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

Cytosine-rich oligonucleotides incorporating a non-nucleotide loop: A further step towards the obtainment of physiologically stable i-motif DNA

i-Motifs, also known as i-tetraplexes, are secondary structures of DNA occurring in cytosine-rich oligonucleotides (CROs) that recall increasing interest in the scientific community for their relevance in various biological processes and DNA nanotechnology. This study reports the design of new structurally modified CROs, named Double-Ended-Linker-CROs (DEL-CROs), capable of forming stable i-motif structures. Here, two C-rich strands having sequences d(AC₄A) and d(C₆) have been attached, in a parallel fashion, to the two linker's edges by their 3' or 5' ends. The resulting DEL-CROs have been investigated for their capability to form i-motif structures by circular dichroism, poly-acrylamide gel electrophoresis, HPLC-size-exclusion chromatography, and NMR studies. This investigation established that DEL-CROs could form more stable i-motif structures than the corresponding unmodified CROs. In particular, the i-motif formed by DEL-5'-d(C₆)₂ resulted stable enough to be detected even at near physiological conditions (37 °C, pH 7.0). The results open the way to developing pH-switchable nanocarriers and aptamers based on suitably functionalized DEL-CROs.

Nucleic Acids as Biotools at the Interface between Chemistry and Nanomedicine in the COVID-19 Era

The recent development of mRNA vaccines against the SARS-CoV-2 infection has turned the spotlight on the potential of nucleic acids as innovative prophylactic agents and as diagnostic and therapeutic tools. Until now, their use has been severely limited by their reduced half-life in the biological environment and the difficulties related to their transport to target cells. These limiting aspects can now be overcome by resorting to chemical modifications in the drug and using appropriate nanocarriers, respectively. Oligonucleotides can interact with complementary sequences of nucleic acid targets, forming stable complexes and determining their loss of function. An alternative strategy uses nucleic acid aptamers that, like the antibodies, bind to specific proteins to modulate their activity. In this review, the authors will examine the recent literature on nucleic acids-based strategies in the COVID-19 era, focusing the attention on their applications for the prophylaxis of COVID-19, but also on antisense- and aptamer-based strategies directed to the diagnosis and therapy of the coronavirus pandemic.

Aptamer-Based Antibacterial and Antiviral Therapy against Infectious Diseases

Nucleic acid aptamers are single-stranded DNA or RNA molecules selected in vitro that can bind to a broad range of targets with high affinity and specificity. As promising alternatives to conventional anti-infective agents, aptamers have gradually revealed their potential in the combat against infectious diseases. This article provides an overview on the state-of-art of aptamer-based antibacterial and antiviral therapeutic strategies. Diverse aptamers targeting pathogen-related components or whole pathogenic cells are summarized according to the species of microorganisms. These aptamers exhibited remarkable in vitro and/or in vivo inhibitory effect for pathogenic invasion, enzymatic activities, or viral replication, even for some highly drug-resistant strains and biofilms. Aptamer-mediated drug delivery and controlled drug release strategies are also included herein. Critical technical barriers of therapeutic aptamers are briefly discussed, followed by some future perspectives for their implementation into clinical utility.

Advanced Raman Spectroscopy Detection of Oxidative Damage in Nucleic Acid Bases: Probing Chemical Changes and Intermolecular Interactions in Guanosine at Ultralow Concentration

DNA/RNA synthesis precursors are especially vulnerable to damage induced by reactive oxygen species occurring following oxidative stress. Guanosine triphosphates are the prevalent oxidized nucleotides, which can be misincorporated during replication, leading to mutations and cell death. Here, we present a novel method based on micro-Raman spectroscopy, combined with ab initio calculations, for the identification, detection, and quantification of oxidized nucleotides at low concentration. We also show that the Raman signature in the terahertz spectral range (<100 cm^-1) contains information on the intermolecular assembly of guanine in tetrads, which allows us to further boost the oxidative damage detection limit. Eventually, we provide evidence that similar analyses can be carried out on samples in very small volumes at very low concentrations by exploiting the high sensitivity of surface-enhanced Raman scattering combined with properly designed superhydrophobic substrates. These results pave the way for employing such advanced spectroscopic methods for quantitatively sensing the oxidative damage of nucleotides in the cell.

