Evolution of polydom-like molecules: identification and characterization of cnidarian polydom (Cnpolydom) in the basal metazoan Hydractinia

The Hydractinia allorecognition system

Hydractinia symbiolongicarpus is a colonial hydroid and a long-standing model system for the study of invertebrate allorecognition. The Hydractinia allorecognition system allows colonies to discriminate between their own tissues and those of unrelated conspecifics that co-occur with them on the same substrate. This recognition mediates spatial competition and mitigates the risk of stem cell parasitism. Here, I review how we have come to our current understanding of the molecular basis of allorecognition in Hydractinia. To date, two allodeterminants have been identified, called Allorecognition 1 (Alr1) and Allorecognition 2 (Alr2), which occupy a genomic region called the allorecognition complex (ARC). Both genes encode highly polymorphic cell surface proteins that are capable of homophilic binding, which is thought to be the mechanism of self/non-self discrimination. Here, I review how we have come to our current understanding of Alr1 and Alr2. Although both are members of the immunoglobulin superfamily, their evolutionary origins remain unknown. Moreover, existing data suggest that the ARC may be home to a family of Alr-like genes, and I speculate on their potential functions.

Cleaner wrasse indirectly affect the cognitive performance of a damselfish through ectoparasite removal

Cleaning organisms play a fundamental ecological role by removing ectoparasites and infected tissue from client surfaces. We used the well-studied cleaning mutualisms involving the cleaner wrasse, Labroides dimidiatus, to test how client cognition is affected by ectoparasites and whether these effects are mitigated by cleaners. Ambon damselfish (Pomacentrus amboinensis) collected from experimental reef patches without cleaner wrasse performed worse in a visual discrimination test than conspecifics from patches with cleaners. Endoparasite abundance also negatively influenced success in this test. Visual discrimination performance was also impaired in damselfish experimentally infected with gnathiid (Crustacea: Isopoda) ectoparasites. Neither cleaner absence nor gnathiid infection affected performance in spatial recognition or reversal learning tests. Injection with immune-stimulating lipopolysaccharide did not affect visual discrimination performance relative to saline-injected controls, suggesting that cognitive impairments are not due to an innate immune response. Our results highlight the complex, indirect role of cleaning organisms in promoting the health of their clients via ectoparasite removal and emphasize the negative impact of parasites on host's cognitive abilities.

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.

Transcriptomes and expression profiling of deep-sea corals from the Red Sea provide insight into the biology of azooxanthellate corals

Despite the importance of deep-sea corals, our current understanding of their ecology and evolution is limited due to difficulties in sampling and studying deep-sea environments. Moreover, a recent re-evaluation of habitat limitations has been suggested after characterization of deep-sea corals in the Red Sea, where they live at temperatures of above 20 °C at low oxygen concentrations. To gain further insight into the biology of deep-sea corals, we produced reference transcriptomes and studied gene expression of three deep-sea coral species from the Red Sea, i.e. Dendrophyllia sp., Eguchipsammia fistula, and Rhizotrochus typus. Our analyses suggest that deep-sea coral employ mitochondrial hypometabolism and anaerobic glycolysis to manage low oxygen conditions present in the Red Sea. Notably, we found expression of genes related to surface cilia motion that presumably enhance small particle transport rates in the oligotrophic deep-sea environment. This is the first study to characterize transcriptomes and in situ gene expression for deep-sea corals. Our work offers several mechanisms by which deep-sea corals might cope with the distinct environmental conditions present in the Red Sea As such, our data provide direction for future research and further insight to organismal response of deep-sea coral to environmental change and ocean warming.

Polydom Is an Extracellular Matrix Protein Involved in Lymphatic Vessel Remodeling

RATIONALE

Lymphatic vasculature constitutes a second vascular system essential for immune surveillance and tissue fluid homeostasis. Maturation of the hierarchical vascular structure, with a highly branched network of capillaries and ducts, is crucial for its function. Environmental cues mediate the remodeling process, but the mechanism that underlies this process is largely unknown.

OBJECTIVE

Polydom (also called Svep1) is an extracellular matrix protein identified as a high-affinity ligand for integrin α9β1. However, its physiological function is unclear. Here, we investigated the role of Polydom in lymphatic development.

METHODS AND RESULTS

We generated Polydom-deficient mice. Polydom^-/- mice showed severe edema and died immediately after birth because of respiratory failure. We found that although a primitive lymphatic plexus was formed, it failed to undergo remodeling in Polydom^-/- embryos, including sprouting of new capillaries and formation of collecting lymphatic vessels. Impaired lymphatic development was also observed after knockdown/knockout of polydom in zebrafish. Polydom was deposited around lymphatic vessels, but secreted from surrounding mesenchymal cells. Expression of Foxc2 (forkhead box protein c2), a transcription factor involved in lymphatic remodeling, was decreased in Polydom^-/- mice. Polydom bound to the lymphangiogenic factor Ang-2 (angiopoietin-2), which was found to upregulate Foxc2 expression in cultured lymphatic endothelial cells. Expressions of Tie1/Tie2 receptors for angiopoietins were also decreased in Polydom^-/- mice.

