C-type Lectin Binds to β-Integrin to Promote Hemocytic Phagocytosis in an Invertebrate

Phagocytosis is a conserved cellular response among metazoans. Opsonins are some molecules that label targets to increase their susceptibility to phagocytosis. Opsonins are usually captured by receptors on the surface of phagocytes. Our previous study found the C-type lectin FcLec4 from Chinese white shrimp Fenneropenaeus chinensis might function as an opsonin to facilitate bacterial clearance. In the present study we purified the native FcLec4 protein and confirmed its opsonic activity in the near relation, kuruma shrimp Marsupenaeus japonicus. The possible receptor of FcLec4 was identified as β-integrin by panning a T7 phage display library of shrimp hemocytes and then confirmed by co-immunoprecipitation assay. We further proved that the interaction between FcLec4 and β-integrin did not rely on the carbohydrate recognition domain but on the N terminus of FcLec4. In addition, inhibition of FcLec4 expression using RNAi delayed bacterial clearance, and β-integrin knockdown suppressed the opsonic activity of FcLec4. This study is the first to show the direct interaction between an opsonin and its receptor in crustaceans. Our study provides new insights into invertebrate phagocytosis and the functions of C-type lectins.     

对虾等甲壳类动物肠道与血淋巴菌群的组成、功能与动态平衡调控

对虾等甲壳类动物体内存在2个菌群:肠道菌群和血淋巴菌群。肠道菌群的种类和数量较多,而血淋巴菌群较少。两种菌群均包含益生菌和致病菌,在宿主体内代谢、营养和免疫反应中发挥重要功能。肠道菌群动态平衡的调控主要通过双氧化酶产生的活性氧来完成;血淋巴菌群通过C-型凝集素调控的抗菌肽表达及酚氧化酶原激活系统来维持其动态平衡。阐明对虾等甲壳类体内菌群的组成、功能和动态平衡调控的机理,可以为对虾等经济甲壳类健康养殖的微生态制剂开发和疾病控制提供指导。     

Human T Cell Activation Results in Extracellular Signal-regulated Kinase (ERK)-Calcineurin-dependent Exposure of Tn Antigen on the Cell Surface and Binding of the Macrophage Galactose-type Lectin (MGL)

The C-type lectin macrophage galactose-type lectin (MGL) exerts an immunosuppressive role reflected by its interaction with terminal GalNAc moieties, such as the Tn antigen, on CD45 of effector T cells, thereby down-regulating T cell receptor signaling, cytokine responses, and induction of T cell death. Here, we provide evidence for the pathways that control the specific expression of GalNAc moieties on human CD4⁺ T cells. GalNAc epitopes were readily detectable on the cell surface after T cell activation and required de novo protein synthesis. Expression of GalNAc-containing MGL ligands was completely dependent on PKC and did not involve NF-κB. Instead, activation of the downstream ERK MAPK pathway led to decreased mRNA levels and activity of the core 1 β3GalT enzyme and its chaperone Cosmc, favoring the expression of Tn antigen. In conclusion, expression of GalNAc moieties mirrors the T cell activation status, and thus only highly stimulated T cells are prone to the suppressive action of MGL.     

A C-type lectin like-domain (CTLD)-containing protein (PtLP) from the swimming crab Portunus trituberculatus

C-type lectins play important roles in the non-self innate immune system of invertebrates. In this study, we isolated the full-length cDNA of the C-type lectin like-domain (CTLD)-containing protein, designated PtLP, from the hepatopancreas of the swimming crab Portunus trituberculatus, one of the most common edible crabs of East Asia. The PtLP cDNA consists of 923bp and encodes a polypeptide of 164 amino acids containing a well-conserved C-type lectin like-domain (CTLD). The deduced amino acid sequence of PtLP shows 29-36% amino acid sequence identity to other crustacean C-type lectin sequences. A phylogenetic analysis revealed that PtLP is in a large cluster together with black tiger shrimp PmAV, a gene involved in virus resistance of shrimp, and all of the C-type lectins from the various shrimps. Quantitative RT-PCR analysis showed that the PtLP mRNA was expressed highly in hepatopancreas and moderately in gills, hemocytes, and ovary of normal swimming crabs.     

