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Hairpin oligonucleotides forming G-quadruplexes: New aptamers with anti-HIV activity
Abstract
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.
Copyright © 2014 Elsevier Masson SAS. All rights reserved.
... However, the really significant and innovative modifications have been reached by modifying the Hotoda's aptamer molecularity from tetramolecular to bi-and monomolecular, to circumvent the poor aggregation rate of four strands to form the tetramolecular G4 structure. Bimolecular Hotoda's aptamer derivatives have been synthesized by joining the 3 0 -or 5 0 -ends of two TGGGAG 6-mers through a hexaethylenglycol loop [32], while the preparation of a family of monomolecular Hotoda's aptamer derivatives has been performed by chemically connecting the 3 0 -or 5 0 -ends of four TGGGAG strands by suitable spacers (tetra-endlinked G4s) [33]. In both cases, the original parallel strand orientation was preserved and a substantial improvement of the biological and physical-chemical properties was obtained [32,33]. ...
... Bimolecular Hotoda's aptamer derivatives have been synthesized by joining the 3 0 -or 5 0 -ends of two TGGGAG 6-mers through a hexaethylenglycol loop [32], while the preparation of a family of monomolecular Hotoda's aptamer derivatives has been performed by chemically connecting the 3 0 -or 5 0 -ends of four TGGGAG strands by suitable spacers (tetra-endlinked G4s) [33]. In both cases, the original parallel strand orientation was preserved and a substantial improvement of the biological and physical-chemical properties was obtained [32,33]. ...
... In the original Hotoda's aptamer, the parallel orientation of the strands is achieved through a tetramolecular G4-complex [21] ( Fig. 1), which is characterized by a relatively slow formation rate. In recent Hotoda's aptamer derivatives, the parallel strand orientation has been obtained either through formation of bimolecular G4 complexes formed by hairpin ODNs or by joining the 3 0 -ends of four ODNs by means of a suitable linker [32]. In this paper, we investigated the properties of a new class of Hotoda's aptamer derivatives in which four ODNs are linearly joined through their 3 0 -or 5 0 -ends. ...
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.
... The G-quadruplex-based structure of ODN A contributes to its antiviral activity It has been previously shown that the strong antiviral activity of ODN A is due to its activation of the viral RNase H [11-13, 15, 16, 29]. However, the finding that ODN A forms G-based hyperstructures raised the question of whether these structures can interfere with HIV infectivity [38][39][40][41]. Therefore, we now included ODN G in our experimental set-up. ...
... Note that Jurkat 1G5 T cells contain a firefly luciferase expression cassette under the control of an HIV-1 LTR promoter; thus, Env-CD4 interaction and subsequent cell fusion enables Tat-mediated luciferase expression (schematically depicted in Fig. 5c, left panel). As expected, this assay clearly revealed that both ODN A and ODN G diminished the interaction of membrane-bound viral Env and cellular CD4 molecules (Fig. 5c, right panel), confirming that G-based structures can per se interfere with HIV infectivity [38][39][40][41]. ...
... Obviously, the formation of G-based quadruplexes would explain the surprisingly high stability of ODN Abased hyperstructures, which combined with its intrinsic solubility, is highly advantageous for further microbicide development. It is known that related DNA aptamers and G-quadruplexes can diminish HIV infectivity by interfering with the binding of viral particles to host cells, or by inhibiting reverse transcription or HIV integration [38][39][40][41]57]. To determine whether the passenger strand contributes to ODN A's significant antiviral potency we used ODN G, a variant unable to recognize the PPT. ...
Background
HIV is primarily transmitted by sexual intercourse and predominantly infects people in Third World countries. Here an important medical need is self-protection for women, particularly in societies where condoms are not widely accepted. Therefore, availability of antiviral microbicides may significantly reduce sexual HIV transmission in such environments.
Methods
Here, we investigated structural characteristics and the antiviral activity of the polypurine tract (PPT)-specific ODN A, a 54-mer oligodeoxynucleotide (ODN) that has been previously shown to trigger the destruction of viral RNA genomes by prematurely activating the retroviral RNase H. The stability of ODN A and mutants thereof was tested at various storage conditions. Furthermore, antiviral effects of ODN A were analyzed in various tissue culture HIV-1 infection models. Finally, circular dichroism spectroscopy was employed to gain insight into the structure of ODN A.
Results
We show here that ODN A is a powerful tool to abolish HIV-1 particle infectivity, as required for a candidate compound in vaginal microbicide applications. We demonstrate that ODN A is not only capable to prematurely activate the retroviral RNase H, but also prevents HIV-1 from entering host cells. ODN A also exhibited extraordinary stability lasting several weeks. Notably, ODN A is biologically active under various storage conditions, as well as in the presence of carboxymethylcellulose CMC (K-Y Jelly), a potential carrier for application as a vaginal microbicide. ODN A’s remarkable thermostability is apparently due to its specific, guanosine-rich sequence. Interestingly, these residues can form G-quadruplexes and may lead to G-based DNA hyperstructures. Importantly, the pronounced antiviral activity of ODN A is maintained in the presence of human semen or semen-derived enhancer of virus infection (SEVI; i.e. amyloid fibrils), both known to enhance HIV infectivity and reduce the efficacy of some antiviral microbicides.
Conclusions
Since ODN A efficiently inactivates HIV-1 and also displays high stability and resistance against semen, it combines unique and promising features for its further development as a vaginal microbicide against HIV.
... Similarly to tetramolecular G-quadruplexes containing IPSs, an interesting application of a bimolecular Gquadruplex incorporating IPSs has involved the design of aptamers endowed with anti-HIV properties. In fact, very recently, the synthesis of new modified ODNs based on the Hotoda's original sequence, 5'TG 3 AG3' [91], has been proposed [105], in which the presence of 3'-3' and 5'-5' IPSs containing hexaethylenglycol (HEG) moieties promotes the formation of parallel hairpin bimolecular G-quadruplex structures (Fig. 10). These complexes have shown high thermal stabilities, an elevated resistance in human serum and high or moderate anti-HIV-1 activities with low cytotoxicities. ...
... This property has been used to prepare a TBA analogue that has allowed the elucidation at an atomic level of several aspects of the TBA/thrombin interaction [70]. Similarly, the introduction of 3'-3' or 5'-5' IPSs containing HEG and connecting two ODN sequences 5'TG 3 AG3', has been exploited to promote the parallel assembly in a bimolecular aptamer that has been proven to possess anti-HIV properties [105]. In order to support the pre-organization of the strands in a specific topology, the synthesis of bunch-ODNs has been proposed, in which four ODNs are linked together through their 3'-or 5'-ends with the aim of directing the entropically unfavourable guanine assembly and enhancing the thermal stability [74,79,81,98]. ...
... Finally, the introduction of 3'-3' IPSs, by masking the 3'ends that are substrates for the ubiquitous 3'-exonucleases, has endowed several anti-coagulant [73] and anti-HIV aptamers [105] with a remarkable resistance in a biological environment. This modification could be easily extended to other biologically active aptamers adopting G-quadruplex structures [10], particularly taking into account the accessibility and simplicity of the synthetic method. ...
The natural sequences of nucleic acids generally consist of nucleotides linked together by canonical 3'-5' phosphodiester bonds. An inversion of polarity site (IPS) can be defined as the point of the sequence in which a 3'-3' or a 5'-5' phosphodiester bond occurs. By extending this definition, an IPS can be described as that part of the sequence in which two 3'- or two 5'-hydroxyl groups are connected by a linker, variable in size or in chemical nature. In G-quadruplex structures an IPS can be introduced in three different positions: inside a non G-tract, inside a G-tract and just between a non G-tract and a G-tract. Investigations have been reported concerning all the three types of modification. This review describes the effects of the presence of one or more IPSs in G-quadruplex structures, particularly regarding their topological and structural characteristics, glycosidic bond preference, and thermal stability, with special attention to biologically active G-quadruplex forming aptamers. The perspectives and potential developments of this research area are also discussed.
... The anti-HIV data of 5 -end-conjugated TEL-ODNs based on Hotoda's sequence (Figure 4a, I, EC 50 = 82 nM) disclosed the importance of kinetic factors, together with conjugation at the 5 -end, in relation to the anti-HIV activity. Figure 4. (a) G-quadruplex structures of monomolecular TEL-ODNs modified at 5 -end with TBDPS group (I) and the both 5 -end and internal modified TEL-G4 (II) with a cytosine that replaces the adenosine base of the Hotoda's sequence [41,42], (b) Bimolecular G-quadruplex Hairpins with related anti-HIV activity (EC 50 ) and thermal stability (T m ) [43]. ...
... Di Fabio et al. also reported the synthesis and biophysical characterization of a new family of modified d(TGGGAG) sequences, the so-called hairpins, that consists of bimolecular d(TGGGAG) G-quadruplexes conjugated at the 5 -end with aromatic groups (Figure 4b) [43]. ...
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).
... The most recent strategy for precise control of G4 folding is based on 'hairpin' ONs [48]. Di Fabio et al. used Hotoda's hexanucleotides to design hairpin mimics that formed a bimolecular analogue of the tetrameric anti-HIV aptamer. ...
... In [45] and [48], mini-libraries of TEL-ODN-based or 'hairpin'-based G4s, respectively, differing in linker position or type and terminal substituents, were synthesized and tested for the ability to inhibit viral entry. Several pseudo-mono/ bi-molecular G4s demonstrated high stability and substantial anti-HIV activity. ...
