Meconium identifies high levels of metals in newborns from a mining community in the U.S.

BACKGROUND: This pilot study was conducted to determine if we could identify intrauterine exposure to metals in meconium, as a measure of exposure for mother-child pairs living in proximity to a mining operation. OBJECTIVES: We used meconium as a means to measure metal exposure in utero. We set out to quantify the exposure to selected metals that are currently being mined and also are found in the Superfund site in Butte, Montana, and to compare it to that of Columbia, South Carolina, US, where mining is not occurring. METHODS: This cross-sectional study was conducted between May and November 2018. We received Institutional Review Board approval and we consented women following the birth of their newborns, and collected meconium within 24 h of birth, without any identifiers. Each laboratory used the same protocol for collection, transport, and storage; and the same laboratory protocol was used for the analysis of all samples. Samples were digested using standard acid/peroxide digestion methods and measured by inductively coupled plasma mass spectroscopy. RESULTS: We collected meconium specimens from 17 infants in Columbia, South Carolina and 15 infants in Butte, Montana. The concentrations found in Columbia were in the low µg kg-1 range (or less) and were similar to the low levels that have been identified in other studies of meconium. The magnitude of the differences in concentrations found in Butte compared to Columbia was 1792 times higher for Cu, 1650 times higher for Mn, and 1883 times higher for Zn. CONCLUSION: Using meconium to measure exposure of newborns has implications for risk assessment in a mining-exposed population. This approach was inexpensive and thorough. The magnitude of the differences in the metal levels identified from the two study sites suggests there is an urgent need for further research to learn if there are health consequences to these highly exposed infants.

Assessing human metal accumulations in an urban superfund site.

Butte, Montana is part of the largest superfund site in the continental United States. Open-pit mining continues in close proximity to Butte's urban population. This study seeks to establish baseline metal concentrations in the hair and blood of individuals living in Butte, MT and possible routes of exposure. Volunteers from Butte (n=116) and Bozeman (n=86) were recruited to submit hair and blood samples and asked to complete a lifestyle survey. Elemental analysis of hair and blood samples was performed by ICP-MS. Three air monitors were stationed in Butte to collect particulate and filters were analyzed by ICP-MS. Soil samples from the yards of Butte volunteers were quantified by ICP-MS. Hair analysis revealed concentrations of Al, As, Cd, Cu, Mn, Mo, and U to be statistically elevated in Butte's population. Blood analysis revealed that the concentration of As was also statistically elevated in the Butte population. Multiple regression analysis was performed for the elements As, Cu, and Mn for hair and blood samples. Soil samples revealed detectable levels of As, Pb, Cu, Mn, and Cd, with As and Cu levels being higher than expected in some of the samples. Air sampling revealed consistently elevated As and Mn levels in the larger particulate sampled as compared to average U.S. ambient air data.

Influence of Iron-Doped Apatite Nanoparticles on Viral Infection Examined in Bacterial Versus Algal Systems.

The Centers for Disease Control and Prevention have estimated that each year, two million people in the United States become infected with antibiotic-resistant bacteria, of which, approximately 23000 die as a direct result of these infections. Phage therapy, or the treatment of bacterial infection by specific, antagonistic viruses, provides one alternative to traditional antibiotics. Bacteriophages, or phages, are bacteria-specific viruses that possess biological traits that allow for not only the removal of bacterial infection, but also the evasion of bacterial resistance, which renders antibiotics ineffective. Previous research has shown the addition of iron-doped apatite nanoparticles (IDANPs) to bacteria prior to phage exposure results in increased bacterial plaques in vitro. Coupled with the biocompatible nature of apatite, these results provide promise for future use of IDANPs as adjuvants to phage therapy along with anti-bacterial applications yet to be explored. Although IDANP enhancement of phage infection has been replicated many times in gram-positive and gram-negative prokaryotic hosts as well as with the utilization of both RNA and DNA viruses, the specific mechanisms involved remain elusive. To further understand increased phage infections in a prokaryotic system, and to evaluate the safety of IDANPs as a treatment used in a eukaryotic system, we have replicated plaque assay experiments in an algal system using Chlorella variabilis NC64A and its virus, Paramecium bursaria chlorella virus 1 (PBCV-1). Statistical modeling was used to evaluate alteration in numbers of plaques observed after viral introduction in IDANP-exposed versus non-IDANP-exposed bacterial and algal cell cultures. While IDANPs synthesized between 25°C-45°C and doped with 30% iron have been shown to influence dramatic increases in phage-induced bacterial death, experiments replicated in an algal system indicated viral infections do not increase when C. variabilis cells are pre-exposed to IDANPs. It is essential to potential use of IDANPs as an antibacterial adjuvant that IDANPs do not increase viral infection of eukaryotic host cells during treatment.

