Péter Engelmann

Earthworms and humans in vitro: characterizing evolutionarily conserved stress and immune responses to silver nanoparticles

Little is known about the potential threats of silver nanoparticles (AgNPs) to ecosystem health, with no detailed report existing on the stress and immune responses of soil invertebrates. Here we use earthworm primary cells, cross-referencing to human cell cultures with a particular emphasis on the conserved biological processes, and provide the first in vitro analysis of molecular and cellular toxicity mechanisms in the earthworm Eisenia fetida exposed to AgNPs (83 ± 22 nm). While we observed a clear difference in cytotoxicity of dissolved silver salt on earthworm coelomocytes and human cells (THP-1 cells, differentiated THP-1 cells and peripheral blood mononuclear cells), the coelomocytes and differentiated (macrophage-like) THP-1 cells showed a similar response to AgNPs. Intracellular accumulation of AgNPs in the coelomocytes, predominantly in a phagocytic population, was evident by several methods including transmission electron microscopy. Molecular signatures of oxidative stress and selected biomarker genes probed in a time-resolved manner suggest early regulation of oxidative stress genes and subsequent alteration of immune signaling processes following the onset of AgNP exposure in the coelomocytes and THP-1 cells. Our findings provide mechanistic clues on cellular innate immunity toward AgNPs that is likely to be evolutionarily conserved across the animal kingdom.

Earthworm leukocyte populations specifically harbor lysosomal enzymes that may respond to bacterial challenge

Earthworm leukocytes (coelomocytes) are responsible for innate cellular immune functions such as phagocytosis and encapsulation against parasites and pathogens. Microbial killing results from the combined action of the phagocytic process with humoral immune factors such as agglutinins (e.g., lectins), lysosomal enzymes (e.g., acid phosphatase, lysozyme), and various cytotoxic and antimicrobial molecules. There is also evidence of weak adaptive immune responses against foreign transplants. This study focused on aspects of the innate immune response. First, anti-human acid phosphatase (anti-AcP) polyclonal antibody characterized different acid hydrolase patterns in coelomocytes. Second, flow cytometry identified a strongly immunoreactive coelomocyte population. Third, ultrastructural and cytochemical analyses revealed acid phosphatase in discrete granules (lysosomes) of effector hyaline and granular coelomocytes but not in mature chloragocytes. Coelomocytes were exposed to bacteria to assess how phagocytosis influences: (a) the production of acid phosphatase using Western blot, and (b) release of acid phosphatase using ELISA from cell-free coelomic fluid. Fourth, after phagocytosis, acid phosphatase levels differed between controls and experimentals. Fifth, we found a 39-kDa molecule that reacted intensely with anti-AcP. Our results suggest that effector earthworm coelomocytes may not eliminate pathogens only by phagocytosis but also by extracellular lysis.

Earthworm leukocytes react with different mammalian antigen-specific monoclonal antibodies.

We identified conserved molecules (enzymes, peptides, cytokines) that might play a role in invertebrate innate immunity. We found these molecules by immunoserological and immunohistochemical methods in association with coelomocytes, leukocytes located in the coelomic cavity of the earthworm Eisenia foetida. We detected the enzyme Cu-Zn-superoxide-dismutase (SOD), cytokines (tumor necrosis factor-alpha, TNFalpha; transforming growth factor-alpha, TGFalpha; and alpha peptide hormone, thyreotrope stimulating hormone, TSH) in earthworm coelomocytes with monoclonal antibodies developed originally against human and/or mouse antigens. Three coelomocyte subpopulations were identified according to their form, size and granularity by microscopic and flow cytometric analysis. These cell populations showed different reactivity with antibodies against mammalian cell surface (CD) markers and different intracellular antigens. Two coelomocyte types showed cell surface positivity with anti-Thy-1 (CD90), CD24 and TNF-alpha antibodies. Strong cytoplasmic reaction was shown with anti-TNF-alpha and anti-SOD mAbs and a weaker but unambiguous reaction with thyroid stimulating hormone (TSH) in two cell populations. The third population was negative for all of the monoclonal antibodies. Our flow cytometric results were confirmed by confocal microscopy both on the cell surfaces and intracellularly.

