Changes in the sedimentation characteristics of DNA due to methylmercuration

The toxicology of mercury: Current research and emerging trends

Mercury (Hg) is a persistent bio-accumulative toxic metal with unique physicochemical properties of public health concern since their natural and anthropogenic diffusions still induce high risk to human and environmental health. The goal of this review was to analyze scientific literature evaluating the role of global concerns over Hg exposure due to human exposure to ingestion of contaminated seafood (methyl-Hg) as well as elemental Hg levels of dental amalgam fillings (metallic Hg), vaccines (ethyl-Hg) and contaminated water and air (Hg chloride). Mercury has been recognized as a neurotoxicant as well as immunotoxic and designated by the World Health Organization as one of the ten most dangerous chemicals to public health. It has been shown that the half-life of inorganic Hg in human brains is several years to several decades. Mercury occurs in the environment under different chemical forms as elemental Hg (metallic), inorganic and organic Hg. Despite the raising understanding of the Hg toxicokinetics, there is still fully justified to further explore the emerging theories about its bioavailability and adverse effects in humans. In this review, we describe current research and emerging trends in Hg toxicity with the purpose of providing up-to-date information for a better understanding of the kinetics of this metal, presenting comprehensive knowledge on published data analyzing its metabolism, interaction with other metals, distribution, internal doses and targets, and reservoir organs.

The toxicology of mercury and its compounds

A concentrated review on the toxicology of inorganic mercury together with an extensive review on the neurotoxicology of methylmercury is presented. The challenges of using inorganic mercury in dental amalgam are reviewed both regarding the occupational exposure and the possible health problems for the dental patients. The two remaining "mysteries" of methylmercury neurotoxicology are also being reviewed; the cellular selectivity and the delayed onset of symptoms. The relevant literature on these aspects has been discussed and some suggestions towards explaining these observations have been presented.

Mercury toxicity and treatment: a review of the literature

Mercury is a toxic heavy metal which is widely dispersed in nature. Most human exposure results from fish consumption or dental amalgam. Mercury occurs in several chemical forms, with complex pharmacokinetics. Mercury is capable of inducing a wide range of clinical presentations. Diagnosis of mercury toxicity can be challenging but can be obtained with reasonable reliability. Effective therapies for clinical toxicity have been described.

Effects of exposure of DNA to methyl mercury on its activity as a template-primer for DNA polymerases

A previous publication [Frenkel, Cain, and Chao, Biochem. Biophys. Res. Commun. 127, 849-856 (1985)] described the observation that double-stranded DNA which was briefly exposed to methyl mercury (MeHg) and purified to remove free methyl mercury was transcribed at a higher rate by RNA polymerase II from wheat germ. The specificity of this phenomenon has now been investigated by examining the activity of this MeHg-exposed DNA as a template-primer for DNA polymerases. DNA synthesis by the bacteriophage T4-induced DNA polymerase was higher with the MeHg-exposed DNA as a template-primer than with control DNA. In contrast, the rate of DNA synthesis by E. coli DNA polymerase I was lower with the MeHg-exposed DNA as template-primer. With both enzymes (as well as with RNA polymerase II), after denaturation of the MeHg-exposed and control DNAs the differences in template activity were either eliminated or markedly reduced. The enzymes are thus able to detect a MeHg-induced alteration in DNA. In contrast, circular dichroism, a physical method that is sensitive to conformational changes in DNA, did not detect any difference between the MeHg-exposed and control DNAs.

Exposure of DNA to methyl mercury results in an increase in the rate of its transcription by RNA polymerase II

Double-stranded DNA which was exposed to methyl mercury at concentrations of 1 mM and above, and purified by ethanol precipitation and dialysis, was transcribed at a higher rate by RNA polymerase II than was control DNA. The rate of transcription of single-stranded DNA was not affected by similar exposure to methyl mercury. The higher rate of transcription of methyl mercury-treated double-stranded DNA appears to result from a decreased Km of the enzyme for this DNA. This does not appear to result from extensive denaturation, nor from formation of a large number of single-stranded breaks in the DNA.

