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1.
Part Fibre Toxicol ; 14(1): 8, 2017 03 21.
Article in English | MEDLINE | ID: mdl-28327162

ABSTRACT

BACKGROUND: Carbon black nanoparticles (CBNP) are mainly composed of carbon, with a small amount of other elements (including hydrogen and oxygen). The toxicity of CBNP has been attributed to their large surface area, and through adsorbing intrinsically toxic substances, such as polycyclic aromatic hydrocarbons (PAH). It is not clear whether a PAH surface coating changes the toxicological properties of CBNP by influencing their physicochemical properties, through the specific toxicity of the surface-bound PAH, or by a combination of both. METHODS: Printex®90 (P90) was used as CBNP; the comparators were P90 coated with either benzo[a]pyrene (BaP) or 9-nitroanthracene (9NA), and soot from acetylene combustion that bears various PAHs on the surface (AS-PAH). Oxidative stress and IL-8/KC mRNA expression were determined in A549 and bronchial epithelial cells (16HBE14o-, Calu-3), mouse intrapulmonary airways and tracheal epithelial cells. Overall toxicity was tested in a rat inhalation study according to Organization for Economic Co-operation and Development (OECD) criteria. Effects on cytochrome monooxygenase (Cyp) mRNA expression, cell viability and mucociliary clearance were determined in acute exposure models using explanted murine trachea. RESULTS: All particles had similar primary particle size, shape, hydrodynamic diameter and ζ-potential. All PAH-containing particles had a comparable specific surface area that was approximately one third that of P90. AS-PAH contained a mixture of PAH with expected higher toxicity than BaP or 9NA. PAH-coating reduced some effects of P90 such as IL-8 mRNA expression and oxidative stress in A549 cells, granulocyte influx in the in vivo OECD experiment, and agglomeration of P90 and mucus release in the murine trachea ex vivo. Furthermore, P90-BaP decreased particle transport speed compared to P90 at 10 µg/ml. In contrast, PAH-coating induced IL-8 mRNA expression in bronchial epithelial cell lines, and Cyp mRNA expression and apoptosis in tracheal epithelial cells. In line with the higher toxicity compared to P90-BaP and P90-9NA, AS-PAH had the strongest biological effects both ex vivo and in vivo. CONCLUSIONS: Our results demonstrate that the biological effect of CBNP is determined by a combination of specific surface area and surface-bound PAH, and varies in different target cells.


Subject(s)
Epithelial Cells/drug effects , Nanoparticles/toxicity , Polycyclic Aromatic Hydrocarbons/toxicity , Soot/toxicity , A549 Cells , Animals , Apoptosis/drug effects , Epithelial Cells/metabolism , Female , Humans , Immunity, Innate/drug effects , Inhalation Exposure , Interleukin-8/metabolism , Lung/drug effects , Lung/immunology , Male , Mice, Inbred BALB C , Nanoparticles/chemistry , Particle Size , Polycyclic Aromatic Hydrocarbons/chemistry , Rats, Wistar , Reactive Oxygen Species/metabolism , Soot/chemistry , Surface Properties , Trachea/drug effects , Trachea/pathology
2.
J Virol ; 86(9): 5165-78, 2012 May.
Article in English | MEDLINE | ID: mdl-22357270

ABSTRACT

Epstein-Barr virus (EBV) establishes a persistent latent infection in B lymphocytes and is associated with the development of numerous human tumors. Epstein-Barr nuclear antigen 3C (EBNA 3C) is essential for B-cell immortalization, has potent cell cycle deregulation capabilities, and functions as a regulator of both viral- and cellular-gene expression. We performed transcription profiling on EBNA 3C-expressing B cells and identified several chemokines and members of integrin receptor-signaling pathways, including CCL3, CCL4, CXCL10, CXCL11, ITGA4, ITGB1, ADAM28, and ADAMDEC1, as cellular target genes that could be repressed by the action of EBNA 3C alone. Chemotaxis assays demonstrated that downregulation of CXCL10 and -11 by EBNA 3C is sufficient to reduce the migration of cells expressing the CXCL10 and -11 receptor CXCR3. Gene repression by EBNA 3C was accompanied by decreased histone H3 lysine 9/14 acetylation and increased histone H3 lysine 27 trimethylation. In an EBV-positive cell line expressing all latent genes, we identified binding sites for EBNA 3C at ITGB1 and ITGA4 and in a distal regulatory region between ADAMDEC1 and ADAM28, providing the first demonstration of EBNA 3C association with cellular-gene control regions. Our data implicate indirect mechanisms in CXCL10 and CXCL11 repression by EBNA 3C. In summary, we have unveiled key cellular pathways repressed by EBNA 3C that are likely to contribute to the ability of EBV-immortalized cells to modulate immune responses, adhesion, and B-lymphocyte migration to facilitate persistence in the host.


Subject(s)
Antigens, Viral/metabolism , Down-Regulation/genetics , Integrins/genetics , Promoter Regions, Genetic , Signal Transduction , ADAM Proteins/genetics , Animals , Binding Sites , Cell Adhesion/genetics , Cell Line , Cell Migration Inhibition/genetics , Chemokines/genetics , Chemotaxis/genetics , Epstein-Barr Virus Nuclear Antigens , Gene Expression Regulation , Humans , Mice , Receptors, CXCR3/metabolism , Regulatory Elements, Transcriptional
3.
PLoS One ; 6(12): e28638, 2011.
Article in English | MEDLINE | ID: mdl-22163048

ABSTRACT

Epstein-Barr virus (EBV) is implicated in the pathogenesis of multiple human tumours of lymphoid and epithelial origin. The virus infects and immortalizes B cells establishing a persistent latent infection characterized by varying patterns of EBV latent gene expression (latency 0, I, II and III). The CDK1 activator, Response Gene to Complement-32 (RGC-32, C13ORF15), is overexpressed in colon, breast and ovarian cancer tissues and we have detected selective high-level RGC-32 protein expression in EBV-immortalized latency III cells. Significantly, we show that overexpression of RGC-32 in B cells is sufficient to disrupt G2 cell-cycle arrest consistent with activation of CDK1, implicating RGC-32 in the EBV transformation process. Surprisingly, RGC-32 mRNA is expressed at high levels in latency I Burkitt's lymphoma (BL) cells and in some EBV-negative BL cell-lines, although RGC-32 protein expression is not detectable. We show that RGC-32 mRNA expression is elevated in latency I cells due to transcriptional activation by high levels of the differentially expressed RUNX1c transcription factor. We found that proteosomal degradation or blocked cytoplasmic export of the RGC-32 message were not responsible for the lack of RGC-32 protein expression in latency I cells. Significantly, analysis of the ribosomal association of the RGC-32 mRNA in latency I and latency III cells revealed that RGC-32 transcripts were associated with multiple ribosomes in both cell-types implicating post-initiation translational repression mechanisms in the block to RGC-32 protein production in latency I cells. In summary, our results are the first to demonstrate RGC-32 protein upregulation in cells transformed by a human tumour virus and to identify post-initiation translational mechanisms as an expression control point for this key cell-cycle regulator.


Subject(s)
Cell Cycle Proteins/biosynthesis , Herpesvirus 4, Human/metabolism , Muscle Proteins/biosynthesis , Nerve Tissue Proteins/biosynthesis , Up-Regulation , B-Lymphocytes/metabolism , B-Lymphocytes/virology , CDC2 Protein Kinase/biosynthesis , Cell Line, Tumor , Core Binding Factor Alpha 2 Subunit/biosynthesis , Flow Cytometry/methods , G2 Phase , Gene Expression Profiling , Humans , Plasmids/metabolism , Polyribosomes/metabolism , Protein Biosynthesis , RNA, Messenger/metabolism , Transcription, Genetic
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