Molecular cloning, characterization and expression of a C-type lectin cDNA in Chinese mitten crab, Eriocheir sinensis

C-type lectins are pattern-recognition proteins which are functionally important for pathogen recognition and immune regulation in vertebrates and invertebrates. In this study, a lectin cDNA named as Es-Lectin was cloned and characterized from the Chinese mitten crab, Eriocheir sinensis. The full-length sequence of this Es-Lectin cDNA was 651 bp, including an open reading frame of 483 bp encoding 160 amino acids. The predicted molecular weight of the Es-Lectin was 11.8 kDa. A typical signal peptide of 21 amino acids was deduced at the N-terminus of the predicted protein. This Es-Lectin belongs to a C-type lectin and contains six cysteines, a conserved EPN motif (Glu-Pro-Asn) and an imperfect WND (Trp-Asn-Asp) motif (FND, Phe-Asn-Asp). This Es-Lectin had 55% and 32% identity with other two C-type lectins in E. sinensis, and 29-36% homology with decapods. Although the Es-Lectin was also expressed in gill, hepatopancreas, intestine, muscle and stomach, its expression in haemocytes was the greatest. The expression of Es-Lectins in haemocytes increased at 1.5 h after the Aeromonas hydrophila challenge. After a slight decrease, the Es-Lectin expression in haemocytes significantly increased at 48 h post-challenge. The diverse distribution of Es-Lectin and its enhancement by bacterial challenge indicate that C-type lectins are important in the innate immune response to bacterial infection, and can be activated for innate immune response in crab at the initial stage after pathogen infection.     

A novel C-type lectin (Cflec-3) from Chlamys farreri with three carbohydrate-recognition domains

C-type lectins are a superfamily of carbohydrate-recognition proteins which play crucial roles in the innate immunity. In this study, the gene of a C-type lectin with multiple carbohydrate-recognition domains (CRDs) from scallop Chlamys farreri (designated as Cflec-3) was cloned by rapid amplification of cDNA ends (RACE) approach based on expression sequence tag (EST) analysis. The full-length cDNA of Cflec-3 was of 2256 bp. The open reading frame encoded a polypeptide of 516 amino acids, including a signal sequence and three CRDs. The deduced amino acid sequence of Cflec-3 showed high similarity to members of C-type lectin superfamily. By fluorescent quantitative real-time PCR, the Cflec-3 mRNA was mainly detected in hepatopancreas, adductor, mantle, and marginally in gill, gonad and hemocytes of healthy scallops. After scallops were challenged by Listonella anguillarum, the mRNA level of Cflec-3 in hemocytes was up-regulated and was significantly higher than that of blank at 8 h and 12 h post-challenge. The function of Cflec-3 was investigated by recombination and expression of the cDNA fragment encoding its mature peptide in Escherichia coli BL21 (DE3)-pLysS. The recombined Cflec-3 (rCflec-3) agglutinated Gram-negative bacteria Pseudomonas stutzeri. The agglutinating activity was calcium-dependent and could be inhibited by d-mannose. These results collectively suggested that Cflec-3 was involved in the immune response against microbe infection and contributed to nonself-recognition and clearance of bacterial pathogens in scallop.     

Molecular cloning and expression of a C-type lectin gene from Venerupis philippinarum

C-type lectins have been demonstrated to play important roles in invertebrate innate immunity by mediating the recognition of pathogens and clearing the micro-invaders. In the present study, a C-type lectin gene (denoted as VpCTL) was identified from Venerupis philippinarum by expressed sequence tag and rapid amplification of cDNA ends approaches. The full-length cDNA of VpCTL consists of 904 nucleotides with an open-reading frame of 456 bp encoding a peptide of 151 amino acids. The deduced amino acid sequence of VpCTL shared high similarity with C-type lectins from other species. The C-type lectin domain and the characteristic EPN and WND motifs were found in VpCTL. The VpCTL mRNA was dominantly expressed in the haemocytes of the V. philippinarum. After Listonella anguillarum challenge, the temporal expression of VpCTL mRNA in haemocytes was increased by 97- and 84-fold at 48 and 96 h, respectively. With high expression level in haemocytes and hepatopancreas, and the up-regulated expression in haemocytes indicted that VpCTL was perhaps involved in the immune responses to L. anguillarum challenge.     