Novel monomolecular derivatives of the anti-HIV-1 G-quadruplex-forming Hotoda's aptamer containing inversion of polarity sites

Here we report on the design, preparation and investigation of four analogues of the anti-HIV G-quadruplex-forming Hotoda's aptamer, based on an unprecedented linear topology. In these derivatives, four TGGGAGT tracts have been joined together by exploiting 3'-3' and 5'-5' inversion of polarity sites formed by canonical phosphodiester bonds or a glycerol-based linker. Circular dichroism data suggest that all oligodeoxynucleotides fold in monomolecular G-quadruplex structures characterized by a parallel strand orientation and three side loops connecting 3'- or 5'-ends. The derivative bearing two lipophilic groups, namely HT353LGly, inhibited virus entry into the host cell, with anti-HIV-1 activity in the low nanomolar range; the other derivatives, albeit sharing the same base sequence and similar topology, were inactive. These results highlight that monomolecular Hotoda's aptamers with inversion of polarity sites represent a successful alternative strategy that merges the easiness of synthesis with the maintenance of remarkable activity. They also indicate that two lipophilic groups are necessary and sufficient for biological activity. Our data will inspire the design of further simplified derivatives with improved biophysical and antiviral properties.

Probing the Importance of the G-Quadruplex Grooves for the Activity of the Anti-HIV-Integrase Aptamer T30923

In this paper, we report studies concerning four variants of the G-quadruplex forming anti-HIV-integrase aptamer T30923, in which specific 2′-deoxyguanosines have been singly replaced by 8-methyl-2′-deoxyguanosine residues, with the aim to exploit the methyl group positioned in the G-quadruplex grooves as a steric probe to investigate the interaction aptamer/target. Although, the various modified aptamers differ in the localization of the methyl group, NMR, circular dichroism (CD), electrophoretic and molecular modeling data suggest that all of them preserve the ability to fold in a stable dimeric parallel G-quadruplex complex resembling that of their natural counterpart T30923. However, the biological data have shown that the T30923 variants are characterized by different efficiencies in inhibiting the HIV-integrase, thus suggesting the involvement of the G-quadruplex grooves in the aptamer/target interaction.

Biological macromolecule binding and anticancer activity of synthetic alkyne-containing L-phenylalanine derivatives

Herein, we described the synthesis of two L-phenylalanines α-derivatized with a terminal alkyne moiety whose structures differed by phenyl ring halogen substitution (two o-Cl in 1 vs. one p-Br in 2) and investigated their effect on biological macromolecules and living cells. We explored their interaction with quadruplex DNA (G4 DNA), using tel₂₆ and c-myc as models, and bovine serum albumin (BSA). By CD spectroscopy, we found that 1 caused minor tel26 secondary structure changes, leading also to a slight thermal stabilization of this hybrid antiparallel/parallel G4 structure, while the c-myc parallel topology remained essentially unchanged upon 1 binding. Other CD evidences showed the ability of 1 to bind BSA, while molecular docking studies suggested that the same molecule could be housed into the hydrophobic cavity between sub-domains IIA, IIB, and IIIA of the protein. Furthermore, preliminary aggregation studies, based on concentration-dependent spectroscopic experiments, suggested the ability of 1 to aggregate forming noncovalent polymeric systems in aqueous solution. Differently from 1, the bromine-modified compound was able to bind Cu(II) ion, likely with the formation of a CuL₂ complex, as found by UV spectroscopy. Finally, cell tests excluded any cytotoxic effect of both compounds toward normal cells, but showed slight antiproliferative effects of 2 on PC3 cancerous cells at 24 h, and of 1 on both T98G and MDA-MB-231 cancer cells at 48 h.

Hotoda's Sequence and Anti-HIV Activity: Where Are We Now?

The pharmacological relevance of ODNs forming G-quadruplexes as anti-HIV agents has been extensively reported in the literature over the last few years. Recent detailed studies have elucidated the peculiar arrangement adopted by many G-quadruplex-based aptamers and provided insight into their mechanism of action. In this review, we have reported the history of a strong anti-HIV agent: the 6-mer d(TGGGAG) sequence, commonly called "Hotoda's sequence". In particular, all findings reported on this sequence and its modified sequences have been discussed considering the following research phases: (i) discovery of the first 5'-modified active d(TGGGAG) sequences; (ii) synthesis of a variety of end-modified d(TGGGAG) sequences; (iii) biophysical and NMR investigations of natural and modified Hotoda's sequences; (iv); kinetic studies on the most active 5'-modified d(TGGGAG) sequences; and (v) extensive anti-HIV screening of G-quadruplexes formed by d(TGGGAG) sequences. This review aims to clarify all results obtained over the years on Hotoda's sequence, revealing its potentiality as a strong anti-HIV agent (EC₅₀ = 14 nM).

