Testing of an oral dosing technique for double-crested cormorants, Phalacocorax auritus, laughing gulls, Leucophaeus atricilla, homing pigeons, Columba livia, and western sandpipers, Calidris mauri, with artificially weather MC252 oil.

Scoping studies were designed to determine if double-crested cormorants (Phalacocorax auritus), laughing gulls (Leucophaues atricilla), homing pigeons (Columba livia) and western sandpipers (Calidris mauri) that were gavaged with a mixture of artificially weathered MC252 oil and food for either a single day or 4-5 consecutive days showed signs of oil toxicity. Where volume allowed, samples were collected for hematology, plasma protein electrophoresis, clinical chemistry and electrolytes, oxidative stress and organ weigh changes. Double-crested cormorants, laughing gulls and western sandpipers all excreted oil within 30min of dose, while pigeons regurgitated within less than one hour of dosing. There were species differences in the effectiveness of the dosing technique, with double-crested cormorants having the greatest number of responsive endpoints at the completion of the trial. Statistically significant changes in packed cell volume, white cell counts, alkaline phosphatase, alanine aminotransferase, creatine phosphokinase, gamma glutamyl transferase, uric acid, chloride, sodium, potassium, calcium, total glutathione, glutathione disulfide, reduced glutathione, spleen and liver weights were measured in double-crested cormorants. Homing pigeons had statistically significant changes in creatine phosphokinase, total glutathione, glutathione disulfide, reduced glutathione and Trolox equivalents. Laughing gulls exhibited statistically significant decreases in spleen and kidney weight, and no changes were observed in any measurement endpoints tested in western sandpipers.

Toxic effects of orally ingested oil from the Deepwater Horizon spill on laughing gulls.

The explosion of the Deepwater Horizon oil rig released, millions of gallons of oil into the environment, subsequently exposing wildlife, including numerous bird species. To determine the effects of MC252 oil to species relevant to the Gulf of Mexico, studies were done examining multiple exposure scenarios and doses. In this study, laughing gulls (Leucophaeus atricilla, LAGU) were offered fish injected with MC252 oil at target doses of 5 or 10mL/kg bw per day. Dosing continued for 27 days. Of the adult, mixed-sex LAGUs used in the present study, ten of 20 oil exposed LAGUs survived to the end of the study; a total of 10 of the oil exposed LAGUs died or were euthanized within 20 days of initiation of the study. Endpoints associated with oxidative stress, hepatic total glutathione (tGSH), oxidized glutathione (GSSG) and reduced glutathione (rGSH) significantly increased as mean dose of oil increased, while the rGSH:GSSG ratio showed a non-significant negative trend with oil dose. A significant increase in 3-methyl histidine was found in oil exposed birds when compared to controls indicative of muscle wastage and may have been associated with the gross observation of diminished structural integrity in cardiac tissue. Consistent with previous oil dosing studies in birds, significant changes in liver, spleen, and kidney weight when normalized to body weight were observed. These studies indicate that mortality in response to oil dosing is relatively common and the mortality exhibited by the gulls is consistent with previous studies examining oil toxicity. Whether survival effects in the gull study were associated with weight loss, physiologic effects of oil toxicity, or a behavioral response that led the birds to reject the dosed fish is unknown.

Reprint of: Overview of avian toxicity studies for the Deepwater Horizon Natural Resource Damage Assessment.

