iMab antibody binds single-stranded cytosine-rich sequences and unfolds DNA i-motifs.

i-Motifs (iMs) are non-canonical, four-stranded secondary structures formed by stacking of hemi-protonated CH+·C base pairs in cytosine-rich DNA sequences, predominantly at pH < 7. The presence of iM structures in cells was a matter of debate until the recent development of iM-specific antibody, iMab, which was instrumental for several studies that suggested the existence of iMs in live cells and their putative biological roles. We assessed the interaction of iMab with cytosine-rich oligonucleotides by biolayer interferometry (BLI), pull-down assay and bulk-FRET experiments. Our results suggest that binding of iMab to DNA oligonucleotides is governed by the presence of runs of at least two consecutive cytosines and is generally increased in acidic conditions, irrespectively of the capacity of the sequence to adopt, or not, an iM structure. Moreover, the results of the bulk-FRET assay indicate that interaction with iMab results in unfolding of iM structures even in acidic conditions, similarly to what has been observed with hnRNP K, well-studied single-stranded DNA binding protein. Taken together, our results strongly suggest that iMab actually binds to blocks of 2-3 cytosines in single-stranded DNA, and call for more careful interpretation of results obtained with this antibody.

Correction: Harnessing an emissive guanine surrogate to design small-molecule fluorescent chemosensors of O6-methylguanine-DNA-methyltransferase (MGMT).

Correction for 'Harnessing an emissive guanine surrogate to design small-molecule fluorescent chemosensors of O6-methylguanine-DNA-methyltransferase (MGMT)' by Alexandra Fillion et al., Org. Biomol. Chem., 2022, 20, 1888-1892, https://doi.org/10.1039/D2OB00208F.

Structural Optimization of Azacryptands for Targeting Three-Way DNA Junctions.

Transient melting of the duplex-DNA (B-DNA) during DNA transactions allows repeated sequences to fold into non-B-DNA structures, including DNA junctions and G-quadruplexes. These noncanonical structures can act as impediments to DNA polymerase progression along the duplex, thereby triggering DNA damage and ultimately jeopardizing genomic stability. Their stabilization by ad hoc ligands is currently being explored as a putative anticancer strategy since it might represent an efficient way to inflict toxic DNA damage specifically to rapidly dividing cancer cells. The relevance of this strategy is only emerging for three-way DNA junctions (TWJs) and, to date, no molecule has been recognized as a reference TWJ ligand, featuring both high affinity and selectivity. Herein, we characterize such reference ligands through a combination of in vitro techniques comprising affinity and selectivity assays (competitive FRET-melting and TWJ Screen assays), functional tests (qPCR and Taq stop assays) and structural analyses (molecular dynamics and NMR investigations). We identify novel azacryptands TrisNP-amphi and TrisNP-ana as the most promising ligands, interacting with TWJs with high affinity and selectivity. These ligands represent new molecular tools to investigate the cellular roles of TWJs and explore how they can be exploited in innovative anticancer therapies.

Potentiometric titrations to study ligand interactions with DNA i-motifs.

i-Motifs are non-canonical secondary structures of DNA formed by mutual intercalation of hemi-protonated cytosine-cytosine base pairs, most typically in slightly acidic conditions (pH<7.0). These structures are well-studied in vitro and have recently been suggested to exist in cells. Despite nearly a decade of active research, the quest for small-molecule ligands that could selectively bind to and stabilize i-motifs continues, and no reference, bona fide i-motif ligand is currently available. This is, at least in part, due to the lack of robust methods to assess the interaction of ligands with i-motifs, since many techniques well-established for studies of other secondary structures (such as CD-, UV-, and FRET-melting) may generate artifacts when applied to i-motifs. Here, we describe an implementation of automated, potentiometric (pH) titrations as a robust isothermal method to assess the impact of ligands or cosolutes on thermodynamic stability of i-motifs. This approach is validated through the use of a cosolute previously known to stabilize i-motifs (PEG2000) and three small-molecule ligands that are able to stabilize, destabilize, or have no effect on the stability of i-motifs, respectively.