Many potent DNA aptamers are known to contain a G-quadruplex (G4) core. Structures and applications of the majority of such aptamers have been reviewed previously. The present review focuses on the design and optimization of G4 aptamers. General features of bioactive G4s are analyzed, and the main strategies for construction of aptamers with desired properties and topologies, including modular assembly, control of an aptamer folding and some others, are outlined. Chemical modification as a method for post-SELEX G4 aptamer optimization is also discussed, and the effects of loop and core modifications are compared. Particular attention is paid to the emerging trends, such as the development of genomic G4-inspired aptamers and the combinatorial approaches which aim to find a balance between rational design and selection.
... The differences in anti-viral activities between the four aptamers [TBDPS-d( 5′ TGGGXG 3′ )]4-TEL (with X = A, C, G or T) combined with data of molecular modeling studies, docking the G4s to the V3 loop of gp120, could aid in the understanding of the structural features critical for the biological activity [43]. Bimolecular G-quadruplexes, realized by connecting two d( 5′ TGGGAG 3′ ) fragments to a HEG loop through 3′-3′ or 5′-5′ bridges, in the first case also possessing aromatic residues conjugated through phosphodiester bonds to the available free ends, were showed to exhibit parallel orientation, high thermal stability, elevated resistance in human serum and high-to-moderate anti-HIV-1 activity with low cytotoxicity (Figure 4) [44]. These molecules also showed significant binding to HIV envelope glycoproteins gp120, gp41 and HSA (Human Serum Albumin), as revealed by SPR assays. ...
... Some anti-HIV-1 ODNs forming bimolecular G4s with a HEG loop connecting two Hotoda's sequence tracts through a 3′-3′ bridge described in ref.[44].A remarkable increase of the in vitro anti-HIV activity of the Hotoda's sequence has been observed also upon backbone modifications-replacing the natural phosphodiester bond with locked nucleic acid (LNA) residues-and conjugation with (R)-1-O-(pyren-1-ylmethyl)glycerol (intercalating nucleic acid, INA) or (R)-1-O-[4-(1-pyrenylethynyl)phenylmethyl]glycerol (twisted intercalating nucleic acid, TINA). Incorporation of LNA or INA/TINA monomers produced up to an 8-fold improvement of the anti-HIV-1 activity of ...
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.
... This flexibility could make the sequences regulatory switches, with different function in the G4 and hairpin forms. Other groups have identified G4 sequences that can also switch between G4 and hairpin structures in vitro, showing that this may be a common regulatory strategy evolved for G4s (Hsin-Jui Kuo et al. 2015;Romanucci et al. 2015). While G4-hairpin forming sequences could be an important mechanism for regulating gene expression or acting as a binding site for transcription factors or other proteins, in vivo studies investigating if this switch occurs in live cells and how it impacts cellular function have not been published, leaving their importance unclear. ...
G-quadruplexes (G4s) are highly stable, non-canonical DNA or RNA structures that can form in guanine-rich stretches of nucleic acids. G4-forming sequences have been found in all domains of life, and proteins that bind and/or resolve G4s have been discovered in both bacterial and eukaryotic organisms. G4s regulate a variety of cellular processes through inhibitory or stimulatory roles that depend upon their positions within genomes or transcripts. These include potential roles as impediments to genome replication, transcription, and translation or, in other contexts, as activators of genome stability, transcription, and recombination. This duality suggests that G4 sequences can aid cellular processes but that their presence can also be problematic. Despite their documented importance in bacterial species, G4s remain understudied in bacteria relative to eukaryotes. In this review, we highlight the roles of bacterial G4s by discussing their prevalence in bacterial genomes, the proteins that bind and unwind G4s in bacteria, and the processes regulated by bacterial G4s. We identify limitations in our current understanding of the functions of G4s in bacteria and describe new avenues for studying these remarkable nucleic acid structures.
... In 2014, Romanucci et al. prepared a number of novel analogs bearing different hydrophobic tails at the 5 -ends of Hotoda's sequence for the inhibition of HIV [31]. According to the study, the developed aptamers had low cytotoxicity, high anti-viral activity, good structural stability, and elevated resistance in human serum. ...
The use of short oligonucleotide or peptide molecules as target-specific aptamers has recently garnered substantial attention in the field of the detection and treatment of viral infections. Based on their high affinity and high specificity to desired targets, their use is on the rise to replace antibodies for the detection of viruses and viral antigens. Furthermore, aptamers inhibit intracellular viral transcription and translation, in addition to restricting viral entry into host cells. This has opened up a plethora of new targets for the research and development of novel vaccines against viruses. Here, we discuss the advances made in aptamer technology for viral diagnosis and therapy in the past decade.
... Such a transition is an indication of an active role in the regulatory mechanism. Similar transitions between GQ and hairpins have been shown to have biological relevance previously (Kuo et al. 2015;Romanucci et al. 2015). However, further laboratory work is required to clarify potential topologies as well as the regulatory mechanism of HPGQs found in this study. ...
Many studies show that short non-coding sequences are widely conserved among regulatory elements. More and more conserved sequences are being discovered since the development next generation sequencing technology. A common approach to identify conserved sequences with regulatory roles rely on the topological change such as hairpin formation on the DNA or RNA level. However G quadruplexes, a non-canonical nucleic acid topology with little established biological role, is rarely considered for conserved regulatory element discovery. Here we present the use of G-quadruplex prediction algorithm to identify putative G-quadruplex-forming and conserved elements in E.coli genome. Phylogenetic analysis of 52 G-quadruplex forming sequences revealed two conserved G-quadruplex motifs with potential regulatory role.
... This short d(TGGGAG) sequence forms a very stable parallel tetramolecular G4 and showed significant anti-HIV activity [18]. Taking advantage on our extensive knowledge about d(TGGGAG) sequence [19][20][21], we synthesized new modified d(TGGGAG) sequences with the insertion of a riboflavin moiety in different position of the sequence. ...
In the panorama of modified G-quadruplexes (G4s) with interesting proprieties, here, it has been reported the synthesis of new modified d(TGGGAG) sequences forming G-quadruplexes, with the insertion of a riboflavin unit (Rf, vitamin B2). Exploiting the flavin similarity with the hydrogen bond pattern of guanine and aiming at mimic a typical nucleoside scaffold, the synthesis of the riboflavin building block 3 it has been efficiently carried out. The effect of insertion of riboflavin mimic nucleoside on the G-quadruplex properties has been here, for the first time investigated. A biophysical characterization of Rf-modified sequences (A-D) has been carried out by circular dichroism (CD), fluorescence spectroscopy, differential scanning calorimetry (DSC) and native gel electrophoresis. CD and electrophoresis data have suggested that Rf-modified sequences are able to form parallel tetramolecular G4 structures similar to that of the unmodified sequence. Analysis of the DSC thermograms has revealed that all modified G-quadruplexes have a higher thermal stability compared with the natural sequence, particularly the stabilisation is higher when the Rf residue is introduced at the 3’-end. Further, DSC analysis has revealed that the Rf residues introduced at the 3’-end are able to form additional stabilising interactions, energetically almost comparable to the enthalpic contribution of a G-tetrad. Fluorescence measurement are consistent with this result showing that the Rf residues introduced at 3’-end are able to form stacking interactions with the adjacent bases within the G-quadruplex structure. The whole of data suggested that the introduction of Rf unit can stabilize G-quadruplex structures and can be a promising candidate for future theranostic applications.
... Further aptamers targeting the HIV-1 entry through gp120 interaction are formed by Hotoda's hexamer sequence TG 3 AG (and derivatives bearing lipophilic groups at the 5 -ends) [6] adopting a parallel tetramolecular G4 structure containing an A-tetrad [7]. However, Hotoda's aptamer derivatives are also known to form parallel bimolecular [8] or monomolecular G4 structures [9] based on suitable bifunctional or tetrafunctional linkers [10]. In order to isolate DNA aptamers against the HIV-reverse transcriptase, SELEX approaches have been exploited [11]. ...
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.
... Then, 1.0 mL of a saturated solution of NaHCO 3 and 2.0 mL of hexane were added and the tubes were vortex-mixed. After centrifugation, the hexane layer containing the FAME was placed into a gas chromatography vial that was capped and stored at −20 • C until GC analysis [30][31][32]. ...
During the lipidomic analysis of red blood cell membranes, the distribution and percentage ratios of the fatty acids are measured. Since fatty acids are the key constituents of cell membranes, by evaluating their quantities it possible to understand the general health of the cells and to obtain health indicators of the whole organism. However, because the analysis is precise, it is necessary to ensure that the blood does not undergo significant variations between the point of collection and analysis. The composition of the blood may vary dramatically weeks after collection, hence, here an attempt is made to stabilize these complex matrixes using antioxidants deposited on the paper cards on which the blood itself is deposited.
... Inspired by these findings and aiming to expand the repertoire of potential end-modified d(TGGGAG) aptamers, we recently synthesized and biophysically characterized a variety of d(TGGGAG) ODN 5'end conjugated with hydrophobic moieties via a phosphodiester bond [22][23][24]. All 5'-end modified sequences formed parallel tetramolecular G-quadruplexes with strongly increased thermal stability as confirmed by CD analysis. ...
The biological relevance of tetramolecular G-quadruplexes especially as anti-HIV agents has been extensively reported in the literature over the last years. In the light of our recent results regarding the slow G-quadruplex folding kinetics of ODNs based on d(TGGGAG) sequence, here we report a systematic anti-HIV screening to investigate the impact of the G-quadruplex folding on their anti-HIV activity. In particular, varying the single stranded concentrations of ODNs, it has been tested a pool of ODN sample solutions with different G-quadruplex concentrations. The anti-HIV assays have been designed favouring the limited kinetics involved in the tetramolecular G4-association based on the d(TGGGAG) sequence. Aiming to determine the stoichiometry of G-quadruplex structures in the same experimental conditions of the anti-HIV assays, a native gel electrophoresis was performed. The gel confirmed the G-quadruplex formation for almost all sample solutions while showing the formation of high order G4 structures for the more concentrated ODNs solutions. The most significant result is the discovery of a potent anti-HIV activity of the G-quadruplex formed by the natural d(TGGGAG) sequence (IC50 = 14 nM) that, until now, has been reported to be completely inactive against HIV infection.