The Oil Pollution Act of 1990 establishes liability for injuries to natural resources because of the release or threat of release of oil. Assessment of injury to natural resources resulting from an oil spill and development and implementation of a plan for the restoration, rehabilitation, replacement or acquisition of natural resources to compensate for those injuries is accomplished through the Natural Resource Damage Assessment (NRDA) process. The NRDA process began within a week of the Deepwater Horizon oil spill, which occurred on April 20, 2010. During the spill, more than 8500 dead and impaired birds representing at least 93 avian species were collected. In addition, there were more than 3500 birds observed to be visibly oiled. While information in the literature at the time helped to identify some of the effects of oil on birds, it was not sufficient to fully characterize the nature and extent of the injuries to the thousands of live oiled birds, or to quantify those injuries in terms of effects on bird viability. As a result, the US Fish and Wildlife Service proposed various assessment activities to inform NRDA injury determination and quantification analyses associated with the Deepwater Horizon oil spill, including avian toxicity studies. The goal of these studies was to evaluate the effects of oral exposure to 1-20ml of artificially weathered Mississippi Canyon 252 oil kg bw-1 day-1 from one to 28 days or one to five applications of oil to 20% of the bird's surface area. It was thought that these exposure levels would not result in immediate or short-term mortality but might result in physiological effects that ultimately could affect avian survival, reproduction and health. These studies included oral dosing studies, an external dosing study, metabolic and flight performance studies and field-based flight studies. Results of these studies indicated changes in hematologic endpoints including formation of Heinz bodies and changes in cell counts. There were also effects on multiple organ systems, cardiac function and oxidative status. External oiling affected flight patterns and time spent during flight tasks indicating that migration may be affected by short-term repeated exposure to oil. Feather damage also resulted in increased heat loss and energetic demands. The papers in this special issue indicate that the combined effects of oil toxicity and feather effects in avian species, even in the case of relatively light oiling, can significantly affect the overall health of birds.

Overview of avian toxicity studies for the Deepwater Horizon Natural Resource Damage Assessment.

The Oil Pollution Act of 1990 establishes liability for injuries to natural resources because of the release or threat of release of oil. Assessment of injury to natural resources resulting from an oil spill and development and implementation of a plan for the restoration, rehabilitation, replacement or acquisition of natural resources to compensate for those injuries is accomplished through the Natural Resource Damage Assessment (NRDA) process. The NRDA process began within a week of the Deepwater Horizon oil spill, which occurred on April 20, 2010. During the spill, more than 8500 dead and impaired birds representing at least 93 avian species were collected. In addition, there were more than 3500 birds observed to be visibly oiled. While information in the literature at the time helped to identify some of the effects of oil on birds, it was not sufficient to fully characterize the nature and extent of the injuries to the thousands of live oiled birds, or to quantify those injuries in terms of effects on bird viability. As a result, the US Fish and Wildlife Service proposed various assessment activities to inform NRDA injury determination and quantification analyses associated with the Deepwater Horizon oil spill, including avian toxicity studies. The goal of these studies was to evaluate the effects of oral exposure to 1-20ml of artificially weathered Mississippi Canyon 252 oil kg bw-1 day-1 from one to 28 days or one to five applications of oil to 20% of the bird's surface area. It was thought that these exposure levels would not result in immediate or short-term mortality but might result in physiological effects that ultimately could affect avian survival, reproduction and health. These studies included oral dosing studies, an external dosing study, metabolic and flight performance studies and field-based flight studies. Results of these studies indicated changes in hematologic endpoints including formation of Heinz bodies and changes in cell counts. There were also effects on multiple organ systems, cardiac function and oxidative status. External oiling affected flight patterns and time spent during flight tasks indicating that migration may be affected by short-term repeated exposure to oil. Feather damage also resulted in increased heat loss and energetic demands. The papers in this special issue indicate that the combined effects of oil toxicity and feather effects in avian species, even in the case of relatively light oiling, can significantly affect the overall health of birds.

Smoking rates among gamblers at Nevada casinos mirror US smoking rate.

OBJECTIVES: To determine the percentage of gamblers who smoke while gambling at three of Nevada's major gambling destinations, Las Vegas, Reno/Sparks and Lake Tahoe. METHODS: Teams of two people counted the number of smokers and total number of gamblers at various Nevada casinos. The total number of gamblers observed smoking was then multiplied by three to determine the total number of smokers. This methodology for determining the number of smokers in a room was established by Repace and Lowry in 1980. RESULTS: We observed a total of 14 052 gamblers at the three sites, of which a total of 947 were smoking. We estimated the percentage of smokers at three gaming tourist centres in Nevada (Las Vegas, Reno/Sparks and Lake Tahoe). The percentage of smokers at Las Vegas (20.3% (95% CI 0.9)) and Reno/Sparks (21.5% (95% CI 1.2%)) did not significantly differ from the US population percentage of smokers (20.9% (95% CI 0.6%)) (p>0.05). However, at Lake Tahoe the percentage of smokers (16.4% (95% CI 1.8%)) was significantly lower than the published US population smoker percentage (p<0.0001). Mean percentage of smokers by location did not significantly differ (p = 0.43) CONCLUSIONS: The results of this study suggest that the percentage of gamblers who smoke was less than or not different from the overall US percentage of a population who smoke. These findings provide additional evidence to refute the exemption to smoking bans for casinos based upon the supposition that a greater percentage of casino customers are smokers than the general population and therefore a smoking ban for casinos may result in an economic hardship.