Anti-HIV activity of new higher order G-quadruplex aptamers obtained from tetra-end-linked oligonucleotides

By combining the ability of short G-rich oligodeoxyribonucleotides (ODNs) containing the sequence 5'CGGA3' to form higher order G-quadruplex (G4) complexes with the tetra-end-linked (TEL) concept to produce aptamers targeting the HIV envelope glycoprotein 120 (gp120), three new TEL-ODNs (1-3) having the sequence 5'CGGAGG3' were synthesized with the aim of studying the effect of G4 dimerization on their anti-HIV activity. Furthermore, in order to investigate the effect of the groups at the 5' position, the 5' ends of 1-3 were left uncapped (1) or capped with either the lipophilic dimethoxytrityl (DMT) (2) or the hydrophilic glucosyl-4-phosphate (3) moieties. The here reported results demonstrate that only the DMT-substituted TEL-ODN 2 is effective in protecting human MT-4 cell cultures from HIV infection (76% max protection), notwithstanding all the three new aptamers proved to be capable of forming stable higher order dimeric G4s when annealed in K+-containing buffer, thus suggesting that the recognition of a hydrophobic pocket on the target glycoprotein by the aptamers represents a main structural feature for triggering their anti-HIV activity.

New G-Quadruplex-Forming Oligodeoxynucleotides Incorporating a Bifunctional Double-Ended Linker (DEL): Effects of DEL Size and ODNs Orientation on the Topology, Stability, and Molecularity of DEL-G-Quadruplexes

G-quadruplexes (G4s) are unusual secondary structures of DNA occurring in guanosine-rich oligodeoxynucleotide (ODN) strands that are extensively studied for their relevance to the biological processes in which they are involved. In this study, we report the synthesis of a new kind of G4-forming molecule named double-ended-linker ODN (DEL-ODN), in which two TG₄T strands are attached to the two ends of symmetric, non-nucleotide linkers. Four DEL-ODNs differing for the incorporation of either a short or long linker and the directionality of the TG₄T strands were synthesized, and their ability to form G4 structures and/or multimeric species was investigated by PAGE, HPLC⁻size-exclusion chromatography (HPLC⁻SEC), circular dichroism (CD), and NMR studies in comparison with the previously reported monomeric tetra-ended-linker (TEL) analogues and with the corresponding tetramolecular species (TG₄T)₄. The structural characterization of DEL-ODNs confirmed the formation of stable, bimolecular DEL-G4s for all DEL-ODNs, as well as of additional DEL-G4 multimers with higher molecular weights, thus suggesting a way towards the obtainment of thermally stable DNA nanostructures based on reticulated DEL-G4s.

Monomolecular G-quadruplex structures with inversion of polarity sites: new topologies and potentiality

In this paper, we report investigations, based on circular dichroism, nuclear magnetic resonance spectroscopy and electrophoresis methods, on three oligonucleotide sequences, each containing one 3′-3′ and two 5′-5′ inversion of polarity sites, and four G-runs with a variable number of residues, namely two, three and four (mTG₂T, mTG₃T and mTG₄T with sequence 3′-TG_nT-5′-5′-TG_nT-3′-3′-TG_nT-5′-5′-TG_nT-3′ in which n = 2, 3 and 4, respectively), in comparison with their canonical counterparts (TG_nT)₄ (n = 2, 3 and 4). Oligonucleotides mTG₃T and mTG₄T have been proven to form very stable unprecedented monomolecular parallel G-quadruplex structures, characterized by three side loops containing the inversion of polarity sites. Both G-quadruplexes have shown an all-syn G-tetrad, while the other guanosines adopt anti glycosidic conformations. All oligonucleotides investigated have shown a noteworthy antiproliferative activity against lung cancer cell line Calu 6 and colorectal cancer cell line HCT-116 ^p53−/−. Interestingly, mTG₃T and mTG₄T have proven to be mostly resistant to nucleases in a fetal bovine serum assay. The whole of the data suggest the involvement of specific pathways and targets for the biological activity.

