Heavy-atom effects associated with methylmercury (II) binding to rabbit glyceraldehyde-3-phosphate dehydrogenase

The complex of CH₃Hg(II) with the accessible cysteines of glyceraldehyde-3-phosphate dehydrogenase (GAPD, EC 1.2.1.12) from rabbit muscle has been studied by phosphorescence and optically detected magnetic resonance (ODMR) spectroscopy. The wavelength dependence of the phosphorescence decay kinetics has also been measured. Comparison of CH₃Hg(II)–GAPD with GAPD by these methods shows that a specific optically resolved tryptophan site of GAPD is perturbed by the interaction with a nearby mercury atom. The perturbation on the luminescence and ODMR properties is typical of an external heavy-atom effect. Based on the x-ray diffraction structure of the lobster enzyme, it is proposed that the heavy-atom effect results from the interaction of tryptophan-310 with CH₃Hg(II) bound to cysteine-281 in the rabbit muscle enzyme.     

Effect of Inorganic and Organic Ligands on the Bioavailability of Methylmercury as Determined by Using a mer-lux Bioreporter

A mer-lux bioreporter was constructed to assess the bioavailability of methylmercury [CH₃Hg(II)] in Escherichia coli. The bioreporter was shown to be sensitive, with a detection limit of 2.5 nM CH₃Hg(II), and was used to investigate the effects of chlorides, humic acids, and thiols on the bioavailability of CH₃Hg(II) in E. coli. It was found that increasing the concentration of chlorides resulted in an increase in CH₃Hg(II) bioavailability, suggesting that there was passive diffusion of the neutral complex (CH₃HgCl⁰). Humic acids were found to reduce the bioavailability of CH₃Hg(II) in varying degrees. Complexation with cysteine resulted in increased bioavailability of CH₃Hg(II), while assays with equivalent concentrations of methionine and leucine had little or no effect on bioavailability. The mechanism of uptake of the mercurial-cysteine complexes is likely not passive diffusion but could result from the activities of a cysteine transport system. The bioavailability of CH₃Hg(II) decreased with increasing glutathione concentrations.     

A facile transesterification route to ferrocenyl esters

In the presence of tetrabutylammonium hydroxide as catalyst and at room temperature, ethyl ferrocenecarboxylate, ethyl ferrocenylacetate, ethyl 3-ferrocenylpropanoate, 1,1′-ferrocenyl-bis(ethyl propanoate), ethyl 3-ferrocenylpropenoate and 1,1′-ferrocenyl-bis(ethyl propenoate) undergoes facile transesterification reaction with aliphatic, benzyl and allyl alcohols to furnish the corresponding ferrocenyl esters in good to excellent yields. Ring closing metathesis of the ester Fc-1,1′-(CHCH-CO₂CH₂CHCH₂)₂ yields the corresponding closed loop ferrocenyl ester.     

Metal ion-biomolecule interactions. XII. 1H and 13C NMR evidence for the preferred reaction of thymidine over guanosine in exchange and competition reactions with Mercury(II) and Methylmercury(II)

Mercury(II) bridge complexes of the type [Nuc-Hg-Nuc] (Nuc = thymidine or guanosine), and methylmercury(II) complexes of thymidine and guanosine of the type [CH₃Hg(Nuc)], have been prepared under appropriate conditions of pH and reactant's stochiometry in acqueous soluton. The various complexes have been characterized by ¹H and ¹³C NMR and used as probes, in competition and exchange studies, to establish the relative affinities of Hg(II) and CH₃Hg(II) towards the nucleosides guanosine and thymidine. These studies have confirmed that Hg(II) and CH₃Hg(II) bind to N₃ of thymidine in preference to N₁ of guanosine. The studies further show that reactions of mercury(II) with the nucleosides are thermodynamically controlled; the preperential binding reflects the relative stabilities of the respective complexes.     

Increase of fungitoxicity of mercuric chloride by methionine,ethionine and S-methylcysteine

The fungitoxicity of mercuric chloride to Aspergillus niger was increased in the presence of d-, l-, dl-methionine, dl-ethionine, dl-S-methylcysteine or sodium methylmercaptide. The same effect was observed with methionine for two other fungi investigated: Cladosporium cucumerinum and Scopulariopsis brevicaulis. It is suggested that this effect can be ascribed to the formation of CH₃SHg⁺ or (CH₃S)₂Hg, or the corresponding ethyl compounds. CH₃SHgCl and (CH₃S)₂Hg were synthetically prepared and proved indeed far more fungitoxic than HgCl₂. The hypothesis was further substantiated by the observation that A. niger rapidly converts dl-methionine into CH₃SH, which undoubtedly reacts with Hg²⁺ to give the above mentioned methylthiomercury compounds.     

