One-step scalable fluorescent microgel bioassay for the ultrasensitive detection of endogenous viral miR-US4-5p.

Human cytomegalovirus (hCMV) infection is the leading cause of birth defects in newborns and death in immunosuppressed people. Traditional techniques require time-consuming and costly analyses, and sometimes result in false positive results; thus, a rapid and accurate detection for hCMV infection is necessary. Recently, hcmv-miR-US4-5p was selected as the biomarker for cytomegalovirus diagnosis and follow-up. Herein, we propose a bioassay based on microgels endowed with optical fluorescent oligonucleotide probes for the detection of circulating endogenous hcmv-microRNAs. In particular, a double strand probe, based on the fluorescence recovery after target capture, was conjugated on microgels and the probe density was opportunely optimised. Then, the microgels were directly mixed with the sample. The fluorescence read-out was measured as a function of target concentration at a fixed number of microgels per tube. As a bead-based assay, the performances of optical detection in terms of dynamic working range and limit of detection could be finely tuned by tuning the number of microgels per tube. The limit of detection of the assay could be tuned in the range from 39.1 fM to 156 aM by changing the microgel concentration from 50 µg mL-1 to 0.5 µg mL-1, respectively. The assay results specific for the selected target were stable over a one-year time span and they were not affected by the presence of human serum. Therefore, this bioassay based on microgels might represent a flexible platform that should be able to predict, identify and follow-up several diseases by monitoring freely circulating oligonucleotides in body fluids.

Fluorescence enhancement upon G-quadruplex folding: synthesis, structure, and biophysical characterization of a dansyl/cyclodextrin-tagged thrombin binding aptamer.

A novel fluorescent thrombin binding aptamer (TBA), conjugated with the environmentally sensitive dansyl probe at the 3'-end and a ß-cyclodextrin residue at the 5'-end, has been efficiently synthesized exploiting Cu(I)-catalyzed azide-alkyne cycloaddition procedures. Its conformation and stability in solution have been studied by an integrated approach, combining in-depth NMR, CD, fluorescence, and DSC studies. ITC measurements have allowed us to analyze in detail its interaction with human thrombin. All the collected data show that this bis-conjugated aptamer fully retains its G-quadruplex formation ability and thrombin recognition properties, with the terminal appendages only marginally interfering with the conformational behavior of TBA. Folding of this modified aptamer into the chairlike, antiparallel G-quadruplex structure, promoted by K(+) and/or thrombin binding, typical of TBA, is associated with a net fluorescence enhancement, due to encapsulation of dansyl, attached at the 3'-end, into the apolar cavity of the ß-cyclodextrin at the 5'-end. Overall, the structural characterization of this novel, bis-conjugated TBA fully demonstrates its potential as a diagnostic tool for thrombin recognition, also providing a useful basis for the design of suitable aptamer-based devices for theranostic applications, allowing simultaneously both detection and inhibition or modulation of the thrombin activity.

The triazatruxene derivative azatrux binds to the parallel form of the human telomeric G-quadruplex under molecular crowding conditions: biophysical and molecular modeling studies.

The present study has employed a combination of spectroscopic, calorimetric and computational methods to explore the binding of the three side-chained triazatruxene derivative, termed azatrux, to a human telomeric G-quadruplex sequence, under conditions of molecular crowding. The binding of azatrux to the tetramolecular parallel [d(TGGGGT)](4) quadruplex in the presence and absence of crowding conditions, was also characterized. The data indicate that azatrux binds in an end-stacking mode to the parallel G-quadruplex scaffold and highlights the key structural elements involved in the binding. The selectivity of azatrux for the human telomeric G-quadruplex relative to another biologically relevant G-quadruplex (c-Kit87up) and to duplex DNA was also investigated under molecular crowding conditions, showing that azatrux has good selectivity for the human telomeric G-quadruplex over the other investigated DNA structures.

Binding properties of human telomeric quadruplex multimers: a new route for drug design.

Human telomeric G-quadruplex structures are known to be promising targets for an anticancer therapy. In the past decade, several research groups have been focused on the design of new ligands trying to optimize the interactions between these small molecules and the G-quadruplex motif. In most of these studies, the target structures were the single quadruplex units formed by short human DNA telomeric sequences (typically 21-26 nt). However, the 3'-terminal single-stranded human telomeric DNA is actually 100-200 bases long and can form higher-order structures by clustering several consecutive quadruplex units (multimers). Despite the increasing number of structural information on longer DNA telomeric sequences, very few data are available on the binding properties of these sequences compared with the shorter DNA telomeric sequences. In this paper we use a combination of spectroscopic (CD, UV and fluorescence) and calorimetric techniques (ITC) to compare the binding properties of the (TTAGGG)(8)TT structure formed by two adjacent quadruplex units with the binding properties of the (AG(3)TT)(4) single quadruplex structure. The three side-chained triazatruxene derivative azatrux and TMPyP4 cationic porphyrin were used as quadruplex ligands. We found that, depending on the drug, the number of binding sites per quadruplex unit available in the multimer structure was smaller or greater than the one expected on the basis of the results obtained from individual quadruplex binding studies. This work suggests that the quadruplex units along a multimer structure do not behave as completely independent. The presence of adjacent quadruplexes results in a diverse binding ability not predictable from single quadruplex binding studies. The existence of quadruplex-quadruplex interfaces in the full length telomeric overhang may provide an advantageous factor in drug design to enhance both affinity and selectivity for DNA telomeric quadruplexes.