Pierangelo Bellio1, Letizia Di Pietro1, Alisia Mancini1, Marisa Piovano2, Marcello Nicoletti3, Fabrizia Brisdelli1, Donatella Tondi4, Laura Cendron5, Nicola Franceschini1, Gianfranco Amicosante1, Mariagrazia Perilli1, Giuseppe Celenza6. 1. Department of Biotechnological and Applied Clinical Sciences, University of l'Aquila, Via Vetoio, 1, 67100 l'Aquila, Italy. 2. Department of Chemistry, Universidad Técnica Federico Santa María, Casilla 110 V, Valparaíso, 6, Chile. 3. Department of Environmental Biology, University Sapienza, P.le A. Moro, 00185, Rome, Italy. 4. Department of Life Sciences, University of Modena e Reggio Emilia, Via Campi 103, 41100, Modena, Italy. 5. Department of Biology, University of Padova, Viale G. Colombo 3, 35131, Padova, Italy. 6. Department of Biotechnological and Applied Clinical Sciences, University of l'Aquila, Via Vetoio, 1, 67100 l'Aquila, Italy. Electronic address: giuseppe.celenza@univaq.it.
Abstract
BACKGROUND: RecA is a bacterial multifunctional protein essential to genetic recombination, error-prone replicative bypass of DNA damages and regulation of SOS response. The activation of bacterial SOS response is directly related to the development of intrinsic and/or acquired resistance to antimicrobials. Although recent studies directed towards RecA inactivation via ATP binding inhibition described a variety of micromolar affinity ligands, inhibitors of the DNA binding site are still unknown. PURPOSE: Twenty-seven secondary metabolites classified as anthraquinones, depsides, depsidones, dibenzofurans, diphenyl-butenolides, paraconic acids, pseudo-depsidones, triterpenes and xanthones, were investigated for their ability to inhibit RecA from Escherichia coli. They were isolated in various Chilean regions from 14 families and 19 genera of lichens. METHODS: The ATP hydrolytic activity of RecA was quantified detecting the generation of free phosphate in solution. The percentage of inhibition was calculated fixing at 100µM the concentration of the compounds. Deeper investigations were reserved to those compounds showing an inhibition higher than 80%. To clarify the mechanism of inhibition, the semi-log plot of the percentage of inhibition vs. ATP and vs. ssDNA, was evaluated. RESULTS: Only nine compounds showed a percentage of RecA inhibition higher than 80% (divaricatic, perlatolic, alpha-collatolic, lobaric, lichesterinic, protolichesterinic, epiphorellic acids, sphaerophorin and tumidulin). The half-inhibitory concentrations (IC50) calculated for these compounds were ranging from 14.2µM for protolichesterinic acid to 42.6µM for sphaerophorin. Investigations on the mechanism of inhibition showed that all compounds behaved as uncompetitive inhibitors for ATP binding site, with the exception of epiphorellic acid which clearly acted as non-competitive inhibitor of the ATP site. Further investigations demonstrated that epiphorellic acid competitively binds the ssDNA binding site. Kinetic data were confirmed by molecular modelling binding predictions which shows that epiphorellic acid is expected to bind the ssDNA site into the L2 loop of RecA protein. CONCLUSION: In this paper the first RecA ssDNA binding site ligand is described. Our study sets epiphorellic acid as a promising hit for the development of more effective RecA inhibitors. In our drug discovery approach, natural products in general and lichen in particular, represent a successful source of active ligands and structural diversity.
BACKGROUND: RecA is a bacterial multifunctional protein essential to genetic recombination, error-prone replicative bypass of DNA damages and regulation of SOS response. The activation of bacterial SOS response is directly related to the development of intrinsic and/or acquired resistance to antimicrobials. Although recent studies directed towards RecA inactivation via ATP binding inhibition described a variety of micromolar affinity ligands, inhibitors of the DNA binding site are still unknown. PURPOSE: Twenty-seven secondary metabolites classified as anthraquinones, depsides, depsidones, dibenzofurans, diphenyl-butenolides, paraconic acids, pseudo-depsidones, triterpenes and xanthones, were investigated for their ability to inhibit RecA from Escherichia coli. They were isolated in various Chilean regions from 14 families and 19 genera of lichens. METHODS: The ATP hydrolytic activity of RecA was quantified detecting the generation of free phosphate in solution. The percentage of inhibition was calculated fixing at 100µM the concentration of the compounds. Deeper investigations were reserved to those compounds showing an inhibition higher than 80%. To clarify the mechanism of inhibition, the semi-log plot of the percentage of inhibition vs. ATP and vs. ssDNA, was evaluated. RESULTS: Only nine compounds showed a percentage of RecA inhibition higher than 80% (divaricatic, perlatolic, alpha-collatolic, lobaric, lichesterinic, protolichesterinic, epiphorellic acids, sphaerophorin and tumidulin). The half-inhibitory concentrations (IC50) calculated for these compounds were ranging from 14.2µM for protolichesterinic acid to 42.6µM for sphaerophorin. Investigations on the mechanism of inhibition showed that all compounds behaved as uncompetitive inhibitors for ATP binding site, with the exception of epiphorellic acid which clearly acted as non-competitive inhibitor of the ATP site. Further investigations demonstrated that epiphorellic acid competitively binds the ssDNA binding site. Kinetic data were confirmed by molecular modelling binding predictions which shows that epiphorellic acid is expected to bind the ssDNA site into the L2 loop of RecA protein. CONCLUSION: In this paper the first RecA ssDNA binding site ligand is described. Our study sets epiphorellic acid as a promising hit for the development of more effective RecA inhibitors. In our drug discovery approach, natural products in general and lichen in particular, represent a successful source of active ligands and structural diversity.
Authors: Charlie Y Mo; Matthew J Culyba; Trevor Selwood; Jeffrey M Kubiak; Zachary M Hostetler; Anthony J Jurewicz; Paul M Keller; Andrew J Pope; Amy Quinn; Jessica Schneck; Katherine L Widdowson; Rahul M Kohli Journal: ACS Infect Dis Date: 2018-01-08 Impact factor: 5.084
Authors: Ana Victoria Cheng Jaramillo; Michael B Cory; Allen Li; Rahul M Kohli; William M Wuest Journal: Bioorg Med Chem Lett Date: 2022-03-26 Impact factor: 2.940