Heavy metal-nucleotide interactions. IX. Raman difference spectroscopic studies on the binding of CH3Hg(II) to 1-methylthymine, thymidine-5'-monophosphate, DNA models and native DNA

Raman spectra have been obtained for dTMP and its complex with CH3Hg (II) in aqueous solution as a function of pH. Difference spectroscopy is employed to increase the sensitivity of the Raman technique. The binding reaction is essentially quantitative from pH 3 to 9, and the value of the equilibrium constant for CH3HgOH2+ + dThd in equilibrium CH3Hg(dThdH--1) + H30+ is estimated from intensity measurements to be 0.6 in reasonable agreement with an earlier value based upon uv spectrophotometric data. Binding is to N(3) with substitution of CH3Hg+ for the proton. A similar reaction occurs with 1-MeThy. Raman spectra for aqueous and crystalline 1-MeThy and for the complex CH3Hg(1-MeThyH--1) are reported. The spectrum of crystalline Hg(1-MeThyH--1)2, for which the crystal structure is known, also was obtained for comparison. Raman difference spectroscopy was used to confirm that CH3Hg (II) binds to N(3) of dTMP and N(1) of GMP at r = 0.2 (MeHg+: phosphate) ratios with mixtures of GMP + CMP + AMP + dTMP. In contrast, native calf thymus DNA does not appear to bind CH3Hg(II) at these sites at r = 0.15, although no significant amount of free CH3HgOH is present. With r = 0.3, extensive binding occurs both to the Thy and Gua bases. Raman difference spectroscopy is a valuable technique for studying the binding of ions and molecules to polynucleotides in moderately dilute aqueous solution.

Quantitative separation of nucleotides on mercurated dextran

Dextran gels of varying porosites (Sephadex G series) were chemically modified so as to contain covalently bound monofunctional mercury. Mercurated Sephadex of the porosity G-25 was then used to fractionate mixtures of mono- and dinucleotides into the constituent components. Separation is based on the affinity of the nitrogen binding sites of the purine and pyrimidine derivatives for organomercurial Hg+. Thus, a mixture composed of the four mononucleotides Cyd-5'-P, Ado-3'-P, Guo-2'(3')-P, dThd-5'-P and of the four dinucleotides Cyd-P-Cyd, Ado-P-Ado, Guo-P-Urd, and Urd-P-Urd could be separated into eight well-resolved fractions by using a combination Tris-bicarbonate/carbonate buffer system of increasing pH as an eluent. Complete separation was also achieved when a mixture of Ado 3:5'-P, Ado 5'-P, Ado-5'-PP, and Ado-5'-PPP was fractionated on mercurated Sephadex G-25. Again, Tris-bicarbonate/carbonate buffer served as an eluent. Lastly, fractionation can also be performed at a constant pH by offering other suitable ligands, for instance Cl-, that will compete with nucleotides for monofunctional Hg+. The fractionation behavior of mercurated Sephadex G-25 can be fully understood on the basis of the complexing properties of monofunctional Hg+. This has been shown by calculating the net retention volume ratios of several nucleotides with the help of the known interaction parameters of corresponding nucleosides with CH3 HgOH and by comparing the predicted ratios with the experimentally measured ones. Finally, the acid-base properties of mercurated Sephadex G-25 as well as its affinity for chloride and iodide ions have been determined. The data agree quite well with those known for CH3 HgOH.

Mercurated dextran column chromatography for fractionating mononucleotides

Mercurated dextran (polysaccharide) was found to fractionate mononucleotides according to their affinity for organomercurial Hg(+). The nucleotides are released from the chromatographic column in the sequence CMP, AMP, GMP, and TMP when borate buffer of increasing pH is used as an eluent.