Efficient Multicomponent Synthesis of Diverse Antibacterial Embelin-Privileged Structure Conjugates.

A library of embelin derivatives has been synthesized through a multicomponent reaction from embelin (1), aldehydes and privileged structures such as 4-hydroxycoumarin, 4-hydroxy-2H-pyran-2-one and 2-naphthol, in the presence of InCl3 as catalyst. This multicomponent reaction implies Knoevenagel condensation, Michael addition, intramolecular cyclization and dehydration. Many of the synthesized compounds were active and selective against Gram-positive bacteria, including one important multiresistant Staphylococcus aureus clinical isolate. It was found how the conjugation of diverse privileged substructure with embelin led to adducts having enhanced antibacterial activities.

Synthesis and biological evaluation of naphthoquinone-coumarin conjugates as topoisomerase II inhibitors.

Based on previous Topoisomerase II docking studies of naphthoquinone derivatives, a series of naphthoquinone-coumarin conjugates was synthesized through a multicomponent reaction from aromatic aldehydes, 4-hydroxycoumarin and 2-hydroxynaphthoquinone. The hybrid structures were evaluated against the α isoform of human topoisomerase II (hTopoIIα), Escherichia coli DNA Gyrase and E. coli Topoisomerase I. All tested compounds inhibited the hTopoIIα-mediated relaxation of negatively supercoiled circular DNA in the low micromolar range. This inhibition was specific since neither DNA Gyrase nor Topoisomerase I were affected. Cleavage assays pointed out that naphthoquinone-coumarins act by catalytically inhibiting hTopoIIα. ATPase assays and molecular docking studies further pointed out that the mode of action is related to the hTopoIIα ATP-binding site.

5-Ethynylarylnaphthalimides as antitumor agents: Synthesis and biological evaluation.

A set of 5-ethynylarylnaphthalimides was synthesized by Sonogashira cross-coupling reactions and evaluated for antiproliferative and antitopoisomerase II in vitro activities. Furthermore docking studies of these molecules as DNA-intercalators were carried out and the in vivo DNA-damaging activity was also determined with the model organism Saccharomyces cerevisiae. From the obtained results three naphthalimides 6, 13 and 14 showed strong topoisomerase II inhibitory activity. These three molecules also presented good docking scores as DNA-intercalators using a self-complementary oligodeoxynucleotide d(ATGCAT)2 as a model, and compounds 13 and 14 were among the most cytotoxic in the in vivo DNA-damaging activity.

Synthesis and study of antiproliferative, antitopoisomerase II, DNA-intercalating and DNA-damaging activities of arylnaphthalimides.

A series of arylnaphthalimides were designed and synthesized to overcome the dose-limiting cytotoxicity of N-acetylated metabolites arising from amonafide, the prototypical antitumour naphthalimide whose biomedical properties have been related to its ability to intercalate the DNA and poison the enzyme Topoisomerase II. Thus, these arylnaphthalimides were first evaluated for their antiproliferative activity against two tumour cell lines and for their antitopoisomerase II in vitro activities, together with their ability to intercalate the DNA in vitro and also through docking modelization. Then, the well-known DNA damage response in Saccharomyces cerevisiae was employed to critically evaluate whether these novel compounds can damage the DNA in vivo. By performing all these assays we conclude that the 5-arylsubstituted naphthalimides not only keep but also improve amonafide's biological activities.

Synthesis of Structurally Related Coumarin Derivatives as Antiproliferative Agents.