... Structural and thermal stability studies by CD were performed on FIX fractions collected under the peak at 11 min and adjusting protein concentration at 0.15 mg/mL with 10 mM phosphate buffer, pH 7.4, as reported in Ref. [18]. Spectra were collected in quartz cuvettes 110-QS (Hellma Italia S.R.L, Milano, Italy) with a path length of 1 mm in the range 190 nm-260 nm on a JASCO J-715 spectropolarimeter equipped with a JASCO PTC-348 thermoelectrically controlled cuvette holder [19]. Samples had slightly different protein concentrations, thereby upon dilution with phosphate buffer they contained different NaCl amounts which could somewhat alter CD spectra at wavelengths below 200 nm. ...
Plasma-derived proteins are a subset of relevant biotherapeutics also known as "well-characterized biologicals". They are enriched from plasma through several steps of physical and biochemical methodologies, reaching the regulatory accepted standards of safety, levels of impurities, activity and lot-to-lot consistency. Final products accepted for commercialization are submitted to tight analytical, functional and safety controls by a number of different approaches that fulfill the requirements of sensitivity and reliability. We report here the use of a multianalytical approach for the comparative evaluation of different lots of Factor IX isolated from plasma preparations and submitted or not to a step of nanofiltration. The approach include, among the other, proteomic techniques based on both MALDI-TOF and LC-MS Orbitrap mass spectrometry, circular dichroism for structural characterization, chromatographic and electrophoretic techniques, ELISA and functional assays based on clotting activity and binding to known anticoagulants. Comparative data obtained on two sets of nanofiltered and non-nanofiltered lots with different final activity show that the products have substantially overlapping profiles in terms of activity, contaminants, structural properties and protein content, suggesting that the proposed multianalytical approach is robust enough to be used for the routine validation of clinical lots.
... The wild-type tetramolecular parallel GQ of TG 3 AG had a of 41.5 ∘ C. The HEG GQs had much higher thermal stability: the first analog 76.0 ∘ C and the second 75.5 ∘ C. The conjugated GQs exhibited elevated resistance in human serum and high or moderate anti-HIV-1 activity with low cytotoxicity. As a result, these conjugated hairpins represent the first active anti-HIV-1 bimolecular GQs based on the TG 3 AG sequence [215]. A doubly modified GQ containing polarity inversion has also been described: L-residues and inversion of polarity sites have been introduced into five TBA DNAs by Esposito et al. ...
Synthetic analogs of natural nucleotides have long been utilized for structural studies of canonical and noncanonical nucleic acids, including the extensively investigated polymorphic G-quadruplexes (GQs). Dependence on the sequence and nucleotide modifications of the folding landscape of GQs has been reviewed by several recent studies. Here, an overview is compiled on the thermodynamic stability of the modified GQ folds and on how the stereochemical preferences of more than 70 synthetic and natural derivatives of nucleotides substituting for natural ones determine the stability as well as the conformation. Groups of nucleotide analogs only stabilize or only destabilize the GQ, while the majority of analogs alter the GQ stability in both ways. This depends on the preferred syn or anti N-glycosidic linkage of the modified building blocks, the position of substitution, and the folding architecture of the native GQ. Natural base lesions and epigenetic modifications of GQs explored so far also stabilize or destabilize the GQ assemblies. Learning the effect of synthetic nucleotide analogs on the stability of GQs can assist in engineering a required stable GQ topology, and exploring the in vitro action of the single and clustered natural base damage on GQ architectures may provide indications for the cellular events.
... As a part of our continuing research effort on the synthesis of new natural product analogues by exploiting phosphoramidite chemistry [21][22][23][24] and inspired by oligoflavonoid structures [1], here, we present an efficient synthesis of some new silibinin derivatives, the Phosphate-Linked Silibinin dimers (PLSd) and related studies of their redox behaviour. In particular, exploiting the selective protection of the hydroxyl groups of the silibinin, we have developed an efficient strategy for the synthesis in good yields of new 3-3, 3-9′′ and 9′′-9′′ silibinin dimers (Scheme 1). ...
By exploiting the regioselective protection of the hydroxyl groups of silibinin along with the well-known phosphoramidite chemistry, we have developed an efficient strategy for the synthesis of new silibinin-modified species, which we have named Phosphate-Linked Silibinin Dimers (PLSd), in which the monomer units are linked by phosphodiester bonds. The antioxidant abilities of the new PLSd were estimated on HepG2 cells using DPPH free radical scavenging and xanthine/xanthine oxidase assays. The new phosphate-metabolites showed a higher anti-oxidant activity than the silibinin, as well as very low toxicity. The ability to scavenge reactive oxygen species (ROS) such as singlet oxygen (1 2 O) and hydroxyl radical (HO •) reveals that the two dimers are able to scavenge HO • about two times more effectively than silibinin. Finally, solubility studies have shown that the PLSd present good water solubility (more than 20 mg·L −1) under circumneutral pH values, whereas the silibinin was found to be very poorly soluble (less than 0.4 mg·L −1) and not stable under alkaline conditions. Together, the above promising results warrant further investigation of the future potential of the PLSd as anti-oxidant metabolites within the large synthetic polyphenols field.
... Later on, Koizumi et al. synthesized a set of G-rich oligonucleotides and identified the hexadeosyribonucleotide d(TGGGAG), known as Hotoda's sequence, [49,50]. Several authors have used the Hotoda's sequence as a lead sequence to make a series of modifications at the 5 and 3 ends of the molecule or mutations in the sequence that allowed to find molecules with high anti-HIV activity [50][51][52][53][54][55][56]. ...
Appropriate diagnosis is the key factor for treatment of viral diseases. Time is the most important factor in rapidly developing and epidemiologically dangerous diseases, such as influenza, Ebola and SARS. Chronic viral diseases such as HIV-1 or HCV are asymptomatic or oligosymptomatic and the therapeutic success mainly depends on early detection of the infective agent. Over the last years, aptamer technology has been used in a wide range of diagnostic and therapeutic applications and, concretely, several strategies are currently being explored using aptamers against virus proteins. From a diagnostics point of view, aptamers are being designed as a bio-recognition element in diagnostic systems to detect viral proteins either in the blood (serum or plasma) or into infected cells. Another potential use of aptamers is for therapeutics of viral infections, interfering in the interaction between the virus and the host using aptamers targeting host-cell matrix receptors, or attacking the virus intracellularly, targeting proteins implicated in the viral replication cycle. In this paper, we review how aptamers working against viral proteins are discovered, with a focus on recent advances that improve the aptamers’ properties as a real tool for viral infection detection and treatment.
... Since both Mg ++ and K + are present in the E. coli cytosol, a regulatory switch based on both states is possible. Similar transitions between GQ and hairpins have previously been shown to have biological relevance (60,61). However it cannot be conclusive as the CD signatures of G-quadruplexes were shown to vary and the CD signature we obtained in Mg ++ resembles to that of an alternate GQ-forming sequence (62). ...
Many studies show that short non-coding sequences are widely conserved among regulatory elements. More and more conserved sequences are being discovered since the development of next generation sequencing technology. A common approach to identify conserved sequences with regulatory roles relies on topological changes such as hairpin formation at the DNA or RNA level. G-quadruplexes, non-canonical nucleic acid topologies with little established biological roles, are increasingly considered for conserved regulatory element discovery. Since the tertiary structure of G-quadruplexes is strongly dependent on the loop sequence which is disregarded by the generally accepted algorithm, we hypothesized that G-quadruplexes with similar topology and, indirectly, similar interaction patterns, can be determined using phylogenetic clustering based on differences in the loop sequences. Phylogenetic analysis of 52 G-quadruplex forming sequences in the Escherichia coli genome revealed two conserved G-quadruplex motifs with a potential regulatory role. Further analysis revealed that both motifs tend to form hairpins and G quadruplexes, as supported by circular dichroism studies. The phylogenetic analysis as described in this work can greatly improve the discovery of functional G-quadruplex structures and may explain unknown regulatory patterns.
Synthetically modified DNA G-quadruplexes (GQs) have great potential in the development of designer molecules for a wide range of applications. Identification of the role of various structural elements in the folding and final topology of artificial GQs is necessary to predict their secondary structure. We report here the results of spectroscopic and electrophoretic studies of GQ scaffolds formed by G-rich sequences comprising four G3-tracts of different polarity connected by either a single-nucleotide thymine loop or a non-natural tetraethyleneglycol loop. Depending on G-strand polarities, loop arrangement and the presence of extra 5′-base G-rich oligonucleotides form monomeric, dimeric, or multimeric species of different topologies. In most cases, oligonucleotides were able to fold into stable parallel or hybrid GQs. However, certain specific arrangements of loops and G-tracts resulted in a diverse mixture of low stable structures. Comparative analysis of topology, stability, and structural heterogeneity of different G-rich sequences suggests the important role of loop type and arrangement, G3-tract polarities, and the presence of 5′-capping residues in the outcome of the folding process. The results also imply that the formation of anti-parallel G-hairpin intermediates is a key event in major favourable folding pathways.
I-motifs are largely underexplored tetraplex nucleic acid structures which have been suggested to play essential biological functions and might constitute future therapeutic targets. I-motifs generally require acidic conditions to fold in vitro, a particularity which significantly complicates the use of native i-motif forming sequences for interactions studies with potential ligands and biological components (e.g. proteins). In this context, we report herein on the assembly of a peptide-DNA conjugate capable to fold at room temperature into a stable i-motif structure at neutral pH. To achieve the controlled assembly of the i-motif forming conjugate, we developed a new synthetic pathway of four successive orthogonal ligation reactions between bifunctional C-rich DNA strands and a tetrafunctional cyclopeptide scaffold.
