Jussara Amato

Aminosilane functionalizations of mesoporous oxidized silicon for oligonucleotide synthesis and detection

Direct solid phase synthesis of peptides and oligonucleotides (ONs) requires high chemical stability of the support material. In this work, we have investigated the passivation ability of porous oxidized silicon multilayered structures by two aminosilane compounds, 3-aminopropyltriethoxysilane and 3-aminopropyldimethylethoxysilane (APDMES), for optical label-free ON biosensor fabrication. We have also studied by spectroscopic reflectometry the hybridization between a 13 bases ON, directly grown on the aminosilane modified porous oxidized silicon by in situ synthesis, and its complementary sequence. Even if the results show that both devices are stable to the chemicals (carbonate/methanol) used, the porous silica structure passivated by APDMES reveals higher functionalization degree due to less steric hindrance of pores.

Exploring the Chemical Space of G‑Quadruplex Binders: Discovery of a Novel Chemotype Targeting the Human Telomeric Sequence

Recent findings have unambiguously demonstrated that DNA G-rich sequences can adopt a G-quadruplex folding in living cells, thus further validating them as crucial targets for anticancer therapy. Herein, to identify new potent G4 binders as antitumor drug candidates, we have targeted a 24-nt G4-forming telomeric sequence employing a receptor-based virtual screening approach. Among the best candidates, in vitro binding experiments allowed identification of three novel G4 ligands. Among them, the best compound features an unprecedented binding selectivity for the human telomeric DNA G-quadruplex with no detectable binding for other G4-forming sequences present at different genomic sites. This behavior correlates with the detected ability to generate DNA damage response in tumor cells at the telomeric level and efficient antiproliferative effect on different tumor cell lines at low micromolar concentrations.

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.

Tetra-end-linked oligonucleotides forming DNA G-quadruplexes: a new class of aptamers showing anti-HIV activity.

The biophysical and biological properties of unprecedented anti-HIV aptamers are presented. The most active aptamer (1L) shows a significant affinity to the HIV protein gp120.

Hybridization of short complementary PNAs to G-quadruplex forming oligonucleotides: An electrospray mass spectrometry study

We investigated the interaction of the short peptide nucleic acid (PNA) strand [acccca]-PNA with oligodeoxynucleotides containing one, two, or four tracts of TGGGGT units. Electrospray ionization mass spectrometry allowed exploring the wide variety of complex stoichiometries that were found to coexist in solution. In water, the PNA strand forms short heteroduplexes with the complementary DNA sequences, but higher-order structures are also found, with PNA(2n).DNA(n) triplex units, culminating in precipitation at very low ionic strength. In the presence of ammonium acetate, there is a competition between PNA.DNA heteroduplex formation and DNA G-quadruplex formation. Heteroduplex formation is favored when the PNA + DNA mixture in ammonium acetate is heated and cooled at room temperature, but not if the PNA is added at room temperature to the preformed G-quadruplex. We also found that the short [acccca]-PNA strand binds to G-quadruplexes.

Investigating the role of T7 and T12 residues on the biological properties of thrombin-binding aptamer: enhancement of anticoagulant activity by a single nucleobase modification.

An acyclic pyrimidine analogue, containing a five-member cycle fused on the pyrimidine ring, was synthesized and introduced at position 7 or 12 of the 15-mer oligodeoxynucleotide GGTTGGTGTGGTTGG, known as thrombin-binding aptamer (TBA). Characterization by 1H NMR and CD spectroscopies of the resulting aptamers, TBA-T7b and TBA-T12b, showed their ability to fold into the typical antiparallel chairlike G-quadruplex structure formed by TBA. The apparent CD melting temperatures indicated that the introduction of the acyclic residue, mainly at position 7, improves the thermal stability of resulting G-quadruplexes with respect to TBA. The anticoagulant activity of the new molecules was then valued in PT assay, and it resulted that TBA-T7b is more potent than TBA in prolonging clotting time. On the other hand, in purified fibrinogen assay the thrombin inhibitory activity of both modified sequences was lower than that of TBA using human enzyme, whereas the potency trend was again reversed using bovine enzyme. Obtained structure-activity relationships were investigated by structural and computational studies. Taken together, these results reveal the active role of TBA residues T7 and T12 and the relevance of some amino acids located in the anion binding exosite I of the protein in aptamer-thrombin interaction.

