Your search keyword '"Alleman, L."' showing total 109 results

101. Study of in vitro and in vivo genotoxic effects of air pollution fine (PM 2.5-0.18 ) and quasi-ultrafine (PM 0.18 ) particles on lung models.

Author

Platel A, Privat K, Talahari S, Delobel A, Dourdin G, Gateau E, Simar S, Saleh Y, Sotty J, Antherieu S, Canivet L, Alleman LY, Perdrix E, Garçon G, Denayer FO, Lo Guidice JM, and Nesslany F

Subjects

Air Pollutants, Animals, DNA Damage, France, Lung, Mice, Mice, Inbred BALB C, Particle Size, Particulate Matter, Air Pollution

Abstract

Air pollution and particulate matter (PM) are classified as carcinogenic to humans. Pollutants evidence for public health concern include coarse (PM 10 ) and fine (PM 2.5 ) particles. However, ultrafine particles (PM 0.1 ) are assumed to be more toxic than larger particles, but data are still needed to better understand their mechanism of action. In this context, the aim of our work was to investigate the in vitro and in vivo genotoxic potential of fine (PM 2.5-018 ) and quasi ultra-fine (PM 0.18 ) particles from an urban-industrial area (Dunkirk, France) by using comet, micronucleus and/or gene mutation assays. In vitro assessment was performed with 2 lung immortalized cell lines (BEAS-2B and NCI-H292) and primary normal human bronchial epithelial cells (NHBE) grown at the air-liquid interface or in submerged conditions (5 µg PM/cm 2 ). For in vivo assessment, tests were performed after acute (24 h, 100 µg PM/animal), subacute (1 month, 10 µg PM/animal) and subchronic (3 months, 10 µg PM/animal) intranasal exposure of BALB/c mice. In vitro, our results show that PM 2.5-018 and PM 0.18 induced primary DNA damage but no chromosomal aberrations in immortalized cells. Negative results were noted in primary cells for both endpoints. In vivo assays revealed that PM 2.5-018 and PM 0.18 induced no significant increases in DNA primary damage, chromosomal aberrations or gene mutations, whatever the duration of exposure. This investigation provides initial answers regarding the in vitro and in vivo genotoxic mode of action of PM 2.5-018 and PM 0.18 at moderate doses and highlights the need to develop standardized specific methodologies for assessing the genotoxicity of PM. Moreover, other mechanisms possibly implicated in pulmonary carcinogenesis, e.g. epigenetics, should be investigated., Competing Interests: Declaration of Competing Interest The authors declared that there is no conflict of interest., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

102. Incidence of sexually transmitted infections during pre-exposure prophylaxis for HIV: a worrying outcome at 2 years!

Author

Ducours M, Alleman L, Puges M, Deborde M, Hessamfar M, Le-Marec F, Dabis F, Pereyre S, Bébéar C, Descaux A, and Cazanave C

Subjects

Adult, Anal Canal microbiology, France epidemiology, Homosexuality, Male, Hospitals, University, Humans, Incidence, Longitudinal Studies, Male, Pharynx microbiology, Prevalence, Rectum microbiology, Sexually Transmitted Diseases, Bacterial microbiology, Urine microbiology, HIV Infections prevention & control, Pre-Exposure Prophylaxis, Sexually Transmitted Diseases, Bacterial epidemiology

Abstract

Competing Interests: Competing interests: None declared.

Published

2019

103. Toxicological effects of ambient fine (PM 2.5-0.18 ) and ultrafine (PM 0.18 ) particles in healthy and diseased 3D organo-typic mucocilary-phenotype models.

Author

Sotty J, Garçon G, Denayer FO, Alleman LY, Saleh Y, Perdrix E, Riffault V, Dubot P, Lo-Guidice JM, and Canivet L

Subjects

Bronchi, Epithelial Cells, Humans, Particle Size, Phenotype, S100 Proteins, Air Pollutants toxicity, Particulate Matter toxicity

