Environmentally persistent free radicals (EPFRs) in combustiongenerated particulate matter (PM) are capable of inducing pulmonary pathologies and contributing to the development of environmental asthma. In vivo exposure of infant rats to EPFRs demonstrates their ability to induce airway hyperresponsiveness to methacholine, a hallmark of asthma. However, the mechanisms by which combustionderived EPFRs elicit in vivo responses remain elusive. In this study, we used a chemically defined EPFR consisting of approximately 0.2 mm amorphrous silica containing 3% cupric oxide with the organic pollutant 1,2-dichlorobenzene (DCB-230). DCB-230 possesses similar radical content to urban-collected EPFRs but offers several advantages, including lack of contaminants and chemical uniformity. DCB-230 was readily taken up by BEAS-2B and at high doses (200 mg/cm 2 ) caused substantial necrosis. At low doses (20 mg/cm 2 ), DCB-230 particles caused lysosomal membrane permeabilization, oxidative stress, and lipid peroxidation within 24 hours of exposure. During this period, BEAS-2B underwent epithelial-to-mesenchymal transition (EMT), including loss of epithelial cell morphology, decreased E-cadherin expression, and increased a-smooth muscle actin (a-SMA) and collagen I production. Similar results were observed in neonatal air-liquid interface culture (i.e., disruption of epithelial integrity and EMT). Acute exposure of infant mice to DCB-230 resulted in EMT, as confirmed by lineage tracing studies and evidenced by coexpression of epithelial E-cadherin and mesenchymal a-SMA proteins in airway cells and increased SNAI1 expression in the lungs. EMT in neonatal mouse lungs after EPFR exposure may provide an explanation for epidemiological evidence supporting PM exposure and increased risk of asthma.Keywords: particulate matter; epithelial-mesenchymal transition; environmental asthma; pediatric Combustion-generated particulate matter (PM) from industrial processes and burning of biomass and fossil fuels has been linked with adverse pulmonary health effects (1). Environmental PM, both fine and ultrafine, is capable of airway deposition, alveolar penetration, respiratory distress, and exacerbation of preexisting pulmonary conditions. Previous studies highlight the potential roles of PM exposure in predisposing to asthma and pulmonary fibrosis (2-4). Additionally, PM has adjuvant effects when combined with innocuous antigen (5-7) and induces cellular damage, stimulating fibrotic remodeling in adult rodent exposure models (2). The developing pulmonary and immune systems are particularly vulnerable (8). We have developed a model for studying particulate exposures in neonatal rodents (, 7 d of age) (9), which we apply here to understand the effects of combustiongenerated environmentally persistent free radicals (EPFRs) on pulmonary airway remodeling.Delineation of the influences of particulate burden from the reactive chemical species complexed with the particulate has proven difficult. The nature of the chemical species drastically influences ...
Particular matter (PM) is emitted during thermal decomposition of waste. During this process, aromatic compounds chemisorb to the surface of metal-oxide-containing PM, forming a surface-stabilized environmentally persistent free radical (EPFR). We hypothesized that EPFR-containing PM redox cycle to produce ROS and that this redox cycle is maintained in biological environments. To test our hypothesis, we incubated model EPFRs with the fluorescent probe dihydrorhodamine (DHR). Marked increases in DHR fluorescence were observed. Using a more specific assay, hydroxyl radicals (•OH) were also detected, and their level was further increased by co-treatment with thiols or ascorbic acid (AA), known components of epithelial lining fluid. Next, we incubated our model EPFR in bronchoalveolar lavage fluid (BALF) or serum. Detection of EPFRs and •OH verified that PM generate ROS in biological fluids. Moreover, incubation of pulmonary epithelial cells with EPFR-containing PM increased •OH levels compared to PM lacking EPFRs. Finally, measurements of oxidant injury in neonatal rats exposed to EPFRs by inhalation suggested that EPFRs induce an oxidant injury within lung lining fluid and that the lung responds by increasing antioxidant levels. In summary, our EPFR-containing PM redox cycle to produce ROS, and these ROS are maintained in biological fluids and environments. Moreover, these ROS may modulate toxic responses of PM in biological tissues such as the lung.
