ENDOTHELIAL CELL DYSFUNCTION BY ENVIRONMENTAL CONTAMINANTS

Oesterling, Elizabeth Grace

01 January 2008

Within the last few decades, epidemiological evidence has linked exposure to air pollution, both its particles and its organic components, with cardiovascular disease (CVD) progression. CVD is a life long disease with the disruption of the endothelium being the inaugural event in this inflammatory process. The vascular endothelium is extremely susceptible to environmental insults given its tremendous surface area and that it is in constant contact with blood and components circulating within the blood, including xenobiotics. The endothelium is important as a barrier from blood constituents however, dysfunction of this barrier leads to the influx of lymphocytes and granulocytes that lead to the fatty build‐up characteristic of atherosclerosis. The studies presented in this dissertation tested the hypothesis that two unique environmental contaminants, alumina nanoparticles and benzo[a]pyrene (B[a]P), lead to increased endothelial cell dysfunction, characterized by increased adhesion molecule expression. Alumina nanoparticles induced vascular cell adhesion molecule‐1 (VCAM‐1), intercellular adhesion molecule‐1 (ICAM‐1), and E‐selectin (ELAM‐1), as well as increased monocyte adhesion to activated endothelium. Polystyrene nanoparticles did not elicit this response. B[a]P induced ICAM‐1 expression, but only after toxification by aryl hydrocarbon receptor (AhR) controlled enzymes. Silencing of either AhR or the membrane microdomains called caveolae attenuated the B[a]P‐induced ICAM‐1 response. It was also shown that the induction of ICAM‐1 occurred by signaling through MEK, p‐38 MAPK, and activator protein‐1 (AP‐1). These data provide a novel mechanism by which air pollutants like B[a]P may cause increased atherosclerosis and describe a new toxicant, alumina nanoparticles, as a possible threat for the development of inflammatory diseases, such as atherosclerosis. Little is known about dietary interventions capable of alleviating xenobiotic‐induced toxicity. Nutrition is an obtainable and inexpensive means of possible preventative therapy. With this in mind, it was also hypothesized that plant polyphenols, such as flavonoids, can down‐regulate B[a]P‐induced ICAM‐1. Selective flavonoids, containing both a 4’ B‐ring hydroxyl substitution and a 2‐3 C‐ring double bond, protected against B[a]P‐induced ICAM‐1 activation, however this protection did not correlate with the flavonoid’s antioxidant capacity.

Manufactured nanoparticles

endothelium

adhesion molecules

cardiovascular disease

polycyclic aromatic hydrocarbons

Medical Toxicology

Effets des nanoparticules manufacturées sur les cellules pulmonaires humaines

Tabbaa Chalabi, Rajaa

08 1900

La détection et la caractérisation des nanoparticules manufacturées (NPM) est l’une des premières étapes pour contrôler et diminuer leurs risques potentiels sur la santé humaine et l’environnement. Différents systèmes d’échantillonnage dans l’air existent pour l’évaluation d’une exposition aux NPM. Cependant, ils ne mesurent pas le risque potentiel de cette exposition à la santé humaine ni les mécanismes cellulaires qui en seraient responsables. Nos objectifs de recherche sont 1) Évaluer les effets de différents types de nanoparticules sur des cellules pulmonaires humaines et 2) Identifier de nouveaux mécanismes intracellulaires activés lors de l’exposition à divers types de NPM. Méthodologie: La lignée de cellules A549 a été utilisée. Trois types de NPM ont été étudiés (différentes concentrations et temps d’exposition): les nanoparticules de dioxyde de titane de type anatase (TiO2), les nanotubes de carbone simple paroi (NTCSP) et les nanoparticules de noir de carbone (NC). La viabilité cellulaire a été mesurée par le test MTS, le test PrestoBlue et le test d’exclusion du bleu de Trypan (uniquement pour les NTCSP). La mesure du stress oxydatif a été déterminée par la mesure des dérivés réactifs de l’oxygène (ROS) en utilisant l’essai DCFH-DA. L’activation d’une réponse anti-oxydative a été déterminée par la mesure de la forme réduite (GSH) et oxydée (GSSG) du glutathion, ainsi que du ratio GSH/GSSG (seulement avec NTCSP et TiO2). Résultats: Les trois nanoparticules ne semblent pas être toxiques pour les cellules A549 car il y a une diminution significative mais minime de la viabilité cellulaire. Cependant, elles induisent une augmentation du contenu intracellulaire en ROS qui est à la fois dépendante du temps et de la concentration. Aucun changement dans les concentrations de GSH et GSSG n’a été observé. En conclusion, nos données indiquent que la mesure de la viabilité n’est pas un critère suffisant pour conclure à la toxicité des NPM. La production de ROS est un critère intéressant, cependant il faudra démontrer l’activation de systèmes anti-oxydatifs pour expliquer l’absence de mortalité cellulaire suite à l’exposition aux NPM. / Detection and characterization of manufactured nanoparticles (NPs) is one of the first steps to control and reduce potential risks to human health and the environment. Various sampling schemes in air exist for the evaluation of exposure to NPs. However, they do not measure the potential risk of this exposure to the human health and the cellular mechanisms that are responsible. Our research objectives are 1) To evaluate the effects of different types of nanoparticles on human lung cells and 2) Identify new intracellular mechanisms activated during exposure to various types of NPs. Methodology: The cell line A549 was used. Three types of NPs were studied (different concentrations and exposure time): titanium dioxide nanoparticles of anatase (TiO2), the simple wall carbon nanotubes (SWCN) and black carbon nanoparticles (BC). Cell viability was measured by the MTS assay, the PrestoBlue assay and the Trypan blue due exclusion test (only for the SWCN). To investigate whether the NPs stimulated ROS generation in A549 cels, the intracellular ROS level was measured using the DCFH-DA assay. The potential induction of oxidative stress responses in cells when exposed to TiO2 and SWCN was determined by the quantification of the extracellular levels of reduced (GSH) and oxidized glutathione (GSSG) forms. Results: The three nanoparticles do not appear to be toxic to A549 cells because there is a significant but small decrease in cell viability. However, they induce ROS production which is both time and concentration dependent. No change in the concentrations of GSH and GSSG were observed. In conclusion, our data indicate that measuring the cell viability is not a sufficient criterion for concluding if the NPs are toxic. ROS production is an interesting criterion, however, we have to demonstrate the activation of anti-oxidative systems to explain the absence of cell death following exposure to the NPs.

nanoparticules manufacturées

cellules épithéliales alvéolaires

nanotubes de carbone simple paroi

dioxyde de titane

noir de carbone

viabilité cellulaire

stress oxydatif

mécanismes intracellulaires

risque potentiel

manufactured nanoparticles

alveolar epithelial cells

simple wall carbon nanotubes

titanium dioxide nanoparticles

carbon black

cell viability

oxidative stress

intracellular mechanisms

potential risk