Stabilization vs. destabilization of G-quadruplex superstructures: the role of the porphyrin derivative having spermine arms

The interaction of the porphyrin derivative H₂TCPPSpm4, having spermine pendants in the four meso positions, with the G-quadruplex (GQ) structure formed by the DNA aptamer TGGGAG has been investigated by means of UV, electronic circular dichroism and PAGE studies. The results reported here demonstrate that the porphyrin derivative is capable of stabilizing or destabilizing the higher-ordered structures of parallel GQs, depending on the method used to reach their relative stoichiometry (titration vs. single addition). Noteworthily, when two equivalents of H₂TCPPSpm4 were mixed directly with one equivalent of the (TGGGAG)₄ GQ to reach a 2 : 1 H₂TCPPSpm4 : GQ ratio T_1/2 higher than 80 °C was also observed confirming the presence of higher-ordered GQ structures.

Anti-HIV Activities of Intramolecular G4 and Non-G4 Oligonucleotides

New natural and chemically modified DNA aptamers that inhibit HIV-1 activity at submicromolar concentrations (presumably via preventing viral entry into target cells) are reported. The new DNA aptamers were developed based on known intramolecular G-quadruplexes (G4s) that were functionally unrelated to HIV inhibition [the thrombin-binding aptamer and the fragment of the human oncogene promoter (Bcl2)]. The majority of previously described DNA inhibitors of HIV infection adopt intermolecular structures, and thus their folding variability represents an obvious disadvantage. Intramolecular architectures refold correctly after denaturation and are generally easier to handle. However, whether the G4 topology or other factors account for the anti-HIV activity of our aptamers is unknown. The impact of chemical modification (thiophosphoryl internucleotide linkages) on aptamer activity is discussed. The exact secondary structures of the active compounds and further elucidation of their mechanisms of action hopefully will be the subjects of future studies.

Kinetic ESI-MS Studies of Potent Anti-HIV Aptamers Based on the G-Quadruplex Forming Sequence d(TGGGAG)

To investigate what properties make tetramolecular G-quadruplex ODNs good anti-HIV aptamers, we studied the stoichiometry and the self-assembly kinetics of the highly active 5'-end modified G-quadruplexes based on the d(TGGGAG) sequence. Our results demonstrate that the 5'-end conjugation does not necessarily increase the folding rate of the G-quadruplex; indeed, it ascribes anti-HIV activity. Unexpectedly, the G4-folding kinetics of the inactive G4 is similar to that of the 5'-end modified sequences. ESI-MS studies also revealed the formation of higher order G4 structures identified as octameric complexes along with tetramolecular G-quadruplexes.

Screening Platform toward New Anti-HIV Aptamers Set on Molecular Docking and Fluorescence Quenching Techniques

By using a new rapid screening platform set on molecular docking simulations and fluorescence quenching techniques, three new anti-HIV aptamers targeting the viral surface glycoprotein 120 (gp120) were selected, synthesized, and assayed. The use of the short synthetic fluorescent peptide V35-Fluo mimicking the V3 loop of gp120, as the molecular target for fluorescence-quenching binding affinity studies, allowed one to measure the binding affinities of the new aptamers for the HIV-1 gp120 without the need to obtain and purify the full recombinant gp120 protein. The almost perfect correspondence between the calculated Kd and the experimental EC50 on HIV-infected cells confirmed the reliability of the platform as an alternative to the existing methods for aptamer selection and measuring of aptamer-protein equilibria.

G-Quadruplex Forming Oligonucleotides as Anti-HIV Agents

Though a variety of different non-canonical nucleic acids conformations have been recognized, G-quadruplex structures are probably the structural motifs most commonly found within known oligonucleotide-based aptamers. This could be ascribed to several factors, as their large conformational diversity, marked responsiveness of their folding/unfolding processes to external stimuli, high structural compactness and chemo-enzymatic and thermodynamic stability. A number of G-quadruplex-forming oligonucleotides having relevant in vitro anti-HIV activity have been discovered in the last two decades through either SELEX or rational design approaches. Improved aptamers have been obtained by chemical modifications of natural oligonucleotides, as terminal conjugations with large hydrophobic groups, replacement of phosphodiester linkages with phosphorothioate bonds or other surrogates, insertion of base-modified monomers, etc. In turn, detailed structural studies have elucidated the peculiar architectures adopted by many G-quadruplex-based aptamers and provided insight into their mechanism of action. An overview of the state-of-the-art knowledge of the relevance of putative G-quadruplex forming sequences within the viral genome and of the most studied G-quadruplex-forming aptamers, selectively targeting HIV proteins, is here presented.