Bioreductive metabolism of mitomycin C in EMT6 mouse mammary tumor cells: cytotoxic and non-cytotoxic pathways, leading to different types of DNA adducts. The effect of dicumarol.

The six DNA adducts formed in EMT6 mouse mammary tumor cells upon treatment with mitomycin C (MC) fall into two groups: (1) four guanine adducts of MC and (2) two guanine adducts derived from 2,7-diaminomitosene (2,7-DAM), the major reductive metabolite of MC. The two groups of adducts were proposed to originate from two pathways arising from reductive activation of MC: (a) direct alkylation of DNA and (b) formation of 2,7-DAM, which then alkylates DNA. The aim of this study was to test the validity of this proposal and to evaluate the significance of alkylation of DNA by 2,7-DAM. Treatment of the cells with 2,7-DAM itself yielded the same 2,7-DAM-guanine adducts as treatment with MC; however, 2,7-DAM was approximately 100-fold less cytotoxic than MC. The uptake and efflux of 2,7-DAM by EMT6 cells was comparable to that of MC, but 2,7-DAM alkylated DNA with higher efficiency than MC. These results validate the two proposed pathways and show that formation of 2,7-DAM-DNA adducts in MC-treated cells represents a relatively non-toxic pathway of reductive metabolism of MC. A selective stimulatory effect of dicumarol (DIC) on 2,7-DAM-DNA adduct formation in EMT6 cells treated with MC was also investigated. DIC had no effect on alkylation by MC in cell-free systems, nor did it have significant effects on adduct formation or cell survival for cells treated with 2,7-DAM. It is proposed that in the cell DIC stimulates a reductase enzyme located at subcellular sites where the activated MC species has no direct access to DNA and therefore is diverted into the non-cytotoxic pathway, which leads to the formation of 2,7-DAM and its adducts.

Basal and drug-induced antioxidant enzyme activities correlate with age-dependent doxorubicin oxidative toxicity.

Doxorubicin continues to be one of the most widely used anticancer agents in the clinic despite its dose-limiting side-effects. Many of doxorubicin's dose-limiting toxicities occur due to its generation of toxic oxygen species, resulting in oxidative stress. Some clinical observations have suggested that doxorubicin may have greater toxicity in older patients. The studies presented here compare basal and doxorubicin-induced antioxidant enzyme activities in brain, heart, kidney and liver tissues of Fisher 344 rats of different ages to determine whether differences in these enzymes can account for the age-dependent differences observed in doxorubicin-induced toxicity. Three groups of animals were tested, young animals (2-months-old), adult animals (10-months-old) and old animals (18-months-old). The results of these studies show that in general young and adult animals have similar levels of antioxidant enzyme activity while the older animals have less. Only in the young animals is antioxidant enzyme activity significantly increased following doxorubicin treatment suggesting that enzyme induction occurs only in the young group of animals. Lipid peroxidation is shown to have the greatest increase in the old animals following doxorubicin treatment while the young animals have the smallest increase. The results from these studies suggest that there is an increase in doxorubicin-induced oxidative damage with age and that these differences may be due to basal and drug-induced differences in tissue antioxidant enzyme activities.

Cellular distribution, metabolism and regulation of the xanthine oxidoreductase enzyme system.

Xanthine oxidase (EC 1.1.3.22) and xanthine dehydrogenase (EC 1.1.1. 204) are both members of the molybdenum hydroxylase flavoprotein family and represent different forms of the same gene product. The two enzyme forms and their reactions are often referred to as xanthine oxidoreductase (XOR) activity. Physiologically, XOR is known as the rate-limiting enzyme in purine catabolism but has also been shown to be able to metabolize a number of other physiological compounds. Recent studies have also demonstrated its ability to metabolize xenobiotics, including a number of anticancer compounds, to their active metabolites. During the past 10 years, evidence has mounted to support a role for XOR in the pathophysiology of inflammatory diseases and atherosclerosis as well as its previously determined role in ischemia-reperfusion injury. While significant progress has recently been made in our understanding of the physiological and biochemical nature of this enzyme system, considerable work still needs to be done. This paper will review some of the more recent work characterizing the interactions and the factors that influence the interactions of XOR with various physiological and xenobiotic compounds.