Abstract

The knowledge of the underlying mechanisms by which particulate matter (PM) exerts its health effects is still incomplete since it may trigger various symptoms as some persons may be more susceptible than others. Detailed studies realized in more relevant in vitro models are highly needed. Healthy normal human bronchial epithelial (NHBE), asthma-diseased human bronchial epithelial (DHBE), and COPD-DHBE cells, differentiated at the air-liquid interface, were acutely or repeatedly exposed to fine (i.e., PM 2.5-0.18 , also called FP) and quasi-ultrafine (i.e., PM 0.18 , also called UFP) particles. Immunofluorescence labelling of pan-cytokeratin, MUC5AC, and ZO-1 confirmed their specific cell-types. Baselines of the inflammatory mediators secreted by all the cells were quite similar. Slight changes of TNFα, IL-1β, IL-6, IL-8, GM-CSF, MCP-1, and/or TGFα, and of H3K9 histone acetylation supported a higher inflammatory response of asthma- and especially COPD-DHBE cells, after exposure to FP and especially UFP. At baseline, 35 differentially expressed genes (DEG) in asthma-DHBE, and 23 DEG in COPD-DHBE, compared to NHBE cells, were reported. They were involved in biological processes implicated in the development of asthma and COPD diseases, such as cellular process (e.g., PLA2G4C, NLRP1, S100A5, MUC1), biological regulation (e.g., CCNE1), developmental process (e.g., WNT10B), and cell component organization and synthesis (e.g., KRT34, COL6A1, COL6A2). In all the FP or UFP-exposed cell models, DEG were also functionally annotated to the chemical metabolic process (e.g., CYP1A1, CYP1B1, CYP1A2) and inflammatory response (e.g., EREG). Another DEG, FGF-1, was only down-regulated in asthma and specially COPD-DHBE cells repeatedly exposed. While RAB37 could help to counteract the down-regulation of FGF-1 in asthma-DHBE cells, the deregulation of FGR, WNT7B, VIPR1, and PPARGC1A could dramatically contribute to make it worse in COPD-DHBE cells. Taken together, these data contributed to support the highest effects of UFP versus FP and highest sensitivity of asthma- and notably COPD-DHBE versus NHBE cells., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

104. Exposure to Atmospheric Ultrafine Particles Induces Severe Lung Inflammatory Response and Tissue Remodeling in Mice.

Author

Saleh Y, Antherieu S, Dusautoir R, Y Alleman L, Sotty J, De Sousa C, Platel A, Perdrix E, Riffault V, Fronval I, Nesslany F, Canivet L, Garçon G, and Lo-Guidice JM

Subjects

Air Pollutants analysis, Animals, Disease Models, Animal, Environmental Exposure analysis, Lung immunology, Male, Mice, Mice, Inbred BALB C, Particle Size, Particulate Matter administration & dosage, Time Factors, Air Pollutants adverse effects, Environmental Exposure adverse effects, Lung drug effects, Lung pathology, Particulate Matter adverse effects, Systemic Inflammatory Response Syndrome chemically induced, Systemic Inflammatory Response Syndrome pathology

Abstract

Exposure to particulate matter (PM) is leading to various respiratory health outcomes. Compared to coarse and fine particles, less is known about the effects of chronic exposure to ultrafine particles, despite their higher number and reactivity. In the present study, we performed a time-course experiment in mice to better analyze the lung impact of atmospheric ultrafine particles, with regard to the effects induced by fine particles collected on the same site. Trace element and PAH analysis demonstrated the almost similar chemical composition of both particle fractions. Mice were exposed intranasally to FF or UFP according to acute (10, 50 or 100 µg of PM) and repeated (10 µg of PM 3 times a week during 1 or 3 months) exposure protocols. More particle-laden macrophages and even greater chronic inflammation were observed in the UFP-exposed mice lungs. Histological analyses revealed that about 50% of lung tissues were damaged in mice exposed to UFP for three months versus only 35% in FF-exposed mice. These injuries were characterized by alveolar wall thickening, macrophage infiltrations, and cystic lesions. Taken together, these results strongly motivate the update of current regulations regarding ambient PM concentrations to include UFP and limit their emission.

Published

2019

105. Air pollution-derived PM 2.5 impairs mitochondrial function in healthy and chronic obstructive pulmonary diseased human bronchial epithelial cells.

