A family of unusual immunoglobulin superfamily genes in an invertebrate histocompatibility complex.

Most colonial marine invertebrates are capable of allorecognition, the ability to distinguish between themselves and conspecifics. One long-standing question is whether invertebrate allorecognition genes are homologous to vertebrate histocompatibility genes. In the cnidarian Hydractinia symbiolongicarpus, allorecognition is controlled by at least two genes, Allorecognition 1 (Alr1) and Allorecognition 2 (Alr2), which encode highly polymorphic cell-surface proteins that serve as markers of self. Here, we show that Alr1 and Alr2 are part of a family of 41 Alr genes, all of which reside in a single genomic interval called the Allorecognition Complex (ARC). Using sensitive homology searches and highly accurate structural predictions, we demonstrate that the Alr proteins are members of the immunoglobulin superfamily (IgSF) with V-set and I-set Ig domains unlike any previously identified in animals. Specifically, their primary amino acid sequences lack many of the motifs considered diagnostic for V-set and I-set domains, yet they adopt secondary and tertiary structures nearly identical to canonical Ig domains. Thus, the V-set domain, which played a central role in the evolution of vertebrate adaptive immunity, was present in the last common ancestor of cnidarians and bilaterians. Unexpectedly, several Alr proteins also have immunoreceptor tyrosine-based activation motifs and immunoreceptor tyrosine-based inhibitory motifs in their cytoplasmic tails, suggesting they could participate in pathways homologous to those that regulate immunity in humans and flies. This work expands our definition of the IgSF with the addition of a family of unusual members, several of which play a role in invertebrate histocompatibility.

Jellyfish anaphylaxis: A wide spectrum of sensitization routes.

Background: Recent studies demonstrated that, in the past few years, the number of jellyfish species is increasing worldwide; this increase can be explained by environmental and climatic reasons. Contacts with jellyfish can cause acute and chronic effects, including allergic reactions. Although anaphylaxis caused by jellyfish is a rare event, repetitive stings during bathing as well as marine sports and job activities represent important risk factors that can increase the probability of sensitization. Recently, it was also pointed out the possibility of anaphylaxis caused by jellyfish ingestion. In these cases, the sensitization could also be related to previous stings. In cases in which there is no history of jellyfish contact or ingestion, it has been hypothesized that there is a sensitization to an unknown cross-reactive antigen. Objective: The purpose of this work was to collect and review published studies and cases of anaphylaxis associated with jellyfish. Methods: We performed a medical literature data base search, which included English language articles published until September 2019, by using the key words "jellyfish" associated with "anaphylaxis" or "anaphylactic shock." Results: The results of our research showed that dangerous reactions can be caused both by contact and ingestion. Moreover, the latest changes in food habits, life style, and globalization could lead to a more frequent exposure to jellyfish both by contact and ingestion, and, consequently, to a higher probability of sensitization. Conclusion: Prospective studies and well-structured research are needed to better understand all the potential immunologic elements of jellyfish, to clarify its role in sensitization, and to avoid possible dangerous allergic reactions caused by cross-reactivity.

The putative immune recognition repertoire of the model cnidarian Hydractinia symbiolongicarpus is large and diverse.

Immune recognition of molecular patterns from microorganisms or self-altered cells activate effector responses that neutralize and eliminate these potentially harmful agents. In virtually every metazoan group the process is carried out by pattern recognition receptors, typically constituted by immunoglobulin (Ig), leucine rich repeat (LRR), and/or lectin domains. In order to get insights into the ancestral immune recognition repertoire of animals, we have sequenced the transcriptome of bacterially challenged colonies of the model cnidarian Hydractinia symbiolongicarpus using the Illumina platform. Over 116,000 assembled contigs were annotated by sequence similarity, domain architecture, and functionally. From these, a subset of 315 unique transcripts was predicted as the putative immune recognition repertoire of H. symbiolongicarpus. Interestingly, canonical Toll-like receptors (TLR) were not predicted, nor any transmembrane protein with the Toll/interleukine-1 receptor (TIR) domain. Yet, a variety of predicted proteins with transmembrane domains associated with LRR ectodomains were identified, as well as homologs of the key transduction factor NF-kB, and its associated regulatory proteins. This also has been documented in Hydra, and suggests that recognition and signaling initiation has been decoupled in the TLR system of hydrozoans. In contrast, both canonical and non-canonical NOD-like receptors were identified in H. symbiolongicarpus, showing a higher diversity than the TLR system and perhaps a wider functional landscape. The collection of Ig-like containing putative immune recognition molecules was diverse, and included at least 26 unique membrane-bound predicted proteins and 88 cytoplasmic/secreted predicted molecules. In addition, 25 and 5 transcripts encoding the Ig-like containing allorecognition determinants ALR1 and ALR2, respectively, were identified. Sequence and phylogenetic analyses suggested the presence of various transcriptionally active alr loci, and the action of recombination-based mechanisms diversifying them. Transcripts encoding at least six lectin families with putative roles in immune recognition were found, including 19 unique C-type lectins and 21 unique rhamnose-binding lectins. Other predicted immune recognition receptors included scavenger receptors from three families, lipopolysaccharide-binding proteins, cell-adhesion molecules and thioester-bond containing proteins. This analysis demonstrated that the putative immune recognition repertoire of H. symbiolongicarpus is large and diverse.