Chemically optimizing the molecular structure of aptamers may enhance properties such as biological activity or metabolic stability. DNA quadruplex–based HIV-1 fusion inhibitors were found to interact with HIV-1 surface glycoprotein in aptamer mode. In this work, a series of quadruplex-based HIV-1 fusion inhibitors with flexible oligodeoxynucleotide fragments at the 3′ terminal was discovered. The flexible extension did not greatly influence quadruplex formation at the 5′-end. Increasing the length of the flexible fragment may increase antifusion activity. Compared with a traditional inhibitor, d( ⁵′ TGGGAG 3′ ) 4 , these novel inhibitors showed enhanced interaction with HIV-1 glycoproteins gp120 and gp41, which increased inhibition of 6-helical bundle formation during the course of virus fusion. These inhibitors also showed improved stability, compared with natural oligodeoxynucleotide. This work may inform the design of anti–HIV-1 DNA helix-based inhibitors with new structures or mechanisms.
G-quadruplex stabilizers are an established opportunity in anticancer chemotherapy. To circumvent the antiproliferative effects of G4 ligands, cancer cells recruit PARP enzymes at telomeres. Herein, starting from the structural similarity of a potent G4 ligand previously discovered by our group and a congeneric PARP inhibitor, a library of derivatives was synthesized to discover the first dual G4/PARP ligand. We demonstrate that a properly decorated thieno[3,2-c]quinolin-4(5H)-one stabilizes the G4 fold in vitro and in cells, induces a DNA damage response localized to telomeres, inhibits PARylation in cells and has an antiproliferative effect in BRCA2 deficient tumor cells.
G-rich DNA oligonucleotides derived from the promoter region of the HIV-1 Long Terminal Repeat (LTR) were assembled onto an addressable cyclopeptide platform through sequential oxime ligation, thiol-iodoacetamide SN2 reaction and copper-catalyzed azide-alkyne cycloaddition reactions. The resulting conjugate was shown to fold into a highly stable antiparallel G4 architecture as demonstrated by UV, circular dichroism (CD), and NMR spectroscopic analysis. The binding affinities of six state-of-the-art G4 binding ligands toward the HIV G4 structure were compared to those obtained with a telomeric G4 structure and a hairpin structure. Surface plasmon resonance binding analysis provides new insights into the binding mode of broadly exploited G4 chemical probes and further suggests that potent and selective recognition of viral G4 structures of functional significance might be achieved
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.
DNA triplexes with hydrophobic modifications were designed and evaluated for their activity as inhibitors of the cell fusion of human immunodeficiency virus type 1 (HIV-1). Triplex inhibitors displayed low micromolar activities in the cell-cell fusion assay and nanomolar activities in the anti-HIV-1 pseudovirus test. Helix structure and the presence of sufficient numbers of hydrophobic regions were essential for the antifusion activity. Results from native polyacrylamide gel electrophoresis and a fluorescent resonance energy transfer-based inhibitory assay indicated that these triplexes may interact with the primary pocket at the glycoprotein 41 (gp41) N-heptad repeat, thereby inhibiting formation of the HIV-1 gp41 6-helical bundle. Triplex-based complexes may represent a novel category of HIV-1 inhibitors in anti-HIV-1 drug discovery.
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.
A series of d((5')TGGGAG(3')) sequences, 5'-conjugated with a variety of aromatic groups through phosphodiester linkages, were synthesized, showing CD spectra diagnostic of parallel-stranded, tetramolecular G-quadruplex structures. When tested for anti-HIV-1 and HIV-2 activity, potent inhibition of HIV-1 infection in CEM cell cultures was found, associated with high selectivity index values. Surface Plasmon Resonance assays revealed specific binding to HIV-1 gp120 and gp41.
Two G-quadruplex forming sequences, 5′-TGGGAG and the 17-mer sequence T30177, which exhibit anti-HIV-1 activity on cell lines,
were modified using either locked nucleic acids (LNA) or via insertions of (R)-1-O-(pyren-1-ylmethyl)glycerol (intercalating nucleic acid, INA) or (R)-1-O-[4-(1-pyrenylethynyl)phenylmethyl]glycerol (twisted intercalating nucleic acid, TINA). Incorporation of LNA or INA/TINA monomers
provide as much as 8-fold improvement of anti-HIV-1 activity. We demonstrate for the first time a detailed analysis of the
effect the incorporation of INA/TINA monomers in quadruplex forming oligonucleotides (QFOs) and the effect of LNA monomers
in the context of biologically active QFOs. In addition, recent literature reports and our own studies on the gel retardation
of the phosphodiester analogue of T30177 led to the conclusion that this sequence forms a parallel, dimeric G-quadruplex.
Introduction of the 5′-phosphate inhibits dimerisation of this G-quadruplex as a result of negative charge–charge repulsion.
Contrary to that, we found that attachment of the 5′-O-DMT-group produced a more active 17-mer sequence that showed signs of aggregation—forming multimeric G-quadruplex species
in solution. Many of the antiviral QFOs in the present study formed more thermally stable G-quadruplexes and also high-order
G-quadruplex structures which might be responsible for the increased antiviral activity observed.
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.
Nucleic acid aptamers can be selected from pools of random-sequence oligonucleotides to bind a wide range of biomedically relevant proteins with affinities and specificities that are comparable to antibodies. Aptamers exhibit significant advantages relative to protein therapeutics in terms of size, synthetic accessibility and modification by medicinal chemistry. Despite these properties, aptamers have been slow to reach the marketplace, with only one aptamer-based drug receiving approval so far. A series of aptamers currently in development may change how nucleic acid therapeutics are perceived. It is likely that in the future, aptamers will increasingly find use in concert with other therapeutic molecules and modalities.
The sequence d(GGGGTTTTGGGG) from the 3' overhang of the Oxytricha telomere has been crystallized and its three-dimensional structure solved to 2.5 A resolution. The oligonucleotide forms hairpins, two of which join to make a four-stranded helical structure with the loops containing four thymine residues at either end. The guanine residues are held together by cyclic hydrogen bonding and an ion is located in the centre. The four guanine residues in each segment have a glycosyl conformation that alternates between anti and syn. There are two four-stranded molecules in the asymmetric unit showing that the structure has some intrinsic flexibility.
The phosphorothioate oligonucleotide T2G4T2 was identified as an inhibitor of HIV infection in vitro by combinatorial screening of a library of phosphorothioate oligonucleotides that contained all possible octanucleotide sequences. The oligonucleotide forms a parallel-stranded tetrameric guanosine-quartet structure. Tetramer formation and the phosphorothioate backbone are essential for antiviral activity. The tetramer binds to the human immunodeficiency virus envelope protein gp120 at the V3 loop and inhibits both cell-to-cell and virus-to-cell infection.
The structure formed by the DNA oligonucleotide d(G3T4G3) has been studied by one- and two-dimensional 1H NMR spectroscopy. In NaCl solution, d(G3T4G3), like d(G4T4G4) (Oxy-1.5), forms a dimeric quadruplex with the thymines in loops across the diagonal of the end quartets. Unlike Oxy-1.5, the dimer is not symmetric, and both monomer strands are observed in NMR spectra. Three quartets are formed from the GGG tracts. Glycosidic conformations of the guanines are 5'-syn-syn-anti-(loop)-syn-anti-anti in one strand and 5'-syn-anti-anti-(loop)-syn-syn-anti in the other strand. Thus, the stacking of the quartets (tail-to-tail, head-to-tail) is unlike all previously described fold-back (tail-to-tail, head-to-head) and parallel-stranded (head-to-tail, head-to-tail) quadruplexes.
Repeat tracts of guanine bases found in DNA and RNA can form tetraplex structures in the presence of a variety of monovalent
cations. Evidence suggests that guanine tetraplexes assume important functions within chromosomal telomeres, immunoglobulin
switch regions, and the human immunodeficiency virus genome. The structure of a parallel-stranded tetraplex formed by the
hexanucleotide d(TG4T) and stabilized by sodium cations was determined by x-ray crystallography to 1.2 angstroms resolution.
Sharply resolved sodium cations were found between and within planes of hydrogen-bonded guanine quartets, and an ordered groove
hydration was observed. Distinct intra- and intermolecular stacking arrangements were adopted by the guanine quartets. Thymine
bases were exclusively involved in making extensive lattice contacts.
Recently, we have described the design and characterization of oligonucleotides containing only G and T bases, i.e. T30695 and T30177, that are potent inhibitors of human immunodeficiency virus type 1 (HIV-1) replication in culture (Jing, N., Rando, R. F., Pommier, Y., and Hogan, M. E. (1997) Biochemistry 36, 12498-12505). To understand that observation and to rationalize the generally high thermal stability of oligonucleotide folding for these compounds, we have used NMR methods, coupled to molecular modeling, to obtain a high resolution structure model for T30695, which is the most potent of the integrase inhibitors that have been identified thus far. Modeling and NMR data obtained in the presence of Li+ ions show that T30695 assumes an intramolecular fold with a distorted G-octet core and a set of three open, partially disordered loops. This is referred to as Li+-form structure. The NMR-based model suggests that, upon coordination with three K+ equivalents, the central G-octet becomes more regular and that the loop domains become orderly and compact. This is referred to as K+-form structure. Based upon the assay of inhibition of HIV-1 integrase, T30695 demonstrated a strong inhibition of HIV-1 integrase activity as the K+-form structure, but a poor inhibition of HIV-1 integrase activity as the Li+-form structure. The structure/activity analysis suggests that the K+-induced conformation transition of the tetrad-forming oligonucleotides, such as T30695 and T30177, plays a key role in inhibition of HIV-1 integrase activity.