HIV-associated cardiovascular diseases have been widely described, but clinical studies aimed at establishing cause-effect relationships between HIV-associated cardiovascular disease and either the HIV infection or antiretroviral therapy have been problematic. Endothelial dysfunction is a sensitive marker and early event in atherosclerosis, and many have suggested that protease inhibitors promote endothelial dysfunction indirectly by inducing elevations in circulating lipids. To determine whether nucleoside reverse transcriptase inhibitors and/or protease inhibitors induce endothelial dysfunction, and to test whether this effect is dependent upon drug-mediated alteration in plasma lipid concentrations, we treated male Sprague-Dawley rats with pharmacological doses of azidothymidine (AZT), indinavir, or AZT plus indinavir through their drinking water for 1 month and assessed endothelial function in aortic rings using an isometric force measurement. Circulating levels of plasma lipids and endothelin-1, a marker for endothelial injury and/or dysfunction, were also determined. We found that AZT and AZT plus indinavir treatments dramatically reduced endothelium-dependent vessel relaxation. However, AZT treatment did not significantly alter plasma levels of cholesterol or triglyceride. In addition, plasma endothelin-1 levels were elevated in rats treated with AZT plus indinavir. Indinavir treatment alone increased plasma cholesterol levels but had no effect on endothelial function. These findings suggest that in addition to modulating plasma lipid levels, antiretrovirals, particularly AZT and perhaps other nucleoside reverse transcriptase inhibitors, may have direct effects on the vascular endothelium. Together with other increased risk factors for atherosclerosis in HIV patients, AZT-induced endothelial dysfunction may contribute to the cardiovascular diseases associated with HIV antiretroviral therapy.
Pulmonary arterial hypertension (PAH) is a progressive disease of the pulmonary vasculature involving endothelial and vascular smooth muscle cell (VSMC) proliferation, vasoconstriction, right ventricular hypertrophy, and eventually, right heart failure and death. PAH occurs 1000-fold more frequently in HIV patients than in the general population. Although conventional HIV therapy with nucleoside reverse transcriptase inhibitors (NRTIs) leads to regression of PAH, highly active antiretroviral therapy (HAART; two NRTI plus a protease inhibitor) increases the incidence of HIV-associated PAH as much as twofold. Although there are relatively few models for PAH, previous reports indicate the disease can be initiated by endothelial injury and release of the mitogen endothelin-1 (ET-1). ET-1, in turn, stimulates VSMC proliferation. To determine whether HAART induces endothelial injury and release of cytokines like ET-1, we treated human umbilical vein endothelial cells with micromolar amounts of AZT (3'-azido-3'-deoxythymidine), the protease inhibitor indinavir, or AZT plus indinavir, and measured cell viability, mitochondrial function, and ET-1 release. Both AZT and indinavir induced marked decreases in cellular oxygen uptake, as well as increases in ET-1 release. Although the drugs had no apparent effect on proliferation in VSMCs alone, in cocultures of VSMCs plus endothelial cells, the drugs increased proliferation of both endothelial cells and VSMCs. Finally, when cocultures of endothelial cells and VSMCs were treated with BQ-123 and BQ-788, selective antagonists for ET(A) and ET(B) receptors, respectively, drug-induced proliferation of both VSMCs and endothelial cells was attenuated. These data thus suggest that HIV drug cocktails may exacerbate preexisting HIV-associated PAH by inducing endothelial mitochondrial dysfunction, in turn stimulating the release of ET-1, and ultimately, vascular cell proliferation.
Vascular smooth muscle cell (VSMC) proliferation is pivotal in the progression of hypertension, atherosclerosis, and restenosis. Resveratrol is a grape polyphenol that is implicated as an important contributor to red wine's vascular protective effects. Its antimitogenic action on VSMC is attributed to an array of pleiotropic effects, including modulation of the estrogen receptor (ER). To elucidate the mechanisms underlying resveratrol-mediated ER modulation and its inhibition of VSMC proliferation, we treated VSMC with resveratrol with or without the ER antagonist ICI 182,780 and measured cell proliferation and nitric oxide (NO) production. Resveratrol dose-dependently decreased VSMC DNA synthesis, with a half maximal inhibitory concentration (IC50) of 3.73+/-0.57 microM, and dramatically slowed cell growth, but did not induce VSMC apoptosis. Resveratrol-mediated decrease in proliferation was reversed by cotreatment with ICI 182,780, and resveratrol effectively competed with 17beta-estradiol for binding to the ER, exhibiting an IC50 of 8.92+/-0.14 microM. Resveratrol induced a sustained increase in ER-dependent NO production. Further, resveratrol-mediated decrease in VSMC proliferation was blunted by cotreatment with the general nitric oxide synthase (NOS) inhibitor N5-(1-Iminomethyl)-L-ornithine, dihydrochloride or with the inducible NOS (iNOS)-selective inhibitor S,S'-1,4-phenylene-bis (1,2-ethanediyl)bis-isothiourea, dihydrobromide, but not with the neuronal NOS-selective inhibitor 7-nitroindazole. Though resveratrol did not alter iNOS protein levels, it dose-dependently increased levels of iNOS activity, of the iNOS cofactor tetrahydrobiopterin (BH4), and of guanosine triphosphate cyclohydrolase I protein, the rate-limiting enzyme in BH4 biosynthesis. In addition, all of these effects were abolished by cotreatment with ICI 182,780. Thus, the antimitogenic effects of resveratrol on VSMC may be mediated by an ER-induced increase in iNOS activity.