Modulation of COUP-TF expression in a cnidarian by ectopic Wnt signalling and allorecognition.

BACKGROUND: COUP transcription factors are required for the regulation of gene expression underlying development, differentiation, and homeostasis. They have an evolutionarily conserved function, being a known marker for neurogenesis from cnidarians to vertebrates. A homologue of this gene was shown previously to be a neuronal and nematocyte differentiation marker in Hydra. However, COUP-TFs had not previously been studied in a colonial cnidarian. METHODOLOGY/PRINCIPAL FINDINGS: We cloned a COUP-TF homologue from the colonial marine cnidarian Hydractinia echinata. Expression of the gene was analysed during normal development, allorecognition events and ectopic Wnt activation, using in situ hybridisation and quantitative PCR. During normal Hydractinia development, the gene was first expressed in post-gastrula stages. It was undetectable in larvae, and its mRNA was present again in putative differentiating neurons and nematocytes in post-metamorphic stages. Global activation of canonical Wnt signalling in adult animals resulted in the upregulation of COUP-TF. We also monitored a strong COUP-TF upregulation in stolons undergoing allogeneic interactions. COUP-TF mRNA was most concentrated in the tissues that contacted allogeneic, non-self tissues, and decreased in a gradient away from the contact area. Interestingly, the gene was transiently upregulated during initial contact of self stolons, but dissipated rapidly following self recognition, while in non-self contacts high expression levels were maintained. CONCLUSIONS/SIGNIFICANCE: We conclude that COUP-TF is likely involved in neuronal/nematocyte differentiation in a variety of contexts. This has now been shown to include allorecognition, where COUP-TF is thought to have been co-opted to mediate allorejection by recruiting stinging cells that are the effectors of cytotoxic rejection of allogeneic tissue. Our findings that Wnt activation upregulates COUP-TF expression suggests that Wnts' role in neuronal differentiation could be mediated through COUP-TF.

Invertebrate allorecognition: the origins of histocompatibility.

Alloimmune specificity and histocompatibility, driven by genetic polymorphism, are ancient determinants of self-/non-self-recognition. Recent molecular genetic evidence has revealed an allodeterminant in the cnidarian Hydractinia that consistently predicts histocompatibility reactions.

A hypervariable invertebrate allodeterminant.

Colonial marine invertebrates, such as sponges, corals, bryozoans, and ascidians, often live in densely populated communities where they encounter other members of their species as they grow over their substratum. Such encounters typically lead to a natural histocompatibility response in which colonies either fuse to become a single, chimeric colony or reject and aggressively compete for space. These allorecognition phenomena mediate intraspecific competition, support allotypic diversity, control the level at which selection acts, and resemble allogeneic interactions in pregnancy and transplantation. Despite the ubiquity of allorecognition in colonial phyla, however, its molecular basis has not been identified beyond what is currently known about histocompatibility in vertebrates and protochordates. We positionally cloned an allorecognition gene by using inbred strains of the cnidarian, Hydractinia symbiolongicarpus, which is a model system for the study of invertebrate allorecognition. The gene identified encodes a putative transmembrane receptor expressed in all tissues capable of allorecognition that is highly polymorphic and predicts allorecognition responses in laboratory and field-derived strains. This study reveals that a previously undescribed hypervariable molecule bearing three extracellular domains with greatest sequence similarity to the immunoglobulin superfamily is an allodeterminant in a lower metazoan.

A gene family of putative immune recognition molecules in the hydroid Hydractinia.