An oligonucleotide with a dimeric hairpin guanosine quadruplex (basket type structure) (dG3T4G3-s), containing phosphorothioate
groups, was able to inhibit human immunodeficiency virus type 1 (HIV-1)-induced syncytium formation and virus production (as
measured by p24 core antigen expression) in peripheral blood mononuclear cells. This oligonucleotide lacks primary sequence
homology with the complementary (antisense) sequences to the HIV-1 genome. Furthermore, this oligonucleotide may have increased
nuclease resistance. The activity of this oligonucleotide was increased when the phosphodiester backbone was replaced with
a phosphorothioate backbone. In vivo results showed that dG3T4G3-s was capable of blocking the interaction between gp120 and
CD4. We also found that dG3T4G3-s specifically inhibits the entry of T-cell line-tropic HIV-1 into cells. This compound is
a viable candidate for evaluation as a therapeutic agent against HIV-1 in humans.
We report on the NMR-based solution structure of the 93del d(GGGGTGGGAGGAGGGT) aptamer, a potent nanomolar inhibitor of HIV-1 integrase. This guanine-rich DNA sequence adopts an unusually stable dimeric quadruplex architecture in K⁺ solution. Within each 16-nt monomer subunit, which contains one A·(G·G·G·G) pentad sandwiched between two G·G·G·G tetrads, all G-stretches are parallel, and all guanines are anti with the exception of G1, which is syn. Dimer formation is achieved through mutual pairing of G1 of one monomer, with G2, G6, and G13 of the other monomer, to complete G·G·G·G tetrad formation. There are three single-nucleotide double-chain-reversal loops within each monomer fold, such that the first (T5) and third (A12) loops bridge three G-tetrad layers, whereas the second (A9) loop bridges two G-tetrad layers and participates in A·(G·G·G·G) pentad formation. Results of NMR and of integrase inhibition assays on loop-modified sequences allowed us to propose a strategy toward the potential design of improved HIV-1 integrase inhibitors. Finally, we propose a model, based on molecular docking approaches, for positioning the 93del dimeric DNA quadruplex within a basic channel/canyon formed between subunits of a dimer of dimers of HIV-1 integrase.
• dimeric quadruplex
• DNA aptamer
Unprecedented DNA quadruplex structures containing a 3'-3' or 5'-5' inversion of polarity site in the G-tract are presented; the quadruplexes are characterized by different elements of symmetry and glycosidic angle conformations.
We have determined the NMR solution structures of the quadruplexes formed by d(TGLGLT) and d(TL4T), where L denotes LNA (locked nucleic acid) modified G-residues. Both structures are tetrameric, parallel and right-handed
and the native global fold of the corresponding DNA quadruplex is retained upon introduction of the LNA nucleotides. However,
local structural alterations are observed owing to the locked LNA sugars. In particular, a distinct change in the sugar–phosphate
backbone is observed at the G2pL3 and L2pL3 base steps and sequence dependent changes in the twist between tetrads are also
seen. Both the LNA modified quadruplexes have raised thermostability as compared to the DNA quadruplex. The quadruplex-forming
capability of d(TGLGLT) is of particular interest as it expands the design flexibility for stable parallel LNA quadruplexes
and shows that LNA nucleotides can be mixed with DNA or other modified nucleic acids. As such, LNA-based quadruplexes can
be decorated by a variety of chemical modifications. Such LNA quadruplex scaffolds might find applications in the developing
field of nanobiotechnology.
G-quadruplexes are higher-order DNA and RNA structures formed from G-rich sequences that are built around tetrads of hydrogen-bonded
guanine bases. Potential quadruplex sequences have been identified in G-rich eukaryotic telomeres, and more recently in non-telomeric
genomic DNA, e.g. in nuclease-hypersensitive promoter regions. The natural role and biological validation of these structures
is starting to be explored, and there is particular interest in them as targets for therapeutic intervention. This survey
focuses on the folding and structural features on quadruplexes formed from telomeric and non-telomeric DNA sequences, and
examines fundamental aspects of topology and the emerging relationships with sequence. Emphasis is placed on information from
the high-resolution methods of X-ray crystallography and NMR, and their scope and current limitations are discussed. Such
information, together with biological insights, will be important for the discovery of drugs targeting quadruplexes from particular
genes.
New found interest in the chromosome G-quadruplexes has emerged as an important focus of research in nucleic acids and as a potential target for cancer therapeutics. Existing literature concerning nucleic acids concentrates on aspects of quadruplex structure and historical research. There exists no single comprehensive resource addressing recent advances in therapeutic application and targeting strategies, until now. Quadruplex Nucleic Acids as Therapeutic Targets will be a vital resource for researchers in biochemistry, molecular biology, chemistry, biotechnology, biophysics, medicine, translational science and pharmacology. This timely publication is the first to offer practical application and direct strategies to meet the needs of emerging research.
Hexadeoxyribonucleotides (6-mers) having a 5′-TGGGAG-3′ sequence bearing hydrophobic substituents at their 5′-ends via phosphodiester linkages were prepared and evaluated for anti-HIV-1 activity in vitro. Some of these modified 6-mers showed weak anti-HIV-1 activities and they were less potent than the 6-mer having a DMTr group directly attached at its 5′-terminus.1. Part 111: Hotoda, H.; Koizumi, M.; Koga, R.; Momota, K.; Ohmine, T.; Furukawa, H.; Nishigaki, T.; Kinoshita, T.; Kaneko, M.; Kimura, S.; and Shimada, K. (1994) Proceedings of First International Antisense Conjierence of Japan p62 (Pl-24): In print in Antisense Research and Development. This paper is dedicated to Dr. Yoshihisa Mizuno, Emeritus Professor of Hokkaido University, on the occasion of his 75th birthday.
The last two decades have witnessed the development and application of nucleic acid aptamers in a variety of fields, including target analysis, disease therapy, and molecular and cellular engineering. The efficient and widely applicable aptamer selection, reproducible chemical synthesis and modification, generally impressive target binding selectivity and affinity, relatively rapid tissue penetration, low immunogenicity, and rapid systemic clearance make aptamers ideal recognition elements for use as therapeutics or for in vivo delivery of therapeutics. In this feature article, we discuss the development and biomedical application of nucleic acid aptamers, with emphasis on cancer cell aptamer isolation, targeted cancer therapy, oncology biomarker identification and drug discovery.
Two-pronged attack: We describe the maturation of a bivalent aptamer by a chemically driven two-step process. From an improved monovalent aptamer subdomain that had been modified by polycyclic aromatic hydrocarbons at individual positions, a mature bivalent variant with superior activities to its progenitor molecule was obtained through domain reassembly.
Over the past decades, albumin has emerged as a versatile carrier for therapeutic and diagnostic agents, primarily for diagnosing and treating diabetes, cancer, rheumatoid arthritis and infectious diseases. Market approved products include fatty acid derivatives of human insulin or the glucagon-like-1 peptide (Levemir(®) and Victoza(®)) for treating diabetes, the taxol albumin nanoparticle Abraxane(®) for treating metastatic breast cancer which is also under clinical investigation in further tumor indications, and (99m)Tc-aggregated albumin (Nanocoll(®) and Albures(®)) for diagnosing cancer and rheumatoid arthritis as well as for lymphoscintigraphy. In addition, an increasing number of albumin-based or albumin-binding drugs are in clinical trials such as antibody fusion proteins (MM-111) for treating HER2/neu positive breast cancer (phase I), a camelid albumin-binding nanobody anti-HSA-anti-TNF-α (ATN-103) in phase II studies for treating rheumatoid arthritis, an antidiabetic Exendin-4 analog bound to recombinant human albumin (phase I/II), a fluorescein-labeled albumin conjugate (AFL)-human serum albumin for visualizing the malignant borders of brain tumors for improved surgical resection, and finally an albumin-binding prodrug of doxorubicin (INNO-206) entering phase II studies against sarcoma and gastric cancer. In the preclinical setting, novel approaches include attaching peptides with high-affinity for albumin to antibody fragments, the exploitation of albumin-binding gadolinium contrast agents for magnetic resonance imaging, and physical or covalent attachment of antiviral, antibacterial, and anticancer drugs to albumin that are permanently or transiently attached to human serum albumin (HSA) or act as albumin-binding prodrugs. This review gives an overview of the expanding field of preclinical and clinical drug applications and developments that use albumin as a protein carrier to improve the pharmacokinetic profile of the drug or to target the drug to the pathogenic site addressing diseases with unmet medical needs.
A series of aliphatic and aromatic spacer molecules designed to cap the ends of DNA duplexes have been synthesized. The spacers were converted into dimethoxytrityl-protected phosphoramidites as synthons for oligonucleotides synthesis. The effect of the spacers on the stability of short DNA duplexes was assessed by melting temperature studies. End-caps containing amide groups were found to be less stabilizing than the hexaethylene glycol spacer. End-caps containing either a terthiophene or a naphthalene tetracarboxylic acid diimide were found to be significantly more stabilizing. The former showed a preference for stacking above an A*T base pair. Spacers containing only methylene (-CH(2)-) and amide (-CONH-) groups interact weakly with DNA and consequently may be optimal for applications that require minimal influence on DNA structure but require a way to hold the ends of double-stranded DNA together.