Metal Ion-Biomolecule Interactions. VIII: Methylmercury(II) Complexes of 8-Thioguanosine. Synthesis and Spectroscopic Investigations

The reaction of 8-thioguanosine (8-thioGuo^H₂ with methylmercury(II) has been shown to give rise to 1:1 (neutral and cationic), 1:2 (neutral and cationic), and 1:3 (cationic) complexes of the type [CH₃Hg(8-thioGuoH)], [(CH₃Hg(8-thioGuoH₂)]NO₃, [(CH₃Hg)₂(8-thioGuo)], [(CH₃Hg)₂(8-thioGuoH)]NO₃ and [(CH₃Hg)₃(8-thioGuo)]NO₃, depending upon the reactant stoichiometry and pH. ¹H NMR, ¹³C NMR, and IR, as well as analytical data were used to characterize the complexes. Coupling of methylmercury(II)-protons to mercury-199 has been observed in all compounds. The magnitude of the coupling, ²J(¹H-¹⁹⁹Hg), is strongly dependent on the nature of the ligand bonded to the methylmercury(II) group and correlates with the ¹³C chemical shifts of coordinated CH₃Hg(II) at the different binding sites.     

The MerE protein encoded by transposon Tn21 is a broad mercury transporter in Escherichia coli

In order to clarify the physiological role of the merE gene of transposon Tn21, a pE4 plasmid that contained the merR gene of plasmid pMR26 from Pseudomonas strain K-62, and the merE gene of Tn21 from the Shigella flexneri plasmid NR1 (R100) was constructed. Bacteria with plasmid pE4 (merR-o/p-merE) were more hypersensitive to CH₃Hg(I) and Hg(II), and took up significantly more CH₃Hg(I) and Hg(II), than the isogenic strain. The MerE protein encoded by pE4 was localized in the membrane cell fraction, but not in the soluble fraction. Based on these experimental results, we suggest for the first time that the merE gene is a broad mercury transporter mediating the transport of both CH₃Hg(I) and Hg(II) across the bacterial membrane.     

Optically detected magnetic resonance and mutational analysis reveal significant differences in the photochemistry and structure of chlorophyll f synthase and photosystem II

In cyanobacteria that undergo far red light photoacclimation (FaRLiP), chlorophyll (Chl) f is produced by the ChlF synthase enzyme, probably by photo-oxidation of Chl a. The enzyme forms homodimeric complexes and the primary amino acid sequence of ChlF shows a high degree of homology with the D1 subunit of photosystem II (PSII). However, few details of the photochemistry of ChlF are known. The results of a mutational analysis and optically detected magnetic resonance (ODMR) data from ChlF are presented. Both sets of data show that there are significant differences in the photochemistry of ChlF and PSII. Mutation of residues that would disrupt the donor side primary electron transfer pathway in PSII do not inhibit the production of Chl f, while alteration of the putative Chl_Z, P680 and Q_A binding sites rendered ChlF non-functional. Together with previously published transient EPR and flash photolysis data, the ODMR data show that in untreated ChlF samples, the triplet state of P680 formed by intersystem crossing is the primary species generated by light excitation. This is in contrast to PSII, in which ³P680 is only formed by charge recombination when the quinone acceptors are removed or chemically reduced. The triplet states of a carotenoid (³Car) and a small amount of ³Chl f are also observed by ODMR. The polarization pattern of ³Car is consistent with its formation by triplet energy transfer from Chl_Z if the carotenoid molecule is rotated by 15° about its long axis compared to the orientation in PSII. It is proposed that the singlet oxygen formed by the interaction between molecular oxygen and ³P680 might be involved in the oxidation of Chl a to Chl f.     