Relative contributions of mouse liver subcellular fractions to the bioactivation of mitomycin C at various pH levels.

Mitomycin C (MMC) is a clinically active anticancer drug that requires reductive activation to exert its toxicity. The enzymes currently recognized as capable of activating MMC cannot account for all of the toxicity of the drug. These studies were conducted to identify and compare the subcellular compartments where MMC reduction can take place under different physiological conditions. Subcellular fractionation of mouse liver was achieved using differential centrifugation and isopycnic equilibrium gradient centrifugation. Nuclear, mitochondrial, microsomal, lysosomal, peroxisomal, and cytosolic fractions were assayed for their ability to reductively activate MMC at pH 6.0 and 7.4. MMC reductive activation was determined by its ability to generate reactive oxygen species. The results of these studies showed that MMC reductive activation by the various fractions was pH dependent. At pH 7.4, the microsomal fraction accounted for approximately 78% of the total MMC reductive activation. The peroxisomal fraction accounted for 12% and the nuclear and lysosomal fractions each accounted for 5% of the total reductive activation. At pH 6.0, the microsomes accounted for 51% and the peroxisomes for 34% of the total reductive activation. The mitochondrial fraction, which did not reductively activate MMC at pH 7.4, accounted for 9% of the total activation at pH 6.0. These results suggested that peroxisomes may be important in MMC activation at either pH and that at pH 6.0 the mitochondrial fraction may also be important for MMC reductive activation.

Oxidative stress induced by environmental tobacco smoke in the workplace is mitigated by antioxidant supplementation.

Environmental tobacco smoke (ETS) is a pervasive contaminant in the workplace. Previous studies by this laboratory have shown that exposure to workplace ETS results in increased oxidative stress and damage, as measured by increased levels of the antioxidant enzymes superoxide dismutase, catalase, glutathione reductase, and glutathione peroxidase. 8-Hydroxy-2-deoxyguanosine, a marker of oxidative DNA damage, was also 63% greater in the exposed group compared with controls. Subjects in the previous study who reported workplace exposure to ETS were given a 60-day supply of an over-the-counter antioxidant formulation consisting of 3000 microg of beta-carotene, 60 mg of vitamin C, 30 I.U. of alpha-tocopherol, 40 mg of zinc, 40 microg of selenium, and 2 mg of copper. After the 60-day supplementation period, blood samples were again drawn, and the results were compared with the presupplementation values. A 62% decrease in 8-hydroxy-2-deoxyguanosine was observed after supplementation. Lipid peroxidation levels were also decreased, as were the antioxidant enzyme activities. The biochemical evidence suggests that exposure to ETS in the workplace increases oxidative stress and that antioxidant supplementation may provide some protection.

Oxidative DNA damage in mouse heart, liver, and lung tissue due to acute side-stream tobacco smoke exposure.

Environmental tobacco smoke (ETS) is a hotly debated social, political, and scientific issue, pitting smokers' rights against the health and safety of nonsmokers. Striking an acceptable balance between the two depends largely on the potential health hazard assessment of ETS. Studies from this laboratory have shown that exposure to side-stream cigarette smoke (SSS), the major component of ETS, significantly increases oxidative stress in mouse heart, liver, and lung tissues. This study measures the level of oxidative damage to mouse liver, lung, and heart DNA as a result of this oxidative stress. Adult female Balb/c mice were exposed to a regimen consisting of sequences of a 30-min exposure followed by a 90-min nonexposure. This regimen was performed once for the single exposure and repeated three times for the triple exposure. The heart, lung, and liver were excised from the mice, and DNA was extracted and analyzed for the presence of the oxidative product 8-hydroxy-2'-deoxyguanosine (8-OHdG). In all three tissues, the exposure increased the presence of 8-OHdG above the control levels. In some instances, the increased levels returned to normal by the end of the nonexposure period, while other tissues showed a further increase following nonexposure. These studies demonstrate that limited exposure to SSS produces measurable DNA oxidative damage.