The telomeric ends of eukaryotic chromosomes are composed of simple repeating sequences in which one DNA strand contains short tracts of guanine residues alternating with short tracts of A/T-rich sequences. The guanine-rich strand is always oriented in a 5'-3' direction towards the end of the chromosome and is extended to produce a 3' overhang of about two repeating units in species where the telomeric terminus is known. This overhang has been implicated in the formation of several unusual intra-and intermolecular DNA structures, although none of these structures has been characterized fully. We now report that oligonucleotides encoding Tetrahymena telomeres dimerize to form stable complexes in solution. This salt-dependent dimerization is mediated entirely by the 3'-terminal telomeric overhang (TT-GGGGTTGGGG) and produces complexes in which the N7 position of every guanine in the overhangs is chemically inaccessible. We therefore propose that telomeric DNA dimerizes by hydrogen bonding between two intramolecular hairpin loops, to form antiparallel quadruplexes containing cyclic guanine base tetrads. These novel hairpin dimers may be important in telomere association and recombination and could also provide a general mechanism for pairing two double helices in other recombinational processes.
We have discovered that single-stranded DNA containing short guanine-rich motifs will self-associate at physiological salt concentrations to make four-stranded structures in which the strands run in parallel fashion. We believe these complexes are held together by guanines bonded to each other by Hoogsteen pairing. Such guanine-rich sequences occur in immunoglobulin switch regions, in gene promoters, and in chromosomal telomeres. We speculate that this self-recognition of guanine-rich motifs of DNA serves to bring together, and to zipper up in register, the four homologous chromatids during meiosis.
Structural properties of DNA oligonucleotides corresponding to the single-stranded molecular terminus of telomeres from several organisms were analyzed. Based on physical studies including nondenaturing polyacrylamide gel electrophoresis, absorbance thermal denaturation analysis, and 1H and 31P nuclear magnetic resonance spectroscopy, we conclude that these molecules can self-associate by forming non-Watson-Crick, guanine.guanine based-paired, intramolecular structures. These structures form below 40 degrees C at moderate ionic strength and neutral pH and behave like hairpin duplexes in nondenaturing polyacrylamide gels. Detailed analysis of the hairpin structure formed by the telomeric sequence from Tetrahymena, (T2G4)4, shows that it is a unique structure stabilized by hydrogen bonds and contains G residues in the syn conformation. We propose that this novel form of DNA is important for telomere function and sets a precedent for the biological relevance of non-Watson-Crick base-paired DNA structures.
The solution structure of the DNA quadruplex formed by the association of two strands of the DNA oligonucleotide, d(G3T4G3), in NaCl solution has been determined by 1H two-dimensional NMR techniques, full relaxation matrix calculations and restrained molecular dynamics. The refined structure incorporates the sequences 5'-G1sG2AG3AT4AT5AT6AT7AG8sG9AG10A-3' and 5'-G11sG12AG13AT14AT15AT16AT17AG18sG19sG20A-3' (where S and A denote syn and anti, respectively) in a three-quartet, diagonal-looped structure that we [Strahan, G. D., Shafer, R. H. & Keniry, M. A. (1994) Nucleic Acids Res. 22, 5447-5455] and others [Smith, F. W., Lau, F. W. & Feigon, J. (1994) Proc. Natl. Acad. Sci. USA 91, 10546-10550] have described. The loop structure is compact and incorporates many of the features found in duplex hairpin loops including base stacking, intraloop hydrogen bonding and extensive van der Waals' interactions. The first and third loop thymines stack over the outermost G-quartet and are also associated by hydrogen bonding. The second and the fourth loop thymines fold inwards in order to enhance van der Waals' interactions. The unexpected sequential syn-syn deoxyguanosines in the quadruplex stem appear to be a direct consequence of the way DNA oligonucleotides fold and the subsequent search for the most stable loop structure. The implications of loop sequence and length on the structure of quadruplexes are discussed.
The solution structure of Oxytricha telomere sequence d[G4(T4G4)3] in 0.1 M Na+ containing solution has been determined using a combined NMR-molecular dynamics approach including relaxation matrix refinement. This four G4 repeat sequence folds intramolecularly into a right-handed G-tetraplex containing four stacked G-tetrads which are connected by two lateral T4 loops and a central diagonal T4 loop. The guanine glycosidic bonds adopt a syn-anti alternation along the full length of the d[G4(T4G4)3] sequence while the orientation around adjacent G-tetrads switches between syn.syn.anti.anti and anti.anti.syn.syn alignments. Four distinct grooves are formed by the parallel (two of medium width) and anti-parallel (one wide and one narrow width) alignment of adjacent G-G-G-G segments in the G-tetraplex. The T4 residues in the diagonal loop are well-defined while the T4 residues in both lateral loops are under-defined and sample multiple conformations. The solution structure of the Na(+)-stabilized Oxytricha d[G4(T4G4)3] G-tetraplex and an earlier solution structure reported from our laboratory on the Na(+)-stabilized human d[AG3(T2AG3)3] G-tetraplex exhibit a common folding topology defined by the same syn/anti distribution of guanine residues along individual strands and around individual G-tetrads, as well as a common central diagonal loop which defines the strand directionalities. The well-resolved proton NMR spectra associated with the d[G4(T4G4)3] G-tetraplex opens the opportunity for studies ranging from cation-dependent characterization of G-tetraplex conformation and hydration to ligand and protein recognition of the distinct grooves associated with this folding topology.
Thermal denaturation, gel electrophoresis, and circular dichroism methods were used to characterize DNA oligomers possessing one or two segments of four contiguous G bases in order to investigate their environmentally dependent conformational properties. The sequences of the oligomers studied were the following: HP1-T series, C4T4G4T5-8; HP1-TG series, C4T4G4T1-4G4. In NaCl at concentrations up to 200 mM, the melting profiles of these oligomers are characterized by single inflection points whose Tm values are independent of DNA concentration. In addition, these oligomers run as single bands in polyacrylamide gels under those same conditions as well as in 100 mM K+ or 20 mM Mg2+. These data suggest that these oligomers exist as intramolecular hairpins comprised of four G:C base pairs in the stems, loops of four T bases, and 3'-overhangs of T5-8 or T1-4G4. In the presence of 100 mM K+ plus 20 mM Mg2+, however, gel electrophoresis indicates that oligomers of the HP1-T series exist as equilibria between parent hairpins and four-stranded structures (i.e., quadraplexes). Quadraplex formation for any member of the HP1-T series requires unfolding of the hairpin, exposing the G4 segment prior to quadraplexation. Members of the HP1-TG series self-assemble into multistranded species of high molecular weight in the presence of 100 mM K+ plus 20 mM Mg2+. For this series of oligomers, the data suggest that these higher order species arise from successive additions of parent oligomer to an initially formed quadraplex.(ABSTRACT TRUNCATED AT 250 WORDS)
DNA sequences containing repetitive oligo-guanine sequences are observed in telomeric DNA and in recombination hotspots. In vitro, these sequences fold into at least two classes of unusual conformations involving the formation of guanine tetrads (G-quartets). Through the use of NMR, we have established that in solution in the presence of sodium ions, the oligodeoxynucleotide dTG4T forms a parallel-stranded tetraplex, with hydrogen-bonded guanine tetrads. Here we present the detailed evidence for this configuration in 100 mM sodium ions at neutral pH. We show that the parallel-stranded tetraplex structure is stabilised relative to the single-strands when Na ions are replaced by K ions, without any evidence of significant change in those chemical shifts associated with the tetraplex form. We also present a model for the Na+ solution structure of the tetraplex, by back-calculation from NOE volumes. We obtain excellent agreement with the data for structures with characteristics similar to B-DNA for the internal tetrads, G3 and G4. The outer tetrads, particularly the 5'-terminal G2, display some unstacking. We see no evidence for formation of thymine tetrads analogous to the uridine tetrads observed in RNA, but rather we find the terminal thymine conformations are not well determined by our data. We observe an uninterrupted cylindrical channel through the centre of the complex.
The telomeric DNA oligonucleotide 5'-G4T2G4-3' (Tet 1.5) spontaneously assembles into large superstructures we have termed G-wires. G-wires can be resolved by gel electrophoresis as a ladder pattern. The self-association of Tet 1.5 is noncovalent and exhibits characteristics of G4-DNA, a parallel four-stranded structure stabilized by guanine tetrads. Formation of G-wires is dependent upon the presence of Na+ and/or K+, and once formed, G-wires are resistant to denaturation. The results described here extend our understanding of the structural potential of G-rich nucleic acids and may provide insight into the possible roles of G-rich sequences and the novel structures they can form in biological systems.
Repeats of Gn sequences are detected as single strand overhangs at the ends of eukaryotic chromosomes together with associated binding proteins. Such telomere sequences have been implicated in the replication and maintenance of chromosomal termini. They may also mediate chromosomal organization and association during meiosis and mitosis.
We have determined the three-dimensional solution structure of the human telomere sequence, d[AG3(T2AG3)3] in Na(+)-containing solution using a combined NMR, distance geometry and molecular dynamics approach (including relaxation matrix refinement). The sequence, which contains four AG3 repeats, folds intramolecularly into a G-tetraplex stabilized by three stacked G-tetrads which are connected by two lateral loops and a central diagonal loop. Of the four grooves that are formed, one is wide, two are of medium width and one is narrow. The alignment of adjacent G-G-G segments in parallel generates the two grooves of medium width whilst the antiparallel arrangement results in one wide and one narrow groove. Three of the four adenines stack on top of adjacent G-tetrads while the majority of the thymines sample multiple conformations.
The availability of the d[AG3(T2AG3)3] solution structure containing four AG3 human telomeric repeats should permit the rational design of ligands that recognize and bind with specificity and affinity to the individual grooves of the G-tetraplex, as well as to either end containing the diagonal and lateral loops. Such ligands could modulate the equilibrium between folded G-tetraplex structures and their unfolded extended counterparts.
