RNA hydrolysis and inhibition of translation by a Co(III)-cyclen complex

Crystalline multicomponent compounds involving hexaammine cobalt(iii) cations

Among nine synthesized multicomponent compounds involving hexaammine cobalt(iii) cations and N-, N,O- and O-donor organic moieties, the compound [Co(NH3)6]Cl3·2(phen)·3H2O shows the best biological activity against plant pathogenic bacteria.

Effects of the Metal Ion on the Mechanism of Phosphodiester Hydrolysis Catalyzed by Metal-Cyclen Complexes

In this study, mechanisms of phosphodiester hydrolysis catalyzed by six di- and tetravalent metal-cyclen (M-C) complexes (Zn-C, Cu-C, Co-C, Ce-C, Zr-C and Ti-C) have been investigated using DFT calculations. The activities of these complexes were studied using three distinct mechanisms: (1) direct attack ( DA ), (2) catalyst-assisted ( CA ), and (3) water-assisted ( WA ). All divalent metal complexes (Zn-C, Cu-C and Co-C) coordinated to the BNPP substrate in a monodentate fashion and activated its scissile phosphoester bond. However, all tetravalent metal complexes (Ce-C, Zr-C, and Ti-C) interacted with BNPP in a bidentate manner and strengthened this bond. The DA mechanism was energetically the most feasible for all divalent M-C complexes, while the WA mechanism was favored by the tetravalent complexes, except Ce-C. The divalent complexes were found to be more reactive than their tetravalent counterparts. Zn-C catalyzed the hydrolysis with the lowest barrier among all M-C complexes, while Ti-C was the most reactive tetravalent complex. The activities of Ce-C and Zr-C, except Ti-C, were improved with an increase in the coordination number of the metal ion. The structural and mechanistic information provided in this study will be very helpful in the development of more efficient metal complexes for this critical reaction.

An efficient tRNA cleaver without additional co-reactants at physiological condition

A square-planar Cu(II) complex, [Cu(Me-Im)(gly-gly)]∙H₂O 1 (Me-Im = 1-methyl-imidazole, gly-gly = glycylglycinato), has been prepared and structurally characterized by single crystal X-ray. The complex 1 was tested for its ability to the transfer RNA by UV-vis spectroscopy, cyclic voltammetry (CV), capillary electrophoresis (CE). Comparative spectroscopic analysis shows a maximum fluorescence-quenching ratio of 0.41 of 1 upon binding to RNA, which gives a binding constant (K_b) of 1.24 × 10⁵ M^-1. Cyclic voltammograms of complex 1 attached on the mercaptoethanol (-SH) linked Au electrodes in phosphate buffer solution give a well-defined and quasi-reversible redox couple, indicate complex 1 can efficiently degrade the high-order structure of RNA in physiological conditions (pH 7.0 phosphate buffer solution at 37 °C) without additional co-reactants, yielding a digestion coefficient more than 90% within 113 h. This study targeting the genetic biomacromolecule degradation based on the strong binding of chemical nucleases paves an important way to the novel materials in the decontamination of microorganisms (e.g., bacteria and viruses) at mild condition.

Structural and functional study for tRNA cleavage by Glycine o-phenanthroline CuII complex, [CuCl(phen)(gly)]∙4H2O

The o-phenanthroline gly Cu(II) complex, [CuCl(phen)(gly)]∙4H₂O 1, has been prepared and structurally characterized. The transfer RNA binding and degradation properties of complex 1 have been investigated by UV-vis spectroscopy, cyclic voltammetry (CV), capillary electrophoresis (CE) and atomic force microscopy (AFM) methods. The results showed that 1 can efficiently cleave tRNA in the physiological conditions (pH 7.0, and 37 °C), and has a digestion coefficient nearly up to 100% within 75 h. AFM image for 1/RNA exhibited arrayed tandem repetitions of tRNA segments. This study is targeting the destruction of the high-order structures of genetic biomacromolecules which paves an important way to novel materials for the decontamination of microorganisms (e.g., bacteria and viruses).

Mechanistic insights for β-cyclodextrin catalyzed phosphodiester hydrolysis

Hydrolysis of phosphodiester bond in different substrates containing alkyl or aryl substituents, in the presence of β-cyclodextrin (β-CD) as a catalyst, has been investigated employing the density functional theory. It has been shown that the mechanism of β-CD catalyzed phosphodiester hydrolysis in modeled substrates viz. [p-nitrophenyl][(2,2) methylpropan] phosphodiester (G1); [p-nitrophenyl] [(2,2)methyl butan] phosphodiester (G2); (p-nitrophenyl) (2-methyl pentan) phosphodiester (G3); (p-nitrophenyl) (phenyl) phosphodiester (G4); (p-nitrophenyl) (m-tert-butyl phenyl) phosphodiester (G5) and (p-nitrophenyl) (p-nitrophenyl) phosphodiester (G6) involves net phosphoryl transfer from p-nitrophenyl to the catalyst. The hydrolysis occurs in a single-step D(N)A(N) mechanism wherein the β-CD acts as a competitive general base. The nucleophile addition is facilitated via face-to-face hydrogen-bonded interactions from the secondary hydroxyl groups attached to the top rim of β-CD. The insights for cleavage of phosphodiester along the dissociative pathway have been derived using the molecular electrostatic potential studies as a tool. The activation barrier of substrates containing alkyl group (G2 and G3) are found to be lower than those containing aryl groups (G4, G5 and G6).