Author

Leclercq B, Kluza J, Antherieu S, Sotty J, Alleman LY, Perdrix E, Loyens A, Coddeville P, Lo Guidice JM, Marchetti P, and Garçon G

Subjects

Air Pollutants toxicity, Air Pollution analysis, Air Pollution statistics & numerical data, Bronchi cytology, Epithelial Cells drug effects, Humans, Hypersensitivity, Lung drug effects, Mitochondria metabolism, NF-E2-Related Factor 2, Particulate Matter metabolism, Pulmonary Disease, Chronic Obstructive metabolism, Air Pollutants analysis, Mitochondria drug effects, Particulate Matter analysis, Particulate Matter toxicity

Abstract

In order to clarify whether the mitochondrial dysfunction is closely related to the cell homeostasis maintenance after particulate matter (PM 2.5 ) exposure, oxidative, inflammatory, apoptotic and mitochondrial endpoints were carefully studied in human bronchial epithelial BEAS-2B, normal human bronchial epithelial (NHBE) and chronic obstructive pulmonary disease (COPD)-diseased human bronchial epithelial (DHBE) cells acutely or repeatedly exposed to air pollution-derived PM 2.5 . Some modifications of the mitochondrial morphology were observed within all these cell models repeatedly exposed to the highest dose of PM 2.5 . Dose- and exposure-dependent oxidative damages were reported in BEAS-2B, NHBE and particularly COPD-DHBE cells acutely or repeatedly exposed to PM 2.5 . Nuclear factor erythroid 2-p45 related factor 2 (NRF2) gene expression and binding activity, together with the mRNA levels of some NRF2 target genes, were directly related to the number of exposures for the lowest PM 2.5 dose (i.e., 2 μg/cm 2 ), but, surprisingly, inversely related to the number of exposures for the highest dose (i.e., 10 μg/cm 2 ). There were dose- and exposure-dependent increases of both nuclear factor kappa-B (NF-κB) binding activity and NF-κB target cytokine secretion in BEAS-2B, NHBE and particularly COPD-DHBE cells exposed to PM 2.5 . Mitochondrial ROS production, membrane potential depolarization, oxidative phosphorylation, and ATP production were significantly altered in all the cell models repeatedly exposed to the highest dose of PM 2.5 . Collectively, our results indicate a cytosolic ROS overproduction, inducing oxidative damage and activating oxygen sensitive NRF2 and NF- k B signaling pathways for all the cell models acutely or repeatedly exposed to PM 2.5 . However, one of the important highlight of our findings is that the prolonged and repeated exposure in BEAS-2B, NHBE and in particular sensible COPD-DHBE cells further caused an oxidative boost able to partially inactivate the NRF2 signaling pathway and to critically impair mitochondrial redox homeostasis, thereby producing a persistent mitochondrial dysfunction and a lowering cell energy supply., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

106. Genetic and epigenetic alterations in normal and sensitive COPD-diseased human bronchial epithelial cells repeatedly exposed to air pollution-derived PM 2.5 .

Author

Leclercq B, Platel A, Antherieu S, Alleman LY, Hardy EM, Perdrix E, Grova N, Riffault V, Appenzeller BM, Happillon M, Nesslany F, Coddeville P, Lo-Guidice JM, and Garçon G

Subjects

Air Pollutants analysis, Air Pollution analysis, Cell Line, Epigenesis, Genetic, Epithelial Cells drug effects, Humans, Hypersensitivity, Particulate Matter analysis, Toxicity Tests, Air Pollutants toxicity, Particulate Matter toxicity, Pulmonary Disease, Chronic Obstructive genetics

Abstract

Even though clinical, epidemiological and toxicological studies have progressively provided a better knowledge of the underlying mechanisms by which air pollution-derived particulate matter (PM) exerts its harmful health effects, further in vitro studies on relevant cell systems are still needed. Hence, aiming of getting closer to the human in vivo conditions, primary human bronchial epithelial cells derived from normal subjects (NHBE) or sensitive chronic obstructive pulmonary disease (COPD)-diseased patients (DHBE) were differentiated at the air-liquid interface. Thereafter, they were repeatedly exposed to air pollution-derived PM 2.5 to study the occurrence of some relevant genetic and/or epigenetic endpoints. Concentration-, exposure- and season-dependent increases of OH-B[a]P metabolites in NHBE, and to a lesser extent, COPD-DHBE cells were reported; however, there were more tetra-OH-B[a]P and 8-OHdG DNA adducts in COPD-DHBE cells. No increase in primary DNA strand break nor chromosomal aberration was observed in repeatedly exposed cells. Telomere length and telomerase activity were modified in a concentration- and exposure-dependent manner in NHBE and particularly COPD-DHBE cells. There were a global DNA hypomethylation, a P16 gene promoter hypermethylation, and a decreasing DNA methyltransferase activity in NHBE and notably COPD-DHBE cells repeatedly exposed. Changes in site-specific methylation, acetylation, and phosphorylation of histone H3 (i.e., H3K4me3, H3K9ac, H3K27ac, and H3S10ph) and related enzyme activities occurred in a concentration- and exposure-dependent manner in all the repeatedly exposed cells. Collectively, these results highlighted the key role played by genetic and even epigenetic events in NHBE and particularly sensitive COPD-DHBE cells repeatedly exposed to air pollution-derived PM 2.5 and their different responsiveness. While these specific epigenetic changes have been already described in COPD and even lung cancer phenotypes, our findings supported that, together with genetic events, these epigenetic events could dramatically contribute to the shift from healthy to diseased phenotypes following repeated exposure to relatively low doses of air pollution-derived PM 2.5 ., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