Hairpin oligonucleotides forming G-quadruplexes: new aptamers with anti-HIV activity

We describe the facile syntheses of new modified oligonucleotides based on d(TG3AG) that form bimolecular G-quadruplexes and possess a HEG loop as an inversion of polarity site 3'-3' or 5'-5' and aromatic residues conjugated to the 5'-end through phosphodiester bonds. The conjugated hairpin G-quadruplexes exhibited parallel orientation, high thermal stability, elevated resistance in human serum and high or moderate anti-HIV-1 activity with low cytotoxicity. Further, these molecules showed significant binding to HIV envelope glycoproteins gp120, gp41 and HSA, as revealed by SPR assays. As a result, these conjugated hairpins represent the first active anti-HIV-1 bimolecular G-quadruplexes based on the d(TG3AG) sequence.

Synthesis, biophysical characterization and anti-HIV activity of d(TG3AG) Quadruplexes bearing hydrophobic tails at the 5'-end

Novel conjugated G-quadruplex-forming d(TG3AG) oligonucleotides, linked to hydrophobic groups through phosphodiester bonds at 5'-end, have been synthesized as potential anti-HIV aptamers, via a fully automated, online phosphoramidite-based solid-phase strategy. Conjugated quadruplexes showed pronounced anti-HIV activity with some preference for HIV-1, with inhibitory activity invariably in the low micromolar range. The CD and DSC monitored thermal denaturation studies on the resulting quadruplexes, indicated the insertion of lipophilic residue at the 5'-end, conferring always improved stability to the quadruplex complex (20<ΔTm<40°C). The data suggest no direct functional relationship between the thermal stability and anti-HIV activity of the folded conjugated G-quartets. It would appear that the nature of the residue at 5' end of the d(TG3AG) quadruplexes plays an important role in the thermodynamic stabilization but a minor influence on the anti-HIV activity. Moreover, a detailed CD and DSC analyses indicate a monophasic behaviour for sequences I and V, while for ODNs (II-IV) clearly show that these quadruplex structures deviate from simple two-state melting, supporting the hypothesis that intermediate states along the dissociation pathway may exist.

DNA-based nanostructures: The effect of the base sequence on octamer formation from d(XGGYGGT) tetramolecular G-quadruplexes

In a previous work we have demonstrated that the DNA sequence CGGTGGT folds into a higher order G-quadruplex structure (2Q), obtained by the 5'-5' stacking of two unusual G(:C):G(:C):G(:C):G(:C) planar octads belonging to two identical tetra-stranded parallel quadruplexes, when annealed in the presence of ammonium or potassium ions. In the present paper, we discuss the role played by the title nucleosides X and Y (where X and Y stand for A, C, G, or T) on the formation and stability of 2Q structures formed by the XGGYGGT oligodeoxynucleotides. We found that the above mentioned dimerization pathway is not peculiar to the CGGTGGT sequence, but is possible for all the remaining CGGYGGT sequences (with Y = A, C, or G). Furthermore, we have found that the TGGAGGT sequence, despite the absence of the 5'-ending C, is also capable of forming a 2Q-like higher order quadruplex by using a slightly different dimerization interface, as characterized by NMR spectroscopy. To the best of our knowledge, this is the first characterization of a quadruplex multimer formed by an oligodeoxynucleotide presenting a thymine at its 5'-end. Examples of such structures were observed previously only in crystals and in the presence of non-physiological cations. Our results expand the repertoire of DNA quadruplex nanostructures of chosen length and add further complexity to the structural polymorphism of G-rich DNA sequences.