Inhibition of mitochondrial respiration as a source of adaphostin-induced reactive oxygen species and cytotoxicity.

Adaphostin is a dihydroquinone derivative that is undergoing extensive preclinical testing as a potential anticancer drug. Previous studies have suggested that the generation of reactive oxygen species (ROS) plays a critical role in the cytotoxicity of this agent. In this study, we investigated the source of these ROS. Consistent with the known chemical properties of dihydroquinones, adaphostin simultaneously underwent oxidation to the corresponding quinone and generated ROS under aqueous conditions. Interestingly, however, this quinone was not detected in intact cells. Instead, high performance liquid chromatography demonstrated that adaphostin was concentrated by up to 300-fold in cells relative to the extracellular medium and that the highest concentration of adaphostin (3000-fold over extracellular concentrations) was detected in mitochondria. Consistent with a mitochondrial site for adaphostin action, adaphostin-induced ROS production was diminished by >75% in MOLT-4 rho(0) cells, which lack mitochondrial electron transport, relative to parental MOLT-4 cells. In addition, inhibition of oxygen consumption was observed when intact cells were treated with adaphostin. Loading of isolated mitochondria to equivalent adaphostin concentrations caused inhibition of uncoupled oxygen consumption in mitochondria incubated with the complex I substrates pyruvate and malate or the complex II substrate succinate. Further analysis demonstrated that adaphostin had no effect on pyruvate or succinate dehydrogenase activity. Instead, adaphostin inhibited reduced decylubiquinone-induced cytochrome c reduction, identifying complex III as the site of inhibition by this agent. Moreover, adaphostin enhanced the production of ROS by succinate-charged mitochondria. Collectively, these observations demonstrate that mitochondrial respiration rather than direct redox cycling of the hydroquinone moiety is a source of adaphostin-induced ROS and identify complex III as a potential target for antineoplastic agents.

Nei deficient Escherichia coli are sensitive to chromate and accumulate the oxidized guanine lesion spiroiminodihydantoin.

Growth inhibition and oxidized guanine lesion formation were studied in a number of base excision repair (BER) deficient Escherichia coli (E. coli) following chromate exposure. The only BER deficient bacterial strain that demonstrated significant growth inhibition by chromate, in comparison to its matched wild-type cell line, was the Nei deficient (TK3D11). HPLC coupled with electrospray ionization mass spectrometry showed that the Nei deficient E. coli accumulated the further oxidized guanine lesion, spiroiminodihydantoin (Sp), in genomic DNA at levels that were approximately 20-fold greater than its wild-type counterpart. However, no accumulation of the putative intermediate of Sp, 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-oxodG), was observed in the Nei deficient strain. A MutM-/MutY- double deletion mutant that was deficient in BER enzymes for the recognition and repair of 8-oxodG demonstrated no sensitivity toward chromate nor was there an associated increase in Sp accumulation over that of its wild type. However, the MutM-/MutY- double deletion mutant did show approximately 20-fold accumulation of 8-oxodG upon chromate exposure over that of the wild type and the Nei deficient E. coli. These data demonstrate that the Nei BER enzyme is critical for the recognition and repair of the Sp lesion in bacterial cell lines and demonstrates the protective effect of a specific BER enzyme on DNA lesions formed by chromate. To our knowledge, these are the first studies to show the formation and biological significance of the Sp lesion in a cellular system. This study has significant mechanistic and toxicological implications for how chromate may serve as an initiator of carcinogenesis and suggests a role for specific repair enzymes that may ameliorate the carcinogenic potential of chromate.