107. Differential responses of healthy and chronic obstructive pulmonary diseased human bronchial epithelial cells repeatedly exposed to air pollution-derived PM 4 .

Author

Leclercq B, Happillon M, Antherieu S, Hardy EM, Alleman LY, Grova N, Perdrix E, Appenzeller BM, Lo Guidice JM, Coddeville P, and Garçon G

Subjects

Air Pollution, Cell Line, Epithelial Cells metabolism, Humans, Lung cytology, Lung drug effects, Lung metabolism, Oxidative Stress drug effects, Pulmonary Disease, Chronic Obstructive metabolism, Air Pollutants toxicity, Epithelial Cells drug effects, Particulate Matter toxicity

Abstract

While the knowledge of the underlying mechanisms by which air pollution-derived particulate matter (PM) exerts its harmful health effects is still incomplete, detailed in vitro studies are highly needed. With the aim of getting closer to the human in vivo conditions and better integrating a number of factors related to pre-existing chronic pulmonary inflammatory, we sought to develop primary cultures of normal human bronchial epithelial (NHBE) cells and chronic obstructive pulmonary disease (COPD)-diseased human bronchial epithelial (DHBE) cells, grown at the air-liquid interface. Pan-cytokeratin and MUC5AC immunostaining confirmed the specific cell-types of both these healthy and diseased cell models and showed they are closed to human bronchial epithelia. Thereafter, healthy and diseased cells were repeatedly exposed to air pollution-derived PM 4 at the non-cytotoxic concentration of 5 μg/cm 2 . The differences between the oxidative and inflammatory states in non-exposed NHBE and COPD-DHBE cells indicated that diseased cells conserved their specific physiopathological characteristics. Increases in both oxidative damage and cytokine secretion were reported in repeatedly exposed NHBE cells and particularly in COPD-DHBE cells. Diseased cells repeatedly exposed had lower capacities to metabolize the organic chemicals-coated onto the air-pollution-derived PM 4 , such as benzo[a]pyrene (B[a]P), but showed higher sensibility to the formation of OH-B[a]P DNA adducts, because their diseased state possibly affected their defenses. Differential profiles of epigenetic hallmarks (i.e., global DNA hypomethylation, P16 promoter hypermethylation, telomere length shortening, telomerase activation, and histone H3 modifications) occurred in repeatedly exposed NHBE and particularly in COPD-DHBE cells. Taken together, these results closely supported the highest responsiveness of COPD-DHBE cells to a repeated exposure to air pollution-derived PM 4 . The use of these innovative in vitro exposure systems such as NHBE and COPD-DHBE cells could therefore be consider as a very useful and powerful promising tool in the field of the respiratory toxicology, taking into account sensitive individuals., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

108. DoD's Medical Radiobiology Advisory Team: experts on the ground.

Author

VanHorne-Sealy J, Livingston B, and Alleman L

Subjects

Environmental Monitoring, Humans, International Cooperation, Japan, Radiation Monitoring, United States, Earthquakes, Nuclear Power Plants, Radioactive Hazard Release, Radiobiology, Tsunamis

Abstract

The Medical Radiobiology Advisory Team (MRAT) is the operations arm of the Armed Forces Radiobiology Research Institute (AFRRI), located at Naval Support Activity in Bethesda, MD. AFRRI is internationally recognized as expert in the biological effects of ionizing radiation research, training, and mitigation. During the U.S. Department of Defense's (DoD) response to the Fukushima Daiichi reactor incident, Operation Tomodachi, the MRAT provided guidance and advice to the U.S. Military leaders in Japan. This support helped ensure the safety of U.S. service members, family members, and civilians and supported the humanitarian relief in a coordinated effort with the Government of Japan (GOJ).

Published

2012

109. Cholesterine crystals in the opaque lens of a child.

Author

Alleman LA

Published

1897