Characterization of a novel protein with homology to C-type lectins expressed by the Cotesia rubecula bracovirus in larvae of the lepidopteran host,Pieris rapae

Polydnaviruses are essential for the survival of many Ichneumonoid endoparasitoids, providing active immune suppression of the host in which parasitoid larvae develop. The Cotesia rubecula bracovirus is unique among polydnaviruses in that only four major genes are detected in parasitized host (Pieris rapae) tissues, and gene expression is transient. Here we describe a novel C. rubecula bracovirus gene (CrV3) encoding a lectin monomer composed of 159 amino acids, which has conserved residues consistent with invertebrate and mammalian C-type lectins. Bacterially expressed CrV3 agglutinated sheep red blood cells in a divalent ion-dependent but Ca2+-independent manner. Agglutination was inhibited by EDTA but not by biological concentrations of any saccharides tested. Two monomers of approximately 14 and approximately 17 kDa in size were identified on SDS-PAGE in parasitized P. rapae larvae. The 17-kDa monomer was found to be an N-glyscosylated form of the 14-kDa monomer. CrV3 is produced in infected hemocytes and fat body cells and subsequently secreted into hemolymph. We propose that CrV3 is a novel lectin, the first characterized from an invertebrate virus. CrV3 shows over 60% homology with hypothetical proteins isolated from polydnaviruses in two other Cotesia wasps, indicating that these proteins may also be C-type lectins and that a novel polydnavirus lectin family exists in Cotesia-associated bracoviruses. CrV3 is probably interacting with components in host hemolymph, resulting in suppression of the Pieris immune response. The high similarity of CrV3 with invertebrate lectins, as opposed to those from viruses, may indicate that some bracovirus functions were acquired from their hosts.     

Identification and tissue expression analysis of C-type lectin and galectin in the Pacific oyster, Crassostrea gigas

As an initial step in the functional analysis of lectins in the Pacific oyster, Crassostrea gigas, we attempted to obtain the full coding sequences of C. gigas lectins and conduct tissue expression analyses. To obtain lectin genes quickly, we identified C. gigas expressed sequence tags that coded for lectins in GenBank, and selected three encoding partial sequences of C-type lectin 1 (CgCLec-1), galectin (CgGal) and fucolectin. We obtained full open reading frames of CgCLec-1 and CgGal cDNAs by RACE-PCR. CgCLec-1 is a typical C-type lectin with a signal peptide and C-type lectin domain. CgCLec-1 mRNA was expressed only in specialized basophilic cells involved with digestive enzyme secretion in the digestive gland, suggesting that CgCLec-1 is secreted into the lumen of the digestive diverticula. CgGal is a prototype galectin with a single galactose-binding domain that was expressed in all of the tissues examined. As suggested for vertebrate galectin-1 (prototype galectin), CgGal may function in general cell activities such as cell adhesion. Fucolectin in C. gigas was expressed specifically in the gonads, indicating a possible function in gonadal development. CgCLec-1 and CgGal expression in hemocytes was not upregulated after injecting Vibrio tubiashii into adductor muscle, suggesting that bacterial infection does not induce synthesis of these lectins. Of the three lectins examined, CgCLec-1 is an interesting target for future investigations of innate immunity in the digestive system of C. gigas.     

Immulectin, an inducible C-type lectin from an insect, Manduca sexta, stimulates activation of plasma prophenol oxidase.