CONCLUSIONS

Polydom affects remodeling of lymphatic vessels in both mouse and zebrafish. Polydom deposited around lymphatic vessels seems to ensure Foxc2 upregulation in lymphatic endothelial cells, possibly via the Ang-2 and Tie1/Tie2 receptor system.

RESOLUCIÓN DE CONFLICTOS AL INTERIOR DEL ORGANISMO: EL PAPEL DEL SISTEMA INMUNE

<p>El sistema inmune de los animales está constituido por una gran variedad de células y moléculas que colectivamente reconocen, neutralizan y eliminan potenciales agentes nocivos, tanto bióticos como abióticos. El estudio del sistema inmune ha estado tradicionalmente sesgado hacía algunas especies de importancia médica o económica, a expensas de la gran mayoría de especies que constituyen la diversidad animal. Con la actual facilidad de secuenciar genomas y transcriptomas, se ha abierto la posibilidad de estudiar los sistemas inmunes de muy variados grupos animales. Uno de estos grupos es los cnidarios, que incluye a los corales, anémonas y medusas, en los que el estudio del sistema inmune ha probado ser de gran utilidad para entender dos tipos de conflictos de relevancia en la supervivencia de estos organismos. El primero es la respuesta de los corales a enfermedades de carácter infeccioso y el segundo hace referencia a las reacciones de histocompatibilidad que median la competencia intraespecífica por el espacio habitable. Este artículo de reflexión trata en detalle el papel del sistema inmune de los cnidarios en la resolución de estos conflictos.</p><p> </p><p>Abstract</p><p>The immune system of animals is constituted by a large diversity of cells and molecules that collectively recognize, neutralize, and eliminate potential damaging agents, both biotic and abiotic. The study of the immune system has been traditionally biased towards some species with medical or economic importance, at the expense of the vast majority of species that constitute the animal diversity. With the current possibility of easily sequencing genomes and transcriptomes, there is an opportunity to study the immune systems of a wide variety of animal groups. One of these groups is the cnidarians, which include corals, anemones and jellyfishes, in which the study of the immune system has proved useful to understand two types of conflicts that are relevant for the survival of these organisms. The first one is the response of corals to diseases of infectious nature and the second relates to histocompatibility reactions, which mediate intraspecific competitions for habitable space. This article details the role of the cnidarian immune system to mediate the resolution of these two conflicts.</p><p> </p>

Changes in protein expression of pacific oyster Crassostrea gigas exposed in situ to urban sewage

The composition and concentration of substances in urban effluents are complex and difficult to measure. These contaminants elicit biological responses in the exposed organisms. Proteomic analysis is a powerful tool in environmental toxicology by evidencing alterations in protein expression due to exposure to contaminants and by providing a useful framework for the development of new potential biomarkers. The aim of this study was to determine changes in protein expression signatures (PES) in the digestive gland of oysters Crassostrea gigas transplanted to two farming areas (LIS and RIB) and to one area contaminated by sanitary sewage (BUC) after 14 days of exposure. This species is one of the most cultivated molluscs in the world. The identified proteins are related to the cytoskeleton (CKAP5 and ACT2), ubiquitination pathway conjugation (UBE3C), G protein-coupled receptor and signal transduction (SVEP1), and cell cycle/division (CCNB3). CKAP5 showed higher expression in oysters kept at BUC in comparison with those kept at the farming areas, while ACT2, UBE3C, SVEP1, and CCNB3 were suppressed. The results suggest that these changes might lead to DNA damage, apoptosis, and interference with the immune system in oyster C. gigas exposed to sewage and give initial information on PES of C. gigas exposed to sanitary sewage, which can subsequently be useful in the development of more sensitive tools for biomonitoring coastal areas, particularly those devoted mainly to oyster farming activities.

Mechanisms of the epithelial-to-mesenchymal transition in sea urchin embryos

Sea urchin mesenchyme is composed of the large micromere-derived spiculogenetic primary mesenchyme cells (PMC), veg2-tier macromere-derived non-spiculogenetic mesenchyme cells, the small micromere-derived germ cells, and the macro- and mesomere-derived neuronal mesenchyme cells. They are formed through the epithelial-to-mesenchymal transition (EMT) and possess multipotency, except PMCs that solely differentiate larval spicules. The process of EMT is associated with modification of epithelial cell surface property that includes loss of affinity to the apical and basal extracellular matrices, inter-epithelial cell adherens junctions and epithelial cell surface-specific proteins. These cell surface structures and molecules are endocytosed during EMT and utilized as initiators of cytoplasmic signaling pathways that often initiate protein phosphorylation to activate the gene regulatory networks. Acquisition of cell motility after EMT in these mesenchyme cells is associated with the expression of proteins such as Lefty, Snail and Seawi. Structural simplicity and genomic database of this model will further promote detailed EMT research.