Species Differences Take Shape at Nanoparticles: Protein Corona Made of the Native Repertoire Assists Cellular Interaction

Cells recognize the biomolecular corona around a nanoparticle, but the biological identity of the complex may be considerably different among various species. This study explores the importance of protein corona composition for nanoparticle recognition by coelomocytes of the earthworm Eisenia fetida using E. fetida coelomic proteins (EfCP) as a native repertoire and fetal bovine serum (FBS) as a non-native reference. We have profiled proteins forming the long-lived corona around silver nanoparticles (75 nm OECD reference materials) and compared the responses of coelomocytes to protein coronas preformed of EfCP or FBS. We find that over time silver nanoparticles can competitively acquire a biological identity native to the cells in situ even in non-native media, and significantly greater cellular accumulation of the nanoparticles was observed with corona complexes preformed of EfCP (p < 0.05). An EfCP-nanoparticle mimicry made with a recombinant protein, lysenin, revealed its critical contribution in the observed cell-nanoparticle response. This confirms the determinant role of the recognizable biological identity during invertebrate in vitro testing of nanoparticles. Our finding shows a case of species-specific formation of biomolecular coronas, and this suggests that the use of representative species may need careful consideration in assessing the risks associated with nanoparticles.

Revising lysenin expression of earthworm coelomocytes

Lysenin is a species-specific bioactive molecule of Eisenia andrei earthworms. This protein is a potent antimicrobial factor; however its cellular expression and induction against pathogens are still not fully understood. We developed a novel monoclonal antibody against lysenin and applied this molecular tool to characterize its production and antimicrobial function. We demonstrated by flow cytometry and immunocytochemistry that one subgroup of earthworm immune cells (so called coelomocytes), the chloragocytes expressed the highest amount of lysenin. Then, we compared lysenin expression with earlier established coelomocyte (EFCC) markers. In addition, we determined by immunohistology of earthworm tissues that lysenin production is only restricted to free-floating chloragocytes. Moreover, we observed that upon in vitro Staphylococcus aureus but not Escherichia coli challenged coelomocytes over-expressed and then secreted lysenin. These results indicate that among subpopulations of coelomocytes, lysenin is mainly produced by chloragocytes and its expression can be modulated by Gram-positive bacterial exposure.

Calcium is required for coelomocyte activation in earthworms

The role of calcium signaling in activation of both innate and adaptive immunity is basically important, however, the evolutionary aspects are not clarified yet. Currently limited data are available about calcium levels of coelomocytes, cellular mediators of earthworm immunity. We aimed to observe basal and induced Ca(2+) levels of coelomocyte subgroups after various stimulations in Eisenia fetida and Allolobophora caliginosa using a Ca(2+)-sensitive dye. E. fetida chloragocytes had the highest basal Ca(2+) levels among subpopulations; however there was no detectable Ca(2+) influx after any stimuli, while coelomocytes showed strong Ca(2+) increase after ionomycin treatment, which could be attenuated using phorbol ester. A. caliginosa coelomocytes showed a weak response to ionophore, while chloragocytes, similar to those in E. fetida, exhibited no changes after this stimulation. Intracellular calcium is mainly stored in the endoplasmic reticulum of coelomocytes as proved by thapsigargin treatments. Among several mitogens only phytohemagglutinin caused increased Ca(2+) level in E. fetida coelomocytes, but not in A. caliginosa coelomocytes. Moreover, the chemoattractant fMLP revealed calcium influx of Eisenia coelomocytes. For the first time we observed various basal Ca(2+) levels and sensibility to Ca(2+) influx inducers (including mitogens and chemoattractant) of coelomocyte subgroups using flow cytometry. These observations suggest that Ca(2+) influx and signal transduction may play crucial roles in the innate immunity of the earthworm.