A library of structurally related coumarins was generated through synthesis reactions and chemical modification reactions to obtain derivatives with antiproliferative activity both in vivo and in vitro. Out of a total of 35 structurally related coumarin derivatives, seven of them showed inhibitory activity in in vitro tests against Taq DNA polymerase with IC50 values lower than 250 µM. The derivatives 4-(chloromethyl)-5,7-dihydroxy-2H-chromen-2-one (2d) and 4-((acetylthio)methyl)-2-oxo-2H-chromen-7-yl acetate (3c) showed the most promising anti-polymerase activity with IC50 values of 20.7 ± 2.10 and 48.25 ± 1.20 µM, respectively. Assays with tumor cell lines (HEK 293 and HCT-116) were carried out, and the derivative 4-(chloromethyl)-7,8-dihydroxy-2H-chromen-2-one (2c) was the most promising, with an IC50 value of 8.47 µM and a selectivity index of 1.87. In addition, the derivatives were evaluated against Saccharomyces cerevisiae strains that report about common modes of actions, including DNA damage, that are expected for agents that cause replicative stress. The coumarin derivatives 7-(2-(oxiran-2-yl)ethoxy)-2H-chromen-2-one (5b) and 7-(3-(oxiran-2-yl)propoxy)-2H-chromen-2-one (5c) caused DNA damage in S. cerevisiae. The O-alkenylepoxy group stands out as that with the most important functionality within this family of 35 derivatives, presenting a very good profile as an antiproliferative scaffold. Finally, the in vitro antiretroviral capacity was tested through RT-PCR assays. Derivative 5c showed inhibitory activity below 150 µM with an IC50 value of 134.22 ± 2.37 µM, highlighting the O-butylepoxy group as the functionalization responsible for the activity.

No role of homologous recombination in dealing with ß-lapachone cytotoxicity in yeast.

ß-Lapachone (ß-lap) is a promising antitumoral agent. DNA base oxidation and alkylation are among the expected damages by ß-lap. Herein, we have explored the role that the homologous recombination pathway (HR), a critical DNA repair process in Saccharomyces cerevisiae, has in the cytotoxic profile of ß-lap. We have further compared ß-lap to the closely related compound menadione and the well-known alkylating agent methyl methanesulfonate (MMS). Surprisingly, we found that ß-lap does not trigger HR, as seen for (i) the mutant sensitivity profiles, (ii) concentration-dependent arrest profiles, (iii) absence of nuclear DNA repair factories, and (iv) frequency of recombination between direct repeats.

Pyranonaphthoquinone derivatives of eleutherin, ventiloquinone L, thysanone and nanaomycin A possessing a diverse topoisomerase II inhibition and cytotoxicity spectrum.

A series of pyranonaphthoquinone derivatives related to the known topoisomerase II inhibitor eleutherin 1 have been shown to act as specific topoisomerase II catalytic inhibitors, with several analogues displaying greater potency than the natural product itself. Amongst the compounds tested were the natural products ventiloquinone L 4 and thysanone 8 with a diverse range of topoisomerase II inhibition properties being observed. Interestingly, the natural products are generally weaker inhibitors than their synthetic counterparts, emphasising that subtle changes in the basic molecular structure of a natural product led to significant changes in the inhibition profile. It has also been demonstrated for the first time that analogues related to nanaomycin A and cardinalin-type dimeric pyranonaphthoquinones exhibit potent topoisomerase II inhibitory properties. With respect to structural features, it appears that the nature of the substituents at C1 on the pyran ring and oxygenated substituents on the aryl ring are critical for anti-topoII activity. Importantly, the topoisomerase II inhibition strength does not correlate well with the measured cytotoxicity against yeast, indicating that other molecular features in the pyranonaphthoquinone family must be considered for the design and use of this structural class as highly specific topoisomerase II inhibitors.

Cytological and genetic consequences for the progeny of a mitotic catastrophe provoked by Topoisomerase II deficiency.

Topoisomerase II (Top2) removes topological linkages between replicated chromosomes. Top2 inhibition leads to mitotic catastrophe (MC) when cells unsuccessfully try to split their genetic material between the two daughter cells. Herein, we have characterized the fate of these daughter cells in the budding yeast. Clonogenic and microcolony experiments, in combination with vital and apoptotic stains, showed that 75% of daughter cells become senescent in the short term; they are unable to divide but remain alive. Decline in cell vitality then occurred, yet slowly, uncoordinatedly when comparing pairs of daughters, and independently of the cell death mediator Mca1/Yca1. Furthermore, we showed that senescence can be modulated by ploidy, suggesting that gross chromosome imbalances during segregation may account for this phenotype. Indeed, we found that diploid long-term survivors of the MC are prone to genomic imbalances such as trisomies, uniparental disomies and terminal loss of heterozygosity (LOH), the latter affecting the longest chromosome arms.

