pharmacological approach targeting telomere.

5‐Hydroxymethyl‐2′‐Deoxyuridine Residues in the Thrombin Binding Aptamer: Investigating Anticoagulant Activity by Making a Tiny Chemical Modification

We report an investigation into analogues of the thrombin binding aptamer (TBA). Individual thymidines were replaced by the unusual residue 5‐hydroxymethyl‐2′‐deoxyuridine (hmU). This differs from the canonical thymidine by a hydroxyl group on the 5‐methyl group. NMR and CD data clearly indicate that all TBA derivatives retain the ability to fold into the “chair‐like” quadruplex structure. The presence of the hmU residue does not significantly affect the thermal stability of the modified aptamers compared to the parent, except for analogue H9, which showed a marked increase in melting temperature. Although all TBA analogues showed decreased affinities to thrombin, H3, H7, and H9 proved to have improved anticoagulant activities. Our data open up the possibility to enhance TBA biological properties, simply by introducing small chemical modifications.