Environmental tobacco smoke in the workplace induces oxidative stress in employees, including increased production of 8-hydroxy-2'-deoxyguanosine.

Environmental tobacco smoke (ETS) is a pervasive contaminant in the workplace. Our objective was to determine the oxidative stress effects of ETS on employees who are exposed. The results provide information that is useful to the resolution of risk assessment questions associated with ETS. We analyzed two blood draws from volunteers in our control and exposed groups. The level of exposure to ETS was determined through plasma cotinine measurements, which showed a 65% increase from the control group to the exposed group. Exposure to ETS resulted in a statistically significant increase of 63% of the oxidative DNA mutagen 8-hydroxy-2'-deoxyguanosine in the blood of exposed subjects. This oxidative DNA damage has been linked to an increased risk of developing several degenerative chronic diseases, including coronary heart disease and cancer. The exposed subjects also had increased levels of superoxide dismutase, catalase, glutathione peroxidase (GPOX), and glutathione reductase. However, these increases were only statistically significant in catalase and GPOX. Catalase levels were 13% higher in the exposed group, and GPOX levels were 37% higher in exposed volunteers. The biochemical evidence suggests that exposure to ETS causes oxidative stress, resulting in DNA damage that may increase the risk of certain diseases.

Comparison of oxygen radical generation from the reductive activation of doxorubicin, streptonigrin, and menadione by xanthine oxidase and xanthine dehydrogenase.

Investigations into the enzymes responsible for the reductive activation of antineoplastic agents are of particular interest with regard to the use of these agents in the treatment of solid tumors. Xanthine oxidase (EC 1.1.3.22; XO) and xanthine dehydrogenase (EC 1. 1.1.204; XDH) are two enzymes capable of the reductive activation of antineoplastic agents. Previously, XDH, the enzymatic precursor of XO, was not extensively studied because of difficulties in its isolation. Research in the reductive activation of antineoplastic agents by XDH has increased with the discovery of a rapid and high-yield purification procedure for XDH. In the present investigation, the potential for drug activation of doxorubicin (DOX), streptonigrin (STN), and menadione (MD) by XO and XDH was assessed through oxygen consumption studies. These studies were conducted at pH 7.4 and pH 6.0 to reflect physiological and the acidic pH of solid tumors, respectively. Apparent kinetic constants were determined for DOX, STN, and MD activation by XO and XDH at both pH levels. Higher oxygen consumption was observed for XDH drug activation in comparison to XO drug activation at equivalent enzyme activity for both pH levels. Drug-induced oxygen consumption was affected by pH. Hence, drug activation for DOX, STN, and MD was dependent upon the form of the xanthine-converting enzyme and the pH.

Reductive activation of doxorubicin by xanthine dehydrogenase from EMT6 mouse mammary carcinoma tumors.

The role of enzymes in the reductive activation of various chemotherapeutic agents is an area of considerable interest in studies to better understand the selective toxicities of these agents. Xanthine dehydrogenase (XDH) is an enzyme capable of reductive activation of chemotherapeutic agents. Previously, this enzyme has not been extensively studied because of difficulties in its isolation. We recently isolated this enzyme from EMT6 mouse mammary carcinoma cells and showed that this enzyme is capable of activating mitomycin C. In this study, we examined whether XDH could activate the clinically important antineoplastic agent, doxorubicin. Drug activation was determined under aerobic and hypoxic conditions and at various pHs in order to simulate the different environments found in solid tumors. The results of these studies show that XDH reacts with doxorubicin via a two-electron reduction. This reduction is different from the modified and more extensively studied form of the enzyme, xanthine oxidase (XO), which reacts with doxorubicin via a one-electron reduction. Under hypoxic conditions, the formation of large quantities of 7-deoxydoxorubicin aglycone, a deactivation product of doxorubicin metabolism, may serve to moderate doxorubicin's antineoplastic activity. Under aerobic conditions, however, XDH activation led to a greater rate of formation of oxygen radicals than XO thereby possibly potentiating doxorubicin's cytotoxicity to aerobic tumor cells. Kinetic constants were determined for doxorubicin activation by XDH.

Tissue-specific bioenergetic effects and increased enzymatic activities following acute sublethal peroral exposure to cyanide in the mallard duck.

