Physiological relevance of telomeric G-quadruplex formation: a potential drug target

The concept of a G-quartet, a unique structural arrangement intrinsic to guanine-rich DNA, was first introduced by Gellert and colleagues over 40 years ago. For decades, it has been uncertain whether the G-quartet and the structure that it gives rise to, the G-quadruplex, are purely in vitro phenomena. Nevertheless, the presence of signature G-rich motifs in the eukaryotic genome, and the plethora of proteins that bind to, modify or resolve this nucleic acid structure in vitro have provided circumstantial evidence for its physiological relevance. More recently, direct visualisation of G-quadruplex DNA at native telomeres was achieved, bolstering the evidence for its existence in the cell. Furthermore, G-quadruplex folded telomeric DNA has been found to perturb telomere function and to impede the action of telomerase, an enzyme overexpressed in >85% of human cancers, hence opening up a novel avenue for cancer therapy in the form of G-quadruplex stabilising agents.     

Intragenic G-quadruplex structure formed in the human CD133 and its biological and translational relevance

Cancer stem cells (CSCs) have been identified in several solid malignancies and are now emerging as a plausible target for drug discovery. Beside the questionable existence of CSCs specific markers, the expression of CD133 was reported to be responsible for conferring CSC aggressiveness. Here, we identified two G-rich sequences localized within the introns 3 and 7 of the CD133 gene able to form G-quadruplex (G4) structures, bound and stabilized by small molecules. We further showed that treatment of patient-derived colon CSCs with G4-interacting agents triggers alternative splicing that dramatically impairs the expression of CD133. Interestingly, this is strongly associated with a loss of CSC properties, including self-renewing, motility, tumor initiation and metastases dissemination. Notably, the effects of G4 stabilization on some of these CSC properties are uncoupled from DNA damage response and are fully recapitulated by the selective interference of the CD133 expression.In conclusion, we provided the first proof of the existence of G4 structures within the CD133 gene that can be pharmacologically targeted to impair CSC aggressiveness. This discloses a class of potential antitumoral agents capable of targeting the CSC subpopulation within the tumoral bulk.     

The solution structures of higher-order human telomere G-quadruplex multimers

Human telomeres contain the repeat DNA sequence 5′-d(TTAGGG), with duplex regions that are several kilobases long terminating in a 3′ single-stranded overhang. The structure of the single-stranded overhang is not known with certainty, with disparate models proposed in the literature. We report here the results of an integrated structural biology approach that combines small-angle X-ray scattering, circular dichroism (CD), analytical ultracentrifugation, size-exclusion column chromatography and molecular dynamics simulations that provide the most detailed characterization to date of the structure of the telomeric overhang. We find that the single-stranded sequences 5′-d(TTAGGG)_n, with n = 8, 12 and 16, fold into multimeric structures containing the maximal number (2, 3 and 4, respectively) of contiguous G4 units with no long gaps between units. The G4 units are a mixture of hybrid-1 and hybrid-2 conformers. In the multimeric structures, G4 units interact, at least transiently, at the interfaces between units to produce distinctive CD signatures. Global fitting of our hydrodynamic and scattering data to a worm-like chain (WLC) model indicates that these multimeric G4 structures are semi-flexible, with a persistence length of ∼34 Å. Investigations of its flexibility using MD simulations reveal stacking, unstacking, and coiling movements, which yield unique sites for drug targeting.     

Distinctive structures between chimpanzee and human in a brain noncoding RNA

Human accelerated region 1 (HAR1) is a short DNA region identified recently to have evolved the most rapidly among highly constrained regions since the divergence from our common ancestor with chimpanzee. It is transcribed as part of a noncoding RNA specifically expressed in the developing human neocortex. Employing a panoply of enzymatic and chemical probes, our analysis of HAR1 RNA proposed a secondary structure model differing from that published. Most surprisingly, we discovered that the substitutions between the chimpanzee and human sequences led the human HAR1 RNA to adopt a cloverleaf-like structure instead of an extended and unstable hairpin in the chimpanzee sequence. Thus, the rapid evolutionary changes resulted in a profound rearrangement of HAR1 RNA structure. Altogether, our results provide a structural context for elucidating HAR1 RNA function.     

Water spines and networks in G-quadruplex structures

Quadruplex DNAs can fold into a variety of distinct topologies, depending in part on loop types and orientations of individual strands, as shown by high-resolution crystal and NMR structures. Crystal structures also show associated water molecules. We report here on an analysis of the hydration arrangements around selected folded quadruplex DNAs, which has revealed several prominent features that re-occur in related structures. Many of the primary-sphere water molecules are found in the grooves and loop regions of these structures. At least one groove in anti-parallel and hybrid quadruplex structures is long and narrow and contains an extensive spine of linked primary-sphere water molecules. This spine is analogous to but fundamentally distinct from the well-characterized spine observed in the minor groove of A/T-rich duplex DNA, in that every water molecule in the continuous quadruplex spines makes a direct hydrogen bond contact with groove atoms, principally phosphate oxygen atoms lining groove walls and guanine base nitrogen atoms on the groove floor. By contrast, parallel quadruplexes do not have extended grooves, but primary-sphere water molecules still cluster in them and are especially associated with the loops, helping to stabilize loop conformations.     