More than one non-canonical phosphodiester bond in the G-tract: formation of unusual parallel G-quadruplex structures

In this article, we report an investigation, based on NMR and CD spectroscopic and electrophoretic techniques, of 5'TGGGGT3' analogues containing two or three 3'-3' or 5'-5' inversion sites in the G-run, namely 5'TG3'-3'G5'-5'GGT3' (Q350), 5'TG3'-3'GG5'-5'GT3' (Q305), 5'TGG3'-3'G5'-5'GT3' (Q035), 5'TG3'-3'G5'-5'G3'-3'GT5' (Q353) and 3'TG5'-5'G3'-3'G5'-5'GT3' (Q535). Although the sequences investigated contain either no or only one natural 3'-5' linkage in the G-tract, all modified oligodeoxyribonucleotides (ODNs) have been shown to form stable tetramolecular quadruplex structures. The ability of the 3'-3' or 5'-5' inversion sites to affect the glycosidic conformation of guanosines and, consequently, base stacking, has also been investigated. The results of this study allow us to propose some generalizations concerning strand arrangements and the glycosidic conformational preference of residues adjacent to inverted polarity sites. These rules could be of general interest in the design of modified quadruplex structures, in view of their application as G-wires and modified aptamers.

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.

Interaction of water with the G-quadruplex loop contributes to the binding energy of G-quadruplex to protein

Unlike DNA duplexes that release water upon interaction with protein, the binding of DNA G-quadruplex of the thrombin-binding aptamer (TBA) to thrombin takes up water. Here, to reveal the mechanism of water uptake, we designed four mutants of TBA (ΔT3, ΔT7, ΔT9, ΔT12), in which thymine residues (T3, T7, T9 and T12) were deleted from the loop regions of TBA G-quadruplex. For the mutants the thermodynamics and the osmolyte effects on the interactions with thrombin were investigated. The mutants ΔT3, ΔT9 and ΔT12 decreased the binding constants of the G-quadruplex to thrombin. Furthermore, an osmotic stress analysis indicated that the number of water molecules binding to the complex decreased in the mutants ΔT3 and ΔT9. The decrease in the binding affinity was related to loss of binding of the loop nucleotides to water molecules. Therefore, the interaction between loops of the G-quadruplex and water molecules contributed to the binding energy of G-quadruplex to protein. Our study suggests that water binding is essential for the binding of G-quadruplex to protein.

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.

Strand directionality affects cation binding and movement within tetramolecular G-quadruplexes

Nuclear magnetic resonance study of G-quadruplex structures formed by d(TG₃T) and its modified analogs containing a 5′-5′ or 3′-3′ inversion of polarity sites, namely d(3′TG5′-5′G₂T3′), d(3′T5′-5′G₃T3′) and d(5′TG3′-3′G₂T5’) demonstrates formation of G-quadruplex structures with tetrameric topology and distinct cation-binding preferences. All oligonucleotides are able to form quadruplex structures with two binding sites, although the modified oligonucleotides also form, in variable amounts, quadruplex structures with only one bound cation. The inter-quartet cavities at the inversion of polarity sites bind ammonium ions less tightly than a naturally occurring 5′-3′ backbone. Exchange of ¹⁵ ions between G-quadruplex and bulk solution is faster at the 3′-end in comparison to the 5′-end. In addition to strand directionality, cation movement is influenced by formation of an all-syn G-quartet. Formation of such quartet has been observed also for the parent d(TG₃T) that besides the canonical quadruplex with only all-anti G-quartets, forms a tetramolecular parallel quadruplex containing one all-syn G-quartet, never observed before in unmodified quadruplex structures.

Structural investigations on the anti-HIV G-quadruplex-forming oligonucleotide TGGGAG and its analogues: evidence for the presence of an A-tetrad

Several anti-HIV aptamers adopt DNA quadruplex structures. Among these, "Hotoda's aptamer" (base sequence TGGGAG) was one of the first to be discovered. Although it has been the topic of some recent research, no detailed structural investigations have been reported. Here we report structural investigations on this aptamer and analogues with related sequences, by using UV, CD, and NMR spectroscopy as well as electrophoretic techniques. The addition of a 3'-end thymine has allowed us to obtain a single, investigable quadruplex structure. Data clearly point to the presence of an A-tetrad. Furthermore, the effects of the incorporation of an 8-methyl-2'-deoxyguanosine at the 5'-end of the G-run were investigated.