Guanine-specific oxidation of double-stranded DNA by Cr(VI) and ascorbic acid forms spiroiminodihydantoin and 8-oxo-2'-deoxyguanosine.

7,8-dihydro-8-oxoguanine (8-oxoG) is thought to be a major lesion formed in DNA by oxidative attack at the nucleobase guanine. Recent studies have shown that 8-oxoG has a lower reduction potential than the parent guanine and is a hot spot for further oxidation. Spiroiminodihydantoin (Sp) has been identified as one of these further oxidation products. Chromium(VI) is a human carcinogen that, when reduced by a cellular reductant such as ascorbate, can oxidize DNA. In this study, duplex DNA was reacted with Cr(VI) and ascorbate to identify and quantify the base lesions formed. Guanine bases were observed to be preferentially oxidized with 5' guanines within purine repeats showing enhanced oxidation. Trapping of the guanine lesions by the base excision repair enzymes hOGG1 and mNEIL2 showed nearly exclusive trapping by mNEIL2, suggesting that 8-oxoG was not the major lesion but rather a lesion recognized by mNEIL2 such as Sp. Formation of the Sp lesion in the Cr(VI)/Asc oxidation reaction with DNA was confirmed by LC-ESI-MS detection. HPLC-ECD was used to identify and quantify any 8-oxoG arising from Cr(VI)/Asc oxidation of DNA. Concentrations of Cr(VI) (3.1-50 microM) with a corresponding 1:10 ratio of Asc oxidized between 0.3% and 1.5% of all guanines within the duplex DNA strand to Sp. 8-oxoG was also identified but with the highest Cr(VI) concentration converting approximately 0.1% of all guanines to 8-oxoG. These results show that Sp was present in concentrations approximately 20 times greater than that of 8-oxoG in this system. The results indicate that 8-oxoG, while present, was not the major product of Cr(VI)/Asc oxidation of DNA and that Sp predominates under these conditions. These results further imply that Sp may be the lesion that accounts for the carcinogenicity of this metal in cellular systems.

Recognition of the oxidized lesions spiroiminodihydantoin and guanidinohydantoin in DNA by the mammalian base excision repair glycosylases NEIL1 and NEIL2.

8-Oxoguanine (8-oxoG) is an unstable mutagenic DNA lesion that is prone to further oxidation. High valent metals such as Cr(V) and Ir(IV) readily oxidize 8-oxoG to form guanidinohydantoin (Gh), its isomer iminoallantoin (Ia), and spiroiminodihydantoin (Sp). When present in DNA, these lesions show enhanced base misincorporation over the parent 8-oxoG lesion leading to G --> T and G --> C transversion mutations and polymerase arrest. These findings suggested that further oxidized lesions of 8-oxoG are more mutagenic and toxic than 8-oxoG itself. Repair of oxidatively damaged bases, including Sp and Gh/Ia, are initiated by the base excision repair (BER) system that involves the DNA glycosylases Fpg, Nei, and Nth in E. coli. Mammalian homologs of two of these BER enzymes, OGG1 and NTH1, have little or no affinity for Gh/Ia and Sp. Herein we report that two recently identified mammalian glycosylases, NEIL1 and NEIL2, showed a high affinity for recognition and cleavage of DNA containing Gh/Ia and Sp lesions. NEIL1 and NEIL2 recognized both of these lesions in single-stranded DNA and catalyzed the removal of the lesions through a beta- and delta-elimination mechanism. NEIL1 and NEIL2 also recognized and excised the Gh/Ia lesion opposite all four natural bases in double-stranded DNA. NEIL1 was able to excise the Sp lesion opposite the four natural bases in double-stranded DNA, however, NEIL2 showed little cleavage activity against the Sp lesion in duplex DNA although DNA trapping studies show recognition and binding of NEIL2 to this lesion. This work suggests that NEIL1 and NEIL2 are essential in the recognition of further oxidized lesions arising from 8-oxoG and implies that these BER glycosylases may play an important role in the repair of DNA damage induced by carcinogenic metals.