Immulectin, a C-type lectin from the tobacco hornworm, Manduca sexta, was cloned from a larval fat body cDNA library. The immulectin cDNA encodes a 309 residue polypeptide. Immulectin synthesis was induced by injection of killed gram-positive or gram-negative bacteria or yeast. After injection of bacteria, immulectin mRNA appeared in fat body and immulectin protein was detected in hemolymph. Immulectin contains two carbohydrate recognition domains. The carboxyl-terminal carbohydrate recognition domain is most similar (36% identity) to a lipopolysaccharide-binding protein from the American cockroach, Periplaneta americana. It also shares 26-35% identity to carbohydrate recognition domains of various mammalian C-type lectins. Two immulectin isoforms were identified in the hemolymph of bacteria-injected larvae. Recombinant immulectin agglutinated gram-positive and gram-negative bacteria and yeast. Addition of recombinant immulectin to M. sexta plasma stimulated activation of phenol oxidase. A combination of immulectin with lipopolysaccharide from E. coli activated phenol oxidase more rapidly and to a higher level than immulectin alone, whereas lipopolysaccharide by itself had little effect on phenol oxidase activation. Immulectin synthesized in response to bacterial or fungal infection may help to trigger protective responses in M. sexta in a manner similar to mannose-binding protein, a C-type lectin that functions in the mammalian innate immune system.     

Purification and characterization of a lectin from the banana shrimp Fenneropenaeus merguiensis hemolymph

A lectin from the hemolymph of the banana shrimp Fenneropenaeus merguiensis was purified by affinity chromatography on a fetuin-agarose column following by gel filtration on a Superose-12 column. The native molecular mass of purified F. merguiensis lectin (FmL) determined by gel filtration was 316.2 kDa and its carbohydrate content was estimated to be 4.4%. By SDS-PAGE analysis, purified FmL consisted of 32.3 kDa and 30.9 kDa subunits. These data suggest that this lectin is an oligomer. Two-dimensional electrophoresis showed that it had a pI value of 6.0 and was mainly composed of glycine, serine, histidine, glutamic acids and glutamine, with relatively lower amounts of methionine and tyrosine. Purified FmL expressed higher agglutination activity against rabbit and rat erythrocytes than with those from human, and its activity was Ca²⁺-dependent. The hemagglutinating activity of FmL was stable up to 55 °C and at pH 7.5–8. N-acetylated sugars, such as ManNAc, GlcNAc, GalNAc, and NeuNAc were strong inhibitors of the FmL induced hemagglutinating activity with NeuNAc being most effective. Porcine stomach mucin and fetuin were the most potent inhibitors of FmL. Purified FmL caused selective agglutination of Vibrio harveyi, and Vibrio parahemolyticus both pathogens of this Penaeus species and to a lesser extent Vibrio vulnificus but had no effect on the non-pathogenic strains; Vibrio cholerae, Salmonella typhi and Escherichia coli. Its bacterial agglutination was also completely inhibited by NeuNAc, mucin, fetuin and also anti-FmL antibody. This observation indicates that FmL may contribute to the defense response of this species of penaeid shrimps to potentially pathogenic bacteria.     

Molecular diversity of skin mucus lectins in fish

Among lectins in the skin mucus of fish, primary structures of four different types of lectin have been determined. Congerin from the conger eel Conger myriaster and AJL-1 from the Japanese eel Anguilla japonica were identified as galectin, characterized by its specific binding to β-galactoside. Eel has additionally a unique lectin, AJL-2, which has a highly conserved sequence of C-type lectins but displays Ca²⁺-independent activity. This is rational because the lectin exerts its function on the cutaneous surface, which is exposed to a Ca²⁺ scarce environment when the eel is in fresh water. The third type lectin is pufflectin, a mannose specific lectin in the skin mucus of pufferfish Takifugu rubripes. This lectin showed no sequence similarity with any known animal lectins but, surprisingly, shares sequence homology with mannose-binding lectins of monocotyledonous plants. The fourth lectin was found in the ponyfish Leiognathus nuchalis and exhibits homology with rhamnose-binding lectins known in eggs of some fish species. These lectins, except ponyfish lectin, showed agglutination of certain bacteria. In addition, pufflectin was found to bind to a parasitic trematode, Heterobothrium okamotoi. Taken together, these results demonstrate that skin mucus lectins in fish have wide molecular diversity.     