The structure formed from the DNA oligonucleotide d(G4T4G4) (Oxy-1.5), which contains the Oxytricha telomere repeat T4G4, has been investigated by two-dimensional 1H and 31P NMR spectroscopy. Sequence-specific assignments have been obtained for the 1H and 31P resonances, using a combination of methods including comparisons to the inosine- and uracil-containing derivatives d(G4T4G3I) and d(G4UT3G4). The oligonucleotide forms a symmetrical bimolecular G-quadruplex with four G-quartets and thymine loops at opposite ends of the G-quartets. Guanines are alternatively syn and anti along each "strand" and all of the thymines are anti. The thymines loop diagonally across the G-quartet, resulting in a structure in which adjacent strands are alternately parallel and antiparallel and the glycosidic torsion angles are syn-syn-anti-anti around each G-quartet. There are three different types of grooves, a wide, a narrow, and two medium grooves. A diagonally looped quadruplex is formed in the presence of both Na+ and K+ counterions. The model structure of Oxy-1.5 is compared to the recently published crystal structure of Oxy-1.5 (Kang et al., 1992), which contains many of the same features as those found in solution but differs in that the thymines loop across an edge of the G-quartet.
We have used two-dimensional 1H NMR spectroscopy to study the conformation of the thrombin-binding aptamer d(GGTTGGTGTGGTTGG) in solution. This is one of a series of thrombin-binding DNA aptamers with a consensus 15-base sequence that was recently isolated and shown to inhibit thrombin-catalyzed fibrin clot formation in vitro [Bock, L. C., Griffin, L. C., Latham, J. A., Vermaas, E. H. & Toole, J. J. (1992) Nature (London) 355, 564-566]. The oligonucleotide forms a unimolecular DNA quadruplex consisting of two G-quartets connected by two TT loops and one TGT loop. A potential T.T bp is formed between the two TT loops across the diagonal of the top G-quartet. Thus, all of the invariant bases in the consensus sequence are base-paired. This aptamer structure was determined by NMR and illustrates that this molecule forms a specific folded structure. Knowledge of this structure may be used in the further development of oligonucleotide-based thrombin inhibitors.
The phosphorothioate and phosphodiester oligodeoxynucleotides d(TTGGGGTT) form parallel-stranded tetramer structures stabilized by guanosine quartets. The phosphorothioate tetramer has been shown to inhibit human immunodeficiency virus (HIV) in vitro. The kinetics of association and dissociation of both tetramers have been determined as a function of temperature using size exclusion chromatography to measure the ratio of single strand to tetramer. In phosphate buffered saline (pH 7.2) at 37 degrees C, the fourth-order association rate of the phosphorothioate tetramer was 6.1 (+/- 0.5) x 10(4) M-3 s-1; the dissociation rate was 8.2 (+/- 0.2) x 10(-6) min-1, resulting in a t(1/2) of about 60 days. The association rate of the phosphodiester was about one order of magnitude faster and the dissociation rate about one order of magnitude slower than that of the phosphorothioate tetramer. The association reaction had a negative energy of activation for both compounds. Despite thermodynamic instability of the tetramer at low concentrations, the extremely slow dissociation rate may allow use of the phosphorothioate tetramer for AIDS chemotherapy.
An oligonucleotide (T30177) composed entirely of deoxyguanosine and thymidine has previously been shown to fold upon itself in the presence of potassium into a highly stable four-stranded DNA structure containing two stacked deoxyguanosine quartets (G4s). T30177 also protects host cells from the cytopathic effects of human immunodeficiency virus type 1 (HIV-1). We report that this G4 oligonucleotide is the most potent inhibitor of HIV-1 integrase identified to date, with IC50 values in the nanomolar range. Both the number of quartets formed and the sequence of the loops between the quartets are important for optimal activity. T30177 binds to HIV-1 integrase without being processed and blocks the binding of the normal viral DNA substrate to the enzyme. The normal DNA substrate was not able to compete off T30177 binding to HIV-1 integrase, indicating a tight binding of G4s to the enzyme. Experiments with truncated HIV-1 integrases indicate that the N-terminal region containing a putative zinc finger is required for inhibition by T30177 and that T30177 binds better to full-length or deletion mutant integrases containing the zinc finger region than to a deletion mutant consisting of only the central catalytic domain. The N-terminal region of integrase alone is able to bind efficiently to T30177, but not the linear viral DNA substrate, in the presence of zinc. Hence, G4s represent the first class of compounds that inhibit HIV-1 integrase by interacting with the enzyme N-terminal domain. The greater inhibitory potency of T30177 in buffer containing magnesium versus manganese suggests that divalent metal ion coordination along the phosphodiester backbone may play a role in the inhibitory activity. T30177 inhibited HIV-2 integrase with similar potency as HIV-1 but inhibited feline and simian immunodeficiency virus integrases at higher concentrations, suggesting selectivity can be achieved. We propose that novel AIDS therapies could be based upon guanosine quarters as inhibitors of HIV-1 integrase.
In both DNA and RNA, stretches of guanine bases can form stable four-stranded helices in the presence of sodium or potassium ions. Sequences with a propensity to form guanine tetraplexes have been found in chromosomal telomers, immunoglobulin switch regions, and recombination sites. We report the crystal structure at 0.95 A resolution of a parallel-stranded tetraplex formed by the hexanucleotide d(TG4T) in the presence of sodium ions. The four strands form a right-handed helix that is stabilized by hydrogen-bonding tetrads of co-planar guanine bases. Well-resolved sodium ions are found between and, at defined points, within tetrad planes and are coordinated with the guanine O6 groups. Nine calcium ions have been identified, each with a well-defined hepta-coordinate hydration shell. Hydrogen-bonding water patterns are observed within the tetraplex's helical grooves and clustered about the phosphate groups. Water molecules in the groove may form a hydrogen bond with the O4', and may affect the stacking behavior of guanine. Two distinct stacking arrangements are noted for the guanine tetrads. The thymine bases do not contribute to the four-stranded conformation, but instead stack to stabilize the crystal lattice. We present evidence that the sugar conformation is strained and propose that this originates from forces that optimize guanine base stacking. Discrete conformational disorder is observed at several places in the phosphodiester backbone, which results from a simple crankshaft rotation that requires no net change in the sugar conformation.
Previously, we have described inhibition of HIV-1 infection by T30177, 5'-(GTGGTGGGTGGGTGGGT)-3', an oligonucleotide that is a potent inhibitor of HIV-1 integrase in vitro (Mazumder et al. (1996) Biochemistry 35, 13762). Here a family of oligonucleotides, analogs of T30177, has been studied. On the basis of thermal denaturation, we show that a folded structure of T30177 is much more stable than that of the thrombin binding aptamer, which only differs with T30177 in the loop sequence. Sequence changes reveal that loop interactions are solely responsible for this observed stability difference. In the presence of K+ ion, the fold of T30695, a designed 16mer derivative, is indeed more stable than T30177. Loop folding within T30695 is very ion selective. Quantitative analysis of thermal denaturation suggests that the loops of T30695, 5'-(GGGTGGGTGGGTGGGT)-3', and T30177 confer the ability to coordinate three equivalents of K+ ion (one bound to the core octet and two bound to the loops); however, the thrombin binding aptamer is shown to bind only one K+ equivalent. Folding kinetics and CD titration demonstrate that K+-induced folding of T30695 and T30177 is a two-step process, consistent with a sequential model in which a first equivalent of K+ binds to the octet core, followed by slow K+-induced rearrangement of the loop domains. Comparing structural stability with the capacity of the folded oligomers to inhibit the HIV-1 integrase enzyme in vitro or HIV-1 infection in cell culture, we have found that the folding and activity data are highly correlated, suggesting that formation of an orderly, ion-coordinated loop structure similar to that in T30177 or T30695 may be a prerequisite for both integrase inhibition and anti-HIV-1 activity.
We have determined that hexadeoxyribonucleotides (5'TGGGAG3'), with modified aromatic groups such as a trityl group at the 5'-end, have anti-HIV-1 activity in vitro. The 6-mer bearing a 3,4-dibenzyloxybenzyl (3,4-DBB) group at the 5'-end had the most potent activity and the least cytotoxicity. When the 3'-end of the 5'-(3,4-DBB)-modified 6-mer was substituted with a 2-hydroxyethylphosphate, a 2-hydroxyethylthiophosphate, or a methylphosphate group at the 3'-end, anti-HIV-1 activity increased. Moreover, among various 3'- and 5'-end-modified 6-mers that were tested, the 6-mer (R-95288) bearing a 3,4-DBB group at the 5'-end and a 2-hydroxyethylphosphate group at the 3'-end was the most stable, when incubated with mouse, rat, or human plasma. Therefore, R-95288 was chosen as the best candidate for possible use in therapy on the basis of its anti-HIV-1 activity.
The human immunodeficiency virus (HIV) inhibitor AR177 (T30177, Zintevir) has been identified as a potent inhibitor of HIV integrase in vitro. The compound is currently the subject of clinical phase I/II trials. However, the primary target for the mechanism of action in vivo has not been identified unequivocally. We have found that AR177 inhibits syncytium formation between MOLT-4 cells and HUT-78 cells persistently infected with the HIV-1IIIB or NL4-3 strain, at a 50% effective concentration of 3 microg/ml, roughly 3-fold higher than the concentration required to inhibit HIV replication. Furthermore, flow cytometric analysis has shown that AR177 at 25 microg/ml interferes with the binding of the monoclonal antibody 9284 (directed to the V3 loop of gp120) on HIVIIIB-infected HUT-78 cells, pointing to inhibition of virus binding or virus fusion as the mechanism of action of AR177. To precisely characterize the site/target of intervention by AR177, we have selected HIV-1 (NL4-3) strains resistant to AR177. The binding of the AR177-resistant strain, unlike the parental HIV-1 NL4-3 strain, could not be inhibited by AR177. The resistant phenotype was associated with the emergence of mutations in the gp120 molecule. DNA sequence analysis revealed the presence of the K148E, Q278H, K290Q, and F391I mutations and a deletion of 5 amino acids (FNSTW) at positions 364-368 in the V4 region of the resistant strain but not of the wild-type HIV strain. Selection of resistant strains, although it takes a relatively long time to develop, may also select for strains with lower replicative capacity. No mutations were found in the integrase enzyme gene. Our data argue against HIV integrase being the primary target for the mechanism of anti-HIV action of AR177.
