Hydrophobicity may increase the hydrolytic stability of vanadium(v) catecholate complexes enabling rapid cellular uptake of the intact complex exhibiting potent anti-cancer activity.
The chemistry and short lifetimes of metal‐based anti‐cancer drugs can be turned into an advantage for direct injections into tumors, which then allow the use of highly cytotoxic drugs. The release of their less toxic decomposition products into the blood will lead to decreased toxicity and can even have beneficial effects. We present a ternary VV complex, 1 ([VOL1L2], where L1 is N‐(salicylideneaminato)‐N′‐(2‐hydroxyethyl)ethane‐1,2‐diamine and L2 is 3,5‐di‐tert‐butylcatechol), which enters cells intact to induce high cytotoxicity in a range of human cancer cells, including T98g (glioma multiforme), while its decomposition products in cell culture medium were ≈8‐fold less toxic. 1 was 12‐fold more toxic than cisplatin in T98g cells and 6‐fold more toxic in T98g cells than in a non‐cancer human cell line, HFF‐1. Its high toxicity in T98g cells was retained in the presence of physiological concentrations of the two main metal‐binding serum proteins, albumin and transferrin. These properties favor further development of 1 for brain cancer treatment by intratumoral injections.
Menaquinones (naphthoquinones, MK) are isoprenoids that play key roles in the respiratory electron transport system of some prokaryotes by shuttling electrons between membrane-bound protein complexes acting as electron acceptors and donors. Menaquinone-2 (MK-2), a truncated MK, was synthesized, and the studies presented herein characterize the conformational and chemical properties of the hydrophobic MK-2 molecule. Using 2D NMR spectroscopy, we established for the first time that MK-2 has a folded conformation defined by the isoprenyl side-chain folding back over the napthoquinone in a U-shape, which depends on the specific environmental conditions found in different solvents. We used molecular mechanics to illustrate conformations found by the NMR experiments. The measured redox potentials of MK-2 differed in three organic solvents, where MK-2 was most easily reduced in DMSO, which may suggest a combination of solvent effect (presumably in part because of differences in dielectric constants) and/or conformational differences of MK-2 in different organic solvents. Furthermore, MK-2 was found to associate with the interface of model membranes represented by Langmuir phospholipid monolayers and Aerosol-OT (AOT) reverse micelles. MK-2 adopts a slightly different U-shaped conformation within reverse micelles compared to within solution, which is in sharp contrast to the extended conformations illustrated in literature for MKs.
A hydrophobic Schiff base catecholate vanadium complex was recently discovered to have anticancer properties superior to cisplatin and suited for intratumoral administration. This [VO(HSHED)(DTB)] complex, where HSHED is N-(salicylideneaminato)-N′-(2-hydroxyethyl)-1,2-ethanediamine and the non-innocent catecholato ligand is di-t-butylcatecholato (DTB), has higher stability compared to simpler catecholato complexes. Three new chloro-substituted Schiff base complexes of vanadium(V) with substituted catecholates as co-ligands were synthesized for comparison with their non-chlorinated Schiff base vanadium complexes, and their properties were characterized. Up to four geometric isomers for each complex were identified in organic solvents using 51 V and 1 H NMR spectroscopies. Spectroscopy was used to characterize the structure of the major isomer in solution and to demonstrate that the observed isomers are exchanged in solution. All three chloro-substituted Schiff base vanadium(V) complexes with substituted catecholates were also characterized by UV−vis spectroscopy, mass spectrometry, and electrochemistry. Upon testing in human glioblastoma multiforme (T98g) cells as an in vitro model of brain gliomas, the most sterically hindered, hydrophobic, and stable compound [t 1/2 (298 K) = 15 min in cell medium] was better than the two other complexes (IC 50 = 4.1 ± 0.5 μM DTB, 34 ± 7 μM 3-MeCat, and 19 ± 2 μM Cat). Furthermore, upon aging, the complexes formed less toxic decomposition products (IC 50 = 9 ± 1 μM DTB, 18 ± 3 μM 3-MeCat, and 8.1 ± 0.6 μM Cat). The vanadium complexes with the chloro-substituted Schiff base were more hydrophobic, more hydrolytically stable, more easily reduced compared to their corresponding parent counterparts, and the most sterically hindered complex of this series is only the second non-innocent vanadium Schiff base complex with a potent in vitro anticancer activity that is an order of magnitude more potent than cisplatin under the same conditions.