Synthesis and structural characterization of stable branched DNA g-quadruplexes using the trebler phosphoramidite

Guanine (G)-rich sequences can form a noncanonical four-stranded structure known as the G-quadruplex. G-quadruplex structures are interesting because of their potential biological properties and use in nanosciences. Here, we describe a method to prepare highly stable G-quadruplexes by linking four G-rich DNA strands to form a monomolecular G-quadruplex. In this method, one strand is synthesized first, and then a trebler molecule is added to simultaneously assemble the remaining three strands. This approach allows the introduction of specific modifications in only one of the strands. As a proof of concept, we prepared a quadruplex where one of the chains includes a change in polarity. A hybrid quadruplex is observed in ammonium acetate solutions, whereas in the presence of sodium or potassium, a parallel G-quadruplex structure is formed. In addition to the expected monomolecular quadruplexes, we observed the presence of dimeric G-quadruplex structures. We also applied the method to prepare G-quadruplexes containing a single 8-aminoguanine substitution and found that this single base stabilizes the G-quadruplex structure when located at an internal position.

Label-free probing of G-quadruplex formation by surface-enhanced Raman scattering

In this work, we establish the use of surface-enhanced Raman scattering (SERS) as a label-free analytical technique for the direct detection of G-quadruplex formation. In particular, we demonstrate that SERS analysis allows the evaluation of the relative stability of G quadruplexes that differ for the number of G tetrads and investigate several structural features of quadruplexes, such as the orientation of glycosidic bonds, the identification of distortions in the sugar-phosphate backbone, and the degree of hydrogen-bond solvation. Herein, the fluctuation of the SERS spectra, due to the specific interaction of vibrational modes with the SERS-active substrate, is quantitatively analyzed before and after quadruplex formation. The results of this study suggest a perpendicular orientation of the quadruplexes (with or without the 3'-tetra end linker) with respect to the silver colloidal surface, which opens new perspectives for the use of SERS as a label-free analytical tool for the study of the binding mode between quadruplexes and their ligands.

HIV-1 integrase inhibitor T30177 forms a stacked dimeric G-quadruplex structure containing bulges

T30177 is a G-rich oligonucleotide with the sequence (GTGGTGGGTGGGTGGGT) which inhibits the HIV-1 integrase activity at nanomolar concentrations. Here we show that this DNA sequence forms in K(+) solution a dimeric G-quadruplex structure comprising a total of six G-tetrad layers through the stacking of two propeller-type parallel-stranded G-quadruplex subunits at their 5'-end. All twelve guanines in the sequence participate in the G-tetrad formation, despite the interruption in the first G-tract by a thymine, which forms a bulge between two adjacent G-tetrads. In this work, we also propose a simple analytical approach to stoichiometry determination using concentration-dependent melting curves.

The evolving world of protein-G-quadruplex recognition: a medicinal chemist's perspective

The physiological and pharmacological role of nucleic acids structures folded into the non canonical G-quadruplex conformation have recently emerged. Their activities are targeted at vital cellular processes including telomere maintenance, regulation of transcription and processing of the pre-messenger or telomeric RNA. In addition, severe conditions like cancer, fragile X syndrome, Bloom syndrome, Werner syndrome and Fanconi anemia J are related to genomic defects that involve G-quadruplex forming sequences. In this connection G-quadruplex recognition and processing by nucleic acid directed proteins and enzymes represents a key event to activate or deactivate physiological or pathological pathways. In this review we examine protein-G-quadruplex recognition in physiologically significant conditions and discuss how to possibly exploit the interactions' selectivity for targeted therapeutic intervention.

Unprecedented right- and left-handed quadruplex structures formed by heterochiral oligodeoxyribonucleotides

CD and NMR studies on heterochiral oligodeoxynucleotides (d/l-ODNs) forming quadruplex structures are reported. Heterochiral ODNs, based on sequence TGGGGT, are able to form stable either right- or left-handed quadruplexes depending on d/l ratio and residues position. Results suggest that the 3'-end and the core of the G-run are more important than the 5'-end in determining the quadruplex handness. Particularly, oligonucleotide T(D)G(D)G(L)G(L)G(D)T(D) (L34) at low temperatures forms a well-defined left-handed quadruplex, notwithstanding it is mostly composed by natural d residues. This structure is characterized by three all-anti G-tetrads and one all-syn G-tetrad.