Florian Hamon

Solution structure of a G-quadruplex bound to the bisquinolinium compound Phen-DC3

Phen-DC3 is a highly promising compound that specifically targets G-quadruplexes, with potent biological effects observed in vivo. We used NMR spectroscopy to solve the structure of the complex formed between Phen-DC3 and an intramolecular G-quadruplex derived from the c-myc promoter. Structural information revealed that Phen-DC3 interacts with the quadruplex through extensive π-stacking with guanine bases of the top G-tetrad. On the basis of our structure, modifications are proposed for the development of this compound for selective targeting of a specific G-quadruplex conformation.

An Acyclic Oligoheteroaryle That Discriminates Strongly between Diverse G-Quadruplex Topologies†

These synthetic ligands should fulfill an essentialrequirement to enable correlating their in cellulo biologicaleffects to their quadruplex recognition ability, namely strongspecificity for the targeted quadruplex combined with poorassociation to duplex DNA (ideally adifference of twoordersof magnitude or more between the affinity constants isdesired).

Development of a high-throughput G4-FID assay for screening and evaluation of small molecules binding quadruplex nucleic acid structures.

AbstractG4-FID (G-quadruplex fluorescent intercalator displacement) is a simple and fast method that allows to evaluate the affinity of a compound for G-quadruplex DNA and its selectivity towards duplex DNA. This assay is based on the loss of fluorescence of thiazole orange (TO) upon competitive displacement from DNA by a putative ligand. We describe here the development of a high-throughput version of this assay performed in 96-well microplates, and fully transposable to 384-well microplates. The test was calibrated with a set of G-quadruplex ligands characterized for their ability to bind quadruplex within a large range of affinity. The comparison of the results obtained in microplates and in cuvettes was conducted indicating a full agreement. Additionally, the spectral range of the test was enlarged using two other fluorescent on/off probes whose absorption are red-shifted (TO-PRO-3) and blue-shifted (Hoechst 33258) as compared to that of TO. These labels enable to screen a large diversity of compounds with various optical properties, which was exemplified by evaluation of affinity and selectivity of the porphyrin TMPyP4 that could not be evaluated previously. Altogether, our study demonstrates that the HT-G4-FID assay offers the possibility to label a large variety of G-quadruplexes of biological interest and should enable screening of collections of putative G4-ligands of high structural diversity. It thus represents a powerful tool to bring into light new ligands able to discriminate between quadruplexes of different structures. FigureHigh-throughput screening and evaluation of quadruplex nucleic acid ligands

Specialization Among Iron-Sulfur Cluster Helicases to Resolve G-Quadruplex DNA Structures that Threaten Genomic Stability

Background: The Fe-S helicase FANCJ implicated in Fanconi anemia plays important roles in DNA replication and repair. Results: FANCJ, but not the Fe-S XPD or DDX11 helicases, unwinds unimolecular G4 DNA. Conclusion: FANCJ is a specialized Fe-S helicase, preventing G4-induced DNA damage. Significance: FANCJ has a unique role in DNA metabolism to prevent G4 accumulation that causes genomic instability. G-quadruplex (G4) DNA, an alternate structure formed by Hoogsteen hydrogen bonds between guanines in G-rich sequences, threatens genomic stability by perturbing normal DNA transactions including replication, repair, and transcription. A variety of G4 topologies (intra- and intermolecular) can form in vitro, but the molecular architecture and cellular factors influencing G4 landscape in vivo are not clear. Helicases that unwind structured DNA molecules are emerging as an important class of G4-resolving enzymes. The BRCA1-associated FANCJ helicase is among those helicases able to unwind G4 DNA in vitro, and FANCJ mutations are associated with breast cancer and linked to Fanconi anemia. FANCJ belongs to a conserved iron-sulfur (Fe S) cluster family of helicases important for genomic stability including XPD (nucleotide excision repair), DDX11 (sister chromatid cohesion), and RTEL (telomere metabolism), genetically linked to xeroderma pigmentosum/Cockayne syndrome, Warsaw breakage syndrome, and dyskeratosis congenita, respectively. To elucidate the role of FANCJ in genomic stability, its molecular functions in G4 metabolism were examined. FANCJ efficiently unwound in a kinetic and ATPase-dependent manner entropically favored unimolecular G4 DNA, whereas other Fe-S helicases tested did not. The G4-specific ligands Phen-DC3 or Phen-DC6 inhibited FANCJ helicase on unimolecular G4 ∼1000-fold better than bi- or tetramolecular G4 DNA. The G4 ligand telomestatin induced DNA damage in human cells deficient in FANCJ but not DDX11 or XPD. These findings suggest FANCJ is a specialized Fe-S cluster helicase that preserves chromosomal stability by unwinding unimolecular G4 DNA likely to form in transiently unwound single-stranded genomic regions.

Short loop length and high thermal stability determine genomic instability induced by G-quadruplex-forming minisatellites

G‐quadruplexes (G4) are polymorphic four‐stranded structures formed by certain G‐rich nucleic acids, with various biological roles. However, structural features dictating their formation and/or function in vivo are unknown. In S. cerevisiae, the pathological persistency of G4 within the CEB1 minisatellite induces its rearrangement during leading‐strand replication. We now show that several other G4‐forming sequences remain stable. Extensive mutagenesis of the CEB25 minisatellite motif reveals that only variants with very short (≤ 4 nt) G4 loops preferentially containing pyrimidine bases trigger genomic instability. Parallel biophysical analyses demonstrate that shortening loop length does not change the monomorphic G4 structure of CEB25 variants but drastically increases its thermal stability, in correlation with the in vivo instability. Finally, bioinformatics analyses reveal that the threat for genomic stability posed by G4 bearing short pyrimidine loops is conserved in C. elegans and humans. This work provides a framework explanation for the heterogeneous instability behavior of G4‐forming sequences in vivo, highlights the importance of structure thermal stability, and questions the prevailing assumption that G4 structures with short or longer loops are as likely to form in vivo.