MenJ, annotated as an oxidoreductase, was recently demonstrated to catalyze the reduction (saturation) of a single double bond in the isoprenyl side-chain of mycobacterial menaquinone. This modification was shown to be essential for bacterial survival in J774A.1 macrophage-like cells, suggesting that MenJ may be a conditional drug target in Mycobacterium tuberculosis and other pathogenic mycobacteria. Recombinant protein was expressed in a heterologous host, and the activity was characterized. Although highly regiospecific in vivo, the activity is not absolutely regiospecific in vitro; in addition, the enzyme is not specific for naphthoquinones vs benzoquinones. Coenzyme Q-1 (a benzoquinone, UQ-1) was used as the lipoquinone substrate, and NADH oxidation was followed spectrophotometrically as the activity readout. NADPH could not be substituted for NADH in the reaction mixture. The enzyme contains a FAD binding site that was 72% occupied in the purified recombinant protein. Enzyme activity was maximal at 37 °C and pH 7.0; addition of divalent cations, EDTA, and reducing agents such as dithiothreitol to the reaction mixture had no effect on activity. The addition of detergents did not stimulate activity, and addition of saturating levels of FAD had relatively little effect on the observed kinetic parameters. These properties allowed the development of a facile assay needed to study this potential drug target, which is also amenable to high throughput screening. The K values for UQ-1 using recombinant MenJ from Mycobacterium smegmatis or M. tuberculosis without saturating concentrations of FAD were found to be 52 ± 9.6 and 44 ± 4.8 μM, respectively, while the K values were determined to be 59 ± 14 and 64 ± 15 μM. The K for MK-1, the menaquinone analogue of UQ-1, using recombinant MenJ from M. tuberculosis without saturating concentrations of FAD but in the presence of 0.5% Tween 80 was shown to be 30 ± 2.9 μM. Thus, this is the first report of a kinetic characterization of a member of the geranylgeranyl reductase family of enzymes.
Menaquinones (MKs) are essential for electron transport in prokaryotes, and importantly, partially saturated MKs represent a novel virulence factor. However, little is known regarding how the degree of saturation in the isoprenyl side chain influences conformation or quinone redox potential. MenJ is an enzyme that selectively reduces the second isoprene unit on MK-9 and is contextually essential for the survival of Mycobacterium tuberculosis in J774A.1 macrophage-like cells, suggesting that MenJ may be a conditional drug target for pathogenic mycobacteria. Therefore, fundamental information about the properties of this system is important, and we synthesized the simplest MKs, unsaturated MK-1 and the saturated analogue, MK-1(H2). Using two-dimensional nuclear magnetic resonance spectroscopy, we established that MK-1 and MK-1(H2) adopted similar folded–extended conformations (i.e., the isoprenyl side chain folds upward) in each solvent examined but the folded–extended conformations differed slightly between organic solvents. Saturation of the isoprenyl side chain slightly altered the MK-1 analogue conformation in each solvent. We used molecular mechanics to illustrate the MK-1 analogue conformations. The measured quinone redox potentials of MK-1 and MK-1(H2) differed between organic solvents (presumably due to differences in dielectric constants), and remarkably, an ∼20 mV semiquinone redox potential difference was observed between MK-1 and MK-1(H2) in pyridine, acetonitrile, and dimethyl sulfoxide, demonstrating that the degree of saturation in the isoprenyl side chain of MK-1 influences the quinone redox potential. Finally, MK-1 and MK-1(H2) interacted with Langmuir phospholipid monolayers and Aerosol-OT reverse micelle (RM) model membrane interfaces, where MK-1 adopted a slightly different folded conformation within the RM model membrane interface.
Menaquinones (MKs) contain both a redox active quinone moiety and a hydrophobic repeating isoprenyl side chain of varying lengths and degrees of saturation. This characteristic structure allows MKs to play a key role in the respiratory electron transport system of some prokaryotes by shuttling electrons and protons between membrane-bound protein complexes, which act as electron acceptors and donors. Hydrophobic MK molecules with partially and fully saturated isoprenyl side chains are found in a wide range of eubacteria and archaea, and the structural variations of the MK analogues are evolutionarily conserved but poorly understood. For example, Mycobacterium tuberculosis , the causative agent of tuberculosis, uses predominantly MK-9(II-H 2 ) (saturated at the second isoprene unit) as its electron carrier and depends on the synthesis of MK-9(II-H 2 ) for survival in host macrophages. Thus, MKs with partially saturated isoprenyl side chains may represent a novel virulence factor. Naturally occurring longer MKs are very hydrophobic, whereas MK analogues that have a truncated (i.e., one to three isoprenes) isoprenyl side chain are less hydrophobic. This improves their solubility in aqueous solutions, allowing rigorous study of their structure and biological activity. We present the synthesis and characterization of two partially saturated MK analogues, MK-2(II-H 2 ) and MK-3(II-H 2 ), and two novel fully saturated MK derivatives, MK-2(I,II-H 4 ) and MK-3(I,II,III-H 6 ).
Menaquinones (MK) are hydrophobic molecules that consist of a naphthoquinone headgroup and a repeating isoprenyl side chain and are cofactors used in bacterial electron transport systems to generate cellular energy. We have previously demonstrated that the folded conformation of truncated MK homologues, MK-1 and MK-2, in both solution and reverse micelle microemulsions depended on environment. There is little information on how MKs associate with phospholipids in a model membrane system and how MKs affect phospholipid organization. In this manuscript, we used a combination of Langmuir monolayer studies and molecular dynamics (MD) simulations to probe these questions on truncated MK homologues, MK-1 through MK-4 within a model membrane. We observed that truncated MKs reside farther away from the interfacial water than ubiquinones are are located closer to the phospholipid tails. We also observed that phospholipid packing does not change at physiological pressure in the presence of truncated MKs, though a difference in phospholipid packing has been observed in the presence of ubiquinones. We found through MD simulations that for truncated MKs, the folded conformation varied, but MKs location and association with the bilayer remained unchanged at physiological conditions regardless of side chain length. Combined, this manuscript provides fundamental information, both experimental and computational, on the location, association, and conformation of truncated MK homologues in model membrane environments relevant to bacterial energy production.
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