Petra Procházková

Identification and cloning of an invertebrate-type lysozyme from Eisenia andrei.

Lysozyme is a widely distributed antimicrobial protein having specificity for cleaving the beta-(1,4)-glycosidic bond between N-acetylmuramic acid (NAM) and N-acetylglucosamine (GlcNAc) of peptidoglycan of the bacterial cell walls and thus efficiently contributes to protection against infections caused mainly by Gram-positive bacteria. In the present study, we assembled a full-length cDNA of a novel invertebrate-type lysozyme from Eisenia andrei earthworm (EALys) by RT-PCR and RACE system. The primary structure of EALys shares high homology with other invertebrate lysozymes; however the highest, 72% identity, was shown for the destabilase I isolated from medicinal leech. Recombinant EALys expressed in Escherichia coli exhibited the lysozyme and isopeptidase activity. Moreover, real-time PCR revealed increased levels of lysozyme mRNA in coelomocytes of E. andrei after the challenge with both Gram-positive and Gram-negative bacteria.

Evidence for proteins involved in prophenoloxidase cascade Eisenia fetida earthworms

The prophenoloxidase cascade represents one of the most important defense mechanisms in many invertebrates. Following the recognition of microbial saccharides by pattern recognition molecules, proteinases cleave inactive prophenoloxidase to its active form, phenoloxidase. Phenoloxidase is a key enzyme responsible for the catalysis of the melanization reaction. Final product melanin is involved in wound healing and immune responses. Prophenoloxidase cascade has been widely described in arthropods; data in other invertebrate groups are less frequent. Here we show detectable phenoloxidase activity in 90-kDa fraction of the coelomic fluid of earthworms Eisenia fetida. Amino acid sequencing of peptides from the active fraction revealed a partial homology with invertebrate phenoloxidases and hemocyanins. Moreover, the level of phenoloxidase activity is lower and the activation slower as compared to other invertebrates.

Molecular cloning and expression of TLR in the Eisenia andrei earthworm.

Toll-like receptors (TLRs) play an important role in defense responses to pathogens in invertebrates. Here we characterize the first TLR isolated from an oligochaete annelid, namely, Eisenia andrei (EaTLR) and show its expression pattern. The full-length EaTLR cDNA consists of 2615 bp encoding a putative protein of 675 amino acids. The predicted amino acid sequence comprises of an extracellular domain containing 31 amino acid signal peptide and seven leucine-rich repeats (LRR), capped with cysteine-rich N- and C-terminal LRRs followed by a transmembrane domain and cytoplasmic Toll/IL-1R domain (TIR). TIR domains of twenty individual earthworms were sequenced and the variability suggesting the presence of a high number of TLR genes in the genome of E. andrei was observed. Phylogenetic analysis revealed the highest similarity of EaTLR with polychaete annelid, Capitella teleta and TLRs of mollusks and echinoderms. Finally, the highest constitutive expression of EaTLR was observed in the digestive tract. Gene expression was significantly increased in coelomocytes of E. andrei after the challenge with Gram-positive bacteria.

The Invertebrate Immune System as a Model for Investigating the Environmental Impact of Nanoparticles

Invertebrates lack an adaptive immunity; however, they are endowed with a potent and complex innate immune system similar to that of vertebrates. In most invertebrates, free circulating cells (hemocytes) are responsible for cell-mediated immunity; when activated, different hemocyte types are capable of phagocytosis, reactive oxygen species and NO production, release of hydrolytic enzymes and antimicrobial peptides. Conservation of the general mechanisms of innate immunity from invertebrates to mammals is useful for the evaluation of the environmental impact of nanoparticles. The mechanisms of innate immunity in two model representatives of aquatic (bivalves) and terrestrial (earthworms) environments are summarized, and data supporting the view that cell-mediated immunity can represent the primary target of nanoparticles in invertebrates are presented. The evaluation of immune parameters in invertebrate models may represent a powerful tool for the rapid screening of the immunomodulatory effects of nanoparticles and may provide a basis for designing environmentally safer nanomaterials.

Microbial environment affects innate immunity in two closely related earthworm species Eisenia andrei and Eisenia fetida.

Survival of earthworms in the environment depends on their ability to recognize and eliminate potential pathogens. This work is aimed to compare the innate defense mechanisms of two closely related earthworm species, Eisenia andrei and Eisenia fetida, that inhabit substantially different ecological niches. While E. andrei lives in a compost and manure, E. fetida can be found in the litter layer in forests. Therefore, the influence of environment-specific microbiota on the immune response of both species was followed. Firstly, a reliable method to discern between E. andrei and E. fetida based on species-specific primers for cytochrome c oxidase I (COI) and stringent PCR conditions was developed. Secondly, to analyze the immunological profile in both earthworm species, the activity and expression of lysozyme, pattern recognition protein CCF, and antimicrobial proteins with hemolytic function, fetidin and lysenins, have been assessed. Whereas, CCF and lysozyme showed only slight differences in the expression and activity, fetidin/lysenins expression as well as the hemolytic activity was considerably higher in E. andrei as compared to E. fetida. The expression of fetidin/lysenins in E. fetida was not affected upon the challenge with compost microbiota, suggesting more substantial changes in the regulation of the gene expression. Genomic DNA analyses revealed significantly higher level of fetidin/lysenins (determined using universal primer pairs) in E. andrei compared to E. fetida. It can be hypothesized that E. andrei colonizing compost as a new habitat acquired an evolutionary selection advantage resulting in a higher expression of antimicrobial proteins.

