The Nucleus of Intestinal Cells of the Bacterivore Nematode Caenorhabditis elegans as a Sensitive Sensor of Environmental Pollutants.

Prevalent environmental challenges are climate change, the biodiversity crisis, and the global scale of environmental pollution. We identified the cell nucleus as a sensitive sensor for bio-effects of pollutants such as mercury and nanoparticles. As a major route of pollutant uptake into organisms is ingestion, we have developed a test system that uses single intestinal cells of the nematode roundworm Caenorhabditis elegans. Microscopic observation of the cell nucleus in reporter worms for the methyltransferase fibrillarin (FIB-1::GFP) revealed nuclear staining patterns that are specific for pollutants such as silica nanoparticles, BULK silica particles, silver nanoparticles, ionic AgNO3, and inorganic mercury (HgCl2). While the underlying molecular mechanisms need further investigation, cultivation of the reporter worms in liquid culture on microtiter plates now enables cost-effective screening of more pollutants and samples from the environment, e.g., mesocosm analyses. As C. elegans leads a dual life in the lab and in ecosystems, alteration of nuclear structure and function may likewise explain how environmental pollutants reduce the fitness of wild worms and thus may negatively affect biodiversity.

Silica nanoparticles disrupt OPT-2/PEP-2-dependent trafficking of nutrient peptides in the intestinal epithelium.

Despite of the increasing application of silica nanoparticles and identification of oral exposure as a major entry portal, we lack understanding of nanosilica effects in the gut. Thus, we investigated biointeractions of nanosilica with single intestinal cells. The invertebrate nematode Caenorhabditis elegans was chosen as model organism with a tractable intestine and realistic target organism of nanomaterials in the environment. We found that nanosilica impairs the intestinal uptake of oligopeptides. Downstream to absorption by the apical OPT-2/PEP-2 transporter dipeptides were trapped in aberrant vesicles that grow over time and reach diameters of ≥6 µm. The peptide vesicles do not correspond to known organelles such as gut granules and form independently of related gene products GLO-1 or GLO-3. Formation of aberrant peptide vesicles also occurred independently of insulin/IGF-I receptor (DAF-2) signaling and daf-2 loss of function mutants showed specific vesicle patterns including distinct localization along the apical membrane of single intestinal cells. As malnutrition of exposed C. elegans manifested in reduced growth and a petite phenotype similar to OPT-2/PEP-2 transporter deficient mutants, we conclude that nanosilica-induced peptide vesicles represent a new compartment of di- and tripeptide trapping which disrupts hydrolysis of nutrient peptides and metabolism.

Life span-resolved nanotoxicology enables identification of age-associated neuromuscular vulnerabilities in the nematode Caenorhabditis elegans.

At present, the majority of investigations concerning nanotoxicology in the nematode C. elegans address short-term effects. While this approach allows for the identification of uptake pathways, exposition and acute toxicity, nanoparticle-organism interactions that manifest later in the adult life of C. elegans are missed. Here we show that a microhabitat composed of liquid S-medium and live bacteria in microtiter wells prolongs C. elegans longevity and is optimally suited to monitor chronic eNP-effects over the entire life span (about 34 days) of the nematode. Silver (Ag) nanoparticles reduced C. elegans life span in concentrations ≥10 µg/mL, whereas nano ZnO and CeO2 (1-160 µg/mL) had no effect on longevity. Monitoring of locomotion behaviors throughout the entire life span of C. elegans showed that Ag NPs accelerate the age-associated decline of swimming and increase of uncoordinated movements at concentrations of ≥10 µg/mL, whereas neuromuscular defects did not occur in response to ZnO and CeO2 NPs. By means of a fluorescing reporter worm expressing tryptophan hydroxylase-1::DsRed Ag NP-induced behavioral defects were correlated to axonal protein aggregation and neurodegeneration in single serotonergic HSN as well as sensory ADF neurons. Notably, serotonergic ADF neurons represented a sensitive target for Ag NPs in comparison to GABAergic neurons that showed no signs of degeneration under the same conditions. We conclude that due to its analogy to the jellylike boom culture of C. elegans on microbe-rich rotting plant material liquid S-medium culture in spatially confined microtiter wells represents a relevant as well as practical tool for comparative identification of age-resolved nanoparticle effects and vulnerabilities in a significant target organism. Consistent with this, specifically middle-aged nematodes showed premature neuromuscular defects after Ag NP-exposure.

Effect of nanoparticles on the biochemical and behavioral aging phenotype of the nematode Caenorhabditis elegans.

Invertebrate animal models such as the nematode Caenorhabditis elegans (C. elegans) are increasingly used in nanotechnological applications. Research in this area covers a wide range from remote control of worm behavior by nanoparticles (NPs) to evaluation of organismal nanomaterial safety. Despite of the broad spectrum of investigated NP-bio interactions, little is known about the role of nanomaterials with respect to aging processes in C. elegans. We trace NPs in single cells of adult C. elegans and correlate particle distribution with the worm's metabolism and organ function. By confocal microscopy analysis of fluorescently labeled NPs in living worms, we identify two entry portals for the uptake of nanomaterials via the pharynx to the intestinal system and via the vulva to the reproductive system. NPs are localized throughout the cytoplasm and the cell nucleus in single intestinal, and vulval B and D cells. Silica NPs induce an untimely accumulation of insoluble ubiquitinated proteins, nuclear amyloid and reduction of pharyngeal pumping that taken together constitute a premature aging phenotype of C. elegans on the molecular and behavioral level, respectively. Screening of different nanomaterials for their effects on protein solubility shows that polystyrene or silver NPs do not induce accumulation of ubiquitinated proteins suggesting that alteration of protein homeostasis is a unique property of silica NPs. The nematode C. elegans represents an excellent model to investigate the effect of different types of nanomaterials on aging at the molecule, cell, and whole organism level.