d(CGGTGGT) forms an octameric parallel G-quadruplex via stacking of unusual G(:C):G(:C):G(:C):G(:C) octads

Among non-canonical DNA secondary structures, G-quadruplexes are currently widely studied because of their probable involvement in many pivotal biological roles, and for their potential use in nanotechnology. The overall quadruplex scaffold can exhibit several morphologies through intramolecular or intermolecular organization of G-rich oligodeoxyribonucleic acid strands. In particular, several G-rich strands can form higher order assemblies by multimerization between several G-quadruplex units. Here, we report on the identification of a novel dimerization pathway. Our Nuclear magnetic resonance, circular dichroism, UV, gel electrophoresis and mass spectrometry studies on the DNA sequence dCGGTGGT demonstrate that this sequence forms an octamer when annealed in presence of K+ or NH4+ ions, through the 5′-5′ stacking of two tetramolecular G-quadruplex subunits via unusual G(:C):G(:C):G(:C):G(:C) octads.

New anti-HIV aptamers based on tetra-end-linked DNA G-quadruplexes: effect of the base sequence on anti-HIV activity

This communication reports on the synthesis and biophysical, biological and SAR studies of a small library of new anti-HIV aptamers based on the tetra-end-linked G-quadruplex structure. The new aptamers showed EC(50) values against HIV-1 in the range of 0.04-0.15 μM as well as affinities for the HIV-1 gp120 envelope in the same order of magnitude.

Looking for Efficient G-Quadruplex Ligands: Evidence for Selective Stabilizing Properties and Telomere Damage by Drug-Like Molecules

There is currently significant interest in the development of G‐quadruplex‐interactive compounds, given the relationship between the ability to stabilize these non‐canonical DNA structures and anticancer activity. In this study, a set of biophysical assays was applied to evaluate the binding of six drug‐like ligands to DNA G‐quadruplexes with different folding topologies. Interestingly, two of the investigated ligands showed selective G‐quadruplex‐stabilizing properties and biological activity. These compounds may represent useful leads for the development of more potent and selective ligands.

Synthesis of quadruplex‐forming tetra‐end‐linked oligonucleotides: Effects of the linker size on quadruplex topology and stability

G‐quadruplexes are characteristic structural arrangements of guanine‐rich DNA sequences that abound in regions with relevant biological significance. These structures are highly polymorphic differing in the number and polarity of the strands, loop composition, and conformation. Furthermore, the cation species present in solution strongly influence the topology of the G‐quadruplexes. Recently, we reported the synthesis and structural studies of new G‐quadruplex forming oligodeoxynucleotides (ODNs) in which the 3′‐ and/or the 5′‐ends of four ODN strands are linked together by a non‐nucleotidic tetra‐end‐linker (TEL). These TEL‐ODN analogs having the sequence TGGGGT are able to form parallel G‐quadruplexes characterized by a remarkable high thermal stability. We report here an investigation about the influence of the reduction of the TEL size on the molecularity, topology, and stability of the resulting TEL‐G‐quadruplexes using a combination of circular dichroism (CD), CD melting, 1H NMR spectroscopy, gel electrophoresis, and molecular modeling data. We found that all TEL‐(TGGGGT)4 analogs, regardless the TEL size and the structural orientation of the ODN branches, formed parallel TEL‐G‐quadruplexes. The molecular modeling studies appear to be consistent with the experimental CD and NMR data revealing that the G‐quadruplexes formed by TEL‐ODNs having the longer TEL (L1‐4) are more stable than the corresponding G‐quadruplexes having the shorter TEL (S1‐4). The relative stability of S1‐4 was also reported.