Structure of Vibrio cholerae ribosome hibernation promoting factor

The X-ray crystal structure of ribosome hibernation promoting factor (HPF) from Vibrio cholerae is presented at 2.0 Å resolution. The crystal was phased by two-wavelength MAD using cocrystallized cobalt. The asymmetric unit contained two molecules of HPF linked by four Co atoms. The metal-binding sites observed in the crystal are probably not related to biological function. The structure of HPF has a typical β-α-β-β-β-α fold consistent with previous structures of YfiA and HPF from Escherichia coli. Comparison of the new structure with that of HPF from E. coli bound to the Thermus thermophilus ribosome [Polikanov et al. (2012), Science, 336, 915-918] shows that no significant structural changes are induced in HPF by binding.

Synthesis, characterization, and photoactivated DNA cleavage by copper (II)/cobalt (II) mediated macrocyclic complexes

We report the synthesis of new photonuclease consisting of two Co(II)/Cu(II) complexes of macrocyclic fused quinoline. Metal complexes are [MLX(2)], type where M = Co(II) (5), Cu(II) (6), and X = Cl, and are well characterized by elemental analysis, Fourier transform infrared spectroscopy, (1)H-NMR and electronic spectra. We have shown that photocleavage of plasmid DNA is markedly enhanced when this ligand is irradiated in the presence of Cu(II), and more so than that of cobalt. The chemistry of ternary and binary Co(II) complexes showing efficient light induced (360 nm) DNA cleavage activity is summarized. The role of the metal in photoinduced DNA cleavage reactions is explored by designing complex molecules having macrocyclic structure. The mechanistic pathways are found to be concentration dependent on Co(II)/Cu(II) complexes and the photoexcitation energy photoredox chemistry. Highly effective DNA cleavage ability of 6 is attributed to the effective cooperation of the metal moiety.

A bifunctional molecule as an artificial flavin mononucleotide cyclase and a chemosensor for selective fluorescent detection of flavins

Flavins, comprising flavin mononucleotide (FMN), flavin adenine dinucleotide (FAD), and riboflavin (RF, vitamin B(2)), play important roles in numerous redox reactions such as those taking place in the electron-transfer chains of mitochondria in all eukaryotes and of plastids in plants. A selective chemosensor for flavins would be useful not only in the investigation of metabolic processes but also in the diagnosis of diseases related to flavins; such a sensor is presently unavailable. Herein, we report the first bifunctional chemosensor (PTZ-DPA) for flavins. PTZ-DPA consists of bis(Zn(2+)-dipicolylamine) and phenothiazine. Bis(Zn(2+)-dipicolylamine) (referred to here as XyDPA) was found to be an excellent catalyst in the conversion of FAD into cyclic FMN (riboflavin 4',5'-cyclic phosphate, cFMN) under physiological conditions, even at pH 7.4 and 27 degrees C, with less than 1 mol % of substrate. Utilizing XyDPA's superior function as an artificial FMN cyclase and phenothiazine as an electron donor able to quench the fluorescence of an isoalloxazine ring, PTZ-DPA enabled selective fluorescent discrimination of flavins (FMN, FAD, and RF): FAD shows ON(+), FMN shows OFF(-), and RF shows NO(0) fluorescence changes upon the addition of PTZ-DPA. With this selective sensing property, PTZ-DPA is applicable to real-time fluorescent monitoring of riboflavin kinase (RF to FMN), alkaline phosphatase (FMN to RF), and FAD synthetase (FMN to FAD).

DNA cleavage promoted by 2,9-dimethyl-4,7-diazadecane-2,9-dithiol (DDD) derivatives

Three piperidine derivatives of 2,9-dimethyl-4,7-diazadecane-2,9-dithiol (DDD), NEPDDD, NEMPDDD, and NEMMPDDD, were synthesized and used as catalysts in DNA cleavage. Under physiological conditions, a series of experiments have been done. The effects of DNA cleavage with three ligands were studied under different concentrations, cleavage time, and pH values. The results strongly suggested that the plasmid DNA (pUC 19) can be cleaved efficiently by these ligands. For the cleavage reaction catalyzed by NEMPDDD, Form I DNA could convert to Form II completely, and the DNA-cleavage mechanism involved an oxidative pathway.

Lanthanide-mediated phosphoester hydrolysis and phosphate elimination from phosphopeptides

Lanthanide ions can mediate both phosphomonoester hydrolysis and beta-elimination of inorganic phosphate from polypeptide substrates under near-physiological conditions of pH, temperature, and salt.