Resveratrol and Quercetin Interact to Inhibit Neointimal Hyperplasia in Mice with a Carotid Injury
Restenosis is a critical complication of angioplasty and stenting. Restenosis is multifactorial, involving endothelial injury, inflammation, platelet activation, and vascular smooth muscle cell (VSMC) proliferation. Thus, dietary strategies to prevent restenosis likely require the use of more than one agent. Resveratrol (R) and quercetin (Q) are polyphenols that are known to exhibit vascular protective effects. We tested whether R and Q administered in the diet interact to inhibit vessel stenosis in mice with a carotid injury. B6.129 mice were administered a high-fat diet containing 21% fat and 0.2% cholesterol along with R (25 mg/kg), Q (10 mg/kg), or R + Q for 2 wk. A carotid injury was induced and the mice were again administered the enriched diet for 2 wk. Compared with the controls, R significantly decreased stenosis, assessed as an intima:media ratio, by 76%. Although Q treatment alone exhibited no effect, it potentiated the effect of R in that treatment with R + Q significantly decreased the intima:media ratio by 94%. Moreover, this effect was greater than that of R treatment alone (P < 0.05). Although treatments with R, Q, and R + Q significantly affected platelet activation and endothelial function, the responses observed for R + Q were less than additive. Specifically, the effects of R + Q were less than the sum of effects for treatments with R and Q alone. In contrast, treatment with R + Q exhibited more-than-additive effects on inflammatory markers and significant interactions between R and Q were observed. The presence of synergy between R and Q was thus tested in cultures of VSMC and macrophages. Isobolographic analysis revealed that 2:1 molar ratios of R:Q exhibited synergistic inhibition of VSMC proliferation and macrophage chemotaxis. In conclusion, in combination, R and Q can interact to reduce the extent of restenosis, perhaps due to their synergistic inhibition of VSMC proliferation and inflammation.
Particulate matter (PM) is emitted during the combustion of fuels and wastes. PM exposure exacerbates pulmonary diseases, and the mechanism may involve oxidative stress. At lower combustion temperatures such as occurs in the cool zone of a flame, aromatic compounds chemisorb to the surface of metal-oxide-containing PM, resulting in the formation of surface-stabilized environmentally persistent free radicals (EPFR). Prior studies showed that PM-containing EPFR redox cycle to produce reactive oxygen species (ROS), and after inhalation, EPFR induce pulmonary inflammation and oxidative stress. Our objective was to elucidate mechanisms linking EPFR-induced oxidant injury with increased cytokine production by pulmonary epithelial cells. We thus treated human bronchial epithelial cells with EPFR at sub-toxic doses and measured ROS and cytokine production. To assess aryl hydrocarbon receptor (AhR) activity, cells were transfected with a luciferase reporter for xenobiotic response element activation. To test whether cytokine production was dependent upon AhR activation or oxidative stress, some cells were co-treated with an antioxidant or an AhR antagonist. EPFR increased IL-6 release in an ROS and AhR- and oxidant-dependent manner. Moreover, EPFR induced an AhR activation that was dependent upon oxidant production, since antioxidant co-treatment blocked AhR activation. On the other hand, EPFR treatment increased a cellular ROS production that was at least partially attenuated by AhR knockdown using siRNA. While AhR activation was correlated with an increased expression of oxidant-producing enzymes like cytochrome P450 CYP1A1, it is possible that AhR activation is both a cause and effect of EPFR-induced ROS. Finally, lipid oxidation products also induced AhR activation. ROS-dependent AhR activation may be a mechanism for altered epithelial cell responses after EPFR exposure, potentially via formation of bioactive lipid or protein oxidation products.
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