Iron(III) Complexes of Metal-Binding Copolymers as Proficient Catalysts for Acid Hydrolysis of Phosphodiesters and Oxidative DNA Cleavage - Insight into the Rational Design of Functional Metallopolymers

Recent Advances in Heterogeneous Catalytic Systems Containing Metal Ions for Phosphate Ester Hydrolysis

Organophosphates are a class of organic compounds that are important for living organisms, forming the building blocks for DNA, RNA, and some essential cofactors. Furthermore, non-natural organophosphates are widely used in industrial applications, including as pesticides; in laundry detergents; and, unfortunately, as chemical weapons agents. In some cases, the natural degradation of organophosphates can take thousands of years; this longevity creates problems associated with handling and the storage of waste generated by such phosphate esters, in particular. Efforts to develop new catalysts for the cleavage of phosphate esters have progressed in recent decades, mainly in the area of homogeneous catalysis. In contrast, the development of heterogeneous catalysts for the hydrolysis of organophosphates has not been as prominent. Herein, examples of heterogeneous systems are described and the importance of the development of heterogeneous catalysts applicable to organophosphate hydrolysis is highlighted, shedding light on recent advances related to different solid matrices that have been employed.

Metallopolymers for advanced sustainable applications

Since the development of metallopolymers, there has been tremendous interest in the applications of this type of materials. The interest in these materials stems from their potential use in industry as catalysts, biomedical agents in healthcare, energy storage and production as well as climate change mitigation. The past two decades have clearly shown exponential growth in the development of many new classes of metallopolymers that address these issues. Today, metallopolymers are considered to be at the forefront for discovering new and sustainable heterogeneous catalysts, therapeutics for drug-resistant diseases, energy storage and photovoltaics, molecular barometers and thermometers, as well as carbon dioxide sequesters. The focus of this review is to highlight the advances in design of metallopolymers with specific sustainable applications.

Phosphate Ester Bond Hydrolysis Promoted by Lanthanide-Substituted Keggin-type Polyoxometalates Studied by a Combined Experimental and Density Functional Theory Approach

Hydrolytic cleavage of 4-nitrophenyl phosphate (NPP), a commonly used DNA model substrate, was examined in the presence of series of lanthanide-substituted Keggin-type polyoxometalates (POMs) [Me₂NH₂]₁₁[Ce^III(PW₁₁O₃₉)₂], [Me₂NH₂]₁₀[Ce^IV(PW₁₁O₃₉)₂] (abbreviated as (Ce^IV(PW₁₁)₂), and K₄[EuPW₁₁O₃₉] by means of NMR and luminescence spectroscopies and density functional theory (DFT) calculations. Among the examined complexes, the Ce(IV)-substituted Keggin POM (Ce^IV(PW₁₁)₂) showed the highest reactivity, and its aqueous speciation was fully determined under different conditions of pD, temperature, concentration, and ionic strength by means of ³¹P and ³¹P diffusion-ordered NMR spectroscopy. The cleavage of the phosphoester bond of NPP in the presence of (Ce^IV(PW₁₁)₂) proceeded with an observed rate constant k_obs = (5.31 ± 0.06) × 10^-6 s^-1 at pD 6.4 and 50 °C. The pD dependence of NPP hydrolysis exhibits a bell-shaped profile, with the fastest rate observed at pD 6.4. The formation constant (K_f = 127 M^-1) and catalytic rate constant (k_c = 19.41 × 10^-5 s^-1) for the NPP-Ce(IV)-Keggin POM complex were calculated, and binding between Ce^IV(PW₁₁)₂ and the phosphate group of NPP was also evidenced by the change of the chemical shift of the ³¹P nucleus in NPP upon addition of the POM complex. DFT calculations revealed that binding of NPP to the parent catalyst Ce^IV(PW₁₁)₂ is thermodynamically unlikely. On the contrary, formation of complexes with the monomeric 1:1 species, Ce^IVPW₁₁, is considered to be more favorable, and the most stable complex, [Ce^IVPW₁₁(H₂O)₂(NPP-κO)₂]^7-, was found to involve two NPP ligands coordinated to the Ce^IVcenter of Ce^IVPW₁₁ in the monodentate fashion. The formation of such species is considered to be responsible for the hydrolytic activity of Ce^IV(PW₁₁)₂ toward phosphomonoesters. On the basis of these findings a principle mechanism for the hydrolysis of NPP by the POM is proposed.

Method of continuous variations: applications of job plots to the study of molecular associations in organometallic chemistry

Applications of the method of continuous variations (MCV or the Method of Job) to problems of interest to organometallic chemists are described. MCV provides qualitative and quantitative insights into the stoichiometries underlying association of m molecules of A and n molecules of B to form A(m)B(n) . Applications to complex ensembles probe associations that form metal clusters and aggregates. Job plots in which reaction rates are monitored provide relative stoichiometries in rate-limiting transition structures. In a specialized variant, ligand- or solvent-dependent reaction rates are dissected into contributions in both the ground states and transition states, which affords insights into the full reaction coordinate from a single Job plot. Gaps in the literature are identified and critiqued.

A new bis(rhodamine)-based fluorescent chemosensor for Fe3+

A new bis(rhodamine)-based fluorescent probe 4 was synthesized, and it exhibited high selectivity for Fe³⁺ over other commonly coexistent metal ions in both 50% ethanol and Tris–HCl buffer. Upon the addition of Fe³⁺, the spirocyclic ring of 4 was opened and a significant enhancement of visible color and fluorescence in the range of 500–600 nm was observed.

Efficient double-strand scission of plasmid DNA by quaternized-chitosan zinc complex

N-[(2-Hydroxy-3-trimethylammonium) propyl] chitosan chloride (HTACC) was prepared to construct a chitosan-based zinc complex (HTACC-Zn(II)) as a catalyst with good water solubility for rapid DNA cleavage. Results indicated that the observed rate constant (k(obs)) of plasmid DNA cleaved by HTACC-Zn(II) could be enhanced by 10(7)-fold compared with that of uncatalyzed DNA cleavage. The kinetic behavior of HTACC-Zn(II) for DNA cleavage is well fitted by Michaelis-Menten model. The results of gel electrophoresis suggested that HTACC-Zn(II) preferentially perform double-strand break of plasmid DNA.