Nucleic acids targeted to drugs: SELEX against a quadruplex ligand

A number of small molecules demonstrate selective recognition of G-quadruplexes and are able to stabilize their formation. In this work, we performed the synthesis of two biotin-tagged G4 ligands and analyzed their interactions with DNA by two complementary techniques, FRET and FID. The compound that exhibited the best characteristics (a biotin pyridocarboxamide derivative with high stabilization of an intramolecular quadruplex and excellent duplex-quadruplex specificity) was used as bait for in vitro selection (SELEX). Among 80 DNA aptamer sequences selected, only a small minority (5/80) exhibited G4-prone motifs. Binding of consensus candidates was confirmed by SPR. These results indicate that G4 ligands that appear highly specific when comparing affinities or stabilization for one quadruplex against one duplex, do not only bind quadruplex sequences but may also recognize other nucleic motifs as well. This observation may be relevant when whole genome or transcriptome analysis of binding sites is seeked for, as unexpected binding sites may also be present.

Photo-cross-linking probes for trapping G-quadruplex DNA.

We have developed a straightforward synthetic pathway to a set of six photoactivatable G-quadruplex ligands with a validated G4-binding motif (the bisquinolinium pyridodicarboxamide PDC-360A) tethered through various spacers to two different photo-cross-linking groups: benzophenone and an aryl azide. The high quadruplex-versus-duplex selectivity of the PDC core was retained in the new derivatives and resulted in selective alkylation of two well-known G-quadruplexes (human telomeric G4 and oncogene promoter c-myc G4) under conditions of harsh competition. The presence of two structurally different photoactivatable functions allowed the selective alkylation of G-quadruplex structures at specific nucleobases and irreversible G4 binding. The topology and sequence of the quadruplex matrix appear to influence strongly the alkylation profile, which differs for the telomeric and c-myc quadruplexes. The new compounds are photoactive in cells and thus provide new tools for studying G4 biology.

Cationic Pentaheteroaryls as Selective G‐Quadruplex Ligands by Solvent‐Free Microwave‐Assisted Synthesis

We report herein a solvent-free and microwaved-assisted synthesis of several water soluble acyclic pentaheteroaryls containing 1,2,4-oxadiazole moieties (1-7). Their binding interactions with DNA quadruplex structures were thoroughly investigated by FRET melting, fluorescent intercalator displacement assay (G4-FID) and CD spectroscopy. Among the G-quadruplexes considered, attention was focused on telomeric repeats together with the proto-oncogenic c-kit sequences and the c-myc oncogene promoter. Compound 1, and to a lesser extent 2 and 5, preferentially stabilise an antiparallel structure of the telomeric DNA motif, and exhibit an opposite binding behaviour to structurally related polyoxazole (TOxaPy), and do not bind duplex DNA. The efficiency and selectivity of the binding process was remarkably controlled by the structure of the solubilising moieties.

Impact of G-quadruplex structures and intronic polymorphisms rs17878362 and rs1642785 on basal and ionizing radiation-induced expression of alternative p53 transcripts.

G-quadruplex (G4) structures in intron 3 of the p53 pre-mRNA modulate intron 2 splicing, altering the balance between the fully spliced p53 transcript (FSp53, encoding full-length p53) and an incompletely spliced transcript retaining intron 2 (p53I2 encoding the N-terminally truncated Δ40p53 isoform). The nucleotides forming G4s overlap the polymorphism rs17878362 (A1 wild-type allele, A2 16-base pair insertion) which is in linkage disequilibrium with rs1642785 in intron 2 (c.74+38 G>C). Biophysical and biochemical analyses show rs17878362 A2 alleles form similar G4 structures as A1 alleles although their position is shifted with respect to the intron 2 splice acceptor site. In addition basal FSp53 and p53I2 levels showed allele specific differences in both p53-null cells transfected with reporter constructs or lymphoblastoid cell lines. The highest FSp53 and p53I2 levels were associated with combined rs1642785-GG/rs17878362-A1A1 alleles, whereas the presence of rs1642785-C with either rs17878362 allele was associated with lower p53 pre-mRNA, total TP53, FSp53 and p53I2 levels, due to the lower stability of transcripts containing rs1642785-C. Treatment of lymphoblastoid cell with the G4 binding ligands 360A or PhenDC3 or with ionizing radiation increased FSp53 levels only in cells with rs17878362 A1 alleles, suggesting that under this G4 configuration full splicing is favoured. These results demonstrate the complex effects of intronic TP53 polymorphisms on G4 formation and identify a new role for rs1642785 on mRNA splicing and stability, and thus on the differential expression of isoform-specific transcripts of the TP53 gene.

Screening of a Chemical Library by HT-G4-FID for Discovery of Selective G-quadruplex Binders

Due to the lack of structural guidelines about G-quadruplex ligands, rational design cannot be the only approach to discover potent G4-ligands. As a complementary approach, screening of chemical library may provide interesting scaffolds known as hits provided that specific tools are available. In this work, the Institut Curie-CNRS chemical library was firstly screened by chemoinformatics methods. Similarity estimations by comparison with reference compounds (Phen-DC3, 360A, MMQ12) provided a set of molecules, which were then evaluated by high-throughput G4-FID (HT-G4-FID) against various G-quadruplex DNA. A full investigation of the most interesting molecules, using the HT-G4-FID assay and molecular modeling, supplied an interesting structure-activity relationship confirming the efficiency of this general approach. Overall, we demonstrated that HT-G4-FID coupled with screening of chemical libraries is a powerful tool to identify new G4-DNA binding scaffolds.