The Transcriptomic Response of Arabidopsis thaliana to Zinc Oxide: A Comparison of the Impact of Nanoparticles, Bulk, and Ionic Zinc
Landa P., Prerostova S., Petrova S., Knirsch V., Vankova R., Vanek T.
ENVIRONMENTAL SCIENCE AND TECHNOLOGY 49: 14537−14545, 2015
Klíčová slova:
Abstrakt: The impact of nanosize was evaluated by comparing of the transcriptomic response of Arabidopsis thaliana roots to ZnO nanoparticles (nZnO), bulk ZnO, and ionic Zn2+. Microarray analyses revealed 416 up- and 961 down-regulated transcripts (expression difference > 2-fold, p [FDR] < 0.01) after a seven-day treatment with nZnO (average particle size 20 nm, concentration 4 mg L-1). Exposure to bulk ZnO resulted in 816 up- and 2179 down-regulated transcripts. The most dramatic changes (1711 transcripts up- and 3242 down-regulated) were caused by the presence of ionic Zn2+ (applied as ZnSO4.7H20 at a concentration of 14.14 mg L-1, corresponding to the amount of Zn contained in 4 mg L-1 ZnO). Genes involved in stress response (e.g., to salt, osmotic stress or water deprivation) were the most relatively abundant group of gene transcripts up-regulated by all three Zn treatments while genes involved in cell organization and biogenesis (e.g., tubulins, arabinogalactan proteins) and DNA or RNA metabolism (e.g., histones) were the most relatively abundant groups of down-regulated transcripts. The similarity of the transcription profiles and the increasing number of changed transcripts correlating with the increased concentration of Zn2+ in cultivation medium indicated that released Zn2+ may substantially contribute to the toxic effect of nZnO because particle size has not demonstrated a decisive role.
DOI: 10.1021/acs.est.5b03330
Autoři z ÚEB: Vojtěch Knirsch, Přemysl Landa, Šárka Petrová, Sylva Přerostová, Tomáš Vaněk, Radomíra Vanková
ENVIRONMENTAL SCIENCE AND TECHNOLOGY 49: 14537−14545, 2015
Klíčová slova:
Abstrakt: The impact of nanosize was evaluated by comparing of the transcriptomic response of Arabidopsis thaliana roots to ZnO nanoparticles (nZnO), bulk ZnO, and ionic Zn2+. Microarray analyses revealed 416 up- and 961 down-regulated transcripts (expression difference > 2-fold, p [FDR] < 0.01) after a seven-day treatment with nZnO (average particle size 20 nm, concentration 4 mg L-1). Exposure to bulk ZnO resulted in 816 up- and 2179 down-regulated transcripts. The most dramatic changes (1711 transcripts up- and 3242 down-regulated) were caused by the presence of ionic Zn2+ (applied as ZnSO4.7H20 at a concentration of 14.14 mg L-1, corresponding to the amount of Zn contained in 4 mg L-1 ZnO). Genes involved in stress response (e.g., to salt, osmotic stress or water deprivation) were the most relatively abundant group of gene transcripts up-regulated by all three Zn treatments while genes involved in cell organization and biogenesis (e.g., tubulins, arabinogalactan proteins) and DNA or RNA metabolism (e.g., histones) were the most relatively abundant groups of down-regulated transcripts. The similarity of the transcription profiles and the increasing number of changed transcripts correlating with the increased concentration of Zn2+ in cultivation medium indicated that released Zn2+ may substantially contribute to the toxic effect of nZnO because particle size has not demonstrated a decisive role.
DOI: 10.1021/acs.est.5b03330