G-quadruplex structures of human telomere DNA examined by single molecule FRET and BrG-substitution

The human telomere is known to form the G-quadruplex structure to inhibit the activity of telomerase. Its detailed structure has been of great interest. Recently, two kinds of the parallel-antiparallel hybrid structures have been specified in K(+) solution. However, the G-quadruplex structure is generally thought to be in equilibrium among different structures. Here, we describe the single-pair fluorescence resonance energy transfer (sp-FRET) experiments on telomere samples with bromoguanine (BrG)-substitutions, which control the G-quadruplex structures, at different positions and one without any substitution. The observed FRET distributions were decomposed into five components and the relative population of these components depended on the BrG-substitution positions. In order to consistently explain the variety of conformations, we proposed a novel structural model, the so-called triple-strand-core model. On the basis of this model, the components of the FRET distributions were attributed to the mixed-chair hybrid structures, which were reported recently, and chair-type antiparallel structures, which can be predicted from this model. The FRET efficiencies of these structures were explained in terms of partially broken structures due to steric hindrance and inappropriate capping. This basic model also consistently explains experimental results reported previously. Furthermore, using this model, the folding pathway of the hybrid structures and T-loop formation can be predicted.     

A topological classification of G-quadruplex structures

A topological classification of most quadruplex structures is proposed, based on two main characteristics: 1) the relative orientation of the strands and 2) the nature of the loops connecting the strands.     

Interaction of porphyrin with G-quadruplex structures

Isothermal titration calorimetry (ITC) is a sensitive technique for probing bimolecular processes and can provide direct information about the binding affinity and stoichiometry and the key thermodynamic parameters involved. ITC has been used to investigate the interaction of the ligand H2TMPyP to the two DNA quadruplexes, [d(AGGGT)]4 and [d(TGGGGT)]. Analysis of the ITC data reveals that porphyrin/quadruplex binding stoichiometry under saturating conditions is 1:2 for [d(AGGGT)]4 and 2:1 for [d(TGGGGT)], respectively.     

Induction of parallel human telomeric G-quadruplex structures by Sr(2+)

Human telomeric DNA forms G-quadruplex secondary structures, which can inhibit telomerase activity and are targets for anti-cancer drugs. Here we show that Sr(2+) can induce human telomeric DNA to form both inter- and intramolecular structures having characteristics consistent with G-quadruplexes. Unlike Na(+) or K(+), Sr(2+) facilitated intermolecular structure formation for oligonucleotides with 2 to 5 5'-d(TTAGGG)-3' repeats. Longer 5'-d(TTAGGG)-3' oligonucleotides formed exclusively intramolecular structures. Altering the 5'-d(TTAGGG)-3' to 5'-d(TTAGAG)-3' in the 1st, 3rd, or 4th repeats of 5'-d(TTAGGG)(4)-3' stabilized the formation of intermolecular structures. However, a more compact, intramolecular structure was still observed when the 2nd repeat was altered. Circular dichroism spectroscopy results suggest that the structures were parallel-stranded, distinguishing them from similar DNA sequences in Na(+) and K(+). This study shows that Sr(2+), promotes parallel-stranded, inter- and intramolecular G-quadruplexes that can serve as models to study DNA substrate recognition by telomerase.     

Sialidases: structures, biological significance and therapeutic potential

The structure-based design of a potent inhibitor of the influenza-virus neuraminidase (sialidase) is one of the outstanding successes of rational drug design. Recent clinical trials of the drug have stimulated many companies to seek a share of the potentially huge flu market. Sialidases, however, are involved in the pathogenesis of a whole range of other diseases, so perhaps the knowledge and expertise gained from the influenza story can be used in the design of other drugs, given that they all share certain structural features.     

Structure of a two-G-tetrad intramolecular G-quadruplex formed by a variant human telomeric sequence in K+ solution: insights into the interconversion of human telomeric G-quadruplex structures

Human telomeric DNA G-quadruplex has been considered as an attractive target for cancer therapeutic intervention. The telomeric sequence shows intrinsic structure polymorphism. Here we report a novel intramolecular G-quadruplex structure formed by a variant human telomeric sequence in K⁺ solution. This sequence forms a basket-type intramolecular G-quadruplex with only two G-tetrads but multiple-layer capping structures formed by loop residues. While it is shown that this structure can only be detected in the specifically truncated telomeric sequences without any 5′-flanking residues, our results suggest that this two-G-tetrad conformation is likely to be an intermediate form of the interconversion of different telomeric G-quadruplex conformations.     

Loop lengths of G-quadruplex structures affect the G-quadruplex DNA binding selectivity of the RGG motif in Ewing's sarcoma

The G-quadruplex nucleic acid structural motif is a target for designing molecules with potential anticancer properties. To achieve therapeutic selectivity by targeting the G-quadruplex, the molecules must be able to differentiate between the DNA of different G-quadruplexes. We recently reported that the Arg-Gly-Gly repeat (RGG) of the C-terminus in Ewing's sarcoma protein (EWS), which is a group of dominant oncogenes that arise due to chromosomal translocations, is capable of binding to G-quadruplex telomere DNA and RNA via arginine residues and stabilize the G-quadruplex DNA form in vitro. Here, we show that the RGG of EWS binds preferentially to G-quadruplexes with longer loops, which is not related to the topology of the G-quadruplex structure. Moreover, the G-quadruplex DNA binding of the RGG in EWS depends on the phosphate backbone of the loops in the G-quadruplex DNA. We also investigated the G-quadruplex DNA binding activity of the N- and C-terminally truncated RGG to assess the role of the regions in the RGG in G-quadruplex DNA binding. Our findings indicate that the RGG and the other arginine-rich motif of residues 617-656 of the RGG in EWS are important for the specific binding to G-quadruplex DNA. These findings will contribute to the development of molecules that selectively target different G-quadruplex DNA.