Characterization of human invariant natural killer T cells expressing FoxP3

Recently described forkhead box protein 3 (FoxP3) transcription factor is a key molecule in CD4+ CD25hi+ T-cell characterization. Invariant NK T (iNKT) cells are also characterized as regulatory cells modulating the immune response by rapidly producing T(h)1 and T(h)2 cytokines. We aimed to analyze cellular markers important in regulatory features of human iNKT cells and to study their role in functional assays. iNKT cells were single cell sorted from peripheral mononuclear cells of healthy individuals after immunostaining of invariant TCR α-chain. We found FoxP3 expression in human iNKT clones. Randomly selected iNKT cell clones (CD4+, double negative, CD8+) expressed FoxP3 mRNA and protein at different levels upon stimulation as supported by various approaches. FoxP3 mRNA and protein expression was detected in unstimulated iNKT cells as well. Furthermore, different stimulations changed the FoxP3 expression in iNKT cells over time and the most dramatic changes were observed upon anti-CD3 stimulation. Both the supernatant of iNKT cells and iNKT cells themselves exerted similar stimulation effects on PBMC proliferation in functional assays and these stimulations showed a negative correlation with FoxP3 expression. Our data indicate that the FoxP3 expression in iNKT cells may be a key transcriptional factor in controlling the regulatory function of the iNKT cells.

Earthworm Innate Immune System

Nonself recognition is the basis of innate and adaptive immune responses and it depends on immune receptors. Caenorhabditis elegans and Drosophila animal models have added ample information to define molecular homology especially at the level of signal transduction. Yet, it is unwise to generalize about the immune system/signaling mechanisms of all invertebrates based upon two species. Other invertebrate species (mollusks and annelids) have also evolved effective innate immune responses, although those might have more unique pathways than other more popular and better studied species. We analyzed cellular immune responses in earthworms, and began to identify conserved signal molecules relative to MAP kinase pathways. These pathways appear at every level of evolution suggesting ubiquitous roles in various biological processes (differentiation, adaptation, stress response, apoptosis) including immunity. Analysis of seemingly less complex invertebrate immune systems can provide useful information with putative applications to more complex vertebrate immune system and to the evolution of immune response, including regulation of signaling systems in innate immunity. This knowledge can also help to identify and characterize new bioactive molecules with possible therapeutic use both in human and veterinary medicine.

Nanosilver pathophysiology in earthworms: Transcriptional profiling of secretory proteins and the implication for the protein corona

Abstract Previously we have identified lysenin as a key protein constituent of the secretome from Eisenia fetida coelomocytes and revealed its critical importance in priming interactions between the cells and the protein corona around nanosilver. As alterations of the protein environment can directly affect the corona composition, the extent to which nanoparticles influence the cells’ protein secretion profile is of remarkable interest that has rarely acquired attention. Here, we have probed transcriptional responses of E. fetida coelomocytes to the representative nanosilver NM-300K (15 nm) in a time-dependent manner (2, 4, 8 and 24 h at a low-cytotoxic concentration), and examined the implication of the temporal changes in transcriptional profiles of secretory proteins with a particular reference to that of lysenin. NM-300K was accumulated in/at the cells and lysenin was, after transient induction, gradually suppressed over time indicating a negative feedback cycle. This may limit further enrichment of lysenin in the corona and thereby decrease the lysenin-assisted uptake of the nanoparticles. Other differentially expressed genes were those involved in metal stress (likewise in AgNO3-stressed cells) and in Toll-like receptor (TLR) signaling. This offers an intriguing perspective of the nanosilver pathophysiology in earthworms, in which the conserved pattern recognition receptor TLRs may play an effector role.

Pituitary Adenylate Cyclase-activating Polypeptide-like Compounds Could Modulate the Activity of Coelomocytes in the Earthworm

By means of radioimmunoassay, we studied the concentration of pituitary adenylate cyclase‐activating polypeptide (PACAP)‐like proteins in intact and regenerating earthworms. Transection of animals increased the concentration of PACAP‐like compounds in coelomocytes, and a decreasing rostrocaudal gradient was detected in the regenerating animals. Western blot analysis revealed a range of PAC1‐receptor proteins with molecular weights from 40 to 80 kDa. Electron microscopic immunocytochemistry showed that PAC1 receptors were located on distinct sets of coelomocytes (mainly on amebocytes and on some granulocytes). Based on our results we hypothesize a link between PACAP and coelomocytes, suggesting that PACAP modulates the function of amebocytes and certain granulocytes that play a role in tissue remodeling of regenerating earthworms.