RNA-seq profiles of immune related genes in the staghorn coral Acropora cervicornis infected with white band disease

Coral diseases are among the most serious threats to coral reefs worldwide, yet most coral diseases remain poorly understood. How the coral host responds to pathogen infection is an area where very little is known. Here we used next-generation RNA-sequencing (RNA-seq) to produce a transcriptome-wide profile of the immune response of the Staghorn coral Acropora cervicornis to White Band Disease (WBD) by comparing infected versus healthy (asymptomatic) coral tissues. The transcriptome of A. cervicornis was assembled de novo from A-tail selected Illumina mRNA-seq data from whole coral tissues, and parsed bioinformatically into coral and non-coral transcripts using existing Acropora genomes in order to identify putative coral transcripts. Differentially expressed transcripts were identified in the coral and non-coral datasets to identify genes that were up- and down-regulated due to disease infection. RNA-seq analyses indicate that infected corals exhibited significant changes in gene expression across 4% (1,805 out of 47,748 transcripts) of the coral transcriptome. The primary response to infection included transcripts involved in macrophage-mediated pathogen recognition and ROS production, two hallmarks of phagocytosis, as well as key mediators of apoptosis and calcium homeostasis. The strong up-regulation of the enzyme allene oxide synthase-lipoxygenase suggests a key role of the allene oxide pathway in coral immunity. Interestingly, none of the three primary innate immune pathways - Toll-like receptors (TLR), Complement, and prophenoloxydase pathways, were strongly associated with the response of A. cervicornis to infection. Five-hundred and fifty differentially expressed non-coral transcripts were classified as metazoan (n = 84), algal or plant (n = 52), fungi (n = 24) and protozoans (n = 13). None of the 52 putative Symbiodinium or algal transcript had any clear immune functions indicating that the immune response is driven by the coral host, and not its algal symbionts.

Towards an integrated network of coral immune mechanisms

Reef-building corals form bio-diverse marine ecosystems of high societal and economic value, but are in significant decline globally due, in part, to rapid climatic changes. As immunity is a predictor of coral disease and thermal stress susceptibility, a comprehensive understanding of this new field will likely provide a mechanistic explanation for ecological-scale trends in reef declines. Recently, several strides within coral immunology document defence mechanisms that are consistent with those of both invertebrates and vertebrates, and which span the recognition, signalling and effector response phases of innate immunity. However, many of these studies remain discrete and unincorporated into the wider fields of invertebrate immunology or coral biology. To encourage the rapid development of coral immunology, we comprehensively synthesize the current understanding of the field in the context of general invertebrate immunology, and highlight fundamental gaps in our knowledge. We propose a framework for future research that we hope will stimulate directional studies in this emerging field and lead to the elucidation of an integrated network of coral immune mechanisms. Once established, we are optimistic that coral immunology can be effectively applied to pertinent ecological questions, improve current prediction tools and aid conservation efforts.

Polydom/SVEP1 is a ligand for integrin α9β1

A variety of proteins, including tenascin-C and osteopontin, have been identified as ligands for integrin α9β1. However, their affinities for integrin α9β1 are apparently much lower than those of other integrins (e.g. α3β1, α5β1, and α8β1) for their specific ligands, leaving the possibility that physiological ligands for integrin α9β1 still remain unidentified. In this study, we found that polydom (also named SVEP1) mediates cell adhesion in an integrin α9β1-dependent manner and binds directly to recombinant integrin α9β1 with an affinity that far exceeds those of the known ligands. Using a series of recombinant polydom proteins with N-terminal deletions, we mapped the integrin-binding site to the 21st complement control protein domain. Alanine-scanning mutagenesis revealed that the EDDMMEVPY sequence (amino acids 2636-2644) in the 21st complement control protein domain was involved in the binding to integrin α9β1 and that Glu(2641) was the critical acidic residue for the integrin binding. The importance of this sequence was further confirmed by integrin binding inhibition assays using synthetic peptides. Immunohistochemical analyses of mouse embryonic tissues showed that polydom colocalized with integrin α9 in the stomach, intestine, and other organs. Furthermore, in situ integrin α9β1 binding assays using frozen mouse tissues showed that polydom accounts for most, but not all, of the integrin α9β1 ligands in tissues. Taken together, the present findings indicate that polydom is a hitherto unknown ligand for integrin α9β1 that functions as a physiological ligand in vivo.