Two C-type lectins from shrimp Litopenaeus vannamei that might be involved in immune response against bacteria and virus

C-type lectins play crucial roles in innate immunity to recognize and eliminate pathogens efficiently. In the present study, two C-type lectins from shrimp Litopenaeus vannamei (designated as LvLectin-1 and LvLectin-2) were identified, and their expression patterns, both in tissues and toward pathogen stimulation, were then characterized. The full-length cDNA of LvLectin-1 and LvLectin-2 was 567 and 625 bp, containing an open reading frame (ORF) of 471 and 489 bp, respectively, and deduced amino acid sequences showed high similarity to other members of C-type lectin superfamily. Both two C-type lectins encoded a single carbohydrate-recognition domain (CRD). The motif of Ca²⁺ binding site 2 in CRD, which determined carbohydrate-binding specificity, was QPN (Gln¹²²-Pro¹²³-Asn¹²⁴) in LvLectin-1, but QPD (Gln¹²⁸-Pro¹²⁹-Asp¹³⁰) in LvLectin-2. Two C-type lectins exhibited similar tissue expression pattern, for their mRNA were both constitutively expressed in all tested tissues, including hepatopancreas, muscle, gill, hemocytes, gonad and heart, furthermore they were both mostly expressed in hepatopancreas, though the expression level of LvLectin-2 was much higher than LvLectin-1. The expression level of two C-type lectins mRNA in hemocytes varied greatly after the challenge of Listonella anguillarum or WSSV. After L. anguillarum challenge, the expression of both C-type lectins were significantly (P < 0.01) up-regulated compared with blank group, and LvLectin-1 exhibited higher level than LvLectin-2; while after the stimulation of WSSV, the expression of LvLectin-2 was significantly up-regulated at 6 h (P < 0.01) and 12 h (P < 0.05), but the expression level of LvLectin-1 down-regulated significantly (P < 0.01) to 0.4-fold at 6 and 12 h post-stimulation. The results indicated that the two C-type lectins might be involved in immune response toward pathogen infection, and they might perform different recognition specificity toward bacteria or virus.     

Distribution and Function of Macrophage Galactose-type C-type Lectin 2 (MGL2/CD301b): EFFICIENT UPTAKE AND PRESENTATION OF GLYCOSYLATED ANTIGENS BY DENDRITIC CELLS*

Dendritic cells (DCs) express cell surface lectins that are potentially involved in the recognition, uptake, and presentation of glycosylated foreign substances. A unique calcium-type (C-type) lectin, the macrophage galactose (Gal)-type C-type lectin (MGL/CD301) expressed on DCs, is thought to participate in the recognition of molecules from both altered self and pathogens due to its monosaccharide specificity for Gal and N-acetylgalactosamine (GalNAc). Although mice have two MGL genes, Mgl1 and Mgl2, their distinct roles have not been previously explored. The present report characterizes the properties of MGL2 by examining its distribution and its role in antigen presentation by DCs. We generated an MGL2-specific monoclonal antibody and examined MGL2 expression in tissues by immunohistochemistry and in isolated cells by flow cytometry. The cells reactive with this antibody were shown to be a portion of MGL1-expressing cells, mostly conventional DCs. Internalization of soluble polyacrylamide polymers (PAA) with α-GalNAc residues (GalNAc-PAA) by bone marrow-derived DCs (BM-DCs) was mediated by MGL2, as revealed by a comparison of Mgl1^−/− and Mgl2^−/− BM-DCs with wild-type BM-DCs. Biotinylated GalNAc-PAA conjugated to streptavidin (SAv) was more efficiently presented to SAv-primed T cells by BM-DCs than β-N-acetylglucosamine-PAA conjugated to SAv or SAv alone as shown by thymidine uptake and cytokine production. This is the first report that demonstrates the involvement of GalNAc residues in antigen uptake and presentation by DCs that lead to CD4⁺ T cell activation.