Gabriele Rispoli scite author profile

HIV-1 integrase (IN) has been validated as an attractive target for the treatment of HIV/AIDS. Several studies have confirmed that the metal binding function is a crucial feature in many of the reported IN inhibitors. To provide new insights on the metal chelating mechanism of IN inhibitors, we prepared a series of metal complexes of two ligands (HL1 and HL2), designed as representative models of the clinically used compounds raltegravir and elvitegravir. Potentiometric measurements were conducted for HL2 in the presence of Mg(II), Mn(II), Co(II), and Zn(II) in order to delineate a metal speciation model. We also determined the X-ray structures of both of the ligands and of three representative metal complexes. Our results support the hypothesis that several selective strand transfer inhibitors preferentially chelate one cation in solution and that the metal complexes can interact with the active site of the enzyme.

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Inhibition of Pseudomonas aeruginosa biofilms with a glycopeptide dendrimer containing D-amino acids

Johansson

Kadam

Rispoli

et al. 2011

Med. Chem. Commun.

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Metal-Chelating 2-Hydroxyphenyl Amide Pharmacophore for Inhibition of Influenza Virus Endonuclease

Carcelli

Rogolino²,

Bacchi³

et al. 2013

Mol. Pharmaceutics

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The influenza virus PA endonuclease is an attractive target for development of novel anti-influenza virus therapeutics. Reported PA inhibitors chelate the divalent metal ion(s) in the enzyme's catalytic site, which is located in the N-terminal part of PA (PA-Nter). In this work, a series of 2-hydroxybenzamide-based compounds have been synthesized and biologically evaluated in order to identify the essential pharmacophoric motif, which could be involved in functional sequestration of the metal ions (probably Mg(2+)) in the catalytic site of PA. By using HL(1), H2L(2), and HL(3) as model ligands with Mg(2+) ions, we isolated and fully characterized a series of complexes and tested them for inhibitory activity toward PA-Nter endonuclease. H2L(2) and the corresponding Mg(2+) complex showed an interesting inhibition of the endonuclease activity. The crystal structures of the uncomplexed HL(1) and H2L(2) and of the isolated magnesium complex [Mg(L(3))2(MeOH)2]·2MeOH were solved by X-ray diffraction analysis. Furthermore, the speciation models for HL(1), H2L(2), and HL(3) with Mg(2+) were obtained, and the formation constants of the complexes were measured. Preliminary docking calculations were conducted to investigate the interactions of the title compounds with essential amino acids in the PA-Nter active site. These findings supported the "two-metal" coordination of divalent ions by a donor triad atoms chemotype as a powerful strategy to develop more potent PA endonuclease inhibitors.

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Investigation of the salicylaldehyde thiosemicarbazone scaffold for inhibition of influenza virus PA endonuclease

et al. 2015

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The influenza virus PA endonuclease is an attractive target for the development of novel anti-influenza virus therapeutics, which are urgently needed because of the emergence of drug-resistant viral strains. Reported PA inhibitors are assumed to chelate the divalent metal ion(s) (Mg²⁺ or Mn²⁺) in the enzyme's catalytic site, which is located in the N-terminal part of PA (PA-Nter). In the present work, a series of salicylaldehyde thiosemicarbazone derivatives have been synthesized and evaluated for their ability to inhibit the PA-Nter catalytic activity. Compounds 1-6 have been evaluated against influenza virus, both in enzymatic assays with influenza virus PA-Nter and in virus yield assays in MDCK cells. In order to establish a structure-activity relationship, the hydrazone analogue of the most active thiosemicarbazone has also been evaluated. Since chelation may represent a mode of action of such class of molecules, we studied the interaction of two of them, one with and one without biological activity versus the PA enzyme, towards Mg²⁺, the ion that is probably involved in the endonuclease activity of the heterotrimeric influenza polymerase complex. The crystal structure of the magnesium complex of the o-vanillin thiosemicarbazone ligand 1 is also described. Moreover, docking studies of PA endonuclease with compounds 1 and 2 were performed, to further analyse the possible mechanism of action of this class of inhibitors.

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Hydrogen Bond Optimization via Molecular Design for the Fabrication of Crystalline Organometallic Wheel-and-Axle Compounds Based on Half-Sandwich Ru(II) Units

Bacchi

Cantoni

Granelli

et al. 2011

Crystal Growth & Design

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A new series of half-sandwich ruthenium(II) complexes containing p-aminobenzoic acids (4-aminobenzoic acid and 4-aminocynnamic acid) and different arene ligands (benzene, p-cymene, and indane) have been synthesized and fully characterized giving particular attention to the analysis of the generated crystalline supramolecular architectures. A careful design of the molecular building blocks allows a perfect match to be reached between hydrogen bond donors and acceptors thus leading to the construction of crystalline wheel-and-axle metal–organic (WAAMO) systems, where the wheels are the half-sandwich units [(arene)RuCl2] and the axles are based on the cyclic dimerization of the COOH functions of the aminobenzoic ligands. The R 2 2(8) cyclic pattern is however conserved only in absence of hydrogen bond donor crystallization solvents, which, when present, tend to insert between the COOH group and a Cl–Ru moiety with formation of hydrates or solvates. Far more robust is the supramolecular synthon based on the coupling involving the Ru–NH2 function as donor and the RuCl2 group as acceptor, which has been found in five out of seven X-ray structures reported in this work. The porosity of the WAAMOs can be modulated acting on the steric requirements of the arene ligand and on the length of the covalent segment of the central supramolecular axle.

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