Cellular impact of combinations of endosulfan, atrazine, and chlorpyrifos on human primary hepatocytes and HepaRG cells after short and chronic exposures.

Chronic exposure to low doses of pesticides present in the environment is increasingly suspected to cause major health issues to humans. Toxicological evaluations become more complex when the exposure concerns chemical combinations. Atrazine, chlorpyrifos, and endosulfan are pesticides used worldwide in agriculture and are therefore currently found at residual levels in food and the environment, even in countries in which they are now banned. Our study aimed to use Real-Time Cell Impedance Analyzer to investigate changes in phenotypical status of primary human hepatocytes and differentiated HepaRG cells induced by short and chronic exposures to these three chemicals. In contrast to the traditionally used endpoint cytotoxicity test, this technology allows kinetic measurements in real-time throughout the entire experiment. Our data show significantly higher cytotoxic effects of mixtures as compared to individual pesticides and a greater susceptibility of human hepatocytes as compared to HepaRG to short-term exposure (24 h). Repeated exposure over 2 weeks to endosulfan and endosulfan-containing mixture induced HepaRG cell death in a time- and dose-dependent manner. Of the typical genes involved in metabolism and cell-response to xenobiotics, we found an exposure time- and condition-dependent deregulation of the expression of CYP3A4 and UGT1A in HepaRG cells exposed to low doses of pesticides and mixtures. Our data demonstrate the usefulness of real-time cell monitoring in long-term toxicological evaluations of co-exposure to xenobiotics. In addition, they support but at the same time highlight certain limitations in the use of HepaRG cells as the gold standard liver cell model in toxicity studies.

Impacts of low doses of pesticide mixtures on liver cell defence systems.

Low amounts of residual pesticides are present in the environment, often as mixtures of chemicals which contaminate drinking water and food, being a source of chronic exposure for humans and a growing matter of concern in public health policy. Despite of the needs and growing investigation, little is known about the impact of low doses and mixtures of these chemicals on human health. The purpose of this study was to enlighten if modifications of liver cell metabolic- and/or defence-related capacities could occur under such exposures. In vitro perturbations of several metabolic, stress and survival pathways in human and mice cultured hepatocytes and liver cells were evaluated under exposure to low doses of single molecules or equimolecular combinations of the three pesticides, atrazine, chlorpyrifos and endosulfan. Mainly phases I and II enzymes of detoxification were found modulated, together with apoptotic process deregulation. Hence, CYP3A4 and CYP3A11 were upregulated in primary cultured human and mouse hepatocytes, respectively. These inductions were correlated to an anti-apoptotic process (increased Bcl-xL/Bax ratio, inhibition of the PARP protein cleavage). Such disturbances in pathways involved in cell protection may possibly account for initiation of pathologies or decrease in drugs efficiency in humans exposed to multiple environmental contaminants.

A new phospholipase A2 isolated from the sea anemone Urticina crassicornis - its primary structure and phylogenetic classification.

Disulfide pairings and active site residues are highly conserved in secretory phospholipases A(2) (PLA(2)s). However, secretory PLA(2)s of marine invertebrates display some distinctive structural features. In this study, we report the isolation and characterization of a PLA(2) from the northern Pacific sea anemone, Urticina crassicornis (UcPLA(2)), containing a C27N substitution and a truncated C-terminal sequence. This novel cnidarian PLA(2) shares about 60% identity and almost 70% homology with two putative PLA(2)s identified in the starlet sea anemone (Nematostella vectensis) genome project. UcPLA(2) lacks hemolytic and neurotoxic activities. A search of available sequences revealed that Asn27-'type' PLA(2)s are present in a few other marine animal species, including some vertebrates. The possibility that the C27N replacement represents a structural adaptation for PLA(2) digestion/activity in the marine environment was not supported by experiments testing the influence of ionic strength on UcPLA(2) enzymatic activity. Because of the highly divergent sequences among invertebrate group I PLA(2)s, it is currently not possible to identify orthologous relationships. As the Asn27-containing PLA(2)s are scattered among the other invertebrate group I PLA(2)s, they do not constitute a new, monophyletic PLA(2) clade.

A new cytolytic protein from the sea anemone Urticina crassicornis that binds to cholesterol- and sphingomyelin-rich membranes.

A new pore-forming cytolytic protein was isolated from the Northern red sea anemone, Urticina crassicornis. Its biochemical properties were characterized and partial N-terminal amino acid sequence was determined. The cytolysin, named UcI, has a molecular mass of around 30kDa and lacks phospholipase A(2) activity. UcI lyses bovine erythrocytes at nanomolar concentrations. Hemolysis is a result of a colloid-osmotic shock caused by the opening of toxin-induced ionic pores and can be prevented by osmotic protectants of size >600Da. The functional radius of an average pore was estimated to be about 0.66nm. A more detailed study of the cytolytic activity of UcI was performed with lipid vesicles and monolayers. The toxin binds to monolayers and efficiently permeabilizes small lipid vesicles composed of sphingomyelin and cholesterol. However, the cytolytic activity is not prevented by preincubation with either pure cholesterol or sphingomyelin dispersions. We conclude that the presence of both sphingomyelin and cholesterol, key components of lipid rafts, greatly enhances toxin binding to membranes and probably facilitates pore formation. Alignment of the toxin partial amino acid sequence with sequences of cytolysins belonging to the actinoporin family reveals no sequence homology. We conclude that partial sequence of UcI resembles only the N-terminal part of UpI, a cytolytic protein isolated from a related sea anemone species, Urticina piscivora. The two proteins most probably belong to a separate family of sea anemone cytolysins that are worthy of further characterization.

Interaction of the eukaryotic pore-forming cytolysin equinatoxin II with model membranes: 19F NMR studies.

Sea anemones produce a family of 18-20 kDa proteins, the actinoporins, which lyse cells by forming pores in cell membranes. Sphingomyelin plays an important role in their lytic activity, with membranes lacking this lipid being largely refractory to these toxins. As a means of characterising membrane binding by the actinoporin equinatoxin II (EqTII), we have used 19F NMR to probe the environment of Trp residues in the presence of micelles and bicelles. Trp was chosen as previous data from mutational studies and truncated analogues had identified the N-terminal helix of EqTII and the surface aromatic cluster including tryptophan residues 112 and 116 as being important for membrane interactions. The five tryptophan residues were replaced with 5-fluorotryptophan and assigned by site-directed mutagenesis. The 19F resonance of W112 was most affected in the presence of phospholipid micelles or bicelles, followed by W116, with further change induced by the addition of sphingomyelin. Although binding to phosphatidylcholine is not sufficient to enable pore formation in bilayer membranes, this interaction had a greater effect on the tryptophan residues in our studies than the subsequent interaction with sphingomyelin. Furthermore, sphingomyelin had a direct effect on EqTII in both model membranes, so its role in EqTII pore formation involves more than simply an indirect effect mediated via bulk lipid properties. The lack of change in chemical shift for W149 even in the presence of sphingomyelin indicates that, at least in the model membranes studied here, interaction with sphingomyelin was not sufficient to trigger dissociation of the N-terminal helix from the beta-sandwich, which forms the bulk of the protein.