Lawsone, Juglone, and ß-Lapachone Derivatives with Enhanced Mitochondrial-Based Toxicity.

Naphthoquinones are among the most active natural products obtained from plants and microorganisms. Naphthoquinones exert their biological activities through pleiotropic mechanisms that include reactivity against cell nucleophiles, generation of reactive oxygen species (ROS), and inhibition of proteins. Here, we report a mechanistic antiproliferative study performed in the yeast Saccharomyces cerevisiae for several derivatives of three important natural naphthoquinones: lawsone, juglone, and ß-lapachone. We have found that (i) the free hydroxyl group of lawsone and juglone modulates toxicity; (ii) lawsone and juglone derivatives differ in their mechanisms of action, with ROS generation being more important for the former; and (iii) a subset of derivatives possess the capability to disrupt mitochondrial function, with ß-lapachones being the most potent compounds in this respect. In addition, we have cross-compared yeast results with antibacterial and antitumor activities. We discuss the relationship between the mechanistic findings, the antiproliferative activities, and the physicochemical properties of the naphthoquinones.

Synthesis and antibacterial activity of new symmetric polyoxygenated dibenzofurans.

A series of symmetric polyoxygenated dibenzofurans with 2-methylbutyril moieties at C-4 and C-6 were obtained from commercial phloroglucinol through a sequence of reactions that include monoacylation, iodination, Suzuki-Miyaura coupling, oxidative dimerization and cyclization. Some of the compounds obtained were active against Gram-positive bacteria, including multiresistant Staphylococcus aureus clinical isolates. The dibenzofuran 28 with propyl chains at C-2 and C-8 exhibited the best antibacterial activity with values comparable to those of the natural dibenzofuran achyrofuran. From the obtained results some structure-activity relationships were outlined.

Yeast cytotoxic sensitivity to the antitumour agent ß-lapachone depends mainly on oxidative stress and is largely independent of microtubule- or topoisomerase-mediated DNA damage.

ß-Lapachone (ß-lap) is a promising antitumour drug currently undergoing clinical trials. Although it is known that ß-lap generates reactive oxygen species (ROS), its actual mechanism of action is still controversial. Especially important is to determine whether concomitant DNA or microtubule damage is the key target of its antitumour properties and whether DNA damage is mediated by topoisomerases as previously suggested. Here, we have searched for determinants of ß-lap cytotoxicity in the model organism Saccharomyces cerevisiae through a mechanism-driven approach whereby several pathways of the DNA and microtubule integrity responses, as well as the anti-oxidant response, were downregulated and the outcome of ß-lap treatment examined. We also included in the analysis several ß-lap derivatives expected to modify drug bioavailability and activity. We found that neither topoisomerase II nor microtubules contributed to yeast sensitivity to ß-lap and its equitoxic derivative 3-bromo-ß-lapachone. Instead, we found that oxidative and related environmental stresses were primarily responsible for toxicity. Accordingly, Yap1, the central transcription factor in the antioxidant response in yeast, together with several components involved in stress tolerance (i.e., Snf1 and Hog1) and chromatin remodelling (i.e., the SWR1 and RSC complexes), played major roles in protection against ß-lapachone. Critically, we show that dioxygen enhanced toxicity and that ROS scavengers protected cells from it. Furthermore, we show that both quinones resulted in cell death in a manner which cytologically resembled apoptosis/necrosis. We thus conclude that ß-lap is toxic to yeast through massive ROS production that either directly kills the cells or else triggers programmed cell death.