The effect of antibiotic exposure on eicosanoid generation from arachidonic acid and gene expression in a primitive chordate, Branchiostoma belcheri.

Chloramphenicol (Chl) is an effective antimicrobial agent widely used in veterinary medicine and commonly used in fish. Its use is restricted in the clinic because of adverse effects on the immune system and oxidative stress in mammals. However, the effects of Chl treatment on invertebrates remain unclear. Amphioxus, a basal chordate, is an ideal model to study the origin and evolution of the vertebrate immune system as it has a primary vertebrate-like arachidonic acid (AA) metabolic system. Here, we combined transcriptomic and lipidomic approaches to investigate the immune system and observe the oxygenated metabolites of AA to address the antibiotic effects on amphioxus. Tissue necrosis of the gill slits occurred in the Chl-treated amphioxus, but fewer epithelial cells were lost when treated with both Chl and ampicillin (Amp). The immune related pathways were dysregulated in both of the antibiotic treatment groups. The Chl alone treatment resulted in immunosuppression with down-regulation of the innate immune genes. In contrast, the Chl + Amp treatment resulted in immunostimulation to some extent, as shown by KEGG clustering. Furthermore, Chl induced a 3-fold reduction in the level of the eicosanoids, while the Chl + Amp treatment resulted in 1.7-fold increase of eicosanoid level. Thus in amphioxus, Amp might relieve the effects of the Chl-induced immune suppression and increase the level of eicosanoids from AA. Finally, the oxygenated metabolites from AA might be crucial to evaluate the effects of Chl treatment in animals.

Diversity and composition of the bacterial community in Amphioxus feces.

Amphioxus is a typical filter feeder animal and is confronted with a complex bacterial community in the seawater of its habitat. It has evolved a strong innate immune system to cope with the external bacterial stimulation, however, the ecological system of the bacterial community in Amphioxus remains unknown. Through massive parallel 16S rRNA gene tag pyrosequencing, the investigation indicated that the composition of wild and lab-cultured Amphioxus fecal bacteria was complex with more than 85,000 sequence tags being assigned to 12/13 phyla. The bacterial diversity between the two fecal samples was similar according to OTU richness of V4 tag, Chao1 index, Shannon index and Rarefaction curves, however, the most prominent bacteria in wild feces were genera Pseudoalteromonas (gamma Proteobacteria) and Arcobacter (epsilon Proteobacteria); the highly abundant bacteria in lab-cultured feces were other groups, including Leisingera, Phaeobacter (alpha Proteobacteria), and Vibrio (gamma Proteobacteria). Such difference indicates the complex fecal bacteria with the potential for multi-stability. The bacteria of habitat with 28 assigned phyla had the higher bacterial diversity and species richness than both fecal bacteria. Shared bacteria between wild feces and its habitat reached to approximately 90% (153/169 genera) and 28% (153/548 genera), respectively. As speculative, the less diversity of both fecal bacteria compared to its habitat partly because Amphioxus lives buried and the feces will ultimately end up in the sediment. Therefore, our study comprehensively investigates the complex bacterial community of Amphioxus and provides evidence for understanding the relationship of this basal chordate with the environment.

A novel C1q family member of amphioxus was revealed to have a partial function of vertebrate C1q molecule.

C1q is the target recognition protein of the classical complement pathway and a major connecting link between innate and adaptive immunities. Its globular signature domain is also found in a variety of noncomplement protein that can be grouped together as a C1q family. In this study, we have cloned and identified a novel C1q family member in cephalochordate amphioxus and named it as AmphiC1q1. The high transcriptional levels of this gene were detected during all stages of embryonic development, and the section in situ hybridization demonstrated that AmphiC1q1 was mainly expressed in the ovary, intestine, and nerve system of mature individuals. The transcript of AmphiC1q1 was up-regulated by LPS and gram-negative bacteria, but hardly by lipoteichoic acid and Staphylococcus aureus. The recombinant AmphiC1q1 protein could not bind with N-acetyl-glucosamine and did not possess hemagglutinating activity, indicating that AmphiC1q1 could not act as its lamprey homologue. But both the full-length protein and its truncated globular domain of C1q protein could interact with LPS. Moreover, recombinant AmphiC1q1 protein could inhibit collagen-induced platelet aggregation, but the truncated globular C1q domain protein would not, indicating that the blocking activity of AmphiC1q1 protein was via the collagen region of the protein. Our study on the primitive form of C1q family in protochordate will shed a light on understanding the gradual functional evolution of C1q family and eventual formation of mammalian homologues.

A short-form C-type lectin from amphioxus acts as a direct microbial killing protein via interaction with peptidoglycan and glucan.

To investigate the evolution and immune function of C-type lectin in amphioxus, the primitive representative of the chordate phylum, we identified three C-type lectins consisting solely of a carbohydrate recognition domain and N-terminal signal peptide and found that they had distinct express patterns in special tissues and immune response to stimulations analyzed by quantitative real-time PCR. We characterized the biochemical and biological properties of AmphiCTL1, which was dramatically up-regulated in amphioxus challenged with Staphylococcus aureus, Saccharomyces cerevisiae, and zymosan. Immunohistochemistry demonstrated that the localization of AmphiCTL1 protein was exclusively detected in the inner folding tissues of the hepatic diverticulum. Recombinant AmphiCTL1 was characterized as a typical Ca2+-dependent carbohydrate-binding protein possessing hemagglutinating activity, preferentially bound to all examined four Gram-positive bacteria and two yeast strains, but had little binding activity toward four Gram-negative bacteria we tested. It aggregated S. aureus and S. cerevisiae in a Ca2+-dependent manner and specifically bound to insoluble peptidoglycan and glucan, but not to LPS, lipoteichoic acid, and mannan. Calcium increased the intensity of the interaction between AmphiCTL1 and those components, but was not essential. This lectin directly killed S. aureus and S. cerevisiae in a Ca2+-independent fashion, and its binding to microorganism cell wall polysaccharides such as peptidoglycan and glucan preceded microbial killing activity. These findings suggested that AmphiCTL1 acted as a direct microbial killing C-type lectin through binding microbial targets via interaction with peptidoglycan and glucan. Thus, AmphiCTL1 may be an evolutionarily primitive form of antimicrobial protein involved in lectin-mediated innate immunity.

Molecular and biochemical characterization of galectin from amphioxus: primitive galectin of chordates participated in the infection processes.

A novel F4-carbohydrate recognition domain (CRD)-linker-F3-CRD-type bi-CRD Branchiostoma belcheri tsingtauense galectin (BbtGal)-L together with its alternatively spliced mono-CRD isoform BbtGal-S from amphioxus intestine was encoded by a 9488-bp unique gene with eight exons and seven introns. The recombinant proteins of BbtGal were found to have beta-galactoside-binding activity, indicating that BbtGal was a member of the galectin family. Phylogenetic analysis of this gene along with its splicing form and genome structure suggested that the BbtGal gene was the primitive form of the chordate galectin family. Real-time polymerase chain reaction analyses (PCR) indicated that BbtGal mRNA was expressed during all stages of embryonic development. In terms of tissue distribution, BbtGal-L mRNA was mainly expressed in the immunity-related organs, such as hepatic diverticulum, intestine, and gill, but BbtGal-S was ubiquitously expressed in all tissues. The expression of BbtGal-L mRNA was elevated after acute challenge with various microorganisms, but BbtGal-L only bound to specific bacteria. The immune function of BbtGal was consistent with its localization both outside and inside the cell. Our study on amphioxus galectin may help further understanding of the evolution of chordate galectin in terms of host-pathogen interaction in the immune system.