Reactions of thioether carboxylic acids with mercury(II). Formation and X-ray crystal structure of mercury(II) mercaptoacetate

Reactions of Hg(II) salts with thioether carboxylic acids o-C₆H₄[CH(SCH₂COOH)₂]₂ (1a) and PhCH(SCH₂COOH)₂ (3) in water were found to lead to the decomposition of these ligands with the formation of mercury(II) mercaptoacetate Hg(SCH₂COOH)₂ (2) and aldehydes o-C₆H₄(CHO)₂ and PhCHO, respectively. A similar reaction was observed between Hg(NO₃)₂ and CH₃(CH₂)₂CH(SCH₂COOH)₂ (4). The X-ray structure of Hg(SCH₂COOH)₂ (2) shows a linear -S-Hg-S- moiety. The mechanism of the formation of 2 in the reactions between Hg²⁺ and thioether carboxylic acids in water is discussed.     

One-dimensional copper(II) polymer with bridging μ-trans-oxamidate and thiocyanate ligands: Synthesis, crystal structure and DNA binding studies

A new one-dimensional copper(II) polymer, [Cu₄(dmapox)₂(SCN)₄(CH₃CH₂OH)₂]_n · 2nCH₃CH₂OH, where dmapox is the dianion of N,N′-bis[3-(dimethylamino)propyl]oxamide, was synthesized and characterized by elemental analysis, conductivity measurement, IR and electronic spectral studies. The crystal structure of the copper(II) complex has been determined by X-ray single-crystal diffraction. The complex crystallizes in triclinic, space group and exhibits infinite one-dimensional copper(II) polymeric chain bridged both by the bis-tridentate μ-trans-dmapox and μ-1,3-thiocyanate ligands. The environment around the copper(II) atom can be described as distorted square-pyramid. The Cu···Cu separations through μ-trans-oxamidate and thiocyanate bridges are 5.245(5) Å (Cu1-Cu1ⁱ)(i = −x+1, −y, −z+1), 5.262(4) Å (Cu2-Cu2ⁱⁱ)(ii = −x,−y, −z+1) and 6.022(3) Å (Cu1-Cu2), respectively. The interaction of the copper(II) complex with herring sperm DNA (HS-DNA) has been investigated by using absorption and emission spectral and electrochemical techniques and viscometry. The results reveal that the copper(II) complex interacts with the DNA in the mode of groove binding with the intrinsic binding constant of 2.38 × 10⁵ M⁻¹.     

Dicarbonyliridium(I) complexes of pyridine ester ligands and their reactivity towards various electrophiles

The reaction of dimeric precursor [Ir(CO)₂Cl]₂ with two molar equivalent of the pyridine-ester ligands (L) like methyl picolinate (a), ethyl picolinate (b), methyl nicotinate (c), ethyl nicotinate (d), methyl isonicotinate (e) and ethyl isonicotinate (f) affords the tetra coordinated neutral complexes of the type [Ir(CO)₂ClL] (1a-f). The single crystal X-ray structure of 1d reveals that the Ir atom occupies the centre of an approximately square planar geometry with two CO groups cis- to each other. Intermolecular C-H?O and Ir?C interactions greatly stabilize the supramolecular structure of 1d in the solid state. The oxidative addition (OA) reactions of 1a-f with different electrophiles such as CH₃I, C₂H₅I and I₂ undergo decarbonylation of one CO group to generate the oxidized products of the type [Ir(CO)RClIL] where R = -CH₃ (2a-f); -C₂H₅ (3a-f) and [Ir(CO)ClI₂L] (4a-f). Kinetic study of the reaction of 1c-f with CH₃I indicates a first order reaction which follow the order 1d > 1c > 1f > 1e. All the synthesized complexes were characterized by elemental analyses, IR, and multinuclear NMR spectroscopy.     

Use of chemical ionization for GC–MS metabolite profiling

Metabolite profiling is commonly performed by GC–MS of methoximated trimethylsilyl derivatives. The popularity of this technique owes much to the robust, library searchable spectra produced by electron ionization (EI). However, due to extensive fragmentation, EI spectra of trimethylsilyl derivatives are commonly dominated by trimethylsilyl fragments (e.g. m/z 73 and 147) and higher m/z fragment ions with structural information are at low abundance. Consequently different metabolites can have similar EI spectra, and this presents problems for identification of “unknowns” and the detection and deconvolution of overlapping peaks. The aim of this work is to explore use of positive chemical ionization (CI) as an adjunct to EI for GC–MS metabolite profiling. Two reagent gases differing in proton affinity (CH₄ and NH₃) were used to analyse 111 metabolite standards and extracts from plant samples. NH₃-CI mass spectra were simple and generally dominated by [MH]⁺ and/or the adduct [M+NH₄]⁺. For the 111 metabolite standards, m/z 73 and 147 were less than 3% of basepeak in NH₃-CI and less than 30% of basepeak in CH₄-CI. With CH₄-CI, [MH]⁺ was generally present but at lower relative abundance than for NH₃-CI. CH₄-CI spectra were commonly dominated by losses of CH₄ [M+1-16]⁺, 1–3 TMSOH [M+1-nx90]⁺, and combinations of CH₄ and TMSOH losses [M+1-nx90-16]⁺. CH₄-CI and NH₃-CI mass spectra are presented for 111 common metabolites, and CI is used with real samples to help identify overlapping peaks and aid identification via determination of the pseudomolecular ion with NH₃-CI and structural information with CH₄-CI.     

