6533b7ddfe1ef96bd12753b4
RESEARCH PRODUCT
Determinants for Tight and Selective Binding of a Medicinal Dicarbene Gold(I) Complex to a Telomeric DNA G-Quadruplex: a Joint ESI MS and XRD Investigation
Luigi MessoriFrancesco PapiPaola GratteriLara MassaiCarla BazzicalupiMarta FerraroniBenoît BertrandAngela Casinisubject
0301 basic medicineSpectrometry Mass Electrospray IonizationESI mass spectrometryStereochemistryElectrospray ionizationStackingESI mass spectrometry; G-quadruplexes; X-ray diffraction; cancer; gold[SDV.CAN]Life Sciences [q-bio]/CancerCrystal structurepotential anticancer agents010402 general chemistryG-quadruplex01 natural sciences[ CHIM ] Chemical SciencesCatalysisAdduct[ SDV.CAN ] Life Sciences [q-bio]/Cancerchemistry.chemical_compound03 medical and health sciencescancer[CHIM]Chemical SciencesChemistry010405 organic chemistryloop flexibilityapoptosiscrystal-structureGeneral ChemistryGeneral MedicineTelomeregoldG-quadruplexesinhibition3. Good health0104 chemical sciencesX-ray diffractionstabilizationcarbene complexessmall molecules030104 developmental biologypancreatic-cancer cellsX-ray crystallographySelectivityDNAmetal-complexesdescription
International audience; The dicarbene gold(I) complex [Au(9-methylcaffein-8-ylidene)(2)]BF4 is an exceptional organometallic compound of profound interest as a prospective anticancer agent. This gold(I) complex was previously reported to be highly cytotoxic toward various cancer cell lines invitro and behaves as a selective G-quadruplex stabilizer. Interactions of the gold complex with various telomeric DNA models have been analyzed by a combined ESI MS and X-ray diffraction (XRD) approach. ESI MS measurements confirmed formation of stable adducts between the intact gold(I) complex and Tel 23 DNA sequence. The crystal structure of the adduct formed between [Au(9-methylcaffein-8-ylidene)(2)](+) and Tel 23 DNA G-quadruplex was solved. Tel 23 maintains a characteristic propeller conformation while binding three gold(I) dicarbene moieties at two distinct sites. Stacking interactions appear to drive noncovalent binding of the gold(I) complex. The structural basis for tight gold(I) complex/G-quadruplex recognition and its selectivity are described.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-03-18 |