Animal taxa display a wide array of immune-type receptors that differ in their specificities, diversity, and mode of evolution. These molecules ensure effective recognition of potential pathogens for subsequent neutralization and clearance. We have characterized a family of putative immune recognition molecules in the colonial hydroid Hydractinia symbiolongicarpus. A complementary DNA fragment with high similarity to the sea urchin L: -rhamnose-binding lectin was isolated and used to screen 9.5 genome equivalents of a H. symbiolongicarpus bacterial artificial chromosome library. One of the resulting 19 positive clones was sequenced and revealed the presence of a 5,111-bp gene organized in 13 exons and 12 introns. The gene was predicted to encode a 726-amino acid secreted modular protein composed of a signal peptide, an anonymous serine-rich domain, eight thrombospondin type 1 repeats, and a L: -rhamnose-binding lectin domain. The molecule was thus termed Rhamnospondin (Rsp). Southern hybridization and sequence analyses indicated the presence of a second Rsp gene. The cDNA from both Rsp genes was sequenced in 18 individuals, revealing high levels of genetic polymorphism. Nucleotide substitutions were distributed throughout the molecule and showed a significantly higher number of synonymous substitutions per synonymous sites than its nonsynonymous counterparts. Whole-mount in situ hybridization and semi-quantitative reverse transcription polymerase chain reaction of microorganism-challenged colonies indicated that Rsp molecules were specifically and constitutively expressed in the hypostome of gastrozooids' mouth. Thus, the combination of (1) comparative analysis on domain composition and function, (2) polymorphism, and (3) expression patterns, suggest that Rsp genes encode a family of putative immune recognition receptors, which may act by binding microorganisms invading the colony through the polyp's mouth.

Structural but not functional conservation of an immune molecule: a tachylectin-like gene in Hydractinia.

Tachylectin-related proteins are a recently characterized group of pattern recognition molecules, functioning in the innate immunity of various animals, from the ancient sponges to vertebrates. Tachylectins are characterized by six internal tandem repeats forming beta-propeller domains. We have identified and characterized a tachylectin-related gene in the colonial marine hydroid, Hydractinia echinata. The predicted gene product, termed CTRN, contained an N-terminal signal peptide and had a well-conserved tachylectin-like structure. RT-PCR analyses revealed only post-metamorphic expression while no mRNA was detected during embryonic development or in planula larvae. Exposure of colonies to LPS under conditions known to activate an immune response in Hydractinia did not result in upregulation of the gene. In situ hybridization analysis of metamorphosed animals detected CTRN transcripts only in a small subpopulation of neurons and their precursor cells, localized in a ring-like structure around the mouth of polyps. The same ring-like structure of CTRN expressing neurons was also observed in young polyp buds, predicting the position of the future mouth. This type of expression pattern can hardly be attributed to an immune-relevant gene. Thus, despite high structural similarity to tachylectins, this cnidarian member of this group seems to be an exception to all other tachylectins identified so far as it seems to have no function in cnidarian innate immunity.

A putative double role of a chitinase in a cnidarian: pattern formation and immunity.

Chitinases are enzymes that degrade chitin, the second most abundant polymer in nature. They are ubiquitous among living organisms where they play a role in development, food-digestion and innate immunity. We have cloned and characterized the first cnidarian chitinase cDNA from the hydroid Hydractinia. The Hydractinia chitinase exhibits a typical secreted family 18 hydrolases primary structure. In situ hybridization and RT-PCR experiments showed that it is exclusively expressed in ectodermal tissues of the animal, only following metamorphosis while undetectable in embryonic and larval stages. Most prominent expression was observed in the stolonal compartment of colonies, structures that are covered by a chitinous periderm. Chitinase mRNA was detected in new branching points along stolons and in hyperplastic stolons indicating a role of the enzyme in pattern formation and allorecognition. It was also expressed in polyps where it was mostly restricted to their basal portion. This expression pattern suggests that HyChit1 also fulfills a role in host defense, probably against fungal and nematode pathogens. Endodermal expression of HyChit1 has never been observed, suggesting that the enzyme does not participate in food-digestion.

Self-discrimination in colonial invertebrates: genetic control of allorecognition in the hydroid Hydractinia.

Sessile, colonial invertebrates display the ability to distinguish between their own tissues and those of unrelated members of the same species. These allorecognition responses play a fundamental role in maintaining the genetic and physiological integrity of the colony. While allorecognition responses have been observed in all major colonial invertebrate taxa, the genetics of the response has been addressed only in the ascidian Botryllus and, more recently, in the hydroid Hydractinia. In Botryllus, allorecognition is controlled by a single co-dominant locus. This review focuses on current developments on the genetics of allorecognition in Hydractinia.

Isolation of hybridomas secreting monoclonal antibodies against Physalia physalis (Portuguese man-o'war) nematocyst venom.

Balb/C mice were immunized with crude Portuguese Man-O'War (Physalia physalis) nematocyst venom and their spleen immunocytes were fused with plasmacytoma cells. Nine hybridomas which produced IgG specific for Man-O'War venom were identified using a specific ELISA technique. Ammonium sulfate and DEAE cellulose-purified monoclonal anti-venom antibody had an ELISA titer of 1:4000 and an ability to neutralize the lethal activity (4 LD50/0.6 ml ascites fluid) of an i.v. challenge of crude venom. Indirect immunofluorescence testing demonstrated that the monoclonal antibody isolated in these experiments reacted against a venom component located in the nematocyst wall and thread.