Distribution of mercury, methyl mercury and organic sulphur species in soil, soil solution and stream of a boreal forest catchment

Concentrations of methyl mercury, CH₃Hg (II), total mercury, Hg_tot = CH₃Hg (II) + Hg (II), and organic sulphur species were determined in soils, soil solutions and streams of a small (50 ha) boreal forest catchment in northern Sweden. The CH₃Hg (II)/Hg_tot ratio decreased from 1.2–17.2% in the peaty stream bank soils to 0.4–0.8% in mineral and peat soils 20 m away from the streams, indicating that conditions for net methylation of Hg (II) are most favourable in the riparian zone close to streams. Concentrations of CH₃Hg (II) bound in soil and in soil solution were significantly, positively correlated to the concentration of Hg_tot in soil solution. This, and the fact that the CH₃Hg (II)/Hg_tot ratio was higher in soil solution than in soil may indicate that Hg (II) in soil solution is more available for methylation processes than soil bound Hg (II). Reduced organic S functional groups (Org-S_RED) in soil, soil extract and in samples of organic substances from streams were quantified using S K-edge X-ray absorption near-edge structure (XANES) spectroscopy. Org-S_RED, likely representing RSH, RSSH, RSR and RSSR functionalities, made up 50 to 78% of total S in all samples examined. Inorganic sulphide [e.g. FeS₂ (s)] was only detected in one soil sample out of 10, and in none of the stream samples. Model calculations showed that under oxic conditions nearly 100% of Hg (II) and CH₃Hg (II) were complexed by thiol groups (RSH) in the soil, soil solution and in the stream water. Concentrations of free CH₃Hg⁺ and Hg²⁺ ions in soil solution and stream were on the order of 10^–18 and 10^–32M, respectively, at pH 5. For CH₃Hg (II), inorganic bi-sulphide complexes may contribute to an overall solubility at concentrations of inorganic sulphides higher than 10^–9M, whereas considerably higher concentrations of inorganic sulphides (lower redox-potential) are required to increase the solubility of Hg (II).     

A proton nuclear magnetic resonance study of the binding of methylmercury in human erythrocytes

The binding of methylmercury, CH₃Hg(II), by small molecules in the intracellular region of human erythrocytes has been studied by ¹H-NMR spectroscopy. To suppress or completely eliminate interfering resonances from the much more abundant hemoglobin protons, spectra were measured by a technique based on the transfer of saturation throughout the envelope of hemoglobin resonances following a selective presaturation pulse or by the spin-echo Fourier transform method. With these techniques, ¹H-NMR spectra were measured for the more abundant intracellular small molecules, including glycine, alanine, creatine, lactic acid, ergothioneine and glutathione, in both intact and hemolyzed erythrocytes to which CH₃Hg(II) had been added. The results for intact erythrocytes indicate that part of the CH₃Hg(II) is complexed by intracellular glutathione. These results also indicate that exchange of CH₃Hg(II) among glutathione molecules is fast, with the average lifetime of a CH₃Hg(II)-glutathione complex estimated to be less than 0.01 s. From exchange-averaged chemical shifts of the resonance for the proton on the α-carbon of the cysteine residue of glutathione, it is shown that, in hemolyzed erythrocytes, the sulfhydryl group of glutathione binds CH₃Hg(II) more strongly than the sulfhydryl groups of hemoglobin.     