Protection of wildlife and in particular migratory birds, which are protected by the Migratory Bird Treaty Act, from cyanide waste in and around gold mining operations is an important environmental issue. We have investigated the bioenergetic effects of sublethal peroral cyanide exposure using the mallard duck (Anus platyrhynchos) as a model migratory bird. At cyanide concentrations well below levels considered safe by the mining industry and some regulatory agencies (50 ppm weak acid dissociable (WAD) cyanide) significant depletions of heart, liver, and brain tissue ATP levels were observed. Tissue ATP levels were restored to normal by 24 hr postexposure. Rhodanese and 3-mercaptopyruvate sulfurtransferase activities were determined in these tissues both for basal activity and post-cyanide exposure. Only brain tissue showed increased enzymatic activity following cyanide exposure, suggesting tissue-specific regulation of these enzymatic activities. These studies suggest that 50 ppm WAD cyanide is not a safe level of cyanide in water where avian wildlife exposure can occur.

A new cellular target for mitomycin C: a case for mitochondrial DNA.

Mitomycin C (MMC) is an anticancer, antibiotic that is currently used clinically against a wide variety of tumors. Nuclear DNA is regarded as the primary cellular target for mitomycin's toxicity. In this study, the effect of MMC on mitochondrial DNA was tested both in vitro and in vivo. EMT6 mouse mammary carcinoma cells were treated with MMC and conformational changes in their mitochondrial DNA were determined as a measure of mitochondrial DNA damage. A dose-dependent relationship was observed between MMC treatment dosages and mitochondrial DNA damage. Liver tissue mitochondria from Balb/c mice treated with MMC were assayed for mitochondrial integrity. Mitochondrial integrity was lowered in the MMC-treated animals. Liver tissue adenosine triphosphate (ATP) levels were also shown to be significantly decreased in these same animals. We also show that MMC can be activated by mitochondria. These studies provide strong evidence that mitochondrial DNA is a target for MMC and that this interaction has a biochemical consequence that could prove toxic.

Disruption of normal cellular bioenergetics in Balb/c mice by mitomycin C.

Mitomycin C (MMC) is an antineoplastic agent with activity against a wide variety of tumours. The primary cellular target for MMC's antineoplastic activity is thought to be nuclear DNA. The interactions of MMC with nuclear DNA have been studied extensively. This laboratory has shown recently that MMC also interacts with mitochondrial DNA, resulting in a conformational change from the supercoiled to the relaxed state. This interaction could cause mitochondrial dysfunction, resulting in a loss of cellular ATP. The present studies were designed to test whether treatment with MMC would affect tissue ATP levels in Balb/c mice. Mice were treated with single, or multiple (2) i.p. injections of 0, 5, 10 or 20 mg MMC kg-1 body wt. Forty-eight hours after the final MMC treatment, heart, liver and kidney tissues were excised and tissue ATP levels were assessed. Heart tissue was the most sensitive to the MMC treatment and significant decreases in ATP levels were observed at all MMC dosages tested. Liver and kidney tissues showed significant decreases only at the highest dosages tested. These studies demonstrate that tissue specific disruption of cellular bioenergetics occurs following MMC exposure resulting in a decrease of tissue ATP levels.

Preferential kill of hypoxic EMT6 mammary tumor cells by the bioreductive alkylating agent porfiromycin.

Hypoxic cells in solid tumors represent a therapeutically resistant population that limits the curability of many solid tumors by irradiation and by most chemotherapeutic agents. The oxygen deficit, however, creates an environment conducive to reductive processes; this results in a major exploitable difference between normal and neoplastic tissues. The mitomycin antibiotics can be reductively activated by a number of oxidoreductases, in a process required for the production of their therapeutic effects. Preferential activation of these drugs under hypoxia and greater toxicity to oxygen-deficient cells than to their oxygenated counterparts are obtained in most instances. The demonstration that mitomycin C and porfiromycin, used to kill the hypoxic fraction, in combination with irradiation, to eradicate the oxygenated portion of the tumor, produced enhanced cytodestructive effects on solid tumors in animals has led to the clinical evaluation of the mitomycins in combination with radiation therapy in patients with head and neck cancer. The findings from these clinical trials have demonstrated the value of directing a concerted therapeutic attack on the hypoxic fraction of solid tumors as an approach toward enhancing the curability of localized neoplasms by irradiation.