The effect of dibenzo-p-dioxin- and dibenzofuran-contaminated soil on the earthworm Eisenia andrei

Polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs) belong to the group of persistent organic pollutants, highly toxic environmental pollutants that include hydrophobic compounds with the tendency to bioaccumulate. Earthworms (Eisenia andrei) were exposed to PCDD/Fs-contaminated soil, and changes in their lipophilic structures and the gene expression of their defense molecules were followed. Damage to the intestinal wall and adjacent chloragogenous tissue was observed. Further, the up-regulation of the expression of several genes was detected. On the basis of these results, the mechanism of the impact of PCDD/Fs on earthworms has been proposed. Dioxins that accumulate in the lipophilic structures cause an increase in reactive oxidative species that triggers oxidative stress followed by the gene expression of two molecules that play a role in protection against oxidant toxicity, calreticulin (CRT) and Hsp70. Moreover, the effect of microbial biomass on the expression of coelomic cytolytic factor (CCF), a pattern recognition receptor, was also observed.

Sensing microorganisms in the gut triggers the immune response in Eisenia andrei earthworms

The tube-within-tube body plan of earthworms is appropriate for studying the interactions of microorganisms with the immune system of body cavities such as the digestive tract and coelom. This study aims to describe the immune response on the molecular and cellular level in the coelomic cavity and the gut of the earthworm Eisenia andrei after experimental microbial challenge by administering two bacterial strains (Escherichia coli and Bacillus subtilis) or yeast Saccharomyces cerevisiae to the environment. The changes in mRNA levels of defense molecules (pattern recognition receptor CCF, lysozyme, fetidin/lysenins) in the coelomocytes and gut tissue were determined by quantitative PCR. The immune response at a cellular level was captured in histological sections, and the expression of CCF was localized using in situ hybridization. Coelomocytes respond to the presence of bacteria in the coelomic cavity by increasing the mRNA levels of defense molecules, especially CCF. The immune response in gut tissue is less affected by microbial stimulation because the epithelial cells of gut exhibit basically strong mRNA synthesis of ccf as a defense against the continuous microbial load in the gut lumen. The cellular immune response is mediated by coelomocytes released from the mesenchymal lining of the coelomic cavity. These combined immune mechanisms are necessary for the survival of earthworms in the microbially rich environment of soil.

Correlation between the activity of digestive enzymes and nonself recognition in the gut of Eisenia andrei earthworms

Earthworms Eisenia andrei, similarly to other invertebrates, rely on innate defense mechanisms based on the capability to recognize and respond to nonself. Here, we show a correlation between the expression of CCF, a crucial pattern-recognition receptor, and lysozyme, with enzyme activities in the gut of E. andrei earthworms following a microbial challenge. These data suggest that enzyme activities important for the release and recognition of molecular patterns by pattern-recognition molecules, as well as enzymes involved in effector pathways, are modulated during the microbial challenge. In particular, protease, laminarinase, and glucosaminidase activities were increased in parallel to up-regulated CCF and lysozyme expression.

Annelida: Environmental Interactions and Ecotoxicity in Relation to the Earthworm Immune System

Earthworms live in microbial-rich habitats populated with various bacteria, fungi, protozoa, and other organisms. Thus, soil represents an environment with high antigenic pressure, and earthworms have developed potent defense mechanisms. Besides the abundant microbiota, earthworms are also highly influenced by various types of organic and inorganic pollutants and by the nanoparticles that reach the soil system. These contaminants affect earthworm physiology and their ability to reproduce, grow, and survive. As a result, earthworms are well suited for the monitoring soil contamination.

Annelida: Recognition of Nonself in Earthworms

Earthworms belonging to oligochaete annelids became an important model for comparative immunologists in the early 1960s with the publication of transplantation experimental results reporting that autologous transplants of earthworm body wall pieces were accepted, but xenograft or even allografts were not. These transplantation experiments proved the existence of self or nonself recognition in earthworms, paving the way for extensive studies on the earthworm immune mechanisms that evolved to prevent the invasion of pathogens. In 1989 Charles Janeway, Jr., published a general concept based on the existence of pattern recognition receptors (PRRs) on the immune cells that recognize and bind conserved molecular structures of microorganisms known as pathogen-associated molecular patterns and thus trigger the immune response to potential pathogens. In the present review, the structure, specificity, and expression profile of PRRs characterized in earthworms are discussed and their role in innate defense suggested.