1H nmr study of the effectiveness of various thiols for removal of methylmercury from hemolyzed erythrocytes

The effectiveness of eight thiol ligands for removing methylmercury (CH₃Hg(II)) from its glutathione and hemoglobin complexes in hemolyzed erythrocytes has been studied by ¹H nuclear magnetic resonance spectroscopy. These complexes are the predominant methylmercury species in human erythrocytes. The effectiveness was determined from the exchange-averaged chemical shift of the resonance for the proton on the α-carbon of the cysteinyl residue and from the intensity of the resonance for the methylene protons of the glycine residue of reduced glutathione (GSH), both of which provide a measure of the amount of glutathione in the CH₃Hg(II)-complexed form. The thiol ligands were found to release GSH from its CH₃Hg(II) complex in the order 2, 3-dimercap-tosuccinic acid > mercaptosuccinic acid > cysteine > mercaptoacetic acid > D-penicillamine > 2, 3-dimercaptopropanesulfonic acid > N-acetyl-D,L-penicillamine > D.L-homocysteine.     

Availability of tyrosine amide for α-chymotrypsin-catalyzed synthesis of oligo-tyrosine peptides

Oligo-tyrosine peptides such as Tyr-Tyr having angiotensin I-converting enzyme (ACE) inhibitory activity could be synthesized by α-chymotrypsin-catalyzed reaction with l-tyrosine ethyl ester in aqueous media. However, peptide yield in the reaction was below 10%. Since l-tyrosine amide showed highly nucleophilic activity for the deacylation of enzyme through which a new peptide bond was made, its application to the enzymatic peptide synthesis was evaluated in this study. Addition of tyrosine amide into the reaction produced Tyr-Tyr-NH₂, of which yield exceeded 130% on the basis of tyrosine ethyl ester. Although purified Tyr-Tyr-NH₂ did not inhibit ACE activity, α-chymotrypsin could act on the dipeptide amide and convert about 40% of it to Tyr-Tyr. The use of both ester and amide forms of tyrosine is expected to be a potent procedure for α-chymotrypsin-catalyzed synthesis of antihypertensive peptides.     

Cu(II)-mediated phenol oxygenation: Chemical evidence implicates a unique role of the enzyme active site in promoting the chemically difficult tyrosine monooxygenation in TPQ cofactor biogenesis of copper amine oxidases

Cu(II)-mediated autoxidations of 4-tert-butylphenol under various conditions was studied, the data confirmed imidazole is the best ligand to promote phenol oxygenation. The same reaction of 2,4-di-tert-butylphenol proceeded much more quickly to lead nearly exclusively to oxidative coupling rather than oxygenation under high pressure O₂. These results suggested that Cu(II)-catalyzed phenol autoxidation by activating O₂ and phenol in terms of a phenoxy radical (ArO)–Cu(II)–superoxide ternary complex, whereas selectivity between oxygenation and coupling depends mainly on the electronic structure of ArO. It is appeared that CuAOs could achieve stoichiometric tyrosine monooxygenation by modulating the redox potential of Cu(II) and stabilizing the ternary complex through protein conformational adjustment.     

Computer simulation of plastocyanin-cytochrome <Emphasis Type="Italic">f</Emphasis> complex formation in the thylakoid lumen

Plastocyanin diffusion in the thylakoid lumen and its binding to cytochrome f (a subunit of the membrane b ₆ f complex) were studied with a direct multiparticle simulation model that could also take account of their electrostatic interaction. Experimental data were used to estimate the model parameters for plastocyanin-cytochrome f complexing in solution. The model was then employed to assess the dependence of the association rate constant on the dimensions of the lumen. Highest rates were obtained at a lumen span of 8–10 nm; narrowing of the lumen below 7 nm resulted in drastic deceleration of complexing. This corresponded to the experimentally observed effect of hyperosmotic stress on the interaction between plastocyanin and cytochrome f in thylakoids.     

The preparation and electrochemistry of cysteine-ester oxovanadium(IV) complexes

An improved synthesis of VO(CysOCH₃)₂, (CysOCH₃  the anion of cysteine methyl ester), is reported, as is an analogous preparation of VO(CysOCH₂CH₃)₂, (CysOCH₂CH₃  the anion of cysteine ethyl ester). These are the first two examples of isolated vanadium-cysteine compounds. The oxidation of VO(CysOCH₃)₂ in DMSO is a reversible one electron change at 0.24 V versus SCE followed by a rapid chemical reaction which produces a stable vanadium(V) species. This species is reduced back to the vanadium(IV) complex at −1.30 V. The electrochemistry of VO(Cys-OCH₂CH₃)₂ is nearly identical to that of the methyl ester compound.