A series of hexadeoxyribonucleotides (6-mers), d(TGGGAG), substituted with a variety of aromatic groups at the 5'-end were synthesized and tested for anti-human immunodeficiency virus type 1 (HIV-1) activity. While unmodified d(TGGGAG) (31) had no anti-HIV-1 activity, compound 23 with a 3,4-di(benzyloxy)benzyl (DBB) group at the 5'-end potently inhibited the HIV-1IIIB-induced cytopathicity of MT-4 cells in vitro (IC50 = 0.37 microM) without cytotoxicity up to 40 microM. A thermal denaturation study on the 5'-end-substituted 6-mers by means of the circular dichroism (CD) spectra demonstrated that the aromatic substituent attached at the 5'-end of the 6-mer strongly enhanced the formation of a parallel helical structure consisting of four strands (quadruplex). On the contrary, compound 36, in which one of the guanosines of 23 was replaced by a thymidine, did not form a quadruplex, thus exhibiting no anti-HIV-1 activity. Moreover, both compound 15, with a tert-butyldiphenylsilyl group solely at its 3'-end, and compound 21, with a relatively small substituent, a benzyl group, at the 5'-end, formed quadruplexes but had no anti-HIV-1 activity. These findings led us to the conclusion that both the quadruplex structure and the aromatic substituent with adequate size at the 5'-end are crucial for the interaction of the 5'-end-substituted 6-mers with the V3 loop as well as the CD4 binding site on viral gp120, resulting in anti-HIV-1 activity.
We have identified a unique structural transition (in slow exchange on the NMR time scale) in the tertiary fold of the d(G-G-G-C-T4-G-G-G-C) quadruplex on proceeding from Na+ to K+ as counterion in aqueous solution. Both monovalent cation-dependent conformations exhibit certain common structural features, which include head-to-tail dimerization of two symmetry-related stem-hairpin loops, adjacent strands which are antiparallel to each other and adjacent stacked G(syn).G(anti). G(syn).G(anti) tetrads in the central core of the quadruplexes. The Na and K cation stabilized structures of the d(G-G-G-C-T4-G-G-G-C) quadruplexes differ in the conformations of the T-T-T-T loops, the relative alignment of G.C base-pairs positioned opposite each other through their major groove edges and potentially in the number of monovalent cation binding sites. We have identified potential K cation binding cavities within the symmetry-related T-T-T-G segments, suggesting the potential for two additional monovalent cation binding sites in the K cation-stabilized quadruplex relative to its Na cation-stabilized counterpart. Modeling studies suggest that the major groove edges of guanine residues in Watson-Crick G.C base-pairs could potentially be bridged by coordinated K cations in the d(G-G-G-C-T4-G-G-G-C) quadruplex in KCl solution in contrast to formation of G.C.G.C tetrads for the corresponding quadruplex in NaCl solution. Our results defining the molecular basis of a Na to K cation-dependent conformational switch in the loop spanning segment of the d(G-G-G-C-T4-G-G-G-C) quadruplex may have relevance to recent observations that specific K cation coordinated loop conformations within quadruplexes exhibit inhibitory activity against HIV integrase.
Recently, we have demonstrated that T30695, a G-tetrad-forming oligonucleotide, is a potent inhibitor of human immunodeficiency virus, type I (HIV-1) integrase and the K(+)-induced loop folding of T30695 plays a key role in the inhibition of HIV-1 integrase (Jing, N., and Hogan, M. E. (1998) J. Biol. Chem. 273, 34992-34999). Here we have modified T30695 by introducing a hydrophobic bulky group, propynyl dU, or a positively charged group, 5-amino dU, into the bases of T residues of the loops, and by substitution of the T-G loops by T-T loops. Physical measurements have demonstrated that the substitution of propynyl dU or 5-amino dU for T in the T residues of the loops did not alter the structure of T30695, and these derivatives also formed an intramolecular G-quartet structure, which is an essential requirement for anti-HIV activity. Measured IC(50) and EC(50) values show that these substitutions did not induce an apparent decrease in the ability to inhibit HIV-1 integrase activity and in the inhibition of HIV-1 replication in cell culture. However, the substitution of T-T loops for T-G loops induced a substantial decrease in both thermal stability and anti-HIV activity. The data analysis of T30695 and the 21 derivatives shows a significant, functional correlation between thermal stability of the G-tetrad structure and the capacity to inhibit HIV-1 integrase activity and between thermal stability of the G-tetrad structure and the capacity to inhibit HIV-1 replication, as assessed with the virus strains HIV-1 RF, IIIB, and MN in cell culture. This relationship between thermostability and activity provides a basis for improving the efficacy of these compounds to inhibit HIV-1 integrase activity and HIV-1 replication in cell culture.
Telomeric ends of chromosomes, which comprise noncoding repeat sequences of guanine-rich DNA, are fundamental in protecting the cell from recombination and degradation. Disruption of telomere maintenance leads to eventual cell death, which can be exploited for therapeutic intervention in cancer. Telomeric DNA sequences can form four-stranded (quadruplex) structures, which may be involved in the structure of telomere ends. Here we describe the crystal structure of a quadruplex formed from four consecutive human telomeric DNA repeats and grown at a K(+) concentration that approximates its intracellular concentration. K(+) ions are observed in the structure. The folding and appearance of the DNA in this intramolecular quadruplex is fundamentally different from the published Na(+)-containing quadruplex structures. All four DNA strands are parallel, with the three linking trinucleotide loops positioned on the exterior of the quadruplex core, in a propeller-like arrangement. The adenine in each TTA linking trinucleotide loop is swung back so that it intercalates between the two thymines. This DNA structure suggests a straightforward path for telomere folding and unfolding, as well as ways in which it can recognize telomere-associated proteins.
Zintevir is an oligonucleotide analogue, which has the phosphorothioate modification at both termini, that forms a K(+)-induced quadruplex structure and shows potent anti-human immunodeficiency virus (HIV)-1 activity. We synthesized the non-modified analogue (D-17mer) of Zintevir and its enantiomer (L-17mer), and compared their anti-HIV-1 activity and molecular mechanism of action. Although L-17mer forms the exact mirror image quadruplex structure of D-17mer, which has a very similar structure with Zintevir, L-17mer showed comparable anti-HIV-1 activity with Zintevir. The results obtained by the time-of-addition experiments and the immunofluorescence binding assay strongly suggest that the primary molecular target of L-17mer is the viral gp120 envelope protein as well as Zintevir, regardless of their reciprocal chirality.
A guanine-rich PNA dodecamer having the sequence H-G4T4G4-Lys-NH2 (G-PNA) hybridizes with a DNA dodecamer of homologous sequence to form a four-stranded quadruplex (Datta, B.; Schmitt, C.; Armitage, B. A. J. Am. Chem. Soc. 2003, 125, 4111-4118). This report describes quadruplex formation by the PNA alone. UV melting curves and fluorescence resonance energy transfer experiments reveal formation of a multistranded structure stabilized by guanine tetrads. The ion dependency of these structures is analogous to that reported for DNA quadruplexes. Electrospray ionization mass spectrometry indicates that both dimeric and tetrameric quadruplexes are formed by G4-PNA, with the dimeric form being preferred. These results have implications for the use of G-rich PNA for homologous hybridization to G-rich targets in chromosomal DNA and suggest additional applications in assembling quadruplex structures within lipid bilayer environments.
HIV-1 integrase, the retroviral-encoded enzyme involved in the integration of the retrotranscribed viral genome into the host nuclear DNA, is an attractive and still unexploited target. To date, very few inhibitors of this enzyme with a potential therapeutic value have been described. During the search for new HIV-1 targets, we recently described DNA oligodeoxynucleotide aptamers (ODN 93 and ODN 112) that are strong inhibitors of the RNase H activity associated with HIV-1 reverse transcriptase. The striking structural homology between RNase H and integrase led us to study the effect of the RNase H inhibitors on the integrase. Shorter DNA aptamers derived from ODNs 93 and 112 (ODNs 93del and 112del) were able to inhibit HIV-1 integrase in the nanomolar range. They had G-rich sequences able to form G-quartets stabilized by the presence of K(+). The presence of these ions increased the inhibitory efficiency of these agents dramatically. Inhibition of enzymatic activities by ODN 93del and ODN 112del was observed in a cell-free assay system using a recombinant integrase and HIV-1 replication was abolished in infected human cells. Moreover, cell fusion assays showed that these agents do not block viral cell entry at concentrations where viral replication is stopped.
G-quadruplexes and Z-DNA are two important non-B forms of DNA architecture. Results on novel structural elements, folding and unfolding kinetics, and interactions with small molecules and proteins have been reported recently for these forms. These results will enhance our understanding of the biology of these structures and provide a platform for drug design.
Nucleic-acid aptamers have the molecular recognition properties of antibodies, and can be isolated robotically for high-throughput applications in diagnostics, research and therapeutics. Unlike antibodies, however, they can be chemically derivatized easily to extend their lifetimes in biological fluids and their bioavailability in animals. The first aptamer-based clinical drugs have recently entered service. Meanwhile, active research programmes have identified a wide range of anti-viral aptamers that could form the basis for future therapeutics.