Impact of the Halogen Substitution Pattern on the Biological Activity of Organoruthenium 8‑Hydroxyquinoline Anticancer Agents

8-Hydroxyquinoline and its derivatives have a broad variety of pharmacological properties, which make them an ideal bioactive building block in the development of metal-based anticancer drugs. In this account we aimed to rationalize the antiproliferative efficacy of organoruthenium compounds featuring 8-hydroxyquinoline-derived ligands and to elucidate structural determinants by using biological assays and bioanalytical methods. By systematically varying the halide substitution pattern at the 5- and 7-positions of the 8-hydroxyquinoline ligand, as well as the halido leaving group, a series of 5,7-dihalido-8-hydroxyquinoline Ru^II(η⁶-<i>p</i>-cymene) complexes were obtained. Studies on their cytotoxic activity revealed the minor impact of the substitution pattern (with the exception of complexes of 8-hydroxyquinoline) on their activity. Notably, the cellular accumulation showed no correlation with the cytotoxic activity, while the nature of the halido leaving group only had a significant influence in the case of the 8-hydroxyquinoline organoruthenium compounds. However, the compounds were shown to be very stable under a wide variety of pH conditions, making them possible candidates for further development as orally active anticancer agents

Triazolyl- vs Pyridyl-Functionalized <i>N</i>‑Heterocyclic Carbene Complexes: Impact of the Pendant N‑Donor Ligand on Intramolecular C–C Bond Formation

Organometallic Rh(Cp*) (Cp* = η5-pentamethylcyclopentadienyl) complexes with monodentate N-heterocyclic carbene (NHC) ligands bearing a pendant anthracenyl substituent have been shown to undergo intramolecular C–C coupling reactions. Herein, two bidentate NHC ligands substituted with pyridyl or triazolyl donor groups were prepared along with the corresponding MII/III (M = RuII, OsII, RhIII, IrIII) complexes. While the Rh(Cp*) complex featuring an NHC-triazole bidentate ligand underwent the equivalent reaction as the monodentate Rh(NHC) complex, i.e., it formed a polydentate ligand, the pyridyl-pendant derivative was unequivocally shown to be unreactive. This contrasting behavior was further investigated by density functional theory (DFT) calculations that highlighted significant differences between the two types of Rh(III) complexes with pendant pyridyl or triazolyl N-coordinating groups. Modeling of the reaction pathways suggests that the initial formation of a dicationic Rh(III) species is unfavorable and that the internal ligand transformation proceeds first by dissociation of the coordinated N atom of the pendant group from the Rh center. After the formation of a neutral η4-fulvene ligand via combined proton/single electron transfer, a cycloaddition occurs between the exo-ene bond of fulvene and the 9′ and 10′ positions on the pendant anthracenyl group. The resulting experimental UV–visible spectrum recorded in methanol of the polydentate triazolyl-based Rh species revealed the loss of the vibronic coupling typically associated with an anthracenyl functional group. Moreover, TD-DFT modeling indicates the presence of an equilibrium process whereby the N-coordination of the pendant triazolyl group to the RhIII center appears to be highly labile. Charge decomposition analysis (CDA) of the DFT-modeled species with the dissociated triazolyl group revealed a pseudo-η3-allylic interaction between the π-type MOs of the transformed anthracenyl group and the RhIII center; thus, the singly attached chelating ligand is classified as having rare nonadenticity

Stereochemical Characterization of Polyketide Stereotriads Synthesized via Hydrogen-Mediated Asymmetric <i>syn</i>-Crotylation

The stereoselective access to stereotriads as important polyketide building blocks is reported on the basis of the Krische-type hydrogen-mediated <i>syn</i>-crotylation. The products were obtained with an extremely high diastereoselectivity (dr >99:1), and the newly formed <i>syn</i> stereocenters were controlled solely by the chiral catalyst. The stereochemistry was assigned by crystallography and HPLC for both product manifolds. This extension of the burgeoning transfer hydrogen methodology gives divergent asymmetric access to <i>anti</i>,<i>syn</i> and <i>syn</i>,<i>syn</i> polyketide stereotriads from the same α-chiral starting material and avoids potentially epimerizable aldehyde intermediates

Impact of the Halogen Substitution Pattern on the Biological Activity of Organoruthenium 8‑Hydroxyquinoline Anticancer Agents

8-Hydroxyquinoline and its derivatives have a broad variety of pharmacological properties, which make them an ideal bioactive building block in the development of metal-based anticancer drugs. In this account we aimed to rationalize the antiproliferative efficacy of organoruthenium compounds featuring 8-hydroxyquinoline-derived ligands and to elucidate structural determinants by using biological assays and bioanalytical methods. By systematically varying the halide substitution pattern at the 5- and 7-positions of the 8-hydroxyquinoline ligand, as well as the halido leaving group, a series of 5,7-dihalido-8-hydroxyquinoline Ru^II(η⁶-<i>p</i>-cymene) complexes were obtained. Studies on their cytotoxic activity revealed the minor impact of the substitution pattern (with the exception of complexes of 8-hydroxyquinoline) on their activity. Notably, the cellular accumulation showed no correlation with the cytotoxic activity, while the nature of the halido leaving group only had a significant influence in the case of the 8-hydroxyquinoline organoruthenium compounds. However, the compounds were shown to be very stable under a wide variety of pH conditions, making them possible candidates for further development as orally active anticancer agents

Anticancer Ruthenium(η⁶‑<i>p</i>‑cymene) Complexes of Nonsteroidal Anti-inflammatory Drug Derivatives

Oxicams are a versatile family of heterocyclic compounds, and the two representatives meloxicam and piroxicam are widely used drugs for the treatment of a variety of inflammatory and rheumatic diseases in humans. As cancer-associated inflammation is known to occur in carcinogenesis, we aimed to combine compounds carrying bioactive oxicam moieties with ruthenium­(arene) fragments, known for anticancer activity. Ru^II(arene) complexes with methyl ester derivatives of the oxicam scaffold were prepared and characterized by standard methods and crystallographically. The organoruthenium compounds formed from Ru^II(η⁶-<i>p</i>-cymene) chlorido moieties and oxicam-based ligands were subjected to bioanalytical investigations to establish their physicochemical properties with regard to stability in DMSO and water as well as reactivity toward the amino acids l-histidine (His), l-methionine (Met), and l-cysteine (Cys) and the DNA model compound guanosine 5′-monophosphate (5′-GMP). The compounds hydrolyzed rapidly in water to give the respective aqua complexes, formed amino acid complexes with Met and His, but decompose with Cys, while interaction with 5′-GMP was through its phosphate residue. The anticancer activity of the complexes against the colon carcinoma HCT116 and breast cancer MDA MB 231 cancer cell lines was established using an <i>in vitro</i> assay. The cytotoxicity was found strongly dependent on the lipophilicity of the compound, as was shown through correlation with log<i> k</i>_w and clog<i> P</i> values of the ligands. The most lipophilic compound [chlorido­(methyl 4-oxido-2-benzyl-2<i>H</i>-1,2-benzothiazine-3-carboxylate-1,1-dioxide)­(η⁶-<i>p</i>-cymene)­ruthenium­(II)] was the most active in the cell assays, with an IC₅₀ of 80 μM in HCT116 cells

A Bioactive l‑Phenylalanine-Derived Arene in Multitargeted Organoruthenium Compounds: Impact on the Antiproliferative Activity and Mode of Action

Ru^II(η⁶-arene) compounds carrying bioactive flavonol ligands have shown promising anticancer activity against tumor cells via a multitargeting mode of action, i.e., through interaction with DNA and inhibition of topoisomerase IIα. By introducing a novel arene ligand based on the amino acid l-phenylalanine (Phe), we aimed to alter the pharmacological properties of the complexes. We report here a series of novel Ru^II(η⁶-arene)Cl complexes with different substituents on the phenyl ring of the flavonol which should maintain the multitargeting capability of the parent η⁶-<i>p</i>-cymene (cym) complexes. Studies with selected examples revealed stability in aqueous solution after quickly forming aqua complexes but rapid decomposition in pure DMSO. The reactions with protein and DNA models proceeded quickly and resulted in cleavage of the flavonol or adduct formation, respectively. The compounds were found to be cytotoxic with significant antiproliferative activity in cancer cells with IC₅₀ values in the low μM range, while not following the same trends as observed for the cym analogues. Notably, the cellular accumulation of the new derivatives was significantly higher than for their respective cym complexes, and they induced DNA damage in a manner similar to that of cisplatin but to a lesser extent

(Pyridin-2-yl)-NHC Organoruthenium Complexes: Antiproliferative Properties and Reactivity toward Biomolecules

Organoruthenium compounds have been widely investigated for their anticancer activity. Here we use one of the classic ligand classes found in organometallics, i.e., N-heterocyclic carbenes (NHC), and coordinate them to the Ru­(η⁶-<i>p</i>-cymene) scaffold as <i>N</i>,<i>C</i>-bidentate ligands substituted with a pyridyl moiety. Introduction of different substituents gave compounds with a wide variety of properties. We investigated their stability in solution and in the presence of biomolecules, in vitro anticancer activity, and cellular uptake to rationalize their biological properties in dependence on the structure. A clear effect of their structure on the stability in water and DMSO was found for some derivatives, which was reflected in the reactivity to biomolecules that was determined with selected representatives of the compound classes. The antiproliferative activity of the compounds was widely dependent on the lipophilicity of the <i>N</i>,<i>C</i>-bidentate ligand, but as cellular accumulation studies revealed, lipophilicity does not provide the full picture and additional effects must be responsible for the anticancer activity

From Catalysis to Cancer: Toward Structure–Activity Relationships for Benzimidazol-2-ylidene-Derived <i>N</i>‑Heterocyclic-Carbene Complexes as Anticancer Agents

The promise of the metal­(arene) structure as an anticancer pharmacophore has prompted intensive exploration of this chemical space. While <i>N</i>-heterocyclic carbene (NHC) ligands are widely used in catalysis, they have only recently been considered in metal complexes for medicinal applications. Surprisingly, a comparatively small number of studies have been reported in which the NHC ligand was coordinated to the Ru^II(arene) pharmacophore and even less with an Os^II(arene) pharmacophore. Here, we present a systematic study in which we compared symmetrically substituted methyl and benzyl derivatives with the nonsymmetric methyl/benzyl analogues. Through variation of the metal center and the halido ligands, an in-depth study was conducted on ligand exchange properties of these complexes and their biomolecule binding, noting in particular the stability of the M–C_NHC bond. In addition, we demonstrated the ability of the complexes to inhibit the selenoenzyme thioredoxin reductase (TrxR), suggested as an important target for anticancer metal–NHC complexes, and their cytotoxicity in human tumor cells. It was found that the most potent TrxR inhibitor diiodido­(1,3-dibenzylbenzimidazol-2-ylidene)­(η⁶-p-cymene)­ruthenium­(II) <b>1b</b>^<b>I</b> was also the most cytotoxic compound of the series, with the antiproliferative effects in general in the low to middle micromolar range. However, since there was no clear correlation between TrxR inhibition and antiproliferative potency across the compounds, TrxR inhibition is unlikely to be the main mode of action for the compound type and other target interactions must be considered in future