Nickel toxicity in P. lividus embryos: Dose dependent effects and gene expression analysis

Many industrial activities release Nickel (Ni) in the environment with harmful effects for terrestrial and marine organisms. Despite many studies on the mechanisms of Ni toxicity are available, the understanding about its toxic effects on marine organisms is more limited. We used Paracentrotus livid...

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Bibliographic Details
Published in:Marine environmental research 2018-08, Vol.139, p.113-121
Main Authors: Bonaventura, Rosa, Zito, Francesca, Chiaramonte, Marco, Costa, Caterina, Russo, Roberta
Format: Article
Language:English
Subjects:
Adapters
Animal embryos
Animals
Biomarkers
Cells
Cellular stress response
Defence mechanisms
Deoxyribonucleic acid
Development
DNA
Echinoderm
Embryo, Nonmammalian - drug effects
Embryo, Nonmammalian - physiology
Embryonic Development
Embryos
Environmental effects
Environmental impact
Exposure
Gene Expression
Genes
Heavy metal
Immune response
Immunity
Industrial areas
Invertebrate
Kinases
Manganese
Marine ecology
Marine invertebrates
Marine organisms
Marine pollution
Morphology
mRNA
Nickel
Nickel - toxicity
Paracentrotus - embryology
Paracentrotus - physiology
Phenotypes
Pigment cell
Profiles
Proteins
Skeleton
Stress
Stress response
Terrestrial environments
Toxicity
Transcription
Water Pollutants, Chemical - toxicity
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Summary:Many industrial activities release Nickel (Ni) in the environment with harmful effects for terrestrial and marine organisms. Despite many studies on the mechanisms of Ni toxicity are available, the understanding about its toxic effects on marine organisms is more limited. We used Paracentrotus lividus as a model to analyze the effects on the stress pathways in embryos continuously exposed to different Ni doses, ranging from 0.03 to 0.5 mM. We deeply examined the altered embryonic morphologies at 24 and 48 h after Ni exposure. Some different phenotypes have been classified, showing alterations at the expenses of the dorso-ventral axis as well as the skeleton and/or the pigment cells. At the lowest dose used, Ni mainly induced a multi-spicule phenotype observed at 24 h after treatment. On the contrary, at the highest dose of Ni (0.5 mM), 90% of embryos showed no skeleton and no pigment cells. Therefore, we focused on this dose to study protein and gene expression patterns at 24 and 48 h after exposure. Among the proteins analyzed, i.e. p38MAPK, Grp78 and Mn-SOD, only p38MAPK was induced by Ni treatment. Moreover, we analyzed the mRNA profiles of a pool of genes that are involved in stress response and in development mechanisms, i.e. the transcription factors Pl-NFkB and Pl-FOXO; a marker of DNA repair, Pl-XPB/ERCC3; a mitogen-activated protein kinase (MAPK), Pl-p38; an ER stress gene, Pl-grp78; an adapter protein, Pl-14-3-3ε; two markers of pigment cells, Pl-PKS1 and Pl-gcm. The spatial expression of mesenchymal marker genes has been evaluated in Ni-treated embryos at both 24 and 48 h after exposure. Our results indicated that Ni acts at several levels in P. lividus sea urchin, by affecting embryo development, influencing the embryonic immune response and activating stress response pathways to counteract the suffered injury and to promote embryos surviving. •Ni at 0.5 mM upregulates p38MAPK, grp78, XPB/ERCC3 and NF-kB genes.•PKS1 and gcm gene are down regulated by Ni at 0.5 mM.•Pigment cells decrease in number or are absent in Ni-exposed embryos.•Ni at 0.5 mM induces p38MAPK protein activation after 24 h of exposure.•P. lividus is as a good model to study the signaling pathways activated by Nickel.
ISSN:0141-1136
1879-0291
